//! Creates/loads an animated mesh from the file.
IAnimatedMesh* CSMFMeshFileLoader::createMesh(io::IReadFile* file)
{
     // create empty mesh
     SMesh *mesh = new SMesh();

     // load file
     u16 version;
     u8  flags;
     s32 limbCount;
     s32 i;

     io::BinaryFile::read(file, version);
     io::BinaryFile::read(file, flags);
     io::BinaryFile::read(file, limbCount);

     // load mesh data
     core::matrix4 identity;
     for (i=0; i < limbCount; ++i)
          loadLimb(file, mesh, identity);

     // recalculate buffer bounding boxes
     for (i=0; i < (s32)mesh->getMeshBufferCount(); ++i)
          mesh->getMeshBuffer(i)->recalculateBoundingBox();

     mesh->recalculateBoundingBox();
     SAnimatedMesh *am = new SAnimatedMesh();
     am->addMesh(mesh);
     mesh->drop();
     am->recalculateBoundingBox();

     return am;
}
Example #2
0
//! reads a mesh sections and creates a mesh from it
IAnimatedMesh* CIrrMeshFileLoader::readMesh(io::IXMLReader* reader)
{
	SAnimatedMesh* animatedmesh = new SAnimatedMesh();
	SMesh* mesh = new SMesh();

	animatedmesh->addMesh(mesh);
	mesh->drop();

	core::stringc bbSectionName = "boundingBox";
	core::stringc bufferSectionName = "buffer";
	core::stringc meshSectionName = "mesh";

	if (!reader->isEmptyElement())
	while(reader->read())
	{
		if (reader->getNodeType() == io::EXN_ELEMENT)
		{
			const wchar_t* nodeName = reader->getNodeName();
			if (bbSectionName == nodeName)
			{
				// inside a bounding box, ignore it for now because
				// we are calculating this anyway ourselves later.
			}
			else
			if (bufferSectionName == nodeName)
			{
				// we've got a mesh buffer

				IMeshBuffer* buffer = readMeshBuffer(reader);
				if (buffer)
				{
					mesh->addMeshBuffer(buffer);
					buffer->drop();
				}
			}
			else
				skipSection(reader, true); // unknown section

		} // end if node type is element
		else
		if (reader->getNodeType() == io::EXN_ELEMENT_END)
		{
			if (meshSectionName == reader->getNodeName())
			{
				// end of mesh section reached, cancel out
				break;
			}
		}
	} // end while reader->read();

	mesh->recalculateBoundingBox();
	animatedmesh->recalculateBoundingBox();

	return animatedmesh;
}
	//! creates/loads an animated mesh from the file.
	IAnimatedMesh* CCSMLoader::createMesh(io::IReadFile* file)
	{
		scene::IMesh* m = createCSMMesh(file);

		if (!m)
			return 0;

		SAnimatedMesh* am = new SAnimatedMesh();
		am->Type = EAMT_CSM;
		am->addMesh(m);
		m->drop();

		am->recalculateBoundingBox();
		return am;
	}
Example #4
0
	//! creates/loads an animated mesh from the file.
	IAnimatedMesh* CCSMLoader::createMesh(io::IReadFile* file)
	{
		file->grab(); // originally, this loader created the file on its own.

		scene::IMesh* m = createCSMMesh(file);

		if (!m)
			return 0;

		SAnimatedMesh* am = new SAnimatedMesh();
		am->Type = EAMT_CSM;
		am->addMesh(m);
		m->drop();

		am->recalculateBoundingBox();
		return am;
	}
IAnimatedMesh* CLMTSMeshFileLoader::createMesh(io::IReadFile* file)
{
	u32 i;
	u32 id;

	// HEADER

	file->read(&Header, sizeof(SLMTSHeader));
	if (Header.MagicID == 0x4C4D5354)
	{
		FlipEndianess = true;
		Header.MagicID = os::Byteswap::byteswap(Header.MagicID);
		Header.Version = os::Byteswap::byteswap(Header.Version);
		Header.HeaderSize = os::Byteswap::byteswap(Header.HeaderSize);
		Header.TextureCount = os::Byteswap::byteswap(Header.TextureCount);
		Header.SubsetCount = os::Byteswap::byteswap(Header.SubsetCount);
		Header.TriangleCount = os::Byteswap::byteswap(Header.TriangleCount);
		Header.SubsetSize = os::Byteswap::byteswap(Header.SubsetSize);
		Header.VertexSize = os::Byteswap::byteswap(Header.VertexSize);
	}
	if (Header.MagicID != 0x53544D4C) { // "LMTS"
		os::Printer::log("LMTS ERROR: wrong header magic id!", ELL_ERROR);
		return 0;
	}

	//Skip any User Data (arbitrary app specific data)

	const s32 userSize = Header.HeaderSize - sizeof(SLMTSHeader);
	if (userSize>0)
		file->seek(userSize,true);

	// TEXTURES

	file->read(&id, sizeof(u32));
	if (FlipEndianess)
		id = os::Byteswap::byteswap(id);
	if (id != 0x54584554) { // "TEXT"
		os::Printer::log("LMTS ERROR: wrong texture magic id!", ELL_ERROR);
		return 0;
	}

	Textures = new SLMTSTextureInfoEntry[Header.TextureCount];

	file->read(Textures, sizeof(SLMTSTextureInfoEntry)*Header.TextureCount);
	if (FlipEndianess)
	{
		for (i=0; i<Header.TextureCount; ++i)
			Textures[i].Flags = os::Byteswap::byteswap(Textures[i].Flags);
	}

