public PuzzleData GeneratePuzzle
(
int i_width,
float i_difficulty,
float i_forwardCellsPerSideways
)
{
int length = Mathf.CeilToInt(Mathf.Lerp(m_data.m_lengthAtMinDif, m_data.m_lengthAtMaxDif, i_difficulty));
PuzzleData puzzleData = new PuzzleData(i_width, length);
int currentX = Random.Range(1, i_width - 1);
int direction = Random.Range(0f, 1f) > 0.5f ? 1 : -1;
for (int y = 0; y < length; ++y)
{
puzzleData.GetCell(currentX, y).m_prefabToSpawn = m_data.m_cassettePrefab;
if (currentX == 0 || currentX == i_width - 1)
{
direction = -direction;
}
currentX += direction;
}
puzzleData.AddRows(2);
return(puzzleData);
}
private PuzzleData GeneratePuzzle(int i_puzzleIndex, IPuzzleGenerator i_puzzleGeneratorIF, Vector3 i_startingPosition)
{
PuzzleData puzzleData = i_puzzleGeneratorIF.GeneratePuzzle(m_width, m_emulatedState.m_difficulty, m_forwardCellsPerSideways);
Vector2Int gridSize = new Vector2Int(puzzleData.Width, puzzleData.Height);
GameObject[,] spawnedObjects = new GameObject[gridSize.x, gridSize.y];
m_spawnedObjects.Add(i_puzzleIndex, spawnedObjects);
for (int x = 0; x < puzzleData.Width; ++x)
{
for (int y = 0; y < puzzleData.Height; ++y)
{
PuzzleCell cell = puzzleData.GetCell(x, y);
if (cell.m_prefabToSpawn != null)
{
spawnedObjects[x, y] = Instantiate(cell.m_prefabToSpawn, i_startingPosition + new Vector3(x * m_cellSize, 0, y * m_cellSize), Quaternion.identity, transform);
}
}
}
// Link
for (int x = 0; x < puzzleData.Width; ++x)
{
for (int y = 0; y < puzzleData.Height; ++y)
{
PuzzleCell cell = puzzleData.GetCell(x, y);
if (cell.m_cellsToLinkTo != null)
{
foreach (Vector2Int cellCoords in cell.m_cellsToLinkTo)
{
GameObject objectToLinkFrom = spawnedObjects[x, y];
GameObject objectToLinkTo = spawnedObjects[cellCoords.x, cellCoords.y];
foreach (IActivator activator in objectToLinkFrom.GetComponents <IActivator>())
{
foreach (IActivatee activatee in objectToLinkTo.GetComponents <IActivatee>())
{
activator.AssignActivee(activatee);
}
}
}
}
}
}
return(puzzleData);
}
public PuzzleData GeneratePuzzle
(
int i_width,
float i_difficulty,
float i_forwardCellsPerSideways
)
{
PuzzleData puzzleData = new PuzzleData(i_width, m_data.m_jamLength);
HashSet<int> fullLanes = new HashSet<int>();
// Figure out how many lanes to fill up
int minLanes = m_data.m_lanesOfTrafficAtMinDif;
int maxLanes = i_width - m_data.m_lanesWithoutTrafficAtMaxDif;
int numLanes = Mathf.FloorToInt(Mathf.Lerp(minLanes, maxLanes, i_difficulty)); // Num lanes of traffic
// Pick our lanes
while(fullLanes.Count < numLanes)
{
fullLanes.Add(Random.Range(0, i_width));
}
// Spawn our cars
foreach(int laneIndex in fullLanes)
{
for(int y = 0; y < m_data.m_jamLength; y += 2)
{
PuzzleCell carCell = puzzleData.GetCell(laneIndex, y);
carCell.m_prefabToSpawn = m_data.m_carPrefabs[Random.Range(0, m_data.m_carPrefabs.Count)];
}
}
int extraCellsPostJam = Mathf.CeilToInt(2 * i_forwardCellsPerSideways); // Bit of padding on the exit
puzzleData.AddRows(extraCellsPostJam);
return puzzleData;
}
public PuzzleData GeneratePuzzle
(
int i_width,
float i_difficulty,
float i_forwardCellsPerSideways
)
{
// Slalomy thing
// Pick how wide it's going to be
// Calculate how many rows we need between each barrier
// Calculate how many rows of extra diagonal barriers are needed
/*
* | /| | /|
* |\ /| | / | |\ / |
* | \ / | |\ / | | |^--| |
* | |^-| | | |^-| | | |^^^| |
* | |^^| | | |^^| | | |^^^| |
