public static Vector2 InsideUnitCircle(this System.Random rand)
{
var angle = rand.NextFloat() * Mathf.PI * 2f;
var dist = rand.NextFloat().Sqrt();
return(new Vector2(Mathf.Cos(angle) * dist, Mathf.Sin(angle) * dist));
}
public static Vector3 NextVector2D(this Random random, Vector3 origin, float distance)
{
var doubleDistance = distance * 2;
return(origin + new Vector3(
random.NextFloat(doubleDistance) - distance,
random.NextFloat(doubleDistance) - distance,
0));
}
private Vector2 GetRandomInCircle(Vector2 center, float min, float max, System.Random random)
{
bool isPosX = random.Next(0, 2) == 0;
bool isPosY = random.Next(0, 2) == 0;
float x = isPosX ? random.NextFloat(center.x + min, center.x + max) :
random.NextFloat(center.x - min, center.x - max);
float y = isPosY ? random.NextFloat(center.y + min, center.y + max) :
random.NextFloat(center.y - min, center.y - max);
return(new Vector2(x, y));
}
public static void GetNoiseMap(
float[][] map, int dx = 0, int dy = 0,
int octaves = 1, float persistance = 0.5f, float lacunarity = 2.0f,
float sx = 1.0f, float sy = 1.0f, int seed = 0
)
{
var random = new Random(seed);
var width = map.GetWidth();
var height = map.GetHeight();
var pmin = 0.0f;
var pmax = 1.0f;
for (uint i = 1; i < octaves; ++i)
{
var ppow = Mathx.Pow(persistance, i);
pmin += ppow * 0.25f;
pmax += ppow * 0.75f;
}
var rdx = random.NextFloat(-99999.0f, +99999.0f);
var rdy = random.NextFloat(-99999.0f, +99999.0f);
var fx = 1.0f / (sx * width);
var fy = 1.0f / (sy * height);
for (int y = 0; y < height; ++y)
{
for (int x = 0; x < width; ++x)
{
float amplitude = 1.0f;
float frequency = 1.0f;
float value = 0.0f;
for (int i = 0; i < octaves; ++i)
{
float sampleX = ((x - dx) * fx) * frequency + rdx;
float sampleY = ((y - dy) * fy) * frequency + rdy;
float pv = Mathf.PerlinNoise(sampleX, sampleY);
value += pv * amplitude;
amplitude *= persistance;
frequency *= lacunarity;
}
map[x][y] = Mathf.SmoothStep(pmin, pmax, value);
}
}
}
/**
* \brief
* Computes a random value from the standard normal distribution,
* using sampling from a uniform distribution.
*/
public static float NextGaussianDouble(this System.Random r)
{
float u, v, S;
do
{
u = 2.0f * r.NextFloat() - 1.0f;
v = 2.0f * r.NextFloat() - 1.0f;
S = u * u + v * v;
}while (S >= 1.0f);
float fac = Mathf.Sqrt(-2.0f * Mathf.Log(S) / S);
return(u * fac);
}
public static Vector3 PointOnSphere(this Random random, float radius = 1f)
{
var x = random.NextFloat();
var y = random.NextFloat();
var z = random.NextFloat();
if (x == 0 && y == 0 && z == 0)
{
return(Vector3.forward * radius);
}
var lenInv = 1f / Mathf.Sqrt(x * x + y * y + z * z);
return(new Vector3(x * lenInv, y * lenInv, z * lenInv) * radius);
}
void AddNextRoomNode(IsaacRoomFactory roomFactory,
Queue <LevelGrowthNode> queue, HashSet <IntVector> visited, int maxRooms,
IsaacRoom parentRoom, int direction, float probability)
{
if (random.NextFloat() > probability)
{
return;
}
if (rooms.Count >= maxRooms)
{
return;
}
var nextPosition = parentRoom.position + directions[direction];
if (!visited.Contains(nextPosition))
{
var nextRoom = roomFactory.CreateRoom(nextPosition);
rooms.Add(nextRoom);
var nextNode = new LevelGrowthNode();
nextNode.room = nextRoom;
nextNode.moveDirection = direction;
queue.Enqueue(nextNode);
visited.Add(nextPosition);
// Create a door between the two rooms
ConnectRoomsWithDoors(parentRoom, nextRoom);
}
else
{
// See if we can connect to the other room
// first make sure we don't already have a connection between the two
var nextRoom = GetRoomAt(nextPosition);
if (!ContainsDoorBetween(parentRoom.roomId, nextRoom.roomId))
{
float loopTest = random.NextFloat();
if (loopTest < isaacConfig.cycleProbability)
{
// Connect the two rooms together
if (nextRoom != null)
{
// Create a door between the two rooms
ConnectRoomsWithDoors(parentRoom, nextRoom);
}
}
}
}
}
/// <summary>
/// This function assumes that the cell is big enough to split.
