void NifImporter::SetNormals(Mesh& mesh, const vector<Niflib::Triangle>& tris, const vector<Niflib::Vector3>& n)
{
mesh.checkNormals(TRUE);
if (n.size() > 0)
{
bool needNormals = false;
for (unsigned int i=0; i<n.size(); i++){
Vector3 v = n[i];
Point3 norm(v.x, v.y, v.z);
if (norm != mesh.getNormal(i)) {
needNormals = true;
break;
}
}
if (needNormals)
{
#if VERSION_3DSMAX > ((5000<<16)+(15<<8)+0) // Version 5
mesh.SpecifyNormals();
MeshNormalSpec *specNorms = mesh.GetSpecifiedNormals ();
if (NULL != specNorms)
{
specNorms->ClearAndFree();
specNorms->SetNumFaces(tris.size());
specNorms->SetNumNormals(n.size());
Point3* norms = specNorms->GetNormalArray();
for (unsigned int i=0; i<n.size(); i++){
Vector3 v = n[i];
norms[i] = Point3(v.x, v.y, v.z);
}
MeshNormalFace* pFaces = specNorms->GetFaceArray();
for (unsigned int i=0; i<tris.size(); i++){
const Triangle& tri = tris[i];
pFaces[i].SpecifyNormalID(0, tri.v1);
pFaces[i].SpecifyNormalID(1, tri.v2);
pFaces[i].SpecifyNormalID(2, tri.v3);
}
#if VERSION_3DSMAX > ((7000<<16)+(15<<8)+0) // Version 7+
specNorms->SetAllExplicit(true);
#else
for (int i=0; i<specNorms->GetNumNormals(); ++i) {
specNorms->SetNormalExplicit(i, true);
}
#endif
specNorms->CheckNormals();
}
#endif
}
}
}
Exporter::Result Exporter::exportMesh(NiNodeRef &ninode, INode *node, TimeValue t)
{
ObjectState os = node->EvalWorldState(t);
bool local = !mFlattenHierarchy;
TriObject *tri = (TriObject *)os.obj->ConvertToType(t, Class_ID(TRIOBJ_CLASS_ID, 0));
if (!tri)
return Skip;
Mesh *copymesh = NULL;
Mesh *mesh = &tri->GetMesh();
Matrix3 mtx(true), rtx(true);
if (Exporter::mCollapseTransforms)
{
mtx = GetNodeLocalTM(node, t);
mtx.NoTrans();
Quat q(mtx);
q.MakeMatrix(rtx);
mesh = copymesh = new Mesh(*mesh);
{
int n = mesh->getNumVerts();
for ( unsigned int i = 0; i < n; ++i ) {
Point3& vert = mesh->getVert(i);
vert = mtx * vert;
}
mesh->checkNormals(TRUE);
#if VERSION_3DSMAX > ((5000<<16)+(15<<8)+0) // Version 6+
MeshNormalSpec *specNorms = mesh->GetSpecifiedNormals ();
if (NULL != specNorms) {
specNorms->CheckNormals();
for ( unsigned int i = 0; i < specNorms->GetNumNormals(); ++i ) {
Point3& norm = specNorms->Normal(i);
norm = (rtx * norm).Normalize();
}
}
#endif
}
}
// Note that calling setVCDisplayData will clear things like normals so we set this up first
vector<Color4> vertColors;
if (mVertexColors)
{
bool hasvc = false;
if (mesh->mapSupport(MAP_ALPHA))
{
mesh->setVCDisplayData(MAP_ALPHA); int n = mesh->getNumVertCol();
if (n > vertColors.size())
vertColors.assign(n, Color4(1.0f, 1.0f, 1.0f, 1.0f));
VertColor *vertCol = mesh->vertColArray;
if (vertCol) {
for (int i=0; i<n; ++i) {
VertColor c = vertCol[ i ];
float a = (c.x + c.y + c.z) / 3.0f;
vertColors[i].a = a;
hasvc |= (a != 1.0f);
}
}
}
if (mesh->mapSupport(0))
{
mesh->setVCDisplayData(0);
VertColor *vertCol = mesh->vertColArray;
int n = mesh->getNumVertCol();
if (n > vertColors.size())
vertColors.assign(n, Color4(1.0f, 1.0f, 1.0f, 1.0f));
if (vertCol) {
for (int i=0; i<n; ++i) {
VertColor col = vertCol[ i ];
vertColors[i] = Color4(col.x, col.y, col.z, vertColors[i].a);
hasvc |= (col.x != 1.0f || col.y != 1.0f || col.z != 1.0f);
}
}
}
if (!hasvc) vertColors.clear();
}
#if VERSION_3DSMAX <= ((5000<<16)+(15<<8)+0) // Version 5
mesh->checkNormals(TRUE);
#else
MeshNormalSpec *specNorms = mesh->GetSpecifiedNormals ();
if (NULL != specNorms) {
specNorms->CheckNormals();
if (specNorms->GetNumNormals() == 0)
mesh->checkNormals(TRUE);
} else {
mesh->checkNormals(TRUE);
}
#endif
Result result = Ok;
Modifier* geomMorpherMod = GetMorpherModifier(node);
bool noSplit = FALSE;
// bool noSplit = (NULL != geomMorpherMod);
while (1)
{
FaceGroups grps;
if (!splitMesh(node, *mesh, grps, t, vertColors, noSplit))
{
result = Error;
break;
}
bool exportStrips = mTriStrips && (Exporter::mNifVersionInt > VER_4_2_2_0);
Matrix44 tm = Matrix44::IDENTITY;
if ( mExportExtraNodes || (mExportType != NIF_WO_ANIM && isNodeKeyed(node) ) ) {
tm = TOMATRIX4(getObjectTransform(node, t, false) * Inverse(getNodeTransform(node, t, false)));
} else {
Matrix33 rot; Vector3 trans;
objectTransform(rot, trans, node, t, local);
tm = Matrix44(trans, rot, 1.0f);
}
tm = TOMATRIX4(Inverse(mtx)) * tm;
TSTR basename = node->NodeName();
TSTR format = (!basename.isNull() && grps.size() > 1) ? "%s:%d" : "%s";
int i=1;
FaceGroups::iterator grp;
for (grp=grps.begin(); grp!=grps.end(); ++grp, ++i)
{
string name = FormatString(format, basename.data(), i);
NiTriBasedGeomRef shape = makeMesh(ninode, getMaterial(node, grp->first), grp->second, exportStrips);
if (shape == NULL)
{
result = Error;
break;
}
if (node->IsHidden())
shape->SetVisibility(false);
shape->SetName(name);
shape->SetLocalTransform(tm);
if (Exporter::mZeroTransforms) {
shape->ApplyTransforms();
}
makeSkin(shape, node, grp->second, t);
if (geomMorpherMod) {
vector<Vector3> verts = shape->GetData()->GetVertices();
exportGeomMorpherControl(geomMorpherMod, verts, shape->GetData()->GetVertexIndices(), shape);
shape->GetData()->SetConsistencyFlags(CT_VOLATILE);
}
}
break;
}
if (tri != os.obj)
tri->DeleteMe();
if (copymesh)
delete copymesh;
return result;
}
bool NifImporter::ImportMultipleGeometry(NiNodeRef parent, vector<NiTriBasedGeomRef>& glist)
{
bool ok = true;
if (glist.empty()) return false;
ImpNode *node = i->CreateNode();
if(!node) return false;
INode *inode = node->GetINode();
TriObject *triObject = CreateNewTriObject();
node->Reference(triObject);
string name = parent->GetName();
node->SetName(wide(name).c_str());
// Texture
Mesh& mesh = triObject->GetMesh();
vector< pair<int, int> > vert_range, tri_range;
vector<Triangle> tris;
vector<Vector3> verts;
int submats = glist.size();
// Build list of vertices and triangles. Optional components like normals will be handled later.