* | |-^| | | |-^| | | |--^| |
* | |^^| | | |^^| | | |^^^| |
* | |^-| | | |^-| | | |^^^| |
* | |^^| | | |^^| | | |^--| |
* | |-^| | | |-^| | | |^^^| |
* | / \ | |/ \ | | |^^^| |
* |/ \| | \ | | |--^| |
* | \| |/ \ |
* | \|
*/
// Calculate how long we need it to be
// First we have to pick where we're going to place this
int slalomWidth = 2 + Mathf.Max(Mathf.CeilToInt(Mathf.Lerp(m_data.m_extraRoadWidthPropMinDif, m_data.m_extraRoadWidthPropMaxDif, i_difficulty) * (i_width - 2)), 0);
int slalomLeftLaneX = Random.Range(0, i_width - slalomWidth);
// Figure out how much extra height we need for the hard shoulders
int slalomLeftShoulderWidth = slalomLeftLaneX;
int slalomRightShoulderWidth = i_width - (slalomLeftLaneX + slalomWidth);
int maxShoulderWidth = Mathf.Max(slalomLeftShoulderWidth, slalomRightShoulderWidth);
int shoulderDiagonalMaxHeight = maxShoulderWidth;
int shoulderAdditionalHeight = shoulderDiagonalMaxHeight * 2; // Top and bottom
// Now figure out how much height we need for the slalom
int slalomVerticalSpacePerBarrier = Mathf.CeilToInt((slalomWidth - 1) * i_forwardCellsPerSideways) + Mathf.CeilToInt(Mathf.Lerp(m_data.m_extraSlalomHeightPerBarrierMinDif, m_data.m_extraSlalomHeightPerBarrierMaxDif, i_difficulty));
int slalomHeight = m_data.m_slalomBarriers + (m_data.m_slalomBarriers - 1) * slalomVerticalSpacePerBarrier;
// Total height
int puzzleCellHeight = slalomHeight + shoulderAdditionalHeight;
// Super simple to start
PuzzleData puzzleData = new PuzzleData(i_width, puzzleCellHeight);
// Start placing
Vector2Int slalomBottomLeft = new Vector2Int(slalomLeftShoulderWidth, shoulderDiagonalMaxHeight);
Vector2Int slalomBottomRight = slalomBottomLeft + new Vector2Int(slalomWidth - 1, 0);
Vector2Int slalomTopLeft = slalomBottomLeft + new Vector2Int(0, slalomHeight - 1);
Vector2Int slalomTopRight = slalomBottomRight + new Vector2Int(0, slalomHeight - 1);
void PlaceWall(Vector2Int i_pos, GameObject i_prefab)
{
if (i_pos.x >= 0 && i_pos.x < puzzleData.Width && i_pos.y >= 0 && i_pos.y < puzzleData.Height)
{
PuzzleCell wallCell = puzzleData.GetCell(i_pos.x, i_pos.y);
wallCell.m_prefabToSpawn = i_prefab;
}
}
// Slalom
bool isLeft = (Mathf.RoundToInt(Random.Range(0f, 1f)) == 1);
for (int y = 0; y < slalomHeight; ++y)
{
PlaceWall(slalomBottomLeft + new Vector2Int(-1, y), m_data.m_leftWallPrefab);
PlaceWall(slalomBottomRight + new Vector2Int(1, y), m_data.m_rightWallPrefab);
if (y == 0 || (y % (slalomVerticalSpacePerBarrier + 1) == 0))
{
// Place a wall
for (int x = 0; x < slalomWidth - 1; ++x)
{
if (isLeft)
{
PlaceWall(slalomBottomLeft + new Vector2Int(x, y), m_data.m_slalomWallPrefab);
}
else
{
PlaceWall(slalomBottomRight + new Vector2Int(-x, y), m_data.m_slalomWallPrefab);
}
}
isLeft = !isLeft;
}
}
// Hard shoulder
for (int y = 0; y < shoulderDiagonalMaxHeight; ++y)
{
// Bottom ones
PlaceWall(slalomBottomLeft + new Vector2Int(-1, -1) + new Vector2Int(-y, -y), m_data.m_leftDiagonalWallPrefab);
PlaceWall(slalomBottomRight + new Vector2Int(1, -1) + new Vector2Int(y, -y), m_data.m_rightDiagonalWallPrefab);
// Top ones
PlaceWall(slalomTopLeft + new Vector2Int(-1, 1) + new Vector2Int(-y, y), m_data.m_rightDiagonalWallPrefab);
PlaceWall(slalomTopRight + new Vector2Int(1, 1) + new Vector2Int(y, y), m_data.m_leftDiagonalWallPrefab);
}
puzzleData.AddRows(2);
return(puzzleData);
}
