void Unreal3DExport::WriteModel()
{
// Progress
pInt->ProgressUpdate(Progress, FALSE, GetString(IDS_INFO_WRITE));
// Open data file
fMesh = _tfopen(ModelFileName,_T("wb"));
if( !fMesh )
{
ProgressMsg.printf(GetString(IDS_ERR_FMODEL),ModelFileName);
throw MAXException(ProgressMsg.data());
}
// Open anim file
fAnim = _tfopen(AnimFileName,_T("wb"));
if( !fAnim )
{
ProgressMsg.printf(GetString(IDS_ERR_FANIM),AnimFileName);
throw MAXException(ProgressMsg.data());
}
// data headers
hData.NumPolys = Tris.Count();
hData.NumVertices = VertsPerFrame;
// anim headers
hAnim.FrameSize = VertsPerFrame * sizeof(FMeshVert);
hAnim.NumFrames = FrameCount;
// Progress
CheckCancel();
pInt->ProgressUpdate(Progress, FALSE, GetString(IDS_INFO_WMESH));
// Write data
fwrite(&hData,sizeof(FJSDataHeader),1,fMesh);
if( Tris.Count() > 0 )
{
fwrite(Tris.Addr(0),sizeof(FJSMeshTri),Tris.Count(),fMesh);
}
Progress += U3D_PROGRESS_WMESH;
// Progress
CheckCancel();
pInt->ProgressUpdate(Progress, FALSE, GetString(IDS_INFO_WANIM));
// Write anim
fwrite(&hAnim,sizeof(FJSAnivHeader),1,fAnim);
if( Verts.Count() > 0 )
{
fwrite(Verts.Addr(0),sizeof(FMeshVert),Verts.Count(),fAnim);
}
Progress += U3D_PROGRESS_WANIM;
}
void AFRMod::ModifyObject (TimeValue t, ModContext &mc, ObjectState *os, INode *node) {
Interval iv = FOREVER;
float f, p, b;
int backface;
Point3 pt1, pt2;
pblock->GetValue(PB_FALLOFF,t,f,iv);
pblock->GetValue(PB_PINCH,t,p,iv);
pblock->GetValue(PB_BUBBLE,t,b,iv);
pblock->GetValue(PB_BACKFACE,t,backface,iv);
p1->GetValue(t,&pt1,iv,CTRL_ABSOLUTE);
p2->GetValue(t,&pt2,iv,CTRL_ABSOLUTE);
if (f==0.0) {
os->obj->UpdateValidity(GEOM_CHAN_NUM,iv);
return;
}
Tab<Point3> normals;
if (backface) {
// Need to get vertex normals.
if (os->obj->IsSubClassOf(triObjectClassID)) {
TriObject *tobj = (TriObject*)os->obj;
AverageVertexNormals (tobj->GetMesh(), normals);
} else if (os->obj->IsSubClassOf (polyObjectClassID)) {
PolyObject *pobj = (PolyObject *) os->obj;
MNMesh &mesh = pobj->GetMesh();
normals.SetCount (mesh.numv);
Point3 *vn = normals.Addr(0);
for (int i=0; i<mesh.numv; i++) {
if (mesh.v[i].GetFlag (MN_DEAD)) vn[i]=Point3(0,0,0);
else vn[i] = mesh.GetVertexNormal (i);
}
#ifndef NO_PATCHES
} else if (os->obj->IsSubClassOf (patchObjectClassID)) {
PatchObject *pobj = (PatchObject *) os->obj;
normals.SetCount (pobj->NumPoints ());
Point3 *vn = normals.Addr(0);
for (int i=0; i<pobj->NumPoints(); i++) vn[i] = pobj->VertexNormal (i);
#endif
}
}
if (normals.Count()) {
AFRDeformer deformer(mc,f,p,b,pt1,pt2,&normals);
os->obj->Deform(&deformer, TRUE);
} else {
AFRDeformer deformer(mc,f,p,b,pt1,pt2);
os->obj->Deform(&deformer, TRUE);
}
os->obj->UpdateValidity(GEOM_CHAN_NUM,iv);
}
void BonesDefMod::RebuildPaintNodes()
{
//this sends all our dependant nodes to the painter
MyEnumProc dep;
EnumDependents(&dep);
Tab<INode *> nodes;
for (int i = 0; i < nodes.Count(); i++)
{
ObjectState os = nodes[i]->EvalWorldState(GetCOREInterface()->GetTime());
if ( (os.obj->NumPoints() != painterData[i].bmd->VertexData.Count()) ||
(painterData[i].bmd->isPatch) || (painterData[i].bmd->inputObjectIsNURBS) )
{
int ct = painterData[i].bmd->VertexData.Count();
Tab<Point3> pointList;
pointList.SetCount(ct);
Matrix3 tm = nodes[i]->GetObjectTM(GetCOREInterface()->GetTime());
for (int j =0; j < ct; j++)
{
pointList[j] = painterData[i].bmd->VertexData[j]->LocalPosPostDeform*tm;
}
pPainterInterface->LoadCustomPointGather(ct, pointList.Addr(0), nodes[i]);
}
}
pPainterInterface->UpdateMeshes(TRUE);
}
void MNMeshLoop::Build(MNMeshLoopAdvancer &adv, int startid, BitArray &finalsel)
{
// prepare Loopitems
m_items.SetCount(MESHLOOP_ALLOC_ITEMCOUNT);
int allocated = MESHLOOP_ALLOC_ITEMCOUNT;
// add ourself
int itemcnt = 0;
int wave = 1;
MNMeshLoopItem *item = m_items.Addr(0);
item->wave = 0;
item->distance = 0.0f;
item->id = startid;
item->pos = adv.GetPos(startid);
item->prev = NULL;
finalsel.Set(startid);
item++;
itemcnt++;
Tab<MNMeshLoopFront> fronts;
int outcount = adv.SetupFront(startid,fronts);
// then advance each direction
int added = TRUE;
while(added){
added = FALSE;
for (int o = 0; o < outcount; o++){
MNMeshLoopFront *front = fronts.Addr(o);
// loop ended
if (adv.Advance(front,item,itemcnt,wave,finalsel))
continue;
item++;
itemcnt++;
// expand memory (we could use append but well no clue how it resizes)
if (itemcnt%MESHLOOP_ALLOC_ITEMCOUNT == 0){
m_items.SetCount(itemcnt+MESHLOOP_ALLOC_ITEMCOUNT);
item = m_items.Addr(itemcnt);
}
added = TRUE;
}
wave += 1;
}
m_numitems = itemcnt;
}
int MNMeshLoopAdvancerVertex::SetupFront(int startid, Tab<MNMeshLoopFront> &fronts)
{
// first previous is root
// set initial connectors
Tab<int> &connected = m_mesh->vedg[startid];
int outcount = connected.Count();
// for each direction
fronts.SetCount(outcount);
for (int o = 0; o < outcount; o++){
MNMeshLoopFront *advance = fronts.Addr(o);
int nextid = m_mesh->E(connected[o])->OtherVert(startid);
advance->previndex = 0;
advance->nextid = nextid;
advance->connector = connected[o];
advance->crossed = FALSE;
}
return outcount;
}
void PolyOpBevelFace::Do (MNMesh & mesh)
{
// Topological extrusion first:
MNChamferData chamData;
if (mType<2) {
MNFaceClusters fclust(mesh, MN_USER);
if (!mesh.ExtrudeFaceClusters (fclust)) return;
if (mType == 0) {
// Get fresh face clusters:
MNFaceClusters fclustAfter(mesh, MN_USER);
Tab<Point3> clusterNormals, clusterCenters;
fclustAfter.GetNormalsCenters (mesh, clusterNormals, clusterCenters);
mesh.GetExtrudeDirection (&chamData, &fclustAfter, clusterNormals.Addr(0));
} else {
mesh.GetExtrudeDirection (&chamData, MN_USER);
}
} else {
// Polygon-by-polygon extrusion.