for (vector<NiTriBasedGeomRef>::iterator itr = glist.begin(), end = glist.end(); itr != end; ++itr) {
NiTriBasedGeomDataRef triGeomData = StaticCast<NiTriBasedGeomData>((*itr)->GetData());
// Get verts and collapse local transform into them
int nVertices = triGeomData->GetVertexCount();
vector<Vector3> subverts = triGeomData->GetVertices();
Matrix44 transform = (*itr)->GetLocalTransform();
//Apply the transformations
if (transform != Matrix44::IDENTITY) {
for ( unsigned int i = 0; i < subverts.size(); ++i )
subverts[i] = transform * subverts[i];
}
vert_range.push_back( pair<int,int>( verts.size(), verts.size() + subverts.size()) );
verts.insert(verts.end(), subverts.begin(), subverts.end());
vector<Triangle> subtris = triGeomData->GetTriangles();
for (vector<Triangle>::iterator itr = subtris.begin(), end = subtris.end(); itr != end; ++itr) {
(*itr).v1 += nVertices, (*itr).v2 += nVertices, (*itr).v3 += nVertices;
}
tri_range.push_back( pair<int,int>( tris.size(), tris.size() + subtris.size()) );
tris.insert(tris.end(), subtris.begin(), subtris.end());
}
// Transform up-to-parent
Matrix44 baseTM = (importBones) ? Matrix44::IDENTITY : parent->GetWorldTransform();
node->SetTransform(0,TOMATRIX3(baseTM));
// Set vertices and triangles
mesh.setNumVerts(verts.size());
mesh.setNumTVerts(verts.size(), TRUE);
for (int i=0, n=verts.size(); i < n; ++i){
Vector3 &v = verts[i];
mesh.verts[i].Set(v.x, v.y, v.z);
}
mesh.setNumFaces(tris.size());
mesh.setNumTVFaces(tris.size());
for (int submat=0; submat<submats; ++submat) {
int t_start = tri_range[submat].first, t_end = tri_range[submat].second;
for (int i=t_start; i<t_end; ++i) {
Triangle& t = tris[i];
Face& f = mesh.faces[i];
f.setVerts(t.v1, t.v2, t.v3);
f.Show();
f.setEdgeVisFlags(EDGE_VIS, EDGE_VIS, EDGE_VIS);
f.setMatID(-1);
TVFace& tf = mesh.tvFace[i];
tf.setTVerts(t.v1, t.v2, t.v3);
}
}
mesh.buildNormals();
bool bSpecNorms = false;
MultiMtl *mtl = NULL;
int igeom = 0;
for (vector<NiTriBasedGeomRef>::iterator itr = glist.begin(), end = glist.end(); itr != end; ++itr, ++igeom)
{
NiTriBasedGeomDataRef triGeomData = StaticCast<NiTriBasedGeomData>((*itr)->GetData());
int v_start = vert_range[igeom].first, v_end = vert_range[igeom].second;
int t_start = tri_range[igeom].first, t_end = tri_range[igeom].second;
// Normals
vector<Vector3> subnorms = triGeomData->GetNormals();
Matrix44 rotation = (*itr)->GetLocalTransform().GetRotation();
if (rotation != Matrix44::IDENTITY) {
for ( unsigned int i = 0; i < subnorms.size(); ++i )
subnorms[i] = rotation * subnorms[i];
}
if (!subnorms.empty())
{
#if VERSION_3DSMAX > ((5000<<16)+(15<<8)+0) // Version 5
// Initialize normals if necessary
if (!bSpecNorms) {
bSpecNorms = true;
mesh.SpecifyNormals();
MeshNormalSpec *specNorms = mesh.GetSpecifiedNormals();
if (NULL != specNorms) {
specNorms->BuildNormals();
//specNorms->ClearAndFree();
//specNorms->SetNumFaces(tris.size());
//specNorms->SetNumNormals(n.size());
}
}
MeshNormalSpec *specNorms = mesh.GetSpecifiedNormals();
if (NULL != specNorms)
{
Point3* norms = specNorms->GetNormalArray();
for (int i=0, n=subnorms.size(); i<n; i++){
Vector3& v = subnorms[i];
norms[i+v_start] = Point3(v.x, v.y, v.z);
}
//MeshNormalFace* pFaces = specNorms->GetFaceArray();
//for (int i=0; i<tris.size(); i++){
// Triangle& tri = tris[i];
// MeshNormalFace& face = pFaces[i+t_start];
// face.SpecifyNormalID(0, tri.v1);
// face.SpecifyNormalID(1, tri.v2);
// face.SpecifyNormalID(2, tri.v3);
//}
#if VERSION_3DSMAX > ((7000<<16)+(15<<8)+0) // Version 7+
specNorms->SetAllExplicit(true);
#endif
specNorms->CheckNormals();
}
#endif
}
// uv texture info
if (triGeomData->GetUVSetCount() > 0) {
vector<TexCoord> texCoords = triGeomData->GetUVSet(0);
for (int i=0, n = texCoords.size(); i<n; ++i) {
TexCoord& texCoord = texCoords[i];
mesh.tVerts[i+v_start].Set(texCoord.u, (flipUVTextures) ? 1.0f-texCoord.v : texCoord.v, 0);
}
}
vector<Color4> cv = triGeomData->GetColors();
ImportVertexColor(inode, triObject, tris, cv, v_start);
if ( StdMat2* submtl = ImportMaterialAndTextures(node, (*itr)) )
{
if (mtl == NULL) {
mtl = NewDefaultMultiMtl();
gi->GetMaterialLibrary().Add(mtl);
inode->SetMtl(mtl);
}
// SubMatIDs do not have to be contiguous so we just use the offset
mtl->SetSubMtlAndName(igeom, submtl, submtl->GetName());
for (int i=t_start; i<t_end; ++i)
mesh.faces[i].setMatID(igeom);
}
if (enableSkinSupport)
ImportSkin(node, (*itr));
}
this->i->AddNodeToScene(node);
inode = node->GetINode();
inode->EvalWorldState(0);
for (vector<NiTriBasedGeomRef>::iterator itr = glist.begin(), end = glist.end(); itr != end; ++itr)
{
// attach child
if (INode *parent = GetNode((*itr)->GetParent()))
parent->AttachChild(inode, 1);
inode->Hide((*itr)->GetVisibility() ? FALSE : TRUE);
}
if (removeDegenerateFaces)
mesh.RemoveDegenerateFaces();
if (removeIllegalFaces)
mesh.RemoveIllegalFaces();
if (weldVertices)
WeldVertices(mesh);
if (enableAutoSmooth)
mesh.AutoSmooth(TORAD(autoSmoothAngle), FALSE, FALSE);
return ok;
}
int ExportQuake3Model(const TCHAR *filename, ExpInterface *ei, Interface *gi, int start_time, std::list<ExportNode> lTags, std::list<ExportNode> lMeshes)
{
FILE *file;
int i, j, totalTags, totalMeshes, current_time = 0;
long pos_current, totalTris = 0, totalVerts = 0;
std::list<FrameRange>::iterator range_i;
std::vector<Point3> lFrameBBoxMin;
std::vector<Point3> lFrameBBoxMax;
long pos_tagstart;