	// SUBSETS

	file->read(&id, sizeof(u32));
	if (FlipEndianess)
		id = os::Byteswap::byteswap(id);
	if (id != 0x53425553) // "SUBS"
	{
		os::Printer::log("LMTS ERROR: wrong subset magic id!", ELL_ERROR);
		cleanup();
		return 0;
	}

	Subsets = new SLMTSSubsetInfoEntry[Header.SubsetCount];
	const s32 subsetUserSize = Header.SubsetSize - sizeof(SLMTSSubsetInfoEntry);

	for (i=0; i<Header.SubsetCount; ++i)
	{
		file->read(&Subsets[i], sizeof(SLMTSSubsetInfoEntry));
		if (FlipEndianess)
		{
			Subsets[i].Offset = os::Byteswap::byteswap(Subsets[i].Offset);
			Subsets[i].Count = os::Byteswap::byteswap(Subsets[i].Count);
			Subsets[i].TextID1 = os::Byteswap::byteswap(Subsets[i].TextID1);
			Subsets[i].TextID2 = os::Byteswap::byteswap(Subsets[i].TextID2);
		}
		if (subsetUserSize>0)
			file->seek(subsetUserSize,true);
	}

	// TRIANGLES

	file->read(&id, sizeof(u32));
	if (FlipEndianess)
		id = os::Byteswap::byteswap(id);
	if (id != 0x53495254) // "TRIS"
	{
		os::Printer::log("LMTS ERROR: wrong triangle magic id!", ELL_ERROR);
		cleanup();
		return 0;
	}

	Triangles = new SLMTSTriangleDataEntry[(Header.TriangleCount*3)];
	const s32 triUserSize = Header.VertexSize - sizeof(SLMTSTriangleDataEntry);

	for (i=0; i<(Header.TriangleCount*3); ++i)
	{
		file->read(&Triangles[i], sizeof(SLMTSTriangleDataEntry));
		if (FlipEndianess)
		{
			Triangles[i].X = os::Byteswap::byteswap(Triangles[i].X);
			Triangles[i].Y = os::Byteswap::byteswap(Triangles[i].Y);
			Triangles[i].Z = os::Byteswap::byteswap(Triangles[i].Z);
			Triangles[i].U1 = os::Byteswap::byteswap(Triangles[i].U1);
			Triangles[i].V1 = os::Byteswap::byteswap(Triangles[i].U2);
			Triangles[i].U2 = os::Byteswap::byteswap(Triangles[i].V1);
			Triangles[i].V2 = os::Byteswap::byteswap(Triangles[i].V2);
		}
		if (triUserSize>0)
			file->seek(triUserSize,true);
	}

	/////////////////////////////////////////////////////////////////

	SMesh* mesh = new SMesh();

	constructMesh(mesh);

	loadTextures(mesh);

	cleanup();

	SAnimatedMesh* am = new SAnimatedMesh();
	am->Type = EAMT_LMTS; // not unknown to irrlicht anymore

	am->addMesh(mesh);
	am->recalculateBoundingBox();
	mesh->drop();
	return am;
}
//! creates/loads an animated mesh from the file.
//! \return Pointer to the created mesh. Returns 0 if loading failed.
//! If you no longer need the mesh, you should call IAnimatedMesh::drop().
//! See IReferenceCounted::drop() for more information.
IAnimatedMesh* CSTLMeshFileLoader::createMesh(io::IReadFile* file)
{
	const long filesize = file->getSize();
	if (filesize < 6) // we need a header
		return 0;

	const u32 WORD_BUFFER_LENGTH = 512;

	SMesh* mesh = new SMesh();
	SMeshBuffer* meshBuffer = new SMeshBuffer();
	mesh->addMeshBuffer(meshBuffer);
	meshBuffer->drop();

	core::vector3df vertex[3];
	core::vector3df normal;

	c8 buffer[WORD_BUFFER_LENGTH];

	bool binary = false;
	file->read(buffer, 5);
	if (strncmp("solid", buffer, 5))
		binary = true;
	// read/skip header
	u32 binFaceCount = 0;
	if (binary)
	{
		file->seek(80);
		file->read(&binFaceCount, 4);
#ifdef __BIG_ENDIAN__
		binFaceCount = os::Byteswap::byteswap(binFaceCount);
#endif
	}
	else
		goNextLine(file);

	u16 attrib=0;
	core::stringc token;
	token.reserve(32);

	while (file->getPos() < filesize)
	{
		if (!binary)
		{
			if (getNextToken(file, token) != "facet")
			{
				if (token=="endsolid")
					break;
				mesh->drop();
				return 0;
			}
			if (getNextToken(file, token) != "normal")
			{
				mesh->drop();
				return 0;
			}
		}
		getNextVector(file, normal, binary);
		if (!binary)
		{
			if (getNextToken(file, token) != "outer")
			{
				mesh->drop();
				return 0;
			}
			if (getNextToken(file, token) != "loop")
			{
				mesh->drop();
				return 0;
			}
		}
		for (u32 i=0; i<3; ++i)
		{
			if (!binary)
			{
				if (getNextToken(file, token) != "vertex")
				{
					mesh->drop();
					return 0;
				}
			}
			getNextVector(file, vertex[i], binary);
		}
		if (!binary)
		{
			if (getNextToken(file, token) != "endloop")
			{
				mesh->drop();
				return 0;
			}
			if (getNextToken(file, token) != "endfacet")
			{
				mesh->drop();
				return 0;
			}
		}
		else
		{
			file->read(&attrib, 2);
#ifdef __BIG_ENDIAN__
			attrib = os::Byteswap::byteswap(attrib);
#endif
		}