private IEnumerator GeneratePuzzle(IPuzzleGenerator i_puzzleGeneratorIF, float i_difficulty, float i_startingSplineT, float i_startingSplineTClamped)
{
PuzzleData puzzleData = i_puzzleGeneratorIF.GeneratePuzzle(m_trackWidthInCells, i_difficulty, m_forwardCellsPerSideways);
AddRandomStuff(puzzleData, i_difficulty);
SplineTransformData puzzleStartTransformData = m_spline.CalculateAproxSplineTransformData(i_startingSplineTClamped);
Vector2Int gridSize = new Vector2Int(puzzleData.Width, puzzleData.Height);
SpawnedPuzzle spawnedPuzzleData = new SpawnedPuzzle();
spawnedPuzzleData.m_spawnedObjects = new GameObject[gridSize.x, gridSize.y];
spawnedPuzzleData.m_startPuzzleHeight = m_runningDistancePS;
spawnedPuzzleData.m_endPuzzleHeight = m_runningDistancePS + puzzleData.Height;
spawnedPuzzleData.m_puzzleData = puzzleData;
spawnedPuzzleData.m_startTransformData = puzzleStartTransformData;
m_spawnedPuzzles.Enqueue(spawnedPuzzleData);
float GetT(int i_y)
{
return((i_startingSplineTClamped + i_y * m_trackTPerCell) % 1f);
}
// Work out if we need to offset the starting spline T
float trackLength = m_spline.Length;
float puzzleTLength = (puzzleData.Height * m_cellSize) / trackLength;
float totalAddedT = 0f;
while (!m_spline.DoesTRangeSupportPuzzles(i_startingSplineT, i_startingSplineT + puzzleTLength, out float nextValidT))
{
totalAddedT += (nextValidT - i_startingSplineT);
i_startingSplineT = nextValidT;
i_startingSplineTClamped = i_startingSplineT % 1f;
yield return(0);
}
m_runningDistancePS += Mathf.CeilToInt(totalAddedT * trackLength / m_cellSize);
// Lets figure out wtf we need to spawn this crap
for (int y = 0; y < puzzleData.Height; ++y)
{
// Every time we go up one we need to find our new transform info
float splineT = GetT(y);
SplineTransformData splineTransformData = m_spline.CalculateAproxSplineTransformData(splineT);
int timesAroundTrack = Mathf.FloorToInt(i_startingSplineT);
if (timesAroundTrack % 2 == 1) // If odd, flip
{
splineTransformData.m_worldUp = -splineTransformData.m_worldUp;
}
m_splineTransformsCalulated.Add(splineTransformData);
Vector3 puzzleLeftPos = splineTransformData.m_worldPos - (Vector3.Cross(splineTransformData.m_worldUp.normalized, splineTransformData.m_worldFwd.normalized) * m_cellSize * (m_trackWidthInCells - 1) / 2f);
Quaternion objectRotation = Quaternion.LookRotation(splineTransformData.m_worldFwd.normalized, splineTransformData.m_worldUp.normalized);
for (int x = 0; x < puzzleData.Width; ++x)
{
PuzzleCell cell = puzzleData.GetCell(x, y);
if (cell.m_prefabToSpawn != null)
{
Vector3 positionToSpawn = puzzleLeftPos + (objectRotation * new Vector3(x * m_cellSize, 0, 0));
Quaternion rotationToSpawn = objectRotation;
// Adjust because the track isn't actually flat all the way along
// Lift above the track
Vector3 raycastFrom = positionToSpawn + splineTransformData.m_worldUp * m_upwardProjectionLengthBeforeDownwardRaycast;
if (Physics.Raycast(new Ray(raycastFrom, -splineTransformData.m_worldUp), out RaycastHit hit, m_downwardRaycastLength, m_trackLayer))
{
// Adjust
positionToSpawn = hit.point;
rotationToSpawn = Quaternion.LookRotation(splineTransformData.m_worldFwd.normalized, hit.normal.normalized);
}
spawnedPuzzleData.m_spawnedObjects[x, y] = Instantiate(cell.m_prefabToSpawn, positionToSpawn, cell.m_prefabRotation * rotationToSpawn, transform);
spawnedPuzzleData.m_spawnedObjects[x, y].transform.localScale *= m_modelScaler;