long pos_tagend;
long pos_filesize;
long pos_framestart;
int lazynamesfixed = 0;
const Point3 x_axis(1, 0, 0);
const Point3 z_axis(0, 0, 1);
SceneEnumProc checkScene(ei->theScene, start_time, gi);
totalTags = (int)lTags.size();
if (g_tag_for_pivot)
totalTags++;
totalMeshes = (int)lMeshes.size();
// open file
file = _tfopen(filename, _T("wb"));
if (!file)
{
ExportError("Cannot open file '%s'.", filename);
return FALSE;
}
ExportDebug("%s:", filename);
// sync pattern and version
putChars("IDP3", 4, file);
put32(15, file);
putChars("Darkplaces MD3 Exporter", 64, file);
put32(0, file); // flags
// MD3 header
ExportState("Writing MD3 header");
put32(g_total_frames, file); // how many frames
put32(totalTags, file); // tagsnum
put32(totalMeshes, file); // meshnum
put32(1, file); // maxskinnum
put32(108, file); // headersize
pos_tagstart = ftell(file); put32(0, file); // tagstart
pos_tagend = ftell(file); put32(256, file); // tagend
pos_filesize = ftell(file); put32(512, file); // filesize
ExportDebug(" %i frames, %i tags, %i meshes", g_total_frames, totalTags, totalMeshes);
// frame info
// bbox arrays get filled while exported mesh and written back then
ExportState("Writing frame info");
pos_framestart = ftell(file);
lFrameBBoxMin.resize(g_total_frames);
lFrameBBoxMax.resize(g_total_frames);
for (i = 0; i < g_total_frames; i++)
{
// init frame data
lFrameBBoxMin[i].Set(0, 0, 0);
lFrameBBoxMax[i].Set(0, 0, 0);
// put data
putFloat(-1.0f, file); // bbox min vector
putFloat(-1.0f, file);
putFloat(-1.0f, file);
putFloat( 1.0f, file); // bbox max vector
putFloat(1.0f, file);
putFloat(1.0f, file);
putFloat(0.0f, file); // local origin (usually 0 0 0)
putFloat(0.0f, file);
putFloat(0.0f, file);
putFloat(1.0f, file); // radius of bounding sphere
putChars("", 16, file);
}
// tags
pos_current = ftell(file);
fseek(file, pos_tagstart, SEEK_SET);
put32(pos_current, file);
fseek(file, pos_current, SEEK_SET);
// for each frame range cycle all frames and write out each tag
long pos_tags = pos_current;
if (totalTags)
{
long current_frame = 0;
ExportState("Writing %i tags", totalTags);
for (range_i = g_frame_ranges.begin(); range_i != g_frame_ranges.end(); range_i++)
{
for (i = (*range_i).first; i <= (int)(*range_i).last; i++, current_frame++)
{
SceneEnumProc current_scene(ei->theScene, i * g_ticks_per_frame, gi);
current_time = current_scene.time;
// write out tags
if (lTags.size())
{
for (std::list<ExportNode>::iterator tag_i = lTags.begin(); tag_i != lTags.end(); tag_i++)
{
INode *node = current_scene[tag_i->i]->node;
Matrix3 tm = node->GetObjTMAfterWSM(current_time);
ExportState("Writing '%s' frame %i of %i", tag_i->name, i, g_total_frames);
// tagname
putChars(tag_i->name, 64, file);
// origin, rotation matrix
Point3 row = tm.GetRow(3);
putFloat(row.x, file);
putFloat(row.y, file);
putFloat(row.z, file);
row = tm.GetRow(0);
putFloat(row.x, file);
putFloat(row.y, file);
putFloat(row.z, file);
row = tm.GetRow(1);
putFloat(row.x, file);
putFloat(row.y, file);
putFloat(row.z, file);
row = tm.GetRow(2);
putFloat(row.x, file);
putFloat(row.y, file);
putFloat(row.z, file);
}
}
// write the center of mass tag_pivot which is avg of all objects's pivots
if (g_tag_for_pivot)
{
ExportState("Writing 'tag_pivot' frame %i of %i", i, g_total_frames);
// write the null data as tag_pivot need to be written after actual geometry
// (it needs information on frame bound boxes to get proper blendings)
putChars("tag_pivot", 64, file);
putFloat(0, file);
putFloat(0, file);
putFloat(0, file);
putFloat(1, file);
putFloat(0, file);
putFloat(0, file);
putFloat(0, file);
putFloat(1, file);
putFloat(0, file);
putFloat(0, file);
putFloat(0, file);
putFloat(1, file);
}
}
}
}
// write the tag object offsets
pos_current = ftell(file);
fseek(file, pos_tagend, SEEK_SET);
put32(pos_current, file);
fseek(file, pos_current, SEEK_SET);
// allocate the structs used to calculate tag_pivot
std::vector<Point3> tag_pivot_origin;
std::vector<double> tag_pivot_volume;
if (g_tag_for_pivot)
{
tag_pivot_origin.resize(g_total_frames);
tag_pivot_volume.resize(g_total_frames);
}
// mesh objects
// for each mesh object write uv and frames
SceneEnumProc scratch(ei->theScene, start_time, gi);
ExportState("Writing %i meshes", (int)lMeshes.size());
for (std::list<ExportNode>::iterator mesh_i = lMeshes.begin(); mesh_i != lMeshes.end(); mesh_i++)
{
bool needsDel;
ExportState("Start mesh #%i", mesh_i);
INode *node = checkScene[mesh_i->i]->node;
Matrix3 tm = node->GetObjTMAfterWSM(start_time);
TriObject *tri = GetTriObjectFromNode(node, start_time, needsDel);
if (!tri)
continue;
// get mesh, compute normals
Mesh &mesh = tri->GetMesh();
MeshNormalSpec *meshNormalSpec = mesh.GetSpecifiedNormals();
if (meshNormalSpec)
{
if (!meshNormalSpec->GetNumFaces())
meshNormalSpec = NULL;
else
{
meshNormalSpec->SetParent(&mesh);
meshNormalSpec->CheckNormals();
}
}
mesh.checkNormals(TRUE);
// fix lazy object names
ExportState("Attempt to fix mesh name '%s'", mesh_i->name);
char meshname[64];
size_t meshnamelen = min(63, strlen(mesh_i->name));
memset(meshname, 0, 64);
strncpy(meshname, mesh_i->name, meshnamelen);
meshname[meshnamelen] = 0;
if (!strncmp("Box", meshname, 3) || !strncmp("Sphere", meshname, 6) || !strncmp("Cylinder", meshname, 8) ||
!strncmp("Torus", meshname, 5) || !strncmp("Cone", meshname, 4) || !strncmp("GeoSphere", meshname, 9) ||