		SMeshBuffer* mb = reinterpret_cast<SMeshBuffer*>(mesh->getMeshBuffer(mesh->getMeshBufferCount()-1));
		u32 vCount = mb->getVertexCount();
		video::SColor color(0xffffffff);
		if (attrib & 0x8000)
			color = video::A1R5G5B5toA8R8G8B8(attrib);
		if (normal==core::vector3df())
			normal=core::plane3df(vertex[2],vertex[1],vertex[0]).Normal;
		mb->Vertices.push_back(video::S3DVertex(vertex[2],normal,color, core::vector2df()));
		mb->Vertices.push_back(video::S3DVertex(vertex[1],normal,color, core::vector2df()));
		mb->Vertices.push_back(video::S3DVertex(vertex[0],normal,color, core::vector2df()));
		mb->Indices.push_back(vCount);
		mb->Indices.push_back(vCount+1);
		mb->Indices.push_back(vCount+2);
	}	// end while (file->getPos() < filesize)
	mesh->getMeshBuffer(0)->recalculateBoundingBox();

	// Create the Animated mesh if there's anything in the mesh
	SAnimatedMesh* pAM = 0;
	if ( 0 != mesh->getMeshBufferCount() )
	{
		mesh->recalculateBoundingBox();
		pAM = new SAnimatedMesh();
		pAM->Type = EAMT_OBJ;
		pAM->addMesh(mesh);
		pAM->recalculateBoundingBox();
	}

	mesh->drop();

	return pAM;
}
Example #7
0
    GLlink(ISceneNode *i_parent, ISceneManager *i_mgr, s32 i_id,
           const LinkInfo &i_li, BodyInfo_var i_binfo) :
        ISceneNode(i_parent, i_mgr, i_id),
        m_jointId(i_li.jointId) {
        setAutomaticCulling(scene::EAC_OFF);


        setPosition(vector3df( i_li.translation[0],
                               -i_li.translation[1],
                               i_li.translation[2]));
        Vector3 axis(i_li.rotation[0],
                     i_li.rotation[1],
                     i_li.rotation[2]);
        Matrix33 R;
        hrp::calcRodrigues(R, axis, i_li.rotation[3]);
        Vector3 rpy(rpyFromRot(R));
        //std::cout << "rpy:" << rpy << std::endl;
        setRotation(vector3df(-180/M_PI*rpy[0],
                              180/M_PI*rpy[1],
                              -180/M_PI*rpy[2]));

        m_axis << i_li.jointAxis[0], i_li.jointAxis[1], i_li.jointAxis[2];

        ShapeInfoSequence_var sis = i_binfo->shapes();
        AppearanceInfoSequence_var ais = i_binfo->appearances();
        MaterialInfoSequence_var mis = i_binfo->materials();
        TextureInfoSequence_var txs = i_binfo->textures();
        const TransformedShapeIndexSequence& tsis = i_li.shapeIndices;


        core::vector3df vertex;
        core::vector3df normal;

        for (unsigned int l=0; l<tsis.length(); l++) {
            SMesh* mesh = new SMesh();
            SMeshBuffer* meshBuffer = new SMeshBuffer();
            mesh->addMeshBuffer(meshBuffer);
            meshBuffer->drop();

            const TransformedShapeIndex &tsi = tsis[l];
            short index = tsi.shapeIndex;
            ShapeInfo& si = sis[index];
            const float *vertices = si.vertices.get_buffer();
            const LongSequence& triangles = si.triangles;
            const AppearanceInfo& ai = ais[si.appearanceIndex];
            const float *normals = ai.normals.get_buffer();
            //std::cout << "length of normals = " << ai.normals.length() << std::endl;
            const LongSequence& normalIndices = ai.normalIndices;
            //std::cout << "length of normalIndices = " << normalIndices.length() << std::endl;
            const int numTriangles = triangles.length() / 3;
            //std::cout << "numTriangles = " << numTriangles << std::endl;

            video::SColor color(0xffffffff);
            if (ai.colors.length()) {
                color.set(0xff,
                          0xff*ai.colors[0],
                          0xff*ai.colors[1],
                          0xff*ai.colors[2]);
            } else if (ai.materialIndex >= 0) {
                const MaterialInfo& mi = mis[ai.materialIndex];
                color.set(0xff,
                          0xff*mi.diffuseColor[0],
                          0xff*mi.diffuseColor[1],
                          0xff*mi.diffuseColor[2]);
            } else {
                std::cout << "no material" << std::endl;
            }


