private Quaternion CalculateLeafRotation(LeafPoint leafPoint)
{
Vector3 left, forward;
Quaternion res;
//Aquí cálculos de orientación en función de las opciones de rotación
if (!ivyParameters.globalOrientation)
{
forward = leafPoint.lpForward;
left = leafPoint.left;
}
else
{
forward = ivyParameters.globalRotation;
left = Vector3.Normalize(Vector3.Cross(ivyParameters.globalRotation, leafPoint.lpUpward));
}
//Y aplicamos la rotación
res = Quaternion.LookRotation(leafPoint.lpUpward, forward);
res = Quaternion.AngleAxis(ivyParameters.rotation.x, left) * Quaternion.AngleAxis(ivyParameters.rotation.y, leafPoint.lpUpward) * Quaternion.AngleAxis(ivyParameters.rotation.z, forward) * res;
res = Quaternion.AngleAxis(Random.Range(-ivyParameters.randomRotation.x, ivyParameters.randomRotation.x), left) *
Quaternion.AngleAxis(Random.Range(-ivyParameters.randomRotation.y, ivyParameters.randomRotation.y), leafPoint.lpUpward) *
Quaternion.AngleAxis(Random.Range(-ivyParameters.randomRotation.z, ivyParameters.randomRotation.z), forward) *
res;
return(res);
}
private LeafPoint GetNextLeaf(LeafInfo leafInfo)
{
LeafPoint res = null;
float length = overSegment[0].length + Vector3.Distance(leafInfo.pointWS, overSegment[0].point);
for (int i = 0; i < overBranch.leaves.Count; i++)
{
if (res == null)
{
res = overBranch.leaves[i];
}
else if (overBranch.leaves[i].lpLength < length)
{
res = overBranch.leaves[i];
}
else
{
res = overBranch.leaves[i];
break;
}
}
return(res);
}
public LeafPoint AddLeaf(Vector3 leafPoint, float lpLength, Vector3 lpForward, Vector3 lpUpward, int chosenLeave, BranchPoint initSegment, BranchPoint endSegment)
{
LeafPoint newLeaf = new LeafPoint(leafPoint, lpLength, lpForward, lpUpward, chosenLeave, initSegment, endSegment);
leaves.Add(newLeaf);
return(newLeaf);
}
public LeafPoint InsertLeaf(Vector3 leafPoint, float lpLength, Vector3 lpForward, Vector3 lpUpward,
int chosenLeave, int leafIndex, BranchPoint initSegment, BranchPoint endSegment)
{
LeafPoint newLeaf = new LeafPoint(leafPoint, lpLength, lpForward, lpUpward, chosenLeave, initSegment, endSegment);
int clampedLeafIndex = Mathf.Clamp(leafIndex, 0, int.MaxValue);
leaves.Insert(clampedLeafIndex, newLeaf);
return(newLeaf);
}
private float CalculateLeafScale(BranchContainer branch, LeafPoint leafPoint)
{
//Aquí la escala, que es facilita, incluyendo el tip influence
float scale = Random.Range(ivyParameters.minScale, ivyParameters.maxScale);
if (leafPoint.lpLength - 0.1f >= branch.totalLenght - ivyParameters.tipInfluence)
{
scale *= Mathf.InverseLerp(branch.totalLenght, branch.totalLenght - ivyParameters.tipInfluence, leafPoint.lpLength);
}
return(scale);
}
private void AddLeaf(LeafInfo leafInfo)
{
BranchPoint branchPoint = overBranch.GetNearestPointFrom(mousePoint);
LeafPoint nextLeaf = GetNextLeaf(leafInfo);
int leafIndex = overBranch.leaves.IndexOf(nextLeaf);
lastLeafPoint = overBranch.AddRandomLeaf(leafInfo.pointWS, overSegment[0], overSegment[1], leafIndex, infoPool);
RefreshMesh(true, true);
}
public void UpdateLeavesDictEntry(int initSegmentIdx, LeafPoint leaf)