/// Make sure to call CanSplit function before calling this
/// </summary>
public void Split(float splitRatio, System.Random random)
{
if (bounds.Width == bounds.Length)
{
horizontalSplit = random.NextFloat() < 0.5f;
}
else
{
horizontalSplit = (bounds.Width > bounds.Length);
}
int totalSize = horizontalSplit ? bounds.Width : bounds.Length;
int left = Mathf.RoundToInt(totalSize * splitRatio);
int right = totalSize - left;
var child0 = new BSPNodeObject();
child0.parent = this;
child0.padding = padding;
child0.depthFromRoot = depthFromRoot + 1;
var child1 = new BSPNodeObject();
child1.parent = this;
child1.padding = padding;
child1.depthFromRoot = depthFromRoot + 1;
var loc0 = bounds.Location;
var size0 = bounds.Size;
var loc1 = bounds.Location;
var size1 = bounds.Size;
if (horizontalSplit)
{
size0.x = left;
loc1.x += left;
size1.x = right;
}
else
{
size0.z = left;
loc1.z += left;
size1.z = right;
}
child0.bounds = new Rectangle(loc0, size0);
child1.bounds = new Rectangle(loc1, size1);
children = new BSPNodeObject[] { child0, child1 };
}
public async UniTask <int[, ]> Spawn(int mapWidth = 22, int mapLength = 22, float fillRatio = 10f)
{
System.Random prng = new System.Random(seed.GetHashCode());
this.transform.DestroyChildrenImmediate();
var map = new int[mapWidth, mapLength];
mapObjects = new List <MapObject>();
map.Fill(1);
for (int i = 0; i < mapWidth; i++)
{
for (int j = 0; j < mapLength; j++)
{
//outerWall
if (i == 0 || j == 0 || i == mapWidth - 1 || j == mapLength - 1)
{
map[i, j] = 0;
var wall = Instantiate(outerWallPrefab);
wall.transform.position = new Vector3(i, 1f, j);
wall.transform.parent = this.transform;
var mapObejct = wall.GetComponent <MapObject>();
mapObjects.Add(mapObejct);
mapObejct.InitObject();
}
else
{
var ground = Instantiate(groundBlockPrefab);
ground.transform.position = new Vector3(i, 0f, j);
ground.transform.parent = this.transform;
var mapObejct = ground.GetComponent <MapObject>();
mapObjects.Add(mapObejct);
mapObejct.InitObject();
//Obstacle
if (prng.NextFloat(0f, 100f) < fillRatio && (CharacterManager.Instance.initialLocation.X != i && CharacterManager.Instance.initialLocation.Y != j))
{
map[i, j] = 0;
var obstacle = Instantiate(obstaclePrefab, new Vector3(i, 1f, j), Quaternion.identity);
obstacle.transform.parent = this.transform;
var mapObejcts = obstacle.GetComponent <MapObject>();
mapObejcts.height = Random.Range(1, 4);
mapObjects.Add(mapObejcts);
mapObejcts.InitObject();
}
}
}
}
"Map Spawn Complete".Log();
return(map);
}
public static Tuple <Tuple <float, float>, Tuple <Tuple <float, float>, Tuple <Tuple <float, float>, Unit> > > MakeRandomBody()
{
const double maxValue = 50.0;
__opComma <float, float> fst;
unit unit;
__opComma <Tuple <float, float>, Unit> acceleration = new __opComma <Tuple <float, float>, Unit>();
fst = new __opComma <float, float>();
unit = new unit();
fst.__arg0 = r.NextFloat(maxValue);
fst.__arg1 = r.NextFloat(maxValue);
acceleration.__arg0 = fst;
acceleration.__arg1 = unit;
__opComma <Tuple <float, float>, Tuple <Tuple <float, float>, Unit> > velocity = new __opComma <Tuple <float, float>, Tuple <Tuple <float, float>, Unit> >();
fst = new __opComma <float, float>();
fst.__arg0 = r.NextFloat(maxValue);
fst.__arg1 = r.NextFloat(maxValue);
velocity.__arg0 = fst;
velocity.__arg1 = acceleration;
__opComma <Tuple <float, float>, Tuple <Tuple <float, float>, Tuple <Tuple <float, float>, Unit> > > position = new __opComma <Tuple <float, float>, Tuple <Tuple <float, float>, Tuple <Tuple <float, float>, Unit> > >();
fst = new __opComma <float, float>();
fst.__arg0 = r.NextFloat(maxValue);
fst.__arg1 = r.NextFloat(maxValue);
position.__arg0 = fst;
position.__arg1 = velocity;
return(position);
}
public static void GetRandomMap(bool[][] map, float fill = 0.5f, int seed = 0)
{
var random = new Random(seed);
var width = map.GetWidth();
var height = map.GetHeight();
for (int y = 0; y < height; ++y)
{
for (int x = 0; x < width; ++x)
{
var rv = random.NextFloat();
map[x][y] = rv < fill;
}
}
}
protected override void Process()
{
output = new EntityCollection();
foreach (KeyValuePair <Coordinate, HashSet <string> > chunk in entities.AllChunks)
{
System.Random RNG = graph.ChunkRandoms[chunk.Key];
foreach (string entityID in chunk.Value)
{
if (!entities.TryGetEntity(entityID, out IEntity entity))
{
continue;
}
if (RNG.NextFloat(0, 1) > sampler.SamplePosition(entity.Position))
{
output.AddEntity(entity);
}
}
}
}
public static void Shuffle <T>(IList <T> list, System.Random rd)
{
if (list.Count <= 1)
{
return;
}
int currentIndex = list.Count;
int randomIndex = 0;
T temporaryValue;
while (currentIndex > 0)
{
randomIndex = Mathf.FloorToInt(rd.NextFloat() * currentIndex);
currentIndex--;
temporaryValue = list[currentIndex];
if (list.Count <= randomIndex)
{
continue; // for weird situations on shutdown or so.