            SMeshBuffer* mb = reinterpret_cast<SMeshBuffer*>(mesh->getMeshBuffer(mesh->getMeshBufferCount()-1));
            u32 vCount = mb->getVertexCount();

            const DblArray12& tfm = tsi.transformMatrix;
            CMatrix4<f32> cmat;
            for (int i=0; i<3; i++) {
                for (int j=0; j<4; j++) {
                    cmat[j*4+i] = tfm[i*4+j];
                }
            }
            cmat[3] = cmat[7] = cmat[11] = 0.0;
            cmat[15] = 1.0;
            vector3df pos = cmat.getTranslation();
            pos.Y *= -1;
            vector3df rpy = cmat.getRotationDegrees();
            rpy.X *= -1;
            rpy.Z *= -1;
            vector3df scale = cmat.getScale();

            const float *textureCoordinate = NULL;
            if (ai.textureIndex >= 0) {
                textureCoordinate = ai.textureCoordinate.get_buffer();
                //std::cout << "length of textureCoordinate:" << ai.textureCoordinate.length() << std::endl;
                //std::cout << "length of vertices:" << si.vertices.length() << std::endl;

            }

            for(int j=0; j < numTriangles; ++j) {
                if (!ai.normalPerVertex) {
                    int p;
                    if (normalIndices.length() == 0) {
                        p = j*3;
                    } else {
                        p = normalIndices[j]*3;
                    }
                    if ( normals != NULL ) {
                        normal.X =  normals[p];
                        normal.Y = -normals[p+1]; //left-handed->right-handed
                        normal.Z =  normals[p+2];
                    } else {
                        normal.X = 0;
                        normal.Y = 0;
                        normal.Z = 1;
                    }
                }
                for(int k=0; k < 3; ++k) {
                    long orgVertexIndex = si.triangles[j * 3 + k];
                    if (ai.normalPerVertex) {
                        int p;
                        if (normalIndices.length()) {
                            p = normalIndices[j*3+k]*3;
                        } else {
                            p = orgVertexIndex*3;
                        }
                        normal.X =  normals[p];
                        normal.Y = -normals[p+1]; //left-handed -> right-handed
                        normal.Z =  normals[p+2];
                    }
                    int p = orgVertexIndex * 3;
                    vertex.X =  scale.X*vertices[p];
                    vertex.Y = -scale.Y*vertices[p+1]; // left-handed -> right-handed
                    vertex.Z =  scale.Z*vertices[p+2];
                    //std::cout << vertices[p] <<"," << vertices[p+1] << "," << vertices[p+2] << std::endl;
                    vector2df texc;
                    if (textureCoordinate) {

                        texc.X = textureCoordinate[ai.textureCoordIndices[j*3+k]*2];
                        texc.Y = textureCoordinate[ai.textureCoordIndices[j*3+k]*2+1];
                    }
                    // redundant vertices
                    mb->Vertices.push_back(video::S3DVertex(vertex,normal,color, texc));
                }
                mb->Indices.push_back(vCount);
                mb->Indices.push_back(vCount+2);
                mb->Indices.push_back(vCount+1);
                vCount += 3;
            }
            mesh->getMeshBuffer(0)->recalculateBoundingBox();

            // Create the Animated mesh if there's anything in the mesh
            SAnimatedMesh* pAM = 0;
            if ( 0 != mesh->getMeshBufferCount() )
            {
                mesh->recalculateBoundingBox();
                pAM = new SAnimatedMesh();
                pAM->Type = EAMT_OBJ;
                pAM->addMesh(mesh);
                pAM->recalculateBoundingBox();
            }

            mesh->drop();

            vector3df noscale(1,1,1);

            IMeshSceneNode *node
                = i_mgr->addMeshSceneNode(mesh, this, -1,
                                          pos,
                                          rpy,
                                          noscale);

            if (ai.textureIndex >= 0) {
                const TextureInfo& ti = txs[ai.textureIndex];
                //std::cout << "url:" << ti.url << std::endl;
                video::IVideoDriver* driver = i_mgr->getVideoDriver();
                const char *path = ti.url;
                SMaterial& mat = node->getMaterial(0);
                ITexture *texture = driver->getTexture(path);
                mat.setTexture( 0, texture);
            }

        }

        const SensorInfoSequence& sensors = i_li.sensors;
        for (unsigned int i=0; i<sensors.length(); i++) {
            const SensorInfo& si = sensors[i];
            std::string type(si.type);
            if (type == "Vision") {
                //std::cout << si.name << std::endl;
                ISceneNode *camera = i_mgr->addEmptySceneNode(this);
                camera->setName(si.name);
                camera->setPosition(vector3df( si.translation[0],
                                               -si.translation[1],
                                               si.translation[2]));
                Vector3 axis(si.rotation[0],
                             si.rotation[1],
                             si.rotation[2]);
                Matrix33 R;
                hrp::calcRodrigues(R, axis, si.rotation[3]);
                Vector3 rpy(rpyFromRot(R));
                camera->setRotation(vector3df(-180/M_PI*rpy[0],
                                              180/M_PI*rpy[1],
                                              -180/M_PI*rpy[2]));
                m_cameraInfos.push_back(new GLcamera(si, camera));
            }
        }
    }
Example #8
0
//! creates/loads an animated mesh from the file.
//! \return Pointer to the created mesh. Returns 0 if loading failed.
//! If you no longer need the mesh, you should call IAnimatedMesh::drop().
//! See IReferenceCounted::drop() for more information.
IAnimatedMesh* COCTLoader::createMesh(io::IReadFile* file)
{
	if (!file)
		return 0;

	octHeader header;
	file->read(&header, sizeof(octHeader));

	octVert * verts = new octVert[header.numVerts];
	octFace * faces = new octFace[header.numFaces];
	octTexture * textures = new octTexture[header.numTextures];
	octLightmap * lightmaps = new octLightmap[header.numLightmaps];
	octLight * lights = new octLight[header.numLights];

	file->read(verts, sizeof(octVert) * header.numVerts);
	file->read(faces, sizeof(octFace) * header.numFaces);
	//TODO: Make sure id is in the legal range for Textures and Lightmaps

	u32 i;
	for (i = 0; i < header.numTextures; i++) {
		octTexture t;
		file->read(&t, sizeof(octTexture));
		textures[t.id] = t;
	}
	for (i = 0; i < header.numLightmaps; i++) {
		octLightmap t;
		file->read(&t, sizeof(octLightmap));
		lightmaps[t.id] = t;
	}
	file->read(lights, sizeof(octLight) * header.numLights);