if (!mesh.ExtrudeFaces (MN_USER)) return;
MNFaceClusters fclustAfter(mesh, MN_USER);
Tab<Point3> clusterNormals, clusterCenters;
fclustAfter.GetNormalsCenters (mesh, clusterNormals, clusterCenters);
mesh.GetExtrudeDirection (&chamData, &fclustAfter, clusterNormals.Addr(0));
}
int i;
if (mHeight) {
for (i=0; i<mesh.numv; i++) mesh.v[i].p += chamData.vdir[i]*mHeight;
}
if (mOutline) {
MNTempData temp(&mesh);
Tab<Point3> *outDir;
if (mType == 0) outDir = temp.OutlineDir (MESH_EXTRUDE_CLUSTER, MN_USER);
else outDir = temp.OutlineDir (MESH_EXTRUDE_LOCAL, MN_USER);
if (outDir && outDir->Count()) {
Point3 *od = outDir->Addr(0);
for (i=0; i<mesh.numv; i++) mesh.v[i].p += od[i]*mOutline;
}
}
}
//////////////////////////////////////////////////////////////////////////
// MNMeshLoopAdvancerFace
int MNMeshLoopAdvancerFace::SetupFront(int startid, Tab<MNMeshLoopFront> &fronts)
{
// first previous is root
// set initial connectors
MNFace *face = m_mesh->F(startid);
int outcount = face->deg;
// for each direction
fronts.SetCount(outcount);
for (int o = 0; o < outcount; o++){
MNMeshLoopFront *advance = fronts.Addr(o);
int nextid = m_mesh->E(face->edg[o])->OtherFace(startid);
advance->previndex = 0;
advance->nextid = nextid;
advance->connector = face->edg[o];
advance->crossed = FALSE;
}
return outcount;
}
void UVW_ChannelClass::LoadOlderVersions(ILoad *iload)
{
int ct = 0;
ULONG nb = 0;
switch(iload->CurChunkID())
{
case VERTCOUNT_CHUNK:
iload->Read(&ct, sizeof(ct), &nb);
v.SetCount(ct);
break;
case FACECOUNT_CHUNK:
iload->Read(&ct, sizeof(ct), &nb);
SetCountFaces(ct);
break;
/*
case GEOMPOINTSCOUNT_CHUNK:
iload->Read(&ct, sizeof(ct), &nb);
geomPoints.SetCount(ct);
break;
*/
//old way here for legacy reason only
case FACE_CHUNK:
{
// version = 1;
// oldDataPresent = TRUE;
Tab<TVFace> tf;
tf.SetCount(f.Count());
iload->Read(tf.Addr(0), sizeof(TVFace)*f.Count(), &nb);
for (int i=0;i<f.Count();i++)
{
f[i]->count = 3;
f[i]->t = new int[f[i]->count];
f[i]->v = new int[f[i]->count];
f[i]->t[0] = tf[i].t[0];
f[i]->t[1] = tf[i].t[1];
f[i]->t[2] = tf[i].t[2];
f[i]->flags = 0;
f[i]->vecs = NULL;
}
break;
}
//old way here for legacy reason only
case VERTS_CHUNK:
{
Tab<Point3> p;
p.SetCount(v.Count());
// oldDataPresent = TRUE;
iload->Read(p.Addr(0), sizeof(Point3)*v.Count(), &nb);
for (int i=0;i<v.Count();i++)
{
v[i].SetP(p[i]);
v[i].SetFlag(0);
v[i].SetInfluence(0.0f);
v[i].SetControlID(-1);
}
break;
}
case FACE2_CHUNK:
{
Tab<UVW_TVFaceOldClass> oldData;
oldData.SetCount(f.Count());
iload->ReadVoid(oldData.Addr(0), sizeof(UVW_TVFaceOldClass)*oldData.Count(), &nb);
for (int i = 0; i < f.Count(); i++)
{
//fix for bug 281118 it was checking an uniitiliazed flag
if (oldData[i].flags & 8) // not this was FLAG_QUAD but this define got removed
f[i]->count=4;
else f[i]->count=3;
f[i]->t = new int[f[i]->count];
f[i]->v = new int[f[i]->count];
for (int j = 0; j < f[i]->count; j++)
f[i]->t[j] = oldData[i].t[j];
f[i]->FaceIndex = oldData[i].FaceIndex;
f[i]->MatID = oldData[i].MatID;
f[i]->flags = oldData[i].flags;
f[i]->vecs = NULL;
}
/*
//now compute the geom points
for (int i = 0; i < f.Count(); i++)
{
int pcount = 3;
pcount = f[i]->count;
for (int j =0; j < pcount; j++)
{
BOOL found = FALSE;
int index;
for (int k =0; k < geomPoints.Count();k++)
{
if (oldData[i].pt[j] == geomPoints[k])
{
found = TRUE;
index = k;
k = geomPoints.Count();
}
}
if (found)
{
f[i]->v[j] = index;
}
else
{
f[i]->v[j] = geomPoints.Count();
geomPoints.Append(1,&oldData[i].pt[j],1);
}
}
}
*/
break;
}
case FACE4_CHUNK:
LoadFacesMax9(iload);
break;
case VERTS2_CHUNK:
//fix
{
Tab<UVW_TVVertClass_Max9> tempV;