}
list[currentIndex] = list[randomIndex];
list[randomIndex] = temporaryValue;
}
}
void GenerateLevelLayout()
{
var tiles = new List <MarioTile> ();
marioModel.levelWidth = random.Next(marioConfig.minLength, marioConfig.maxLength);
bool addingGap = false;
int targetGapDistance = 0;
int currentGapDistance = 0;
int currentNonGapDistance = 0;
int y = 0;
for (int x = 0; x < marioModel.levelWidth; x++)
{
var position = new IntVector(x, y, 0);
if (!addingGap)
{
if (x >= 2)
{
bool changeHeight = random.NextFloat() < marioConfig.heightVariationProbablity;
if (changeHeight)
{
bool moveUp = random.NextFloat() < 0.5f;
y += moveUp ? 1 : -1;
}
}
// Create a tile here
var tile = new MarioTile();
tile.position = position;
tile.tileType = MarioTileType.Ground;
tiles.Add(tile);
currentNonGapDistance++;
if (currentNonGapDistance >= marioConfig.minNonGap)
{
// Check if we need to add a gap
addingGap = random.NextFloat() < marioConfig.gapProbability;
if (addingGap)
{
currentGapDistance = 0;
targetGapDistance = random.Next(marioConfig.minGap, marioConfig.maxGap);
}
}
}
else
{
bool corridor = targetGapDistance > marioConfig.maxJumpTileDistance;
// We are adding a gap
var tile = new MarioTile();
tile.position = position;
tile.tileType = corridor ? MarioTileType.Corridor : MarioTileType.Gap;
tiles.Add(tile);
currentGapDistance++;
if (currentGapDistance >= targetGapDistance)
{
addingGap = false;
currentNonGapDistance = 0;
}
}
}
marioModel.tiles = tiles.ToArray();
}
private float getRandomPs()
{
return(r.NextFloat(rMin, rMax));
}
/// <summary>
/// Generate a layout and save it in the model
/// </summary>
void GenerateCityLayout()
{
var roadGraphSettings = new RoadGraphBuilderSettings();
roadGraphSettings.interNodeDistance = cityConfig.interNodeDistance;
var roadGraphBuilder = new RoadGraphBuilder(roadGraphSettings);
float startRadius = cityConfig.startRadius;
float endRadius = cityConfig.endRadius;
var center = Vector3.zero;
float mainRoadStrength = cityConfig.mainRoadStrength;
float sideRoadStrength = cityConfig.sideRoadStrength;
float interRingDistance = (endRadius - startRadius) / (cityConfig.numRings - 1);
// Draw the city rings
{
float ringRadius = startRadius;
for (int r = 0; r < cityConfig.numRings; r++)
{
roadGraphBuilder.CreateCircle(center, ringRadius, mainRoadStrength);
if (r < cityConfig.numRings - 1)
{
float ringLaneRadius = ringRadius + interRingDistance / 2.0f;
roadGraphBuilder.CreateCircle(center, ringLaneRadius, sideRoadStrength);
}
ringRadius += interRingDistance;
}
}
// Draw the ray lanes ejecting out from the center
float interRayAngle = Mathf.PI * 2 / cityConfig.numRays;
for (int i = 0; i < cityConfig.numRays; i++)
{
float ringRadius = startRadius;
int mainSegmentToRemove = random.Next() % (cityConfig.numRings - 1);
for (int r = 0; r < cityConfig.numRings - 1; r++)
{
float nextRingRadius = ringRadius + interRingDistance;
bool bDrawMainSegment = (r != mainSegmentToRemove);
if (bDrawMainSegment)
{
float angle = i * interRayAngle;
var direction = new Vector3(Mathf.Cos(angle), 0, Mathf.Sin(angle));
float midRingRadius = ringRadius + (nextRingRadius - ringRadius) / 2.0f;
var start = center + direction * ringRadius;
var end = center + direction * midRingRadius;
roadGraphBuilder.CreateLine(start, end, mainRoadStrength);
start = center + direction * midRingRadius;
end = center + direction * nextRingRadius;
roadGraphBuilder.CreateLine(start, end, mainRoadStrength);
}
// Draw the side segments
{
float interSideRayAngle = interRayAngle / (r + 2);
float sideRayAngle = i * interRayAngle;
float interSideRingDistance = interRingDistance / 2.0f;
for (int si = 0; si <= r; si++)
{
sideRayAngle += interSideRayAngle;
for (int t = 0; t < 2; t++)
{
bool bRemoveSideSegment = (random.NextFloat() < cityConfig.sideRoadRemovalProbability);
if (!bRemoveSideSegment)
{
float perimeter = Mathf.PI * 2 * ringRadius;
float angleRandomization = cityConfig.randomSideLaneOffsetAngle * Mathf.Deg2Rad / perimeter;
float randomValue = random.NextFloat() * 2 - 1;
float randomizedAngle = sideRayAngle + angleRandomization * randomValue;
float laneStartRadius = ringRadius + interSideRingDistance * t;
float laneEndRadius = ringRadius + interSideRingDistance * (t + 1);
var direction = new Vector3(Mathf.Cos(randomizedAngle), 0, Mathf.Sin(randomizedAngle));
var start = center + direction * laneStartRadius;
var end = center + direction * laneEndRadius;
roadGraphBuilder.CreateLine(start, end, sideRoadStrength);
}
}
}
}
ringRadius = nextRingRadius;
}
}
cityModel.roadGraph = roadGraphBuilder.BakeRoadGraph();
var layoutBuilder = new RoadLayoutBuilder(cityModel.roadGraph, cityConfig.roadMesh);
layoutBuilder.RoadBlockLayoutBuilt += LayoutBuilder_RoadBlockLayoutBuilt;
cityModel.layoutGraph = layoutBuilder.BakeLayoutGraph();
}
public static float NextFloat(this Random random, float min, float max)
{
return(min + (max - min) * random.NextFloat());
}
/// <summary>