	//TODO: Now read in my extended OCT header (flexible lightmaps and vertex normals)


	// This is the method Nikolaus Gebhardt used in the Q3 loader -- create a
	// meshbuffer for every possible combination of lightmap and texture including
	// a "null" texture and "null" lightmap.  Ones that end up with nothing in them
	// will be removed later.

	SMesh * Mesh = new SMesh();
	for (i=0; i<(header.numTextures+1) * (header.numLightmaps+1); ++i)
	{
		scene::SMeshBufferLightMap* buffer = new scene::SMeshBufferLightMap();

		buffer->Material.MaterialType = video::EMT_LIGHTMAP;
		buffer->Material.Lighting = false;
		Mesh->addMeshBuffer(buffer);
		buffer->drop();
	}


	// Build the mesh buffers
	for (i = 0; i < header.numFaces; i++)
	{
		if (faces[i].numVerts < 3)
			continue;

		const f32* const a = verts[faces[i].firstVert].pos;
		const f32* const b = verts[faces[i].firstVert+1].pos;
		const f32* const c = verts[faces[i].firstVert+2].pos;
		const core::vector3df normal =
			core::plane3df(core::vector3df(a[0],a[1],a[2]), core::vector3df(b[0],c[1],c[2]), core::vector3df(c[0],c[1],c[2])).Normal;

		const u32 textureID = core::min_(s32(faces[i].textureID), s32(header.numTextures - 1)) + 1;
		const u32 lightmapID = core::min_(s32(faces[i].lightmapID),s32(header.numLightmaps - 1)) + 1;
		SMeshBufferLightMap * meshBuffer = (SMeshBufferLightMap*)Mesh->getMeshBuffer(lightmapID * (header.numTextures + 1) + textureID);
		const u32 base = meshBuffer->Vertices.size();

		// Add this face's verts
		u32 v;
		for (v = 0; v < faces[i].numVerts; ++v)
		{
			octVert * vv = &verts[faces[i].firstVert + v];
			video::S3DVertex2TCoords vert;
			vert.Pos.set(vv->pos[0], vv->pos[1], vv->pos[2]);
			vert.Color = video::SColor(0,255,255,255);
			vert.Normal.set(normal);

			if (textureID == 0)
			{
				// No texture -- just a lightmap.  Thus, use lightmap coords for texture 1.
				// (the actual texture will be swapped later)
				vert.TCoords.set(vv->lc[0], vv->lc[1]);
			}
			else
			{
				vert.TCoords.set(vv->tc[0], vv->tc[1]);
				vert.TCoords2.set(vv->lc[0], vv->lc[1]);
			}

			meshBuffer->Vertices.push_back(vert);
		}

		// Now add the indices
		// This weird loop turns convex polygons into triangle strips.
		// I do it this way instead of a simple fan because it usually looks a lot better in wireframe, for example.
		// High, Low
		u32 h = faces[i].numVerts - 1;
		u32 l = 0;
		for (v = 0; v < faces[i].numVerts - 2; ++v)
		{
			const u32 center = (v & 1)? h - 1: l + 1;

			meshBuffer->Indices.push_back(base + h);
			meshBuffer->Indices.push_back(base + l);
			meshBuffer->Indices.push_back(base + center);

			if (v & 1)
				--h;
			else
				++l;
		}
	}

	// load textures
	core::array<video::ITexture*> tex;
	tex.reallocate(header.numTextures + 1);
	tex.push_back(0);

	const core::stringc relpath = FileSystem->getFileDir(file->getFileName())+"/";
	for (i = 1; i < (header.numTextures + 1); i++)
	{
		core::stringc path(textures[i-1].fileName);
		path.replace('\\','/');
		if (FileSystem->existFile(path))
			tex.push_back(SceneManager->getVideoDriver()->getTexture(path));
		else
			// try to read in the relative path of the OCT file
			tex.push_back(SceneManager->getVideoDriver()->getTexture( (relpath + path) ));
	}