tempV.SetCount(v.Count());
iload->ReadVoid(tempV.Addr(0), sizeof(UVW_TVVertClass_Max9)*v.Count(), &nb);
for (int i=0;i<v.Count();i++)
{
v[i].SetP(tempV[i].p);
v[i].SetFlag(tempV[i].flags);
v[i].SetInfluence(0.0f);
v[i].SetControlID(-1);
}
break;
}
/*
case GEOMPOINTS_CHUNK:
iload->Read(geomPoints.Addr(0), sizeof(Point3)*geomPoints.Count(), &nb);
break;
*/
}
}
void FExtrudeMod::ModifyTriObject (TimeValue t, ModContext &mc, TriObject *tobj) {
Mesh &mesh = tobj->GetMesh();
Interval iv = FOREVER;
float amount, scale;
Point3 center;
int i, j, type;
mp_pblock->GetValue (kFexAmount, t, amount, iv);
mp_pblock->GetValue (kFexScale, t, scale, iv);
mp_pblock->GetValue (kFexType, t, type, iv);
// Extrude the faces -- this just does the topological operation.
MeshDelta tmd(mesh);
tmd.ExtrudeFaces (mesh, mesh.faceSel);
tmd.Apply(mesh);
// Mark vertices used by selected faces
BitArray sel;
sel.SetSize(mesh.getNumVerts());
for (i=0; i<mesh.getNumFaces(); i++) {
if (mesh.faceSel[i]) {
for (int j=0; j<3; j++) sel.Set(mesh.faces[i].v[j],TRUE);
}
}
MeshTempData temp(&mesh);
Point3 *vertexDir;
Tab<Point3> centerBasedBuffer;
if (type<2) {
int extrusionType = type ? MESH_EXTRUDE_LOCAL : MESH_EXTRUDE_CLUSTER;
vertexDir = temp.FaceExtDir(extrusionType)->Addr(0);
} else {
// We need to move all vertices away from the "center".
// Compute the center point
Point3 center;
mp_base->GetValue(t,¢er,iv,CTRL_ABSOLUTE);
// Create array of vertex directions
centerBasedBuffer.SetCount (mesh.numVerts);
vertexDir = centerBasedBuffer.Addr(0);
for (i=0; i<mesh.numVerts; i++) {
if (!sel[i]) continue;
vertexDir[i] = Normalize((mesh.verts[i] * (*mc.tm)) - center);
}
}
// Actually do the move:
for (i=0; i<mesh.numVerts; i++) {
if (!sel[i]) continue;
mesh.verts[i] += amount * vertexDir[i];
}
// Scale verts
if (scale!=1.0f) {
temp.freeAll ();
temp.SetMesh (&mesh);
FaceClusterList *fc = temp.FaceClusters();
Tab<Point3> *centers = temp.ClusterCenters (MESH_FACE);
// Make sure each vertex is only scaled once.
BitArray done;
done.SetSize(mesh.getNumVerts());
// scale each cluster independently
for (i=0; (DWORD)i<fc->count; i++) {
Point3 cent = (centers->Addr(0))[i];
// Scale the cluster about its center
for (j=0; j<mesh.getNumFaces(); j++) {
if (fc->clust[j]==(DWORD)i) {
for (int k=0; k<3; k++) {
int index = mesh.faces[j].v[k];
if (done[index]) continue;
done.Set(index);
mesh.verts[index] = (mesh.verts[index]-cent)*scale + cent;
}
}
}
}
}
mesh.InvalidateTopologyCache ();
tobj->UpdateValidity(GEOM_CHAN_NUM,iv);
}
void FExtrudeMod::ModifyPolyObject (TimeValue t, ModContext &mc, PolyObject *pobj) {
MNMesh &mesh = pobj->GetMesh();
// Luna task 747
// We cannot support specified normals in Face Extrude at this time.
mesh.ClearSpecifiedNormals();
Interval iv = FOREVER;
float amount, scale;
Point3 center;
int type, i, j;
mp_pblock->GetValue (kFexAmount, t, amount, iv);
mp_pblock->GetValue (kFexScale, t, scale, iv);
mp_pblock->GetValue (kFexType, t, type, iv);
MNTempData temp(&mesh);
bool abort=false;
DWORD flag=MN_SEL; // Later can be used to "inherit" selection from other SO levels.
switch (type) {
case 0: // Group normals
abort = !mesh.ExtrudeFaceClusters (*(temp.FaceClusters(flag)));
if (!abort) {
temp.Invalidate (TOPO_CHANNEL); // Forces reevaluation of face clusters.
mesh.GetExtrudeDirection (temp.ChamferData(), temp.FaceClusters(flag),
temp.ClusterNormals (MNM_SL_FACE, flag)->Addr(0));
}
break;
case 1: // Local normals
abort = !mesh.ExtrudeFaceClusters (*(temp.FaceClusters(flag)));
if (!abort) {
temp.Invalidate (TOPO_CHANNEL); // Forces reevaluation of face clusters.