/// Generate a layout and save it in the model
/// </summary>
void GenerateCityLayout()
{
var width = random.Range(demoConfig.minSize, demoConfig.maxSize);
var length = random.Range(demoConfig.minSize, demoConfig.maxSize);
demoModel.CityWidth = width;
demoModel.CityHeight = length;
demoModel.Cells = new SimpleCityCell[width, length];
for (int x = 0; x < width; x++)
{
for (int z = 0; z < length; z++)
{
var cell = new SimpleCityCell();
cell.Position = new IntVector(x, 0, z);
cell.CellType = SimpleCityCellType.House;
cell.Rotation = GetRandomRotation();
demoModel.Cells[x, z] = cell;
}
}
// Build a road network by removing some houses
// First build roads along the edge of the map
for (int x = 0; x < width; x++)
{
MakeRoad(x, 0);
MakeRoad(x, length - 1);
}
for (int z = 0; z < length; z++)
{
MakeRoad(0, z);
MakeRoad(width - 1, z);
}
// Create roads in-between
for (int x = GetRandomBlockSize() + 1; x < width; x += GetRandomBlockSize() + 1)
{
if (width - x <= 2)
{
continue;
}
for (int z = 0; z < length; z++)
{
MakeRoad(x, z);
}
}
for (int z = GetRandomBlockSize() + 1; z < length; z += GetRandomBlockSize() + 1)
{
if (length - z <= 2)
{
continue;
}
for (int x = 0; x < width; x++)
{
MakeRoad(x, z);
}
}
// Insert 2x houses (bigger houses)
for (int x = 0; x < width; x++)
{
for (int z = 0; z < length; z++)
{
if (CanContainBiggerHouse(x, z))
{
if (random.NextFloat() < demoConfig.biggerHouseProbability)
{
InsertBiggerHouse(x, z);
}
}
}
}
for (int x = 0; x < width; x++)
{
for (int z = 0; z < length; z++)
{
var cell = demoModel.Cells[x, z];
if (cell.CellType == SimpleCityCellType.House)
{
FaceHouseTowardsRoad(cell);
}
}
}
// Create padding cells
var padding = demoConfig.cityWallPadding;
var paddedCells = new List <SimpleCityCell>();
for (int p = 1; p <= padding; p++)
{
var currentPadding = p;
var sx = -currentPadding;
var sz = -currentPadding;
var ex = width + currentPadding - 1;
var ez = length + currentPadding - 1;
// Fill it with city wall padding marker
for (int x = sx; x < ex; x++)
{
SimpleCityCellType cellType = SimpleCityCellType.CityWallPadding;
paddedCells.Add(CreateCell(x, sz, cellType));
paddedCells.Add(CreateCell(x, ez, cellType));
}
for (int z = sz; z < ez; z++)
{
SimpleCityCellType cellType = SimpleCityCellType.CityWallPadding;
paddedCells.Add(CreateCell(sx, z, cellType));
paddedCells.Add(CreateCell(ex, z, cellType));
}
}
demoModel.WallPaddingCells = paddedCells.ToArray();
}
public void Generate(ValueStore keyStore)
{
Reset ();
if (park == null) return;
var seed = 0;
// Generate a random seed.
foreach (char c in keyStore.Seed) {
seed += (int)c;
}
_waterRandom = new SRandom(seed);
_treeRandom = new SRandom(seed);
for (var z = 0; z <= park.zSize; z++)
{
for (var x = 0; x <= park.xSize; x++)
{
// Calculate height of terrain patch based on perlin noise.
var y = (Mathf.PerlinNoise(x/(park.xSize* keyStore.PlainScale) + seed, z/(park.zSize*keyStore.PlainScale) + seed)*
(1 + keyStore.DitchRatio)) -
(float)keyStore.DitchRatio;
if (y < 0 && keyStore.DitchRatio != 0)
y /= keyStore.DitchRatio;
y = y*(y < 0 ? keyStore.MaxDepth : (float)keyStore.MaxHeight);
y = y > 0 ? Mathf.FloorToInt(y) : Mathf.CeilToInt(y);
// Generate terrain type for the terrain patch based on perlin noise.
if (keyStore.GenerateTerrainType)
{
var patch = park.getTerrain(x, z);
if (patch != null)
{
var types = ScriptableSingleton<AssetManager>.Instance.terrainTypes.Length;
var terrainTypeIndex = Mathf.PerlinNoise(x/(park.xSize*keyStore.TerrainScale ) + seed,
z/(park.xSize*keyStore.TerrainScale) + seed);
patch.TerrainType = Mathf.FloorToInt(Mathf.Abs(terrainTypeIndex - 0.5f)*types);
}
}
// Limit heights near road.
var roadWidth = Mathf.Max(MIN_ROAD_WIDTH, keyStore.EntranceClearance);
if (x < roadWidth)
continue;
y = Mathf.Clamp(y, roadWidth - x, x - roadWidth);
// Limit heights near entrance.
var distanceToEntrance = Vector3.Distance(park.parkEntrances.First().transform.position,
new Vector3(x, GROUND_HEIGHT, z));
if (distanceToEntrance < roadWidth)
continue;
// If this location should be raised, change the hight of the patch and the ones around.
if (y != 0)
for (var cornerIndex = 0; cornerIndex < 4; cornerIndex++)
{
var ox = cornerIndex == 1 || cornerIndex == 2 ? 1 : 0;
var oz = cornerIndex == 2 || cornerIndex == 3 ? 1 : 0;
var patch = park.getTerrain(x - ox, z - oz);
if (patch != null)
{
var current = patch.h[cornerIndex] - DEF_HEIGHT;
patch.smoothChangeHeight(park, cornerIndex, y - current);
}
}
}
}
// Randomly flood the map.
for (var i = 0; i < keyStore.FloodRounds; i++)
{
var x = Mathf.RoundToInt(_waterRandom.NextFloat(keyStore.EntranceClearance, park.xSize));
var z = Mathf.RoundToInt(_waterRandom.NextFloat(0, park.zSize));
var patch = park.getTerrain(x, z);
if (patch == null || patch.hasWater() || patch.getLowestHeight() >= GROUND_HEIGHT) continue;
WaterFlooding.flood(new Vector3(x, GROUND_HEIGHT - WATTER_OFFSET, z));
}
// Randomly spawn a forrest.