!strncmp("Tube", meshname, 4) || !strncmp("Pyramid", meshname, 7) || !strncmp("Plane", meshname, 5) ||
!strncmp("Teapot", meshname, 6) || !strncmp("Object", meshname, 6))
{
name_conflict:
lazynamesfixed++;
if (lazynamesfixed == 1)
strcpy(meshname, "base");
else
sprintf(meshname, "base%i", lazynamesfixed);
// check if it's not used by another mesh
for (std::list<ExportNode>::iterator m_i = lMeshes.begin(); m_i != lMeshes.end(); m_i++)
if (!strncmp(m_i->name, meshname, strlen(meshname)))
goto name_conflict;
// approve name
ExportWarning("Lazy object name '%s' (mesh renamed to '%s').", node->GetName(), meshname);
}
// special mesh check
bool shadow_or_collision = false;
if (g_mesh_special)
if (!strncmp("collision", meshname, 9) || !strncmp("shadow", meshname, 6))
shadow_or_collision = true;
// get material
const char *shadername = NULL;
Texmap *tex = 0;
Mtl *mtl = 0;
if (!shadow_or_collision)
{
mtl = node->GetMtl();
if (mtl)
{
// check for multi-material
if (mtl->IsMultiMtl())
{
// check if it's truly multi material
// we do support multi-material with only one texture (some importers set it)
bool multi_material = false;
MtlID matId = mesh.faces[0].getMatID();
for (i = 1; i < mesh.getNumFaces(); i++)
if (mesh.faces[i].getMatID() != matId)
multi_material = true;
if (multi_material)
if (g_mesh_multimaterials == MULTIMATERIALS_NONE)
ExportWarning("Object '%s' is multimaterial and using multiple materials on its faces, that case is not yet supported (truncating to first submaterial).", node->GetName());
// switch to submaterial
mtl = mtl->GetSubMtl(matId);
}
// get shader from material if supplied
char *materialname = GetChar(mtl->GetName());
if (g_mesh_materialasshader && (strstr(materialname, "/") != NULL || strstr(materialname, "\\") != NULL))
shadername = GetChar(mtl->GetName());
else
{
// get texture
tex = mtl->GetSubTexmap(ID_DI);
if (tex)
{
if (tex->ClassID() == Class_ID(BMTEX_CLASS_ID, 0x00))
{
shadername = GetChar(((BitmapTex *)tex)->GetMapName());
if (shadername == NULL || !shadername[0])
ExportWarning("Object '%s' material '%s' has no bitmap.", tex->GetName(), node->GetName());
}
else
{
tex = NULL;
ExportWarning("Object '%s' has material with wrong texture type (only Bitmap are supported).", node->GetName());
}
}
else
ExportWarning("Object '%s' has material but no texture.", node->GetName());
}
}
else
ExportWarning("Object '%s' has no material.", node->GetName());
}
long pos_meshstart = ftell(file);
// surface object
ExportState("Writing mesh '%s' header", meshname);
putChars("IDP3", 4, file);
putChars(meshname, 64, file);
put32(0, file); // flags
put32(g_total_frames, file); // framecount
put32(1, file); // skincount
long pos_vertexnum = ftell(file); put32(0, file); // vertexcount
put32(mesh.getNumFaces(), file); // trianglecount
long pos_trianglestart = ftell(file); put32(0, file); // start triangles
put32(108, file); // header size
long pos_texvecstart = ftell(file); put32(0, file); // texvecstart
long pos_vertexstart = ftell(file); put32(16, file); // vertexstart
long pos_meshsize = ftell(file); put32(32, file); // meshsize
// write out a single 'skin'
ExportState("Writing mesh %s texture", meshname);
if (shadow_or_collision)
putChars(meshname, 64, file);
else if (shadername)
putMaterial(shadername, mtl, tex, file);
else
putChars("noshader", 64, file);
put32(0, file); // flags
// build geometry
ExportState("Building vertexes/triangles");
std::vector<ExportVertex>vVertexes;
std::vector<ExportTriangle>vTriangles;
vVertexes.resize(mesh.getNumVerts());
int vExtraVerts = mesh.getNumVerts();
for (i = 0; i < mesh.getNumVerts(); i++)
{
vVertexes[i].vert = i;
vVertexes[i].normalfilled = false;
// todo: check for coincident verts
}
int vNumExtraVerts = 0;
// check normals
if (!mesh.normalsBuilt && !shadow_or_collision)
ExportWarning("Object '%s' does not have normals contructed.", node->GetName());
// get info for triangles
const float normal_epsilon = 0.01f;
vTriangles.resize(mesh.getNumFaces());
for (i = 0; i < mesh.getNumFaces(); i++)
{
DWORD smGroup = mesh.faces[i].getSmGroup();
ExportState("Mesh %s: checking normals for face %i of %i", meshname, i, mesh.getNumFaces());
for (j = 0; j < 3; j++)
{
int vert = mesh.faces[i].getVert(j);
vTriangles[i].e[j] = vert;
// find a right normal for this vertex and save its 'address'
int vni;
Point3 vn;
if (!mesh.normalsBuilt || shadow_or_collision)
{
vn.Set(0, 0, 0);
vni = 0;
}
else
{
int numNormals;
RVertex *rv = mesh.getRVertPtr(vert);
if (meshNormalSpec)
{
ExportState("face %i vert %i have normal specified", i, j);
// mesh have explicit normals (i.e. Edit Normals modifier)
vn = meshNormalSpec->GetNormal(i, j);
vni = meshNormalSpec->GetNormalIndex(i, j);
}
else if (rv && rv->rFlags & SPECIFIED_NORMAL)
{
ExportState("face %i vert %i have SPECIFIED_NORMAL flag", i, j);
// SPECIFIED_NORMAL flag
vn = rv->rn.getNormal();
vni = 0;
}
else if (rv && (numNormals = rv->rFlags & NORCT_MASK) && smGroup)
{
// If there is only one vertex is found in the rn member.
if (numNormals == 1)
{
ExportState("face %i vert %i have solid smooth group", i, j);
vn = rv->rn.getNormal();
vni = 0;
}
else
{
ExportState("face %i vert %i have mixed smoothing groups", i, j);
// If two or more vertices are there you need to step through them
// and find the vertex with the same smoothing group as the current face.
// You will find multiple normals in the ern member.