	// prepare lightmaps
	core::array<video::ITexture*> lig;
	lig.set_used(header.numLightmaps + 1);
	lig[0] = 0;

	const u32 lightmapWidth = 128;
	const u32 lightmapHeight = 128;
	const core::dimension2d<u32> lmapsize(lightmapWidth, lightmapHeight);

	bool oldMipMapState = SceneManager->getVideoDriver()->getTextureCreationFlag(video::ETCF_CREATE_MIP_MAPS);
	SceneManager->getVideoDriver()->setTextureCreationFlag(video::ETCF_CREATE_MIP_MAPS, false);

	video::CImage tmpImage(video::ECF_R8G8B8, lmapsize);
	for (i = 1; i < (header.numLightmaps + 1); ++i)
	{
		core::stringc lightmapname = file->getFileName();
		lightmapname += ".lightmap.";
		lightmapname += (int)i;

		const octLightmap* lm = &lightmaps[i-1];

		for (u32 x=0; x<lightmapWidth; ++x)
		{
			for (u32 y=0; y<lightmapHeight; ++y)
			{
				tmpImage.setPixel(x, y,
						video::SColor(255,
						lm->data[x][y][2],
						lm->data[x][y][1],
						lm->data[x][y][0]));
			}
		}

		lig[i] = SceneManager->getVideoDriver()->addTexture(lightmapname.c_str(), &tmpImage);
	}
	SceneManager->getVideoDriver()->setTextureCreationFlag(video::ETCF_CREATE_MIP_MAPS, oldMipMapState);

	// Free stuff
	delete [] verts;
	delete [] faces;
	delete [] textures;
	delete [] lightmaps;
	delete [] lights;

	// attach materials
	for (i = 0; i < header.numLightmaps + 1; i++)
	{
		for (u32 j = 0; j < header.numTextures + 1; j++)
		{
			u32 mb = i * (header.numTextures + 1) + j;
			SMeshBufferLightMap * meshBuffer = (SMeshBufferLightMap*)Mesh->getMeshBuffer(mb);
			meshBuffer->Material.setTexture(0, tex[j]);
			meshBuffer->Material.setTexture(1, lig[i]);

			if (meshBuffer->Material.getTexture(0) == 0)
			{
				// This material has no texture, so we'll just show the lightmap if there is one.
				// We swapped the texture coordinates earlier.
				meshBuffer->Material.setTexture(0, meshBuffer->Material.getTexture(1));
				meshBuffer->Material.setTexture(1, 0);
			}
			if (meshBuffer->Material.getTexture(1) == 0)
			{
				// If there is only one texture, it should be solid and lit.
				// Among other things, this way you can preview OCT lights.
				meshBuffer->Material.MaterialType = video::EMT_SOLID;
				meshBuffer->Material.Lighting = true;
			}
		}
	}

	// delete all buffers without geometry in it.
	i = 0;
	while(i < Mesh->MeshBuffers.size())
	{
		if (Mesh->MeshBuffers[i]->getVertexCount() == 0 ||
			Mesh->MeshBuffers[i]->getIndexCount() == 0 ||
			Mesh->MeshBuffers[i]->getMaterial().getTexture(0) == 0)
		{
			// Meshbuffer is empty -- drop it
			Mesh->MeshBuffers[i]->drop();
			Mesh->MeshBuffers.erase(i);
		}
		else
		{
			++i;
		}
	}


	// create bounding box
	for (i = 0; i < Mesh->MeshBuffers.size(); ++i)
	{
		Mesh->MeshBuffers[i]->recalculateBoundingBox();
	}
	Mesh->recalculateBoundingBox();


	// Set up an animated mesh to hold the mesh
	SAnimatedMesh* AMesh = new SAnimatedMesh();
	AMesh->Type = EAMT_OCT;
	AMesh->addMesh(Mesh);
	AMesh->recalculateBoundingBox();
	Mesh->drop();

	return AMesh;
}
IAnimatedMesh* CLMTSMeshFileLoader::createMesh(irr::io::IReadFile* file) {

	u32 i;
	u32 id;

	// HEADER

	file->read(&Header, sizeof(SLMTSHeader));
	if (Header.MagicID != 0x53544D4C) { // "LMTS"
		LMTS_LOG("LMTS ERROR: wrong header magic id!", ELL_ERROR);
		return 0;
	}

	// TEXTURES

	file->read(&id, sizeof(u32));
	if (id != 0x54584554) { // "TEXT"
		LMTS_LOG("LMTS ERROR: wrong texture magic id!", ELL_ERROR);
		return 0;
	}

	Textures = new SLMTSTextureInfoEntry[Header.TextureCount];
	TextureIDs = new u16[Header.TextureCount];

	NumLightMaps = NumTextures = 0;

	for (i=0; i<Header.TextureCount; i++) {
		file->read(&Textures[i], sizeof(SLMTSTextureInfoEntry));
		if (Textures[i].Flags & 1) {
			TextureIDs[i] = NumLightMaps;
			NumLightMaps++;
		} else {
			TextureIDs[i] = NumTextures;
			NumTextures++;
		}

	}

	// SUBSETS

	file->read(&id, sizeof(u32));
	if (id != 0x53425553) { // "SUBS"
		LMTS_LOG("LMTS ERROR: wrong subset magic id!", ELL_ERROR);
		cleanup();
		return 0;
	}

	Subsets = new SLMTSSubsetInfoEntry[Header.SubsetCount];

	for (i=0; i<Header.SubsetCount; i++) {
		file->read(&Subsets[i], sizeof(SLMTSSubsetInfoEntry));
	}

	// TRIANGLES

	file->read(&id, sizeof(u32));
	if (id != 0x53495254) { // "TRIS"
		LMTS_LOG("LMTS ERROR: wrong triangle magic id!", ELL_ERROR);
		cleanup();
		return 0;
	}

	Triangles = new SLMTSTriangleDataEntry[(Header.TriangleCount*3)];

	for (i=0; i<(Header.TriangleCount*3); i++) {
		file->read(&Triangles[i], sizeof(SLMTSTriangleDataEntry));
	}