mesh.GetExtrudeDirection (temp.ChamferData(), flag);
}
break;
case 2: // from center:
mp_base->GetValue(t,¢er,iv,CTRL_ABSOLUTE);
abort = !mesh.ExtrudeFaceClusters (*(temp.FaceClusters(flag)));
if (!abort) {
temp.Invalidate (GEOM_CHANNEL);
MNChamferData *mcd = temp.ChamferData();
mcd->InitToMesh (mesh);
mcd->ClearLimits ();
int j, mp;
// Make clear that there are no map values:
for (mp=-NUM_HIDDENMAPS; mp<mesh.numm; mp++) mcd->MDir(mp).SetCount(0);
// Each vertex on flagged faces moves according to the direction from the center:
for (i=0; i<mesh.numv; i++) {
mcd->vdir[i] = Point3(0,0,0);
if (mesh.v[i].GetFlag (MN_DEAD)) continue;
if (!mesh.vfac[i].Count()) continue;
bool hasflagged = false;
for (j=0; j<mesh.vfac[i].Count(); j++) {
MNFace & mf = mesh.f[mesh.vfac[i][j]];
if (!mf.GetFlag (MN_SEL)) continue;
hasflagged = true;
}
if (!hasflagged) continue;
mcd->vdir[i] = Normalize((mesh.P(i)*(*mc.tm))-center);
}
}
break;
}
if (abort) return;
// Move verts
for (i=0; i<mesh.numv; i++) {
if (mesh.v[i].GetFlag (MN_DEAD)) continue;
mesh.v[i].p += temp.ChamferData()->vdir[i]*amount;
}
// Scale verts
if (scale!=1.0f) {
temp.freeAll ();
temp.SetMesh (&mesh);
MNFaceClusters *fc = temp.FaceClusters();
Tab<Point3> *centers = temp.ClusterCenters (MNM_SL_FACE);
// Make sure each vertex is only scaled once.
BitArray done;
done.SetSize(mesh.numv);
// scale each cluster independently
for (i=0; i<fc->count; i++) {
Point3 cent = (centers->Addr(0))[i];
// Scale the cluster about its center
for (j=0; j<mesh.numf; j++) {
if (fc->clust[j]==i) {
for (int k=0; k<mesh.f[j].deg; k++) {
int index = mesh.f[j].vtx[k];
if (done[index]) continue;
done.Set(index);
mesh.v[index].p = (mesh.v[index].p-cent)*scale + cent;
}
}
}
}
}
mesh.InvalidateTopoCache ();
mesh.FillInMesh ();
pobj->UpdateValidity(GEOM_CHAN_NUM,iv);
}
void RelaxMod::ModifyObject(TimeValue t, ModContext &mc, ObjectState * os, INode *node) {
// Get our personal validity interval...
Interval valid = GetValidity(t);
// and intersect it with the channels we use as input (see ChannelsUsed)
valid &= os->obj->ChannelValidity (t, GEOM_CHAN_NUM);
valid &= os->obj->ChannelValidity (t, TOPO_CHAN_NUM);
valid &= os->obj->ChannelValidity (t, SUBSEL_TYPE_CHAN_NUM);
valid &= os->obj->ChannelValidity (t, SELECT_CHAN_NUM);
Matrix3 modmat,minv;
if (mc.localData == NULL) mc.localData = new RelaxModData;
RelaxModData *rd = (RelaxModData *) mc.localData;
TriObject *triObj = NULL;
PatchObject *patchObj = NULL;
PolyObject *polyObj = NULL;
BOOL converted = FALSE;
// For version 4 and later, we process patch or poly meshes as they are and pass them on.
// Earlier versions converted to TriMeshes (done below).
// For adding other new types of objects, add them here!
#ifndef NO_PATCHES
if(version >= RELAXMOD_VER4 && os->obj->IsSubClassOf(patchObjectClassID)) {
patchObj = (PatchObject *)os->obj;
}
else // If it's a TriObject, process it
#endif // NO_PATCHES
if(os->obj->IsSubClassOf(triObjectClassID)) {
triObj = (TriObject *)os->obj;
}
else if (os->obj->IsSubClassOf (polyObjectClassID)) {
polyObj = (PolyObject *) os->obj;
}
else // If it can convert to a TriObject, do it
if(os->obj->CanConvertToType(triObjectClassID)) {
triObj = (TriObject *)os->obj->ConvertToType(t, triObjectClassID);
converted = TRUE;
}
else
return; // We can't deal with it!
Mesh *mesh = triObj ? &(triObj->GetMesh()) : NULL;
#ifndef NO_PATCHES
PatchMesh &pmesh = patchObj ? patchObj->GetPatchMesh(t) : *((PatchMesh *)NULL);
#else
PatchMesh &pmesh = *((PatchMesh *)NULL);
#endif // NO_PATCHES
float relax, wtdRelax; // mjm - 4.8.99
int iter;
BOOL boundary, saddle;
pblock->GetValue (PB_RELAX, t, relax, FOREVER);
pblock->GetValue (PB_ITER, t, iter, FOREVER);
pblock->GetValue (PB_BOUNDARY, t, boundary, FOREVER);
pblock->GetValue (PB_SADDLE, t, saddle, FOREVER);
LimitValue (relax, MIN_RELAX, MAX_RELAX);
LimitValue (iter, MIN_ITER, MAX_ITER);
if(triObj) {
int i, j, max;
DWORD selLevel = mesh->selLevel;
// mjm - 4.8.99 - add support for soft selection
// sca - 4.29.99 - extended soft selection support to cover EDGE and FACE selection levels.
float *vsw = (selLevel!=MESH_OBJECT) ? mesh->getVSelectionWeights() : NULL;
if (rd->ivalid.InInterval(t) && (mesh->numVerts != rd->vnum)) {
// Shouldn't happen, but does with Loft bug and may with other bugs.