for (int k = 0; k < numNormals; k++)
{
if (rv->ern[k].getSmGroup() & smGroup)
{
vn = rv->ern[k].getNormal();
vni = 1 + k;
}
}
}
}
else
{
ExportState("face %i vert %i flat shaded", i, j);
// Get the normal from the Face if no smoothing groups are there
vn = mesh.getFaceNormal(i);
vni = 0 - (i + 1);
}
}
// subdivide to get all normals right
if (!vVertexes[vert].normalfilled)
{
vVertexes[vert].normal = vn;
vVertexes[vert].normalindex = vni;
vVertexes[vert].normalfilled = true;
}
else if ((vVertexes[vert].normal - vn).Length() >= normal_epsilon)
{
// current vertex not matching normal - it was already filled by different smoothing group
// find a vert in extra verts in case it was already created
bool vert_found = false;
for (int ev = vExtraVerts; ev < (int)vVertexes.size(); ev++)
{
if (vVertexes[ev].vert == vert && (vVertexes[ev].normal - vn).Length() < normal_epsilon)
{
vert_found = true;
vTriangles[i].e[j] = ev;
break;
}
}
// we havent found a vertex, create new
if (!vert_found)
{
ExportVertex NewVert;
NewVert.vert = vVertexes[vert].vert;
NewVert.normal = vn;
NewVert.normalindex = vni;
NewVert.normalfilled = true;
vTriangles[i].e[j] = (int)vVertexes.size();
vVertexes.push_back(NewVert);
vNumExtraVerts++;
}
}
}
}
int vNumExtraVertsForSmoothGroups = vNumExtraVerts;
// generate UV map
// VorteX: use direct maps reading since getNumTVerts()/getTVert is deprecated
// max sets two default mesh maps: 0 - vertex color, 1 : UVW, 2 & up are custom ones
ExportState("Building UV map");
std::vector<ExportUV>vUVMap;
vUVMap.resize(vVertexes.size());
int meshMap = 1;
if (!mesh.mapSupport(meshMap) || !mesh.getNumMapVerts(meshMap) || shadow_or_collision)
{
for (i = 0; i < mesh.getNumVerts(); i++)
{
vUVMap[i].u = 0.5;
vUVMap[i].v = 0.5;
}
if (!shadow_or_collision)
ExportWarning("No UV mapping was found on object '%s'.", node->GetName());
}
else
{
UVVert *meshUV = mesh.mapVerts(meshMap);
for (i = 0; i < (int)vTriangles.size(); i++)
{
ExportState("Mesh %s: converting tvert for face %i of %i", meshname, i, (int)vTriangles.size());
// for 3 face vertexes
for (j = 0; j < 3; j++)
{
int vert = vTriangles[i].e[j];
int tv = mesh.tvFace[i].t[j];
UVVert &UV = meshUV[tv];
if (!vUVMap[vert].filled)
{
// fill uvMap vertex
vUVMap[vert].u = UV.x;
vUVMap[vert].v = UV.y;
vUVMap[vert].filled = true;
vUVMap[vert].tvert = tv;
}
else if (tv != vUVMap[vert].tvert)
{
// uvMap slot for this vertex has been filled
// we should arrange triangle to other vertex, which not filled and having same shading and uv
// check if any of the extra vertices can fit
bool vert_found = false;
for (int ev = vExtraVerts; ev < (int)vVertexes.size(); ev++)
{
if (vVertexes[ev].vert == vert && vUVMap[vert].u == UV.x &&vUVMap[vert].v == UV.y && (vVertexes[ev].normal - vVertexes[vert].normal).Length() < normal_epsilon)
{
vert_found = true;
vTriangles[i].e[j] = vVertexes[ev].vert;
break;
}
}
if (!vert_found)
{
// create new vert
ExportVertex NewVert;
NewVert.vert = vVertexes[vert].vert;
NewVert.normal = vVertexes[vert].normal;
NewVert.normalindex = vVertexes[vert].normalindex;
NewVert.normalfilled = vVertexes[vert].normalfilled;
vTriangles[i].e[j] = (int)vVertexes.size();
vVertexes.push_back(NewVert);
vNumExtraVerts++;
// create new TVert
ExportUV newUV;
newUV.filled = true;
newUV.u = UV.x;
newUV.v = UV.y;
newUV.tvert = tv;
vUVMap.push_back(newUV);
}
}
}
}
}
int vNumExtraVertsForUV = (vNumExtraVerts - vNumExtraVertsForSmoothGroups);
// print some debug stats
ExportDebug(" mesh %s: %i vertexes +%i %s +%i UV, %i triangles", meshname, ((int)vVertexes.size() - vNumExtraVerts), vNumExtraVertsForSmoothGroups, meshNormalSpec ? "EditNormals" : "SmoothGroups", vNumExtraVertsForUV, (int)vTriangles.size());
// fill in triangle start
pos_current = ftell(file);
fseek(file, pos_trianglestart, SEEK_SET);
put32(pos_current - pos_meshstart, file);
fseek(file, pos_current, SEEK_SET);
// detect if object have negative scale (mirrored)
// in this canse we should rearrange triangles counterclockwise
// so stuff will not be inverted
ExportState("Mesh %s: writing %i triangles", meshname, (int)vTriangles.size());
if (DotProd(CrossProd(tm.GetRow(0), tm.GetRow(1)), tm.GetRow(2)) < 0.0)
{
ExportWarning("Object '%s' is mirrored (having negative scale on it's transformation)", node->GetName());
for (i = 0; i < (int)vTriangles.size(); i++)
{
put32(vTriangles[i].b, file); // vertex index
put32(vTriangles[i].c, file); // for 3 vertices
put32(vTriangles[i].a, file); // of triangle
}
}
else
{
for (i = 0; i < (int)vTriangles.size(); i++)
{
put32(vTriangles[i].a, file); // vertex index
put32(vTriangles[i].c, file); // for 3 vertices
put32(vTriangles[i].b, file); // of triangle
}
}
// fill in texvecstart
// write out UV mapping coords.
ExportState("Mesh %s: writing %i UV vertexes", meshname, (int)vUVMap.size());
pos_current = ftell(file);
fseek(file, pos_texvecstart, SEEK_SET);
put32(pos_current - pos_meshstart, file);
fseek(file, pos_current, SEEK_SET);
for (i = 0; i < (int)vUVMap.size(); i++)
{
putFloat(vUVMap[i].u, file); // texture coord u,v
putFloat(1.0f - vUVMap[i].v, file); // for vertex
}
vUVMap.clear();
// fill in vertexstart
pos_current = ftell(file);
fseek(file, pos_vertexstart, SEEK_SET);
put32(pos_current - pos_meshstart, file);
fseek(file, pos_current, SEEK_SET);
// fill in vertexnum
pos_current = ftell(file);
fseek(file, pos_vertexnum, SEEK_SET);
put32((int)vVertexes.size(), file);
fseek(file, pos_current, SEEK_SET);
// write out for each frame the position of each vertex
long current_frame = 0;
ExportState("Mesh %s: writing %i frames", meshname, g_total_frames);
for (range_i = g_frame_ranges.begin(); range_i != g_frame_ranges.end(); range_i++)
{
for (i = (*range_i).first; i <= (int)(*range_i).last; i++, current_frame++)