for (var i = 0; i < keyStore.TreeCount; i++)
{
var x = Mathf.RoundToInt(_treeRandom.NextFloat(keyStore.EntranceClearance, park.xSize -PARK_FENCE_OFFSET));
var z = Mathf.RoundToInt(_treeRandom.NextFloat(PARK_FENCE_OFFSET, park.zSize - PARK_FENCE_OFFSET));
var patch = park.getTerrain(x, z);
if (patch == null || patch.hasWater()) continue;
var y = patch.getHeighestHeight();
if (y != patch.getLowestHeight()) continue;
TreeEntity fir = null;
foreach (var o in ScriptableSingleton<AssetManager>.Instance.getDecoObjects())
if (o.getName().StartsWith("Fir") && o is TreeEntity) fir = o as TreeEntity;
if (fir != null)
{
var tree = ConfigWindow.Instantiate(fir);
tree.transform.position = new Vector3(x, y, z);
tree.transform.forward = Vector3.forward;
tree.Initialize();
tree.startAnimateSpawn(Vector3.zero);
}
}
}
// This is called by the builders that do not support theming
public override void BuildNonThemedDungeon(DungeonSceneProvider sceneProvider)
{
random = new System.Random((int)config.Seed);
propSockets.Clear();
// We know that the dungeon prefab would have the appropriate config and models attached to it
// Cast and save it for future reference
snapConfig = config as SnapConfig;
snapModel = model as SnapModel;
if (snapConfig == null)
{
Debug.LogError("No snap config script found in dungeon game object");
return;
}
if (snapModel == null)
{
Debug.LogError("No snap model script found in dungeon game object");
return;
}
// Generate the module info list
var ModuleInfos = new List <ModuleInfo>();
{
var RegisteredModuleList = new List <GameObject>();
RegisteredModuleList.AddRange(snapConfig.Modules);
RegisteredModuleList.AddRange(snapConfig.StartModules);
RegisteredModuleList.AddRange(snapConfig.EndModules);
RegisteredModuleList.AddRange(snapConfig.BranchEndModules);
var RegisteredModules = new HashSet <GameObject>(RegisteredModuleList);
foreach (var RegisteredModule in RegisteredModules)
{
var moduleInfo = GenerateModuleInfo(RegisteredModule);
ModuleInfos.Add(moduleInfo);
}
}
var StartNode = new ModuleGrowthNode();
StartNode.IncomingModuleDoorIndex = -1;
StartNode.startNode = true;
StartNode.ModuleTransform = Matrix4x4.identity;
var OccupiedBounds = new List <Bounds>();
var LayoutBuildState = new SnapLayoutBuildState();
LayoutBuildState.ModuleInfoList = ModuleInfos;
// Build the main branch
ModuleBuildNode BuildNode = BuildLayoutRecursive(StartNode, OccupiedBounds, 1, snapConfig.MainBranchSize, true, false, LayoutBuildState);
// Build the side branches
{
var MainBranchNodes = new List <ModuleBuildNode>();
// Grab the nodes in the main branch
{
ModuleBuildNode BranchNode = BuildNode;
while (BranchNode != null)
{
BranchNode.bMainBranch = true;
MainBranchNodes.Add(BranchNode);
// Move forward
if (BranchNode.Extensions.Count == 0)
{
break;
}
BranchNode = BranchNode.Extensions[0];
}
}
// Iterate through the nodes in the main branch and start branching out
for (int i = 0; i < MainBranchNodes.Count; i++)
{
ModuleBuildNode BranchStartNode = MainBranchNodes[i];
ModuleBuildNode BranchNextNode = i + 1 < MainBranchNodes.Count ? MainBranchNodes[i + 1] : null;
ModuleInfo BranchModule = BranchStartNode.Module;
int IncomingDoorIndex = BranchStartNode.IncomingDoorIndex;
int OutgoingDoorIndex = BranchNextNode != null ? BranchNextNode.IncomingDoorIndex : -1;
int NumDoors = BranchModule.ConnectionTransforms.Length;
for (int DoorIndex = 0; DoorIndex < NumDoors; DoorIndex++)
{
if (DoorIndex == IncomingDoorIndex || DoorIndex == OutgoingDoorIndex)
{
// These doors are already extended
continue;
}
bool bGrowFromHere = (random.NextFloat() < snapConfig.SideBranchProbability);
if (!bGrowFromHere)
{
continue;
}
// TODO: Optimize me. it recalculates the the bounds for the whole tree for every main branch node
OccupiedBounds.Clear();
CalculateOccupiedBounds(BuildNode, OccupiedBounds);
var BranchGrowNode = new ModuleGrowthNode();
BranchGrowNode.IncomingModuleDoorIndex = DoorIndex;
BranchGrowNode.IncomingModule = BranchStartNode.Module;
BranchGrowNode.ModuleTransform = BranchStartNode.AttachmentConfig.AttachedModuleTransform;
LayoutBuildState = new SnapLayoutBuildState();
LayoutBuildState.ModuleInfoList = ModuleInfos;
ModuleBuildNode BranchBuildNode = BuildLayoutRecursive(BranchGrowNode, OccupiedBounds, 1, snapConfig.SideBranchSize, false, false, LayoutBuildState);
if (BranchBuildNode != null)
{
// Make sure we don't end up with an undesirable leaf node
if (BranchBuildNode.Extensions.Count == 0 && BranchBuildNode.Module != null && snapConfig.SideBranchSize > 1)
{
continue;
}
BranchBuildNode.Parent = BranchStartNode;
BranchStartNode.Extensions.Add(BranchBuildNode);