rd->ivalid.SetEmpty ();
}
if (!rd->ivalid.InInterval(t)) {
rd->SetVNum (mesh->numVerts);
for (i=0; i<rd->vnum; i++) {
rd->fnum[i]=0;
rd->nbor[i].ZeroCount();
}
rd->sel.ClearAll ();
DWORD *v;
int k1, k2, origmax;
for (i=0; i<mesh->numFaces; i++) {
v = mesh->faces[i].v;
for (j=0; j<3; j++) {
if ((selLevel==MESH_FACE) && mesh->faceSel[i]) rd->sel.Set(v[j]);
if ((selLevel==MESH_EDGE) && mesh->edgeSel[i*3+j]) rd->sel.Set(v[j]);
if ((selLevel==MESH_EDGE) && mesh->edgeSel[i*3+(j+2)%3]) rd->sel.Set(v[j]);
origmax = max = rd->nbor[v[j]].Count();
rd->fnum[v[j]]++;
for (k1=0; k1<max; k1++) if (rd->nbor[v[j]][k1] == v[(j+1)%3]) break;
if (k1==max) { rd->nbor[v[j]].Append (1, v+(j+1)%3, 1); max++; }
for (k2=0; k2<max; k2++) if (rd->nbor[v[j]][k2] == v[(j+2)%3]) break;
if (k2==max) { rd->nbor[v[j]].Append (1, v+(j+2)%3, 1); max++; }
if (max>origmax) rd->vis[v[j]].SetSize (max, TRUE);
if (mesh->faces[i].getEdgeVis (j)) rd->vis[v[j]].Set (k1);
else if (k1>=origmax) rd->vis[v[j]].Clear (k1);
if (mesh->faces[i].getEdgeVis ((j+2)%3)) rd->vis[v[j]].Set (k2);
else if (k2>= origmax) rd->vis[v[j]].Clear (k2);
}
}
// mjm - begin - 4.8.99
// if (selLevel==MESH_VERTEX) rd->sel = mesh->vertSel;
if (selLevel==MESH_VERTEX)
rd->sel = mesh->vertSel;
else if (selLevel==MESH_OBJECT)
rd->sel.SetAll ();
// mjm - end
rd->ivalid = os->obj->ChannelValidity (t, TOPO_CHAN_NUM);
rd->ivalid &= os->obj->ChannelValidity (t, SUBSEL_TYPE_CHAN_NUM);
rd->ivalid &= os->obj->ChannelValidity (t, SELECT_CHAN_NUM);
}
Tab<float> vangles;
if (saddle) vangles.SetCount (rd->vnum);
Point3 *hold = new Point3[rd->vnum];
int act;
for (int k=0; k<iter; k++) {
for (i=0; i<rd->vnum; i++) hold[i] = triObj->GetPoint(i);
if (saddle) mesh->FindVertexAngles (vangles.Addr(0));
for (i=0; i<rd->vnum; i++) {
// mjm - begin - 4.8.99
// if ((selLevel!=MESH_OBJECT) && (!rd->sel[i])) continue;
if ( (!rd->sel[i] ) && (!vsw || vsw[i] == 0) ) continue;
// mjm - end
if (saddle && (vangles[i] <= 2*PI*.99999f)) continue;
max = rd->nbor[i].Count();
if (boundary && (rd->fnum[i] < max)) continue;
if (max<1) continue;
Point3 avg(0.0f, 0.0f, 0.0f);
for (j=0,act=0; j<max; j++) {
if (!rd->vis[i][j]) continue;
act++;
avg += hold[rd->nbor[i][j]];
}
if (act<1) continue;
// mjm - begin - 4.8.99
wtdRelax = (!rd->sel[i]) ? relax * vsw[i] : relax;
triObj->SetPoint (i, hold[i]*(1-wtdRelax) + avg*wtdRelax/((float)act));
// triObj->SetPoint (i, hold[i]*(1-relax) + avg*relax/((float)act));
// mjm - end
}
}
delete [] hold;
}
if (polyObj) {
int i, j, max;
MNMesh & mm = polyObj->mm;
float *vsw = (mm.selLevel!=MNM_SL_OBJECT) ? mm.getVSelectionWeights() : NULL;
if (rd->ivalid.InInterval(t) && (mm.numv != rd->vnum)) {
// Shouldn't happen, but does with Loft bug and may with other bugs.
rd->ivalid.SetEmpty ();
}
if (!rd->ivalid.InInterval(t)) {
rd->SetVNum (mm.numv);
for (i=0; i<rd->vnum; i++) {
rd->fnum[i]=0;
rd->nbor[i].ZeroCount();
}
rd->sel = mm.VertexTempSel ();
int k1, k2, origmax;
for (i=0; i<mm.numf; i++) {
int deg = mm.f[i].deg;
int *vtx = mm.f[i].vtx;
for (j=0; j<deg; j++) {
Tab<DWORD> & nbor = rd->nbor[vtx[j]];
origmax = max = nbor.Count();
rd->fnum[vtx[j]]++;
DWORD va = vtx[(j+1)%deg];
DWORD vb = vtx[(j+deg-1)%deg];
for (k1=0; k1<max; k1++) if (nbor[k1] == va) break;
if (k1==max) { nbor.Append (1, &va, 1); max++; }
for (k2=0; k2<max; k2++) if (nbor[k2] == vb) break;
if (k2==max) { nbor.Append (1, &vb, 1); max++; }
}
}
rd->ivalid = os->obj->ChannelValidity (t, TOPO_CHAN_NUM);
rd->ivalid &= os->obj->ChannelValidity (t, SUBSEL_TYPE_CHAN_NUM);
rd->ivalid &= os->obj->ChannelValidity (t, SELECT_CHAN_NUM);
}
Tab<float> vangles;
if (saddle) vangles.SetCount (rd->vnum);
Tab<Point3> hold;
hold.SetCount (rd->vnum);
int act;
for (int k=0; k<iter; k++) {
for (i=0; i<rd->vnum; i++) hold[i] = mm.P(i);
if (saddle) FindVertexAngles (mm, vangles.Addr(0));
for (i=0; i<rd->vnum; i++) {
if ((!rd->sel[i]) && (!vsw || vsw[i] == 0) ) continue;
if (saddle && (vangles[i] <= 2*PI*.99999f)) continue;
max = rd->nbor[i].Count();
if (boundary && (rd->fnum[i] < max)) continue;
if (max<1) continue;
Point3 avg(0.0f, 0.0f, 0.0f);
for (j=0,act=0; j<max; j++) {
act++;
avg += hold[rd->nbor[i][j]];
}
if (act<1) continue;
wtdRelax = (!rd->sel[i]) ? relax * vsw[i] : relax;
polyObj->SetPoint (i, hold[i]*(1-wtdRelax) + avg*wtdRelax/((float)act));
}
}
}
#ifndef NO_PATCHES
else
if(patchObj) {
int i, j, max;
DWORD selLevel = pmesh.selLevel;
// mjm - 4.8.99 - add support for soft selection
// sca - 4.29.99 - extended soft selection support to cover EDGE and FACE selection levels.