}
}
yield return(0);
}
// Link
for (int x = 0; x < puzzleData.Width; ++x)
{
for (int y = 0; y < puzzleData.Height; ++y)
{
PuzzleCell cell = puzzleData.GetCell(x, y);
if (cell.m_cellsToLinkTo != null)
{
foreach (Vector2Int cellCoords in cell.m_cellsToLinkTo)
{
GameObject objectToLinkFrom = spawnedPuzzleData.m_spawnedObjects[x, y];
GameObject objectToLinkTo = spawnedPuzzleData.m_spawnedObjects[cellCoords.x, cellCoords.y];
foreach (IActivator activator in objectToLinkFrom.GetComponents <IActivator>())
{
foreach (IActivatee activatee in objectToLinkTo.GetComponents <IActivatee>())
{
activator.AssignActivee(activatee);
}
}
}
}
}
}
}
public PuzzleData GeneratePuzzle
(
int i_width,
float i_difficulty,
float i_forwardCellsPerSideways
)
{
PuzzleData puzzleData = new PuzzleData(i_width, m_data.m_puzzleLength);
// Place some walls (W) and removed the ability to place walls in places nearby that would block the player from getting through (x)
// May need to go up with (x) as many cells as necessary to go sideways one block
/*
* x x
* x W x
*
*/
bool[,] takenCells = new bool[i_width, m_data.m_puzzleLength];
// Figure out how many blocks we're going to spawn
int totalCells = i_width * m_data.m_puzzleLength;
int blocksToSpawn = Mathf.FloorToInt(totalCells * Mathf.Lerp(m_data.m_wallCellPercentageAtMinDif, m_data.m_wallCellPercentageAtMaxDif, i_difficulty));
int verticalCellsToBlock = Mathf.CeilToInt(i_forwardCellsPerSideways);
// Super bad and simple stuff
int attempts = 0;
while (blocksToSpawn > 0 && attempts < blocksToSpawn * 10)
{
Vector2Int spawnCoords = new Vector2Int(Random.Range(0, i_width), Random.Range(0, m_data.m_puzzleLength));
if (takenCells[spawnCoords.x, spawnCoords.y] == false)
{
// Spawn our wall
PuzzleCell wallCell = puzzleData.GetCell(spawnCoords.x, spawnCoords.y);
wallCell.m_prefabToSpawn = m_data.m_wallPrefab;
// Block the cells around it
void BlockCell(Vector2Int i_coords)
{
if (i_coords.x >= 0 && i_coords.x < i_width)
{
if (i_coords.y >= 0 && i_coords.y < m_data.m_puzzleLength)
{
takenCells[i_coords.x, i_coords.y] = true;
}
}
}
BlockCell(spawnCoords + new Vector2Int(0, 0));
BlockCell(spawnCoords + new Vector2Int(-1, 0));
BlockCell(spawnCoords + new Vector2Int(1, 0));
for (int i = 1; i <= verticalCellsToBlock; ++i)
{
BlockCell(spawnCoords + new Vector2Int(0, -i));
BlockCell(spawnCoords + new Vector2Int(0, i));
BlockCell(spawnCoords + new Vector2Int(-1, -i));
BlockCell(spawnCoords + new Vector2Int(-1, i));
BlockCell(spawnCoords + new Vector2Int(1, -i));
BlockCell(spawnCoords + new Vector2Int(1, i));
}
--blocksToSpawn;
}
++attempts;
}
puzzleData.AddRows(1);
return(puzzleData);
}
public PuzzleData GeneratePuzzle
(
int i_width,
float i_difficulty,
float i_forwardCellsPerSideways
)
{
// SimpleSlalomy thing
// Pick how wide it's going to be
// Calculate how many rows we need between each barrier
// Calculate how many rows of extra diagonal barriers are needed
/*
* | |^-| |
* | |^^| |
* | |-^| |
* | |^^| |
* | |^-| |
* | |^^| |
* |---- ---|
*/
int openingGapWidth = 1 + Mathf.CeilToInt(Mathf.Lerp(m_data.m_extraEntryWidthMinDif, m_data.m_extraEntryWidthMaxDif, i_difficulty));
// Now figure out how much height we need for the SimpleSlalom
int slalomVerticalSpacePerBarrier = Mathf.CeilToInt((i_width - openingGapWidth) * i_forwardCellsPerSideways) + Mathf.CeilToInt(Mathf.Lerp(m_data.m_extraHeightPerBarrierMinDif, m_data.m_extraHeightPerBarrierMaxDif, i_difficulty));