}
}
}
}
snapModel.ResetModel();
sceneProvider.OnDungeonBuildStart();
// Spawn the modules and register them in the model
{
var spawnedModuleList = new List <SnapModule>();
TraverseTree(BuildNode, delegate(ModuleBuildNode Node)
{
// Spawn a module at this location
ModuleInfo moduleInfo = Node.Module;
var templateInfo = new GameObjectPropTypeData();
templateInfo.Template = moduleInfo.ModuleTemplate;
templateInfo.NodeId = moduleInfo.ModuleGuid.ToString();
templateInfo.Offset = Matrix4x4.identity;
templateInfo.IsStaticObject = true;
Node.spawnedModule = sceneProvider.AddGameObject(templateInfo, Node.AttachmentConfig.AttachedModuleTransform);
// Register this in the model
var snapModule = new SnapModule();
snapModule.InstanceID = Node.ModuleInstanceID;
spawnedModuleList.Add(snapModule);
});
snapModel.modules = spawnedModuleList.ToArray();
}
// Generate the list of connections
{
var connectionList = new List <SnapModuleConnection>();
TraverseTree(BuildNode, delegate(ModuleBuildNode Node)
{
if (Node.Parent != null)
{
var Connection = new SnapModuleConnection();
Connection.ModuleAInstanceID = Node.ModuleInstanceID;
Connection.DoorAIndex = Node.AttachmentConfig.AttachedModuleDoorIndex;
Connection.ModuleBInstanceID = Node.Parent.ModuleInstanceID;
Connection.DoorBIndex = Node.IncomingDoorIndex;
connectionList.Add(Connection);
}
});
snapModel.connections = connectionList.ToArray();
}
sceneProvider.OnDungeonBuildStop();
FixupDoorStates(BuildNode);
}
public static float NextFloatRange(this System.Random random, float min, float max)
{
float f = random.NextFloat();
return(MathW.Remap(f, 0, 1, min, max));
}
/// <summary>
/// Generate a layout and save it in the model
/// </summary>
void GenerateCityLayout()
{
var width = random.Range(demoConfig.minSize, demoConfig.maxSize);
var length = random.Range(demoConfig.minSize, demoConfig.maxSize);
demoModel.CityWidth = width;
demoModel.CityHeight = length;
demoModel.Cells = new SimpleCityCell[width, length];
for (int x = 0; x < width; x++)
{
for (int z = 0; z < length; z++)
{
var cell = new SimpleCityCell();
cell.Position = new IntVector(x, 0, z);
cell.CellType = SimpleCityCellType.House;
cell.Rotation = GetRandomRotation();
demoModel.Cells[x, z] = cell;
}
}
// Build a road network by removing some houses
// First build roads along the edge of the map
for (int x = 0; x < width; x++)
{
MakeRoad(x, 0);
MakeRoad(x, length - 1);
}
for (int z = 0; z < length; z++)
{
MakeRoad(0, z);
MakeRoad(width - 1, z);
}
// Create roads in-between
for (int x = GetRandomBlockSize() + 1; x < width; x += GetRandomBlockSize() + 1)
{
if (width - x <= 2)
{
continue;
}
for (int z = 0; z < length; z++)
{
MakeRoad(x, z);
}
}
for (int z = GetRandomBlockSize() + 1; z < length; z += GetRandomBlockSize() + 1)
{
if (length - z <= 2)
{
continue;
}
for (int x = 0; x < width; x++)
{
MakeRoad(x, z);
}
}
RemoveRoadEdges();
// Insert bigger houses
for (int x = 0; x < width; x++)
{
for (int z = 0; z < length; z++)
{
foreach (var blockDimension in demoConfig.customBlockDimensions)
{
bool bProcess = random.NextFloat() < blockDimension.probability;
if (!bProcess)
{
continue;
}
int BlockWidth = blockDimension.sizeX;
int BlockHeight = blockDimension.sizeZ;
InsertHouseDelegate InsertHouse = delegate() {
if (CanContainBiggerHouse(x, z, BlockWidth, BlockHeight))
{
if (random.NextFloat() < demoConfig.biggerHouseProbability)
{
InsertBiggerHouse(x, z, BlockWidth, BlockHeight, 0, blockDimension.markerName);
}
}
};
InsertHouseDelegate InsertHouse90 = delegate()
{
// Try the 90 degrees rotated version
if (CanContainBiggerHouse(x, z, BlockHeight, BlockWidth))
{
if (random.NextFloat() < demoConfig.biggerHouseProbability)
{
InsertBiggerHouse(x, z, BlockHeight, BlockWidth, 90, blockDimension.markerName);
}
}
};
if (random.NextFloat() < 0.5f)
{
InsertHouse();
InsertHouse90();
}
else
{
InsertHouse90();
InsertHouse();
}
}
}
}
for (int x = 0; x < width; x++)
{
for (int z = 0; z < length; z++)
{
var cell = demoModel.Cells[x, z];
if (cell.CellType == SimpleCityCellType.House)
{
FaceHouseTowardsRoad(cell);
}
}
}
// Create padding cells
var padding = demoConfig.cityWallPadding;
var paddedCells = new List <SimpleCityCell>();
for (int p = 1; p <= padding; p++)
{
var currentPadding = p;
var sx = -currentPadding;
var sz = -currentPadding;
var ex = width + currentPadding - 1;
var ez = length + currentPadding - 1;
// Fill it with city wall padding marker
for (int x = sx; x < ex; x++)
{
SimpleCityCellType cellType = SimpleCityCellType.CityWallPadding;
paddedCells.Add(CreateCell(x, sz, cellType));
paddedCells.Add(CreateCell(x, ez, cellType));