float *vsw = (selLevel!=PATCH_OBJECT) ? pmesh.GetVSelectionWeights() : NULL;
if (rd->ivalid.InInterval(t) && (pmesh.numVerts != rd->vnum)) {
// Shouldn't happen, but does with Loft bug and may with other bugs.
rd->ivalid.SetEmpty ();
}
if (!rd->ivalid.InInterval(t)) {
int vecBase = pmesh.numVerts;
rd->SetVNum (pmesh.numVerts + pmesh.numVecs);
for (i=0; i<rd->vnum; i++) {
rd->fnum[i]=1; // For patches, this means it's not a boundary
rd->nbor[i].ZeroCount();
}
rd->sel.ClearAll ();
for (i=0; i<pmesh.numPatches; i++) {
Patch &p = pmesh.patches[i];
int vecLimit = p.type * 2;
for (j=0; j<p.type; j++) {
PatchEdge &e = pmesh.edges[p.edge[j]];
BOOL isBoundary = (e.patches.Count() < 2) ? TRUE : FALSE;
int theVert = p.v[j];
int nextVert = p.v[(j+1)%p.type];
int nextVec = p.vec[j*2] + vecBase;
int nextVec2 = p.vec[j*2+1] + vecBase;
int prevEdge = (j+p.type-1)%p.type;
int prevVec = p.vec[prevEdge*2+1] + vecBase;
int prevVec2 = p.vec[prevEdge*2] + vecBase;
int theInterior = p.interior[j] + vecBase;
// Establish selection bits
if ((selLevel==PATCH_PATCH) && pmesh.patchSel[i]) {
rd->sel.Set(theVert);
rd->sel.Set(nextVec);
rd->sel.Set(prevVec);
rd->sel.Set(theInterior);
}
else
if ((selLevel==PATCH_EDGE) && pmesh.edgeSel[p.edge[j]]) {
rd->sel.Set(e.v1);
rd->sel.Set(e.vec12 + vecBase);
rd->sel.Set(e.vec21 + vecBase);
rd->sel.Set(e.v2);
}
else
if ((selLevel==PATCH_VERTEX) && pmesh.vertSel[theVert]) {
rd->sel.Set(theVert);
rd->sel.Set(nextVec);
rd->sel.Set(prevVec);
rd->sel.Set(theInterior);
}
// Set boundary flags if necessary
if(isBoundary) {
rd->fnum[theVert] = 0;
rd->fnum[nextVec] = 0;
rd->fnum[nextVec2] = 0;
rd->fnum[nextVert] = 0;
}
// First process the verts
int work = theVert;
max = rd->nbor[work].Count();
// Append the neighboring vectors
rd->MaybeAppendNeighbor(work, nextVec, max);
rd->MaybeAppendNeighbor(work, prevVec, max);
rd->MaybeAppendNeighbor(work, theInterior, max);
// Now process the edge vectors
work = nextVec;
max = rd->nbor[work].Count();
// Append the neighboring points
rd->MaybeAppendNeighbor(work, theVert, max);
rd->MaybeAppendNeighbor(work, theInterior, max);
rd->MaybeAppendNeighbor(work, prevVec, max);
rd->MaybeAppendNeighbor(work, nextVec2, max);
rd->MaybeAppendNeighbor(work, p.interior[(j+1)%p.type] + vecBase, max);
work = prevVec;
max = rd->nbor[work].Count();
// Append the neighboring points
rd->MaybeAppendNeighbor(work, theVert, max);
rd->MaybeAppendNeighbor(work, theInterior, max);
rd->MaybeAppendNeighbor(work, nextVec, max);
rd->MaybeAppendNeighbor(work, prevVec2, max);
rd->MaybeAppendNeighbor(work, p.interior[(j+p.type-1)%p.type] + vecBase, max);
// Now append the interior, if not auto
if(!p.IsAuto()) {
work = theInterior;
max = rd->nbor[work].Count();
// Append the neighboring points
rd->MaybeAppendNeighbor(work, p.v[j], max);
rd->MaybeAppendNeighbor(work, nextVec, max);
rd->MaybeAppendNeighbor(work, nextVec2, max);
rd->MaybeAppendNeighbor(work, prevVec, max);
rd->MaybeAppendNeighbor(work, prevVec2, max);
for(int k = 1; k < p.type; ++k)
rd->MaybeAppendNeighbor(work, p.interior[(j+k)%p.type] + vecBase, max);
}
}
}
// mjm - begin - 4.8.99
if (selLevel==PATCH_VERTEX) {
for (int i=0; i<pmesh.numVerts; ++i) {
if (pmesh.vertSel[i]) rd->sel.Set(i);
}
}
else if (selLevel==PATCH_OBJECT) rd->sel.SetAll();
// mjm - end
rd->ivalid = os->obj->ChannelValidity (t, TOPO_CHAN_NUM);
rd->ivalid &= os->obj->ChannelValidity (t, SUBSEL_TYPE_CHAN_NUM);
rd->ivalid &= os->obj->ChannelValidity (t, SELECT_CHAN_NUM);
}
Tab<float> vangles;
if (saddle) vangles.SetCount (rd->vnum);
Point3 *hold = new Point3[rd->vnum];
int act;
for (int k=0; k<iter; k++) {
for (i=0; i<rd->vnum; i++) hold[i] = patchObj->GetPoint(i);
if (saddle)
FindVertexAngles(pmesh, vangles.Addr(0));
for (i=0; i<rd->vnum; i++) {
// mjm - begin - 4.8.99
// if ((selLevel!=MESH_OBJECT) && (!rd->sel[i])) continue;
if ( (!rd->sel[i] ) && (!vsw || vsw[i] == 0) ) continue;
// mjm - end
if (saddle && (i < pmesh.numVerts) && (vangles[i] <= 2*PI*.99999f)) continue;
max = rd->nbor[i].Count();
if (boundary && !rd->fnum[i]) continue;
if (max<1)
continue;
Point3 avg(0.0f, 0.0f, 0.0f);
for (j=0,act=0; j<max; j++) {
act++;
avg += hold[rd->nbor[i][j]];
}
if (act<1)
continue;
// mjm - begin - 4.8.99
wtdRelax = (!rd->sel[i]) ? relax * vsw[i] : relax;
patchObj->SetPoint (i, hold[i]*(1-wtdRelax) + avg*wtdRelax/((float)act));
// patchObj->SetPoint (i, hold[i]*(1-relax) + avg*relax/((float)act));
// mjm - end
}
}
delete [] hold;
patchObj->patch.computeInteriors();
patchObj->patch.ApplyConstraints();
}
#endif // NO_PATCHES
if(!converted) {
os->obj->SetChannelValidity(GEOM_CHAN_NUM, valid);
} else {
// Stuff converted object into the pipeline!