{
bool _needsDel;
// get triobject for current frame
SceneEnumProc current_scene(ei->theScene, i * g_ticks_per_frame, gi);
current_time = current_scene.time;
INode *_node = current_scene[mesh_i->i]->node;
TriObject *_tri = GetTriObjectFromNode(_node, current_time, _needsDel);
if (!_tri)
continue;
// get mesh, compute normals
Mesh &_mesh = _tri->GetMesh();
MeshNormalSpec *_meshNormalSpec = _mesh.GetSpecifiedNormals();
if (_meshNormalSpec)
{
if (!_meshNormalSpec->GetNumFaces())
_meshNormalSpec = NULL;
else
{
_meshNormalSpec->SetParent(&_mesh);
_meshNormalSpec->CheckNormals();
}
}
_mesh.checkNormals(TRUE);
// get transformations for current frame
Matrix3 _tm = _node->GetObjTMAfterWSM(current_time);
ExportState("Mesh %s: writing frame %i of %i", meshname, current_frame, g_total_frames);
Point3 BoxMin(0, 0, 0);
Point3 BoxMax(0, 0, 0);
for (j = 0; j < (int)vVertexes.size(); j++) // number of vertices
{
ExportState("Mesh %s: transform vertex %i of %i", meshname, j, (int)vVertexes.size());
int vert = vVertexes[j].vert;
Point3 &v = _tm.PointTransform(_mesh.getVert(vert));
// populate bbox data
if (!shadow_or_collision)
{
BoxMin.x = min(BoxMin.x, v.x);
BoxMin.y = min(BoxMin.y, v.y);
BoxMin.z = min(BoxMin.z, v.z);
BoxMax.x = max(BoxMax.x, v.x);
BoxMax.y = max(BoxMax.y, v.y);
BoxMax.z = max(BoxMax.z, v.z);
}
// write vertex
double f;
f = v.x * 64.0f; if (f < -32768.0) f = -32768.0; if (f > 32767.0) f = 32767.0; put16((short)f, file);
f = v.y * 64.0f; if (f < -32768.0) f = -32768.0; if (f > 32767.0) f = 32767.0; put16((short)f, file);
f = v.z * 64.0f; if (f < -32768.0) f = -32768.0; if (f > 32767.0) f = 32767.0; put16((short)f, file);
// get normal
ExportState("Mesh %s: transform vertex normal %i of %i", meshname, j, (int)vVertexes.size());
Point3 n;
if (_meshNormalSpec) // mesh have explicit normals (i.e. Edit Normals modifier)
n = _meshNormalSpec->Normal(vVertexes[j].normalindex);
else if (!vVertexes[j].normalfilled || !_mesh.normalsBuilt)
n = _mesh.getNormal(vert);
else
{
RVertex *rv = _mesh.getRVertPtr(vert);
if (vVertexes[j].normalindex < 0)
n = _mesh.getFaceNormal((0 - vVertexes[j].normalindex) - 1);
else if (vVertexes[j].normalindex == 0)
n = rv->rn.getNormal();
else
n = rv->ern[vVertexes[j].normalindex - 1].getNormal();
}
// transform normal
Point3 &nt = _tm.VectorTransform(n).Normalize();
// encode a normal vector into a 16-bit latitude-longitude value
double lng = acos(nt.z) * 255 / (2 * pi);
double lat = atan2(nt.y, nt.x) * 255 / (2 * pi);
put16((((int)lat & 0xFF) << 8) | ((int)lng & 0xFF), file);
}
// blend the pivot positions for tag_pivot using mesh's volumes for blending power
if (g_tag_for_pivot && !shadow_or_collision)
{
ExportState("Mesh %s: writing tag_pivot", meshname);
Point3 Size = BoxMax - BoxMin;
double BoxVolume = pow(Size.x * Size.y * Size.z, 0.333f);
// blend matrices
float blend = (float)(BoxVolume / (BoxVolume + tag_pivot_volume[current_frame]));
float iblend = 1 - blend;
tag_pivot_volume[current_frame] = tag_pivot_volume[current_frame] + BoxVolume;
Point3 row = _tm.GetRow(3) - _node->GetObjOffsetPos();
tag_pivot_origin[current_frame].x = tag_pivot_origin[current_frame].x * iblend + row.x * blend;
tag_pivot_origin[current_frame].y = tag_pivot_origin[current_frame].y * iblend + row.y * blend;
tag_pivot_origin[current_frame].z = tag_pivot_origin[current_frame].z * iblend + row.z * blend;
}
// populate bbox data for frames
lFrameBBoxMin[current_frame].x = min(lFrameBBoxMin[current_frame].x, BoxMin.x);
lFrameBBoxMin[current_frame].y = min(lFrameBBoxMin[current_frame].y, BoxMin.y);
lFrameBBoxMin[current_frame].z = min(lFrameBBoxMin[current_frame].z, BoxMin.z);
lFrameBBoxMax[current_frame].x = max(lFrameBBoxMax[current_frame].x, BoxMax.x);
lFrameBBoxMax[current_frame].y = max(lFrameBBoxMax[current_frame].y, BoxMax.y);
lFrameBBoxMax[current_frame].z = max(lFrameBBoxMax[current_frame].z, BoxMax.z);
// delete the working object, if necessary.
if (_needsDel)
delete _tri;
}
}
// delete if necessary
if (needsDel)
delete tri;
// fill in meshsize
pos_current = ftell(file);
fseek(file, pos_meshsize, SEEK_SET);
put32(pos_current - pos_meshstart, file);
fseek(file, pos_current, SEEK_SET);
// reset back to first frame
SceneEnumProc scratch(ei->theScene, start_time, gi);
totalTris += (long)vTriangles.size();
totalVerts += (long)vVertexes.size();
vTriangles.clear();
vVertexes.clear();
}
// write tag_pivot
ExportState("Writing tag_pivot positions");
if (g_tag_for_pivot)
{
pos_current = ftell(file);
long current_frame = 0;
for (range_i = g_frame_ranges.begin(); range_i != g_frame_ranges.end(); range_i++)
{
for (i = (*range_i).first; i <= (int)(*range_i).last; i++, current_frame++)
{
fseek(file, pos_tags + totalTags*112*current_frame + (int)lTags.size()*112 + 64, SEEK_SET);
// origin
putFloat(tag_pivot_origin[current_frame].x, file);
putFloat(tag_pivot_origin[current_frame].y, file);
putFloat(tag_pivot_origin[current_frame].z, file);
}
}
fseek(file, pos_current, SEEK_SET);
}
tag_pivot_volume.clear();
tag_pivot_origin.clear();
// write frame data
ExportState("Writing culling info");
long current_frame = 0;
pos_current = ftell(file);
for (range_i = g_frame_ranges.begin(); range_i != g_frame_ranges.end(); range_i++)
{
for (i = (*range_i).first; i <= (int)(*range_i).last; i++, current_frame++)
{
fseek(file, pos_framestart + current_frame*56, SEEK_SET);
putFloat(lFrameBBoxMin[current_frame].x, file); // bbox min vector
putFloat(lFrameBBoxMin[current_frame].y, file);
putFloat(lFrameBBoxMin[current_frame].z, file);
putFloat(lFrameBBoxMax[current_frame].x, file); // bbox max vector
putFloat(lFrameBBoxMax[current_frame].y, file);
putFloat(lFrameBBoxMax[current_frame].z, file);