    /////////////////////////////////////////////////////////////////

	constructMesh();

	loadTextures();

	cleanup();

	SAnimatedMesh* am = new SAnimatedMesh();
	am->Type = EAMT_LMTS; // not unknown to irrlicht anymore

	am->addMesh(Mesh);
	am->recalculateBoundingBox();
	Mesh->drop();
	Mesh = 0;
    return am;
	
}
Example #10
0
static IAnimatedMesh* buildMesh(
		mqo::Loader &loader, video::IVideoDriver *driver)
{
	int vertexCount=0;
	int triangleCount=0;
	int qudrangleCount=0;
	int originalVertexCount=0;

	// convert to irrlicht mesh.
	// mqo is shared vertex that has different uv (and normal).
	// therefore, the indexed array is expanded here.
	// 
	// index array is [0, 1, 2, 3, 4, 5...]
	SMesh *mesh=new SMesh;
	TEXTURE_MAP texture_map;
	for(auto it=loader.objects.begin(); it!=loader.objects.end(); ++it){
		mqo::Object &o=*it;
		////////////////////////////////////////////////////////////
		// each mqo object
		////////////////////////////////////////////////////////////
		originalVertexCount+=o.vertices.size();

		std::map<int, SMeshBuffer*> mesh_map;
		for(auto it=o.faces.begin(); it!=o.faces.end(); ++it){
			mqo::Face &f=*it;
			////////////////////////////////////////////////////////////
			// each mqo face
			////////////////////////////////////////////////////////////
			// split by material
			int material_index=f.material_index;
			std::map<int, SMeshBuffer*>::iterator found=
				mesh_map.find(material_index);
			SMeshBuffer *meshBuffer=0;
			if(found==mesh_map.end()){
				// not found. new meshBuffer.
				meshBuffer=createMeshBuffer(
						loader, material_index, texture_map, driver);
				mesh_map.insert(std::make_pair(material_index, meshBuffer));
				mesh->MeshBuffers.push_back(meshBuffer);
			}
			else{
				// use found meshBuffer.
				meshBuffer=found->second;
			}
			// material
			mqo::Material &m=loader.materials[material_index];
			// append face
			switch(f.index_count)
			{
			case 3:
				// triangle
				push_vertex(meshBuffer, o.vertices[f.indices[0]], f.uv[0],
						m.vcol ? f.color[0] : m.color);
				push_vertex(meshBuffer, o.vertices[f.indices[1]], f.uv[1],
						m.vcol ? f.color[1] : m.color);
				push_vertex(meshBuffer, o.vertices[f.indices[2]], f.uv[2],
						m.vcol ? f.color[2] : m.color);

				vertexCount+=3;
				triangleCount+=1;
				break;
			case 4:
				// qudrangle
				// triangle 0
				push_vertex(meshBuffer, o.vertices[f.indices[0]], f.uv[0],
						m.vcol ? f.color[0] : m.color);
				push_vertex(meshBuffer, o.vertices[f.indices[1]], f.uv[1],
						m.vcol ? f.color[1] : m.color);
				push_vertex(meshBuffer, o.vertices[f.indices[2]], f.uv[2],
						m.vcol ? f.color[2] : m.color);
				// triangle 1
				push_vertex(meshBuffer, o.vertices[f.indices[2]], f.uv[2],
						m.vcol ? f.color[2] : m.color);
				push_vertex(meshBuffer, o.vertices[f.indices[3]], f.uv[3],
						m.vcol ? f.color[3] : m.color);
				push_vertex(meshBuffer, o.vertices[f.indices[0]], f.uv[0],
						m.vcol ? f.color[0] : m.color);

				vertexCount+=6;
				triangleCount+=2;
				qudrangleCount+=1;
				break;
			}
		}
	}

	// finalize
	mesh->recalculateBoundingBox();
	SAnimatedMesh *animMesh = new SAnimatedMesh();
	animMesh->Type = EAMT_UNKNOWN;
	animMesh->recalculateBoundingBox();
	animMesh->addMesh(mesh);
	mesh->drop();

	// summary
	std::cout 
		<< originalVertexCount << " vertices"
		<< " is expand to " << vertexCount << " vertices" << std::endl
		<< triangleCount << " triangles ("
		<< qudrangleCount << "quadrangles)" << std::endl
		;

	return animMesh;
}
IAnimatedMesh* CMY3DMeshFileLoader::createMesh(io::IReadFile* file)
{
	MaterialEntry.clear();
	MeshBufferEntry.clear();
	ChildNodes.clear();

	// working directory (from which we load the scene)
	core::stringc filepath = FileSystem->getFileDir(file->getFileName());
	if (filepath==".")
		filepath="";
	else
		filepath.append("/");

	// read file into memory
	SMyFileHeader fileHeader;
	file->read(&fileHeader, sizeof(SMyFileHeader));
#ifdef __BIG_ENDIAN__
	fileHeader.MyId = os::Byteswap::byteswap(fileHeader.MyId);
	fileHeader.Ver = os::Byteswap::byteswap(fileHeader.Ver);
#endif

	if (fileHeader.MyId!=MY3D_ID || fileHeader.Ver!=MY3D_VER)
	{
		os::Printer::log("Bad MY3D file header, loading failed!", ELL_ERROR);
		return 0;
	}

	u16 id;

	file->read(&id, sizeof(id));
#ifdef __BIG_ENDIAN__
	id = os::Byteswap::byteswap(id);
#endif

	if (id!=MY3D_SCENE_HEADER_ID)
	{
		os::Printer::log("Cannot find MY3D_SCENE_HEADER_ID, loading failed!", ELL_ERROR);
		return 0;
	}