{
if (dictRTLeavesByInitSegment.ContainsKey(initSegmentIdx))
{
dictRTLeavesByInitSegment[initSegmentIdx].Add(leaf);
}
else
{
List <LeafPoint> newEntryLeaves = new List <LeafPoint>();
newEntryLeaves.Add(leaf);
dictRTLeavesByInitSegment[initSegmentIdx] = newEntryLeaves;
}
}
public LeafPoint AddRandomLeaf(Vector3 pointWS, BranchPoint initSegment, BranchPoint endSegment, int leafIndex, InfoPool infoPool)
{
int chosenLeave = UnityEngine.Random.Range(0, infoPool.ivyParameters.leavesPrefabs.Length);
Vector3 forward = initSegment.initialGrowDir;
float lpLength = initSegment.length + Vector3.Distance(pointWS, initSegment.point);
LeafPoint res = InsertLeaf(pointWS, lpLength, forward,
-initSegment.grabVector, chosenLeave, leafIndex,
initSegment, endSegment);
return(res);
}
public RTLeafPoint(LeafPoint leafPoint, IvyParameters ivyParameters)
{
this.point = leafPoint.point;
this.lpLength = leafPoint.lpLength;
this.left = leafPoint.left;
this.lpForward = leafPoint.lpForward;
this.lpUpward = leafPoint.lpUpward;
this.initSegmentIdx = leafPoint.initSegmentIdx;
this.endSegmentIdx = leafPoint.endSegmentIdx;
this.chosenLeave = leafPoint.chosenLeave;
this.vertices = leafPoint.verticesLeaves.ToArray();
this.leafCenter = leafPoint.leafCenter;
this.leafRotation = leafPoint.leafRotation;
this.leafScale = leafPoint.leafScale;
CalculateLeafRotation(ivyParameters);
}
//Aquí se construyen las hojas, este método es llamado rama a rama
void BuildLeaves(int b, ref int vertCount)
{
Mesh chosenLeaveMesh;
//Se recorren los materiales
for (int i = 0; i < leavesMaterials.Count; i++)
{
Random.InitState(b + infoPool.ivyParameters.randomSeed + i);
for (int j = 0; j < infoPool.ivyContainer.branches[b].leaves.Count; j++)
{
LeafPoint currentLeaf = infoPool.ivyContainer.branches[b].leaves[j];
//Ahora vemos si para el material que estamos iterando, le corresponde el tipo de hoja que tenemos en este punto
if (typesByMat[i].Contains(currentLeaf.chosenLeave))
{
currentLeaf.verticesLeaves = new List <RTVertexData>();
//Y vemos qué tipo de hoja corresponde a cada punto a cogemos esa malla
chosenLeaveMesh = infoPool.ivyParameters.leavesPrefabs[currentLeaf.chosenLeave].GetComponent <MeshFilter>().sharedMesh;
//definimos el vértice por el que tenemos que empezar a escribir en el array
int firstVertex = vertCount;
Vector3 left, forward;
Quaternion quat;
//Aquí cálculos de orientación en función de las opciones de rotación
if (!infoPool.ivyParameters.globalOrientation)
{
forward = currentLeaf.lpForward;
left = currentLeaf.left;
//left = Vector3.Cross(currentLeaf.lpForward, currentLeaf.lpUpward);
}
else
{
forward = infoPool.ivyParameters.globalRotation;
left = Vector3.Normalize(Vector3.Cross(infoPool.ivyParameters.globalRotation, currentLeaf.lpUpward));
}
//Y aplicamos la rotación
quat = Quaternion.LookRotation(currentLeaf.lpUpward, forward);
quat = Quaternion.AngleAxis(infoPool.ivyParameters.rotation.x, left) * Quaternion.AngleAxis(infoPool.ivyParameters.rotation.y, currentLeaf.lpUpward) * Quaternion.AngleAxis(infoPool.ivyParameters.rotation.z, forward) * quat;