int slalomHeight = m_data.m_slalomBarriers + (m_data.m_slalomBarriers - 1) * slalomVerticalSpacePerBarrier;
// Super simple to start
PuzzleData puzzleData = new PuzzleData(i_width, slalomHeight);
// Start placing
void PlaceWall(Vector2Int i_pos)
{
PuzzleCell wallCell = puzzleData.GetCell(i_pos.x, i_pos.y);
wallCell.m_prefabToSpawn = m_data.m_wallPrefab;
}
// SimpleSlalom
bool isLeft = (Random.Range(0f, 1f) > 0.5f) ? true : false;
for (int barrierIndex = 0; barrierIndex < m_data.m_slalomBarriers; ++barrierIndex)
{
int gapStartIndex = (isLeft ? 0 : i_width - openingGapWidth);
for (int x = 0; x < i_width; ++x)
{
if (x >= gapStartIndex && x < gapStartIndex + openingGapWidth)
{
// Gap
}
else
{
PlaceWall(new Vector2Int(x, barrierIndex * (slalomVerticalSpacePerBarrier + 1))); // Add on 1 for the barrier row itself
}
}
isLeft = !isLeft;
}
puzzleData.AddRows(slalomVerticalSpacePerBarrier);
return(puzzleData);
}
public PuzzleData GeneratePuzzle
(
int i_width,
float i_difficulty,
float i_forwardCellsPerSideways
)
{
// Calculate how long we need it to be
int maxGateOffset = i_width - 1;
int cellsOfSpaceNeeded = Mathf.CeilToInt(maxGateOffset * i_forwardCellsPerSideways) /*+ 1*/; // You need one extra cell to get out of the switch IF it has walls of some sort you need to go through
cellsOfSpaceNeeded += Mathf.FloorToInt((1f - i_difficulty) * m_data.m_puzzleCellLengthHandicapMinDifficulty) + Mathf.FloorToInt(i_difficulty * m_data.m_puzzleCellLengthHandicapMaxDifficulty);
// Switch + space + gate
int puzzleCellLength = 1 + cellsOfSpaceNeeded + 1;
// Super simple to start
PuzzleData puzzleData = new PuzzleData(i_width, puzzleCellLength);
// Place the switchs
List <PuzzleCell> switches = new List <PuzzleCell>();
int switchCount = Mathf.CeilToInt(Mathf.Lerp(m_data.m_switchesPresentMinDif, m_data.m_switchesPresentMaxDif, i_difficulty));
while (switches.Count < Mathf.Min(switchCount, i_width))
{
int switchX = Random.Range(0, i_width);
PuzzleCell switchCell = puzzleData.GetCell(switchX, 0);
if (switchCell.m_prefabToSpawn == null)
{
switchCell.m_prefabToSpawn = m_data.m_switchPrefab;
switches.Add(switchCell);
}
}
// Place the gates
List <PuzzleCell> gates = new List <PuzzleCell>();
List <int> gateXs = new List <int>();
int gateCount = Mathf.CeilToInt(Mathf.Lerp(m_data.m_gatesPresentMinDif, m_data.m_gatesPresentMaxDif, i_difficulty));
int gateY = puzzleCellLength - 1;
while (gates.Count < Mathf.Min(gateCount, i_width))
{
int gateX = Random.Range(0, i_width);
PuzzleCell gateCell = puzzleData.GetCell(gateX, gateY);
if (gateCell.m_prefabToSpawn == null)
{
gateCell.m_prefabToSpawn = m_data.m_gatePrefab;
gates.Add(gateCell);
gateXs.Add(gateX);
}
}
// Fill with walls
for (int x = 0; x < i_width; ++x)
{
PuzzleCell cell = puzzleData.GetCell(x, gateY);
if (cell.m_prefabToSpawn == null)
{
cell.m_prefabToSpawn = m_data.m_wallPrefab;
}
}
// Link
foreach (PuzzleCell switchCell in switches)
{
foreach (int gateX in gateXs)
{
switchCell.m_cellsToLinkTo.Add(new Vector2Int(gateX, gateY));
}
}
// Add empty cells at the end so the player has time to get back to their next thingy
float halfWidth = (i_width - 1) / 2f;
int gateOffsetFromCenter = Mathf.CeilToInt(halfWidth);
int extraCellsNeeded = Mathf.CeilToInt(halfWidth) + gateOffsetFromCenter + 1;
puzzleData.AddRows(extraCellsNeeded);
return(puzzleData);
}