triObj->SetChannelValidity(TOPO_CHAN_NUM, valid);
triObj->SetChannelValidity(GEOM_CHAN_NUM, valid);
triObj->SetChannelValidity(TEXMAP_CHAN_NUM, valid);
triObj->SetChannelValidity(MTL_CHAN_NUM, valid);
triObj->SetChannelValidity(SELECT_CHAN_NUM, valid);
triObj->SetChannelValidity(SUBSEL_TYPE_CHAN_NUM, valid);
triObj->SetChannelValidity(DISP_ATTRIB_CHAN_NUM, valid);
os->obj = triObj;
}
}
//Some helper functions to handle painter UI
void PaintDeformTest::Paint()
{
if (pPainter) //need to check this since some one could have taken the painterinterface plugin out
{
if (!pPainter->InPaintMode())
{
pPainter->InitializeCallback(this); //initialize the callback
//load up our nodes
//gather up all our nodes and local data and store em off
MyEnumProc dep;
DoEnumDependents(&dep);
Tab<INode *> nodes;
Tab<ObjectState> objList;
painterNodeList.ZeroCount();
TimeValue t = GetCOREInterface()->GetTime();
for (int i = 0; i < dep.Nodes.Count(); i++)
{
PaintDefromModData *pmd = GetPMD(dep.Nodes[i]);
if (pmd)
{
nodes.Append(1,&dep.Nodes[i]);
PainterNodeList temp;
temp.node = dep.Nodes[i];
temp.pmd = pmd;
temp.tmToLocalSpace = Inverse(dep.Nodes[i]->GetObjectTM(GetCOREInterface()->GetTime()));
painterNodeList.Append(1,&temp);
ObjectState sos;
sos = dep.Nodes[i]->EvalWorldState(t);
objList.Append(1,&sos);
}
}
//we use the point gather so we need to tell the system to turn it on
pPainter->SetEnablePointGather(TRUE);
pPainter->SetBuildNormalData(TRUE);
//this sends all our dependant nodes to the painter
pPainter->InitializeNodesByObjState(0, nodes,objList);
BOOL updateMesh = FALSE;
for (int i = 0; i < nodes.Count(); i++)
{
ObjectState os = nodes[i]->EvalWorldState(GetCOREInterface()->GetTime());
int ct = os.obj->NumPoints();
//is our local vertex count does not match or the curremt object count we have some
//sort of topo change above us so we need to load a custom point list
//We really need add normals here
//so right now this does not work with patches, nurbs or things that have different topos at the top
//top of the stack
if (os.obj->NumPoints() != painterNodeList[i].pmd->offsetList.Count())
{
Tab<Point3> pointList;
pointList.SetCount(ct);
Matrix3 tm = nodes[i]->GetObjectTM(GetCOREInterface()->GetTime());
for (int j =0; j < ct; j++)
{
pointList[j] = os.obj->GetPoint(j)*tm;
}
pPainter->LoadCustomPointGather(ct, pointList.Addr(0), nodes[i]);
updateMesh = TRUE;
}
}
//reinitialize our nodes if we had a custom list
if (updateMesh)
pPainter->UpdateMeshesByObjState(TRUE,objList);
pPainter->StartPaintSession(); //start the paint session
iPaintButton->SetCheck(TRUE);
}
else //we are currently in a paint mode so turn it off
{
pPainter->EndPaintSession(); //end the paint session
iPaintButton->SetCheck(FALSE);
}
}
}
int TriObject::Display(TimeValue t, INode *inode, ViewExp* vpt, int flags) {
if ( ! vpt || ! vpt->IsAlive() )
{
// why are we here
DbgAssert(!_T("Invalid viewport!"));
return FALSE;
}
float *vsw = NULL;
DWORD oldRndLimits, newRndLimits;
Tab<VertColor> vertexSelColors;
Tab<TVFace> vertexSelFaces;
Matrix3 tm;
GraphicsWindow *gw = vpt->getGW();
gw->setTransform(inode->GetObjectTM(t));
newRndLimits = oldRndLimits = gw->getRndLimits();
// CAL-11/16/01: Use soft selection colors when soft selection is turned on in sub-object mode.
// The condition is satisfied if the display of vertex/edge/face/poly is requested and
// the vertex selection weights are set.
// CAL-12/02/01: Add one more checking to the condition to check if the display of soft
// selection using wireframe or vertex color shading is requested.