putFloat(0, file); // local origin (usually 0 0 0)
putFloat(0, file);
putFloat(0, file);
putFloat(max(lFrameBBoxMin[current_frame].Length(), lFrameBBoxMax[current_frame].Length()) , file); // radius of bounding sphere
}
}
fseek(file, pos_current, SEEK_SET);
lFrameBBoxMin.clear();
lFrameBBoxMax.clear();
// fill in filesize
pos_current = ftell(file);
fseek(file, pos_filesize, SEEK_SET);
put32(pos_current, file);
fseek(file, pos_current, SEEK_SET);
fclose(file);
ExportDebug(" total: %i vertexes, %i triangles", totalVerts, totalTris);
return TRUE;
}
void WMOGroupImpl::buildMaxData()
{
// Group Header Node
INode* groupHeadNode = createGroupHeaderNode();
groupHeadNode->SetGroupHead(TRUE);
groupHeadNode->SetGroupMember(FALSE);
// Geoset
// 一个Render Batch构造一个Node, 并且加入到组中
for (int i = 0; i < m_batchCount; ++i)
{
WMORenderBatch& renderBatch = m_batchData[i];
m_wmoImporter->m_logStream << "Model Geoset " << i << " Vertex Info: "
<< renderBatch.vertexStart << " -- " << renderBatch.vertexEnd << endl;
m_wmoImporter->m_logStream << "Model Geoset " << i << " Index Info: "
<< renderBatch.indexStart << " -- " << renderBatch.indexCount << endl;
// Triangle Mesh Object
// 基本的三角形模型对象
TriObject* triObject = CreateNewTriObject();
// 创建Node, 并且设为Group Header Node的子节点
ImpNode* tmpImpNode = m_wmoImporter->m_impInterface->CreateNode();
tmpImpNode->Reference(triObject);
m_wmoImporter->m_impInterface->AddNodeToScene(tmpImpNode);
INode* realINode = tmpImpNode->GetINode();
realINode->SetGroupHead(FALSE);
realINode->SetGroupMember(TRUE);
groupHeadNode->AttachChild(realINode);
m_geosetNodeList.push_back(realINode);
TCHAR nodeName[256];
sprintf(nodeName, "%s_part_%03d", m_groupName.c_str(), i);
realINode->SetName(nodeName);
// mesh
unsigned short vertexCount = renderBatch.vertexEnd - renderBatch.vertexStart + 1;
unsigned int trigangleCount = renderBatch.indexCount / 3;
Mesh& mesh = triObject->GetMesh();
mesh.setNumVerts(vertexCount);
mesh.setNumTVerts(vertexCount, TRUE);
mesh.setNumFaces(trigangleCount);
mesh.setNumTVFaces(trigangleCount);
// 顶点坐标和UV
for (int i = 0; i < vertexCount; ++i)
{
mesh.verts[i] = *(Point3*)(&(m_vertexData[renderBatch.vertexStart + i]));
// UV坐标反转
mesh.tVerts[i].x = m_textureCoords[renderBatch.vertexStart + i].x;
mesh.tVerts[i].y = 1.0f - m_textureCoords[renderBatch.vertexStart + i].y;
}
// 三角形
for (unsigned int i = 0; i < trigangleCount; ++i)
{
Face& face = mesh.faces[i];
int index1 = m_indexData[renderBatch.indexStart + i*3] - renderBatch.vertexStart;
int index2 = m_indexData[renderBatch.indexStart + i*3+1] - renderBatch.vertexStart;
int index3 = m_indexData[renderBatch.indexStart + i*3+2] - renderBatch.vertexStart;
face.setVerts(index1, index2, index3);
face.Show();
face.setEdgeVisFlags(EDGE_VIS, EDGE_VIS, EDGE_VIS);
TVFace& tface = mesh.tvFace[i];
tface.setTVerts(index1, index2, index3);
}
// 法线
mesh.SpecifyNormals();
MeshNormalSpec *specNorms = mesh.GetSpecifiedNormals();
if (specNorms)
{
specNorms->ClearAndFree();
specNorms->SetNumFaces(trigangleCount);
specNorms->SetNumNormals(vertexCount);
Point3* norms = specNorms->GetNormalArray();
for (int i = 0; i < vertexCount; ++i)
{
norms[i] = *(Point3*)(&m_normalData[renderBatch.vertexStart + i]);
}
MeshNormalFace* pFaces = specNorms->GetFaceArray();
for (unsigned int i = 0; i < trigangleCount; ++i)
{
int index1 = m_indexData[renderBatch.indexStart + i*3] - renderBatch.vertexStart;
int index2 = m_indexData[renderBatch.indexStart + i*3+1] - renderBatch.vertexStart;
int index3 = m_indexData[renderBatch.indexStart + i*3+2] - renderBatch.vertexStart;
pFaces[i].SpecifyNormalID(0, index1);
pFaces[i].SpecifyNormalID(1, index2);
pFaces[i].SpecifyNormalID(2, index3);
}
specNorms->SetAllExplicit(true);
specNorms->CheckNormals();
}
// 删除重复的和无效的面
mesh.RemoveDegenerateFaces();
mesh.RemoveIllegalFaces();
realINode->SetMtl(m_wmoImporter->m_materialList[renderBatch.texture]);
//realINode->BackCull(FALSE); // 取消背面裁减 不是所有的Node都要取消背面裁减
realINode->EvalWorldState(0);
}
}
void SymmetryMod::ModifyTriObject (TimeValue t, ModContext &mc, TriObject *tobj, INode *inode) {
Mesh &mesh = tobj->GetMesh();
Interval iv = FOREVER;
int axis, slice, weld, flip;
float threshold;
mp_pblock->GetValue (kSymAxis, t, axis, iv);
mp_pblock->GetValue (kSymFlip, t, flip, iv);
mp_pblock->GetValue (kSymSlice, t, slice, iv);
mp_pblock->GetValue (kSymWeld, t, weld, iv);
mp_pblock->GetValue (kSymThreshold, t, threshold, iv);
if (threshold<0) threshold=0;
// Get transform from mirror controller:
Matrix3 tm = CompMatrix (t, NULL, &mc, &iv);
Matrix3 itm = Inverse (tm);
// Get DotProd(N,x)=offset plane definition from transform
Point3 Axis(0,0,0);
Axis[axis] = flip ? -1.0f : 1.0f;
Point3 origin = tm.GetTrans();
Point3 N = Normalize(tm*Axis - origin);
float offset = DotProd (N, origin);
// Slice operation does not handle NormalSpecs, but it handles mapping channels.
// move our mesh normal data to a map channel
MeshNormalSpec *pNormals = mesh.GetSpecifiedNormals ();
int normalMapChannel = INVALID_NORMALMAPCHANNEL;
if (pNormals && pNormals->GetNumFaces())
{
pNormals->SetParent(&mesh);
//find an empty map channel
for (int mp = 0; mp < mesh.getNumMaps(); mp++)
{
if (!mesh.mapSupport(mp))
{
normalMapChannel = mp;
mesh.setMapSupport(normalMapChannel,TRUE);
MeshMap& map = mesh.Map(normalMapChannel);
for (int i = 0; i < map.fnum; i++)
{
for (int j = 0; j < 3; j++)
{
unsigned int newID = pNormals->Face(i).GetNormalID(j);
map.tf[i].t[j] = newID;
}
}
map.setNumVerts(pNormals->GetNumNormals());
for (int i = 0; i < map.vnum; i++)
{
map.tv[i] = pNormals->Normal(i);
}
// make sure nothing is done with MeshNormalSpec (until data is copied back)
pNormals->Clear();
break;
}
}
}
// Slice off everything below the plane.