}
for (int z = sz; z < ez; z++)
{
SimpleCityCellType cellType = SimpleCityCellType.CityWallPadding;
paddedCells.Add(CreateCell(sx, z, cellType));
paddedCells.Add(CreateCell(ex, z, cellType));
}
}
demoModel.WallPaddingCells = paddedCells.ToArray();
}
public static int NextIntRanged(this System.Random rand, int min, int max)
{
return(min + UnityEngine.Mathf.FloorToInt(rand.NextFloat() * (max - min)));
}
/// <inheritdoc />
public override List <MeshData> Build(Building building)
{
var random = new System.Random((int)building.Id);
var footprint = building.Footprint;
var roofOffset = building.Elevation + building.MinHeight + building.Height;
var roofHeight = roofOffset + building.RoofHeight;
var offset = new ClipperOffset();
offset.AddPath(footprint.Select(p => new IntPoint(p.X * Scale, p.Y * Scale)).ToList(),
JoinType.jtMiter, EndType.etClosedPolygon);
var result = new List <List <IntPoint> >();
offset.Execute(ref result, random.NextFloat(1, 3) * -Scale);
if (result.Count != 1 || result[0].Count != footprint.Count)
{
Trace.Warn(LogCategory, Strings.RoofGenFailed, Name, building.Id.ToString());
return(base.Build(building));
}
var topVertices = ObjectPool.NewList <Vector2d>(footprint.Count);
double scale = Scale;
foreach (var intPoint in result[0])
{
topVertices.Add(new Vector2d(intPoint.X / scale, intPoint.Y / scale));
}
// NOTE need reverse vertices
topVertices.Reverse();
var floorCount = building.Levels;
var topMesh = CreateMesh(topVertices);
var floorMesh = CreateMesh(footprint);
var roofVertexCount = topMesh.Triangles.Count * 3 * 2 + footprint.Count * 2 * 12;
var floorVertexCount = floorMesh.Triangles.Count * 3 * 2 * floorCount;
var vertexCount = roofVertexCount + floorVertexCount;
var planeCount = footprint.Count + floorCount + 1;
bool limitIsReached = false;
if (vertexCount * 2 > Consts.MaxMeshSize)
{
vertexCount = roofVertexCount;
planeCount = building.Footprint.Count + 1;
limitIsReached = true;
}
var meshIndex = new MultiPlaneMeshIndex(planeCount, vertexCount);
var meshData = new MeshData(meshIndex, vertexCount);
var roofGradient = CustomizationService.GetGradient(building.RoofColor);
int index = FindStartIndex(topVertices[0], footprint);
for (int i = 0; i < topVertices.Count; i++)
{
var top = topVertices[i];
var bottom = footprint[(index + i) % footprint.Count];
var nextTop = topVertices[(i + 1) % topVertices.Count];
var nextBottom = footprint[(index + i + 1) % footprint.Count];
var v0 = new Vector3((float)bottom.X, roofOffset, (float)bottom.Y);
var v1 = new Vector3((float)nextBottom.X, roofOffset, (float)nextBottom.Y);
var v2 = new Vector3((float)nextTop.X, roofHeight, (float)nextTop.Y);
var v3 = new Vector3((float)top.X, roofHeight, (float)top.Y);
meshIndex.AddPlane(v0, v1, v2, meshData.NextIndex);
AddTriangle(meshData, roofGradient, v0, v2, v3);
AddTriangle(meshData, roofGradient, v2, v0, v1);
}
ObjectPool.StoreList(topVertices);
// Attach top reusing roof context object
var context = new RoofContext()
{
Mesh = topMesh,
MeshData = meshData,
MeshIndex = meshIndex,
Bottom = roofHeight,
FloorCount = 1,
FloorHeight = building.Height / floorCount,
FloorFrontGradient = CustomizationService.GetGradient(building.FloorFrontColor),
FloorBackGradient = CustomizationService.GetGradient(building.FloorBackColor),
IsLastRoof = true,
RoofFrontGradient = roofGradient,
RoofBackGradient = roofGradient
};
AttachFloors(context);
if (!limitIsReached)
{
context.Mesh = floorMesh;
context.MeshData = meshData;
context.Bottom = building.Elevation + building.MinHeight;
context.FloorCount = floorCount;
context.IsLastRoof = false;
AttachFloors(context);
return(new List <MeshData>(1)
{
meshData
});
}
var meshDataList = BuildFloors(building, building.Levels, false);
meshDataList.Add(meshData);
return(meshDataList);
}
public void Generate(ValueStore keyStore)
{
Reset();
if (park == null)
{
return;
}
var seed = 0;
// Generate a random seed.
foreach (char c in keyStore.Seed)
{
seed += (int)c;
}
_waterRandom = new SRandom(seed);
_treeRandom = new SRandom(seed);
for (var z = 0; z <= park.zSize; z++)
{
for (var x = 0; x <= park.xSize; x++)
{
// Calculate height of terrain patch based on perlin noise.
var y = (Mathf.PerlinNoise(x / (park.xSize * keyStore.PlainScale) + seed, z / (park.zSize * keyStore.PlainScale) + seed) *
(1 + keyStore.DitchRatio)) -
(float)keyStore.DitchRatio;
if (y < 0 && keyStore.DitchRatio != 0)
{
y /= keyStore.DitchRatio;
}
y = y * (y < 0 ? keyStore.MaxDepth : (float)keyStore.MaxHeight);
y = y > 0 ? Mathf.FloorToInt(y) : Mathf.CeilToInt(y);
// Generate terrain type for the terrain patch based on perlin noise.