// CAL-11/16/01: (TODO) To imporvement the performance of this function,
// vertexSelColors & vertexSelFaces tables can be cached (in Mesh) and used as long as
// the vertex selection weights are not changed.
bool dspSoftSelVert = ((gw->getRndMode()&GW_VERT_TICKS) ||
((mesh.dispFlags&DISP_VERTTICKS) && (flags&DISP_SHOWSUBOBJECT))) &&
(mesh.dispFlags&DISP_SELVERTS);
bool dspSoftSelEdFc = ((mesh.dispFlags&DISP_SELEDGES) || (mesh.dispFlags&DISP_SELFACES) ||
(mesh.dispFlags&DISP_SELPOLYS)) && (flags&DISP_SHOWSUBOBJECT);
bool dspWireSoftSel = (oldRndLimits&GW_WIREFRAME) ||
((oldRndLimits&GW_COLOR_VERTS) && (inode->GetVertexColorType() == nvct_soft_select));
if ((dspSoftSelVert || dspSoftSelEdFc) && dspWireSoftSel &&
(vsw = mesh.getVSelectionWeights())) {
Point3 clr = GetUIColor(COLOR_VERT_TICKS);
vertexSelColors.SetCount(mesh.getNumVerts());
vertexSelFaces.SetCount(mesh.getNumFaces());
// Create the array of colors, one per vertex:
for (int i=0; i<mesh.getNumVerts(); i++) {
// (Note we may want a different color - this gives the appropriate vertex-tick
// color, which we may not want to use on faces. Fades from blue to red.)
vertexSelColors[i] = (vsw[i]) ? SoftSelectionColor(vsw[i]) : clr;
}
// Copy over the face topology exactly to the map face topology:
for (i=0; i<mesh.getNumFaces(); i++) {
DWORD *pv = mesh.faces[i].v;
vertexSelFaces[i].setTVerts(pv[0], pv[1], pv[2]);
}
// CAL-05/21/02: make sure there's data before accessing it.
// Set the mesh to use these colors:
mesh.setVCDisplayData (MESH_USE_EXT_CVARRAY,
(vertexSelColors.Count() > 0) ? vertexSelColors.Addr(0) : NULL,
(vertexSelFaces.Count() > 0) ? vertexSelFaces.Addr(0) : NULL);
// Turn on vertex color mode
if (oldRndLimits&GW_WIREFRAME) {
newRndLimits |= GW_COLOR_VERTS; // turn on vertex colors
newRndLimits &= ~GW_SHADE_CVERTS; // turn off vertex color shading
newRndLimits |= GW_ILLUM; // turn on lit wire frame
gw->setRndLimits(newRndLimits);
}
} else {
switch (inode->GetVertexColorType()) {
case nvct_color:
if (mesh.curVCChan == 0) break;
mesh.setVCDisplayData (0);
break;
case nvct_illumination:
if (mesh.curVCChan == MAP_SHADING) break;
mesh.setVCDisplayData (MAP_SHADING);
break;
case nvct_alpha:
if (mesh.curVCChan == MAP_ALPHA) break;
mesh.setVCDisplayData (MAP_ALPHA);
break;
//case nvct_color_plus_illum:
// if (mesh.curVCChan == MESH_USE_EXT_CVARRAY) break;
// Where do I cache the arrays I'll need to create from the color and illum arrays?
// break;
// CAL-06/15/03: add a new option to view map channel as vertex color. (FID #1926)
case nvct_map_channel:
if (mesh.curVCChan == inode->GetVertexColorMapChannel()) break;
mesh.setVCDisplayData (inode->GetVertexColorMapChannel());
break;
case nvct_soft_select:
// Turn off vertex color if soft selection is not on.
if (oldRndLimits&GW_COLOR_VERTS) {
newRndLimits &= ~GW_COLOR_VERTS;
gw->setRndLimits(newRndLimits);
}
break;
}
}
mesh.render( gw, inode->Mtls(),
(flags&USE_DAMAGE_RECT) ? &vpt->GetDammageRect() : NULL,
COMP_ALL | ((flags&DISP_SHOWSUBOBJECT)?COMP_OBJSELECTED:0),
inode->NumMtls(), (InterfaceServer*)this); // NS: 9/22/00 Added IXTCAccess argument for Vertex Shader support.
// RB: The mesh flag COMP_OBJSELECTED is sort of misnamed. When this bit is set, sub object things (like ticks and selected faces) will be drawn.
if ( vsw )
mesh.setVCDisplayData (MESH_USE_EXT_CVARRAY);
if (newRndLimits != oldRndLimits)
gw->setRndLimits(oldRndLimits);
return(0);
}
void BonesDefMod::CanvasStartPaint()
{
if (iPaintButton!=NULL) iPaintButton->SetCheck(TRUE);
pPainterInterface->SetBuildNormalData(FALSE);
pPainterInterface->SetEnablePointGather(TRUE);
//this sends all our dependant nodes to the painter
MyEnumProc dep;
EnumDependents(&dep);
Tab<INode *> nodes;
painterData.ZeroCount();
for (int i = 0; i < dep.Nodes.Count(); i++)
{
BoneModData *bmd = GetBMD(dep.Nodes[i]);
if (bmd)
{
nodes.Append(1,&dep.Nodes[i]);
ObjectState os;
PainterSaveData temp;
temp.node = dep.Nodes[i];
temp.bmd = bmd;
painterData.Append(1,&temp);
}
}
pPainterInterface->InitializeNodes(0, nodes);
BOOL updateMesh = FALSE;
for (i = 0; i < nodes.Count(); i++)
{
ObjectState os = nodes[i]->EvalWorldState(GetCOREInterface()->GetTime());
if ( (os.obj->NumPoints() != painterData[i].bmd->VertexData.Count()) ||
(painterData[i].bmd->isPatch) || (painterData[i].bmd->inputObjectIsNURBS) )
{
int ct = painterData[i].bmd->VertexData.Count();
Tab<Point3> pointList;
pointList.SetCount(ct);
Matrix3 tm = nodes[i]->GetObjectTM(GetCOREInterface()->GetTime());
for (int j =0; j < ct; j++)
{
pointList[j] = painterData[i].bmd->VertexData[j]->LocalPosPostDeform*tm;
}
pPainterInterface->LoadCustomPointGather(ct, pointList.Addr(0), nodes[i]);
updateMesh = TRUE;
}
}
if (updateMesh)
pPainterInterface->UpdateMeshes(TRUE);
//get mirror nodeindex
SetMirrorBone();
for (i = 0; i < nodes.Count(); i++)
{
painterData[i].node->FlagForeground(GetCOREInterface()->GetTime());
}
//5.1.03
for (i = 0; i < painterData.Count(); i++)
{
BoneModData *bmd = painterData[i].bmd;
//5.1.05
bmd->BuildEdgeList();
}
}