if (slice) SliceTriObject (mesh, N, offset);
MirrorTriObject (mesh, axis, tm, itm,normalMapChannel);
if (weld) WeldTriObject (mesh, N, offset, threshold);
//now move the normals back
if (pNormals && normalMapChannel != -1)
{
MeshMap& map = mesh.Map(normalMapChannel);
pNormals->SetNumFaces(map.fnum);
pNormals->SetNumNormals(map.vnum);
pNormals->SetAllExplicit(true);
BitArray temp;
temp.SetSize(map.vnum);
temp.SetAll();
pNormals->SpecifyNormals(TRUE,&temp);
for (int i = 0; i < map.vnum; i++)
{
pNormals->GetNormalArray()[i] = map.tv[i];
pNormals->SetNormalExplicit(i,true);
}
for (int i = 0; i < map.fnum; i++)
{
for (int j = 0; j < 3; j++)
{
pNormals->SetNormalIndex(i,j,map.tf[i].t[j]);
MeshNormalFace& face = pNormals->Face(i);
face.SpecifyAll(true);
}
}
pNormals->SetFlag(MESH_NORMAL_MODIFIER_SUPPORT);
for (int i = 0; i < pNormals->GetNumFaces(); i++)
{
for (int j = 0; j < 3; j++)
{
int id = pNormals->GetNormalIndex(i,j);
}
}
pNormals->CheckNormals();
pNormals->SetParent(NULL);
// Free the map channel
mesh.setMapSupport(normalMapChannel,FALSE);
}
tobj->UpdateValidity (GEOM_CHAN_NUM, iv);
tobj->UpdateValidity (TOPO_CHAN_NUM, iv);
tobj->UpdateValidity (VERT_COLOR_CHAN_NUM, iv);
tobj->UpdateValidity (TEXMAP_CHAN_NUM, iv);
tobj->UpdateValidity (SELECT_CHAN_NUM, iv);
}
// 1. 加载模型顶点数据
void M2Importer::importGeomObject()
{
// Group Header Node
INode* groupHeadNode = createGroupHeaderNode();
groupHeadNode->SetGroupHead(TRUE);
groupHeadNode->SetGroupMember(FALSE);
if (m_modelHeader->nameLength > 1)
{
TCHAR* modelName = (TCHAR*)(m_m2FileData + m_modelHeader->nameOfs);
groupHeadNode->SetName(modelName);
m_logStream << "ModelName: " << modelName << endl;
}
else
groupHeadNode->SetName("GeomGroup");
// Geoset
// 一个Geoset构造一个Node, 并且加入到组中
unsigned short* verDataIndex = (unsigned short*)(m_m2FileData + m_modelView->ofsIndex);
unsigned short* triData = (unsigned short*)(m_m2FileData + m_modelView->ofsTris);
m_geosetNodeList.reserve(m_modelView->nSub);
m_materialList.reserve(m_modelView->nSub);
for (unsigned int i = 0; i < m_modelView->nSub; ++i)
m_materialList.push_back(0);
for (unsigned int i = 0; i < m_modelView->nSub; ++i)
{
ModelGeoset& geosetData = m_modelGeoset[i];
// Triangle Mesh Object
// 基本的三角形模型对象
TriObject* triObject = CreateNewTriObject();
// 创建Node, 并且设为Group Header Node的子节点
ImpNode* tmpImpNode = m_impInterface->CreateNode();
tmpImpNode->Reference(triObject);
//tmpImpNode->SetPivot(*(Point3*)&(geosetData.v));
m_impInterface->AddNodeToScene(tmpImpNode);
INode* realINode = tmpImpNode->GetINode();
realINode->SetGroupHead(FALSE);
realINode->SetGroupMember(TRUE);
groupHeadNode->AttachChild(realINode);
m_geosetNodeList.push_back(realINode);
TCHAR nodeName[256];
sprintf(nodeName, "GeosetPart_%d", i);
realINode->SetName(nodeName);
// mesh
Mesh& mesh = triObject->GetMesh();
mesh.setNumVerts(geosetData.vcount);
mesh.setNumTVerts(geosetData.vcount, TRUE);
unsigned int triangeCount = geosetData.icount / 3;
mesh.setNumFaces(triangeCount);
mesh.setNumTVFaces(triangeCount);
m_logStream << "Model Geoset " << i << " Vertex Count: " << geosetData.vcount << endl;
m_logStream << "Model Geoset " << i << " Index Count: " << triangeCount << endl;
// 顶点坐标和UV
for (unsigned int i = 0; i < geosetData.vcount; ++i)
{
ModelVertex& vertexData = m_globalVertices[ verDataIndex[geosetData.vstart + i] ];
mesh.verts[i] = *(Point3*)(&vertexData.pos);
// UV坐标反转
mesh.tVerts[i].x = vertexData.texcoords.x;
mesh.tVerts[i].y = 1.0f - vertexData.texcoords.y;
}
// 三角形
for (unsigned int i = 0; i < triangeCount; ++i)
{
Face& face = mesh.faces[i];
face.setVerts(triData[geosetData.istart + i*3] - m_indexCount,
triData[geosetData.istart + i*3+1] - m_indexCount,
triData[geosetData.istart + i*3+2] - m_indexCount);
face.Show();
face.setEdgeVisFlags(EDGE_VIS, EDGE_VIS, EDGE_VIS);
TVFace& tface = mesh.tvFace[i];
tface.setTVerts(triData[geosetData.istart + i*3] - m_indexCount,
triData[geosetData.istart + i*3+1] - m_indexCount,
triData[geosetData.istart + i*3+2] - m_indexCount);
}
// 法线
mesh.SpecifyNormals();
MeshNormalSpec *specNorms = mesh.GetSpecifiedNormals();
if (specNorms)
{
specNorms->ClearAndFree();
specNorms->SetNumFaces(triangeCount);
specNorms->SetNumNormals(geosetData.vcount);
Point3* norms = specNorms->GetNormalArray();
for (unsigned int i = 0; i < geosetData.vcount; ++i)
{
ModelVertex& vertexData = m_globalVertices[ verDataIndex[geosetData.vstart + i] ];
norms[i] = *(Point3*)(&vertexData.normal);
}
MeshNormalFace* pFaces = specNorms->GetFaceArray();
for (unsigned int i = 0; i < triangeCount; ++i)
{
pFaces[i].SpecifyNormalID(0, triData[geosetData.istart + i*3] - m_indexCount);
pFaces[i].SpecifyNormalID(1, triData[geosetData.istart + i*3+1] - m_indexCount);
pFaces[i].SpecifyNormalID(2, triData[geosetData.istart + i*3+2] - m_indexCount);
}
specNorms->SetAllExplicit(true);
specNorms->CheckNormals();
}
// 删除重复的和无效的面
mesh.RemoveDegenerateFaces();
mesh.RemoveIllegalFaces();
//realINode->BackCull(FALSE); // 取消背面裁减 双面绘制与取消背面裁减一起设置
realINode->EvalWorldState(0);
// 索引值修正
m_indexCount += geosetData.vcount;
}
// 加载材质
unsigned short* texLookupData = (unsigned short*)(m_m2FileData + m_modelHeader->ofsTexLookup);
ModelTextureDef* texUnitDefData = (ModelTextureDef*)(m_m2FileData + m_modelHeader->ofsTextures);
ModelTexUnit* texUnitData = (ModelTexUnit*)(m_m2FileData + m_modelView->ofsTex);
for (unsigned int i = 0; i < m_modelView->nTex; ++i)
{
ModelTexUnit& texUnit = texUnitData[i];
unsigned short textureID = texLookupData[texUnit.textureid];
ModelTextureDef& texDef = texUnitDefData[textureID];
string textureName;
if (texDef.type == 0)
textureName = (LPCSTR)(m_m2FileData + texDef.nameOfs);
else
textureName = getReplacableTexture(texDef.type);
StdMat2* material = m_materialList[texUnit.op];
if (!material)
material = createMaterial();
// 根据混合属性决定加在第几层
material->SetSubTexmap(ID_DI, createTexture(textureName.c_str()));
material->EnableMap(ID_DI, TRUE);
//material->SetTwoSided(TRUE); // 双面 设置了此标志的才打开
m_maxInterface->GetMaterialLibrary().Add(material);
m_geosetNodeList[texUnit.op]->SetMtl(material);
}
m_maxInterface->RedrawViews(m_maxInterface->GetTime());
}