if (keyStore.GenerateTerrainType)
{
var patch = park.getTerrain(x, z);
if (patch != null)
{
var types = ScriptableSingleton <AssetManager> .Instance.terrainTypes.Length;
var terrainTypeIndex = Mathf.PerlinNoise(x / (park.xSize * keyStore.TerrainScale) + seed,
z / (park.xSize * keyStore.TerrainScale) + seed);
patch.TerrainType = Mathf.FloorToInt(Mathf.Abs(terrainTypeIndex - 0.5f) * types);
}
}
// Limit heights near road.
var roadWidth = Mathf.Max(MIN_ROAD_WIDTH, keyStore.EntranceClearance);
if (x < roadWidth)
{
continue;
}
y = Mathf.Clamp(y, roadWidth - x, x - roadWidth);
// Limit heights near entrance.
var distanceToEntrance = Vector3.Distance(park.parkEntrances.First().transform.position,
new Vector3(x, GROUND_HEIGHT, z));
if (distanceToEntrance < roadWidth)
{
continue;
}
// If this location should be raised, change the hight of the patch and the ones around.
if (y != 0)
{
for (var cornerIndex = 0; cornerIndex < 4; cornerIndex++)
{
var ox = cornerIndex == 1 || cornerIndex == 2 ? 1 : 0;
var oz = cornerIndex == 2 || cornerIndex == 3 ? 1 : 0;
var patch = park.getTerrain(x - ox, z - oz);
if (patch != null)
{
var current = patch.h[cornerIndex] - DEF_HEIGHT;
patch.smoothChangeHeight(park, cornerIndex, y - current);
}
}
}
}
}
// Randomly flood the map.
for (var i = 0; i < keyStore.FloodRounds; i++)
{
var x = Mathf.RoundToInt(_waterRandom.NextFloat(keyStore.EntranceClearance, park.xSize));
var z = Mathf.RoundToInt(_waterRandom.NextFloat(0, park.zSize));
var patch = park.getTerrain(x, z);
if (patch == null || patch.hasWater() || patch.getLowestHeight() >= GROUND_HEIGHT)
{
continue;
}
WaterFlooding.flood(new Vector3(x, GROUND_HEIGHT - WATTER_OFFSET, z));
}
// Randomly spawn a forrest.
for (var i = 0; i < keyStore.TreeCount; i++)
{
var x = Mathf.RoundToInt(_treeRandom.NextFloat(keyStore.EntranceClearance, park.xSize - PARK_FENCE_OFFSET));
var z = Mathf.RoundToInt(_treeRandom.NextFloat(PARK_FENCE_OFFSET, park.zSize - PARK_FENCE_OFFSET));
var patch = park.getTerrain(x, z);
if (patch == null || patch.hasWater())
{
continue;
}
var y = patch.getHighestHeight();
if (y != patch.getLowestHeight())
{
continue;
}
TreeEntity fir = null;
foreach (var o in ScriptableSingleton <AssetManager> .Instance.getDecoObjects())
{
if (o.getName().StartsWith("Fir") && o is TreeEntity)
{
fir = o as TreeEntity;
}
}
if (fir != null)
{
var tree = ConfigWindow.Instantiate(fir);
tree.transform.position = new Vector3(x, y, z);
tree.transform.forward = Vector3.forward;
tree.Initialize();
tree.startAnimateSpawn(Vector3.zero);
}
}
}
NodeConnection[] ConnectPartitions(BSPNodeObject leftPartition, BSPNodeObject rightPartition, bool horizontalSplit)
{
var connections = new List <NodeConnection>();
if (leftPartition.discarded || rightPartition.discarded)
{
return(connections.ToArray());
}
var leftRooms = new List <BSPNodeObject>();
var rightRooms = new List <BSPNodeObject>();
if (horizontalSplit)
{
FindBoundaryEdgeRooms(leftPartition, BSPNodeDirection.Right, leftRooms);
FindBoundaryEdgeRooms(rightPartition, BSPNodeDirection.Left, rightRooms);
}
else // Vertical split
{
// Left = bottom partition
// Right = top partition
FindBoundaryEdgeRooms(leftPartition, BSPNodeDirection.Top, leftRooms);
FindBoundaryEdgeRooms(rightPartition, BSPNodeDirection.Bottom, rightRooms);
}
// Connect the two rooms together
if (leftRooms.Count == 0 || rightRooms.Count == 0)
{
return(connections.ToArray());
}
Shuffle(leftRooms);
Shuffle(rightRooms);
bool roomsConnected = false;
foreach (var leftRoom in leftRooms)
{
// First check if any of the right rooms are connected
foreach (var rightRoom in rightRooms)
{
if (leftRoom.connectedRooms.Contains(rightRoom))
{
roomsConnected = true;
break;
}
}
foreach (var rightRoom in rightRooms)
{
if (leftRoom.connectedRooms.Contains(rightRoom))
{
// Already connected
continue;
}
bool shouldConnectRooms = true;
if (roomsConnected)
{
// rooms are already connected along this edge. Check if can loop
shouldConnectRooms = random.NextFloat() < bspConfig.loopingProbability;
}
if (shouldConnectRooms)
{
// Connect left and right together
var intersection = Rectangle.Intersect(leftRoom.bounds, rightRoom.bounds);
var minIntersection = bspConfig.roomPadding * 2;
if (intersection.Size.x > minIntersection || intersection.Size.z > minIntersection)
{
// These two rooms can connect
leftRoom.connectedRooms.Add(rightRoom);
rightRoom.connectedRooms.Add(leftRoom);
roomsConnected = true;
var connection = new NodeConnection(leftRoom, rightRoom, bspConfig.roomPadding);
connections.Add(connection);
}
}
}
}
return(connections.ToArray());
}