quat = Quaternion.AngleAxis(Random.Range(-infoPool.ivyParameters.randomRotation.x, infoPool.ivyParameters.randomRotation.x), left) * Quaternion.AngleAxis(Random.Range(-infoPool.ivyParameters.randomRotation.y, infoPool.ivyParameters.randomRotation.y), currentLeaf.lpUpward) * Quaternion.AngleAxis(Random.Range(-infoPool.ivyParameters.randomRotation.z, infoPool.ivyParameters.randomRotation.z), forward) * quat;
quat = currentLeaf.forwarRot * quat;
//Aquí la escala, que es facilita, incluyendo el tip influence
float scale = Random.Range(infoPool.ivyParameters.minScale, infoPool.ivyParameters.maxScale);
currentLeaf.leafScale = scale;
scale *= Mathf.InverseLerp(infoPool.ivyContainer.branches[b].totalLenght, infoPool.ivyContainer.branches[b].totalLenght - infoPool.ivyParameters.tipInfluence, currentLeaf.lpLength);
/*******************/
currentLeaf.leafRotation = quat;
currentLeaf.dstScale = scale;
/*******************/
//Metemos los triángulos correspondientes en el array correspondiente al material que estamos iterando
for (int t = 0; t < chosenLeaveMesh.triangles.Length; t++)
{
int triangle = chosenLeaveMesh.triangles[t] + vertCount;
trisLeaves[i].Add(triangle);
}
//ylos vértices, normales y uvs, aplicando las transformaciones pertinentes, actualizando el contador para la siguiente iteración saber por dónde vamos
for (int v = 0; v < chosenLeaveMesh.vertexCount; v++)
{
Vector3 offset = left * infoPool.ivyParameters.offset.x +
currentLeaf.lpUpward * infoPool.ivyParameters.offset.y +
currentLeaf.lpForward * infoPool.ivyParameters.offset.z;
verts[vertCount] = quat * chosenLeaveMesh.vertices[v] * scale + currentLeaf.point + offset;
normals[vertCount] = quat * chosenLeaveMesh.normals[v];
uvs[vertCount] = chosenLeaveMesh.uv[v];
vColor[vertCount] = chosenLeaveMesh.colors[v];
normals[vertCount] = Quaternion.Inverse(infoPool.ivyContainer.ivyGO.transform.rotation) * normals[vertCount];
verts[vertCount] -= infoPool.ivyContainer.ivyGO.transform.position;
verts[vertCount] = Quaternion.Inverse(infoPool.ivyContainer.ivyGO.transform.rotation) * verts[vertCount];
RTVertexData vertexData = new RTVertexData(verts[vertCount], normals[vertCount], uvs[vertCount], Vector2.zero, vColor[vertCount]);
currentLeaf.verticesLeaves.Add(vertexData);
currentLeaf.leafCenter = currentLeaf.point - infoPool.ivyContainer.ivyGO.transform.position;
currentLeaf.leafCenter = Quaternion.Inverse(infoPool.ivyContainer.ivyGO.transform.rotation) * currentLeaf.leafCenter;
vertCount++;
}
//escribimos en el diccionario el index por donde nos hemos quedado para después poder
//transformar las uvs de cada elemento acorde a su dimensión real
int[] fromTo = new int[2] {
firstVertex, vertCount - 1
};
branchesLeavesIndices.Add(branchesLeavesIndices.Count, fromTo);
}
//for (int p = 0; p < currentBranchPoint.leaves.Count; p++)
//{
//}
}
/*//Después por cada material, recorremos los puntos de la rama
* for (int j = 0; j < infoPool.ivyContainer.branches[b].branchPoints.Count; j++) {
*
*
*
*
*
*
* }*/
}
}
public void AddLeaf(LeafPoint leafPoint)
{
leaves.Add(leafPoint);
}