	SMySceneHeader sceneHeader;
	file->read(&sceneHeader, sizeof(SMySceneHeader));
#ifdef __BIG_ENDIAN__
	sceneHeader.MaterialCount = os::Byteswap::byteswap(sceneHeader.MaterialCount);
	sceneHeader.MeshCount = os::Byteswap::byteswap(sceneHeader.MeshCount);
#endif

	file->read(&id, sizeof(id));
#ifdef __BIG_ENDIAN__
	id = os::Byteswap::byteswap(id);
#endif

	if (id!=MY3D_MAT_LIST_ID)
	{
		os::Printer::log("Can not find MY3D_MAT_LIST_ID, loading failed!", ELL_ERROR);
		return 0;
	}

	core::stringc texturePath =
		SceneManager->getParameters()->getAttributeAsString(MY3D_TEXTURE_PATH);

	file->read(&id, sizeof(id));
#ifdef __BIG_ENDIAN__
	id = os::Byteswap::byteswap(id);
#endif

	c8 namebuf[256];
	for (s32 m=0; m<sceneHeader.MaterialCount; ++m)
	{
		if (id != MY3D_MAT_HEADER_ID)
		{
			os::Printer::log("Cannot find MY3D_MAT_HEADER_ID, loading failed!", ELL_ERROR);
			return 0;
		}

		// read material header
		MaterialEntry.push_back(SMyMaterialEntry());
		SMyMaterialEntry& me=MaterialEntry.getLast();
		file->read(&(me.Header), sizeof(SMyMaterialHeader));

		// read next identificator
		file->read(&id, sizeof(id));
#ifdef __BIG_ENDIAN__
		id = os::Byteswap::byteswap(id);
#endif

		bool gotLightMap=false, gotMainMap=false;

		for (u32 t=0; t<me.Header.TextureCount; ++t)
		{
			if (id==MY3D_TEX_FNAME_ID)
				file->read(namebuf, 256);
			else
			{
				me.Texture2 = readEmbeddedLightmap(file, namebuf);
				if (!me.Texture2)
					return 0;
				gotLightMap = true;
			}

			const core::stringc name(namebuf);
			const s32 pos = name.findLast('.');
			const core::stringc LightingMapStr = "LightingMap";
			const s32 ls = LightingMapStr.size();
			const bool isSubString = (LightingMapStr == name.subString(core::max_(0, (pos - ls)), ls));
			if ((isSubString || (name[pos-1]=='m' &&
				name[pos-2]=='l' && name[pos-3]=='_')) &&
				!gotLightMap)
			{
				const bool oldMipMapState = SceneManager->getVideoDriver()->getTextureCreationFlag(video::ETCF_CREATE_MIP_MAPS);
				SceneManager->getVideoDriver()->setTextureCreationFlag(video::ETCF_CREATE_MIP_MAPS, false);

				me.Texture2FileName = texturePath.size() ? texturePath : filepath;
				me.Texture2FileName.append("Lightmaps/");
				me.Texture2FileName.append(name);

				if (name.size())
					me.Texture2 = SceneManager->getVideoDriver()->getTexture(me.Texture2FileName);

				me.MaterialType = video::EMT_LIGHTMAP_M2;
				gotLightMap = true;

				SceneManager->getVideoDriver()->setTextureCreationFlag(video::ETCF_CREATE_MIP_MAPS, oldMipMapState);
			}
			else
			if (!gotLightMap && gotMainMap)
			{
				me.Texture2FileName = texturePath.size() ? texturePath : filepath;
				me.Texture2FileName.append(name);

				if (name.size())
					me.Texture2 = SceneManager->getVideoDriver()->getTexture(me.Texture2FileName);

				me.MaterialType = video::EMT_REFLECTION_2_LAYER;
			}
			else
			if (!gotMainMap && !gotLightMap)
			{
				me.Texture1FileName = filepath;
				me.Texture1FileName.append(name);
				if (name.size())
					me.Texture1 = SceneManager->getVideoDriver()->getTexture(me.Texture1FileName);

				gotMainMap = true;
				me.MaterialType = video::EMT_SOLID;
			}
			else
			if (gotLightMap)
			{
				me.MaterialType = video::EMT_LIGHTMAP_M2;
			}

			file->read(&id, sizeof(id));
#ifdef __BIG_ENDIAN__
			id = os::Byteswap::byteswap(id);
#endif
		}

		// override material types based on their names
		if (!strncmp(me.Header.Name, "AlphaChannel-", 13))
			me.MaterialType = video::EMT_TRANSPARENT_ALPHA_CHANNEL;
		else
		if (!strncmp(me.Header.Name, "SphereMap-", 10))
			me.MaterialType = video::EMT_SPHERE_MAP;
	}

	// loading meshes

	if (id!=MY3D_MESH_LIST_ID)
	{
		os::Printer::log("Can not find MY3D_MESH_LIST_ID, loading failed!", ELL_ERROR);
		return 0;
	}

	file->read(&id, sizeof(id));
#ifdef __BIG_ENDIAN__
	id = os::Byteswap::byteswap(id);
#endif

	for (s32 mesh_id=0; mesh_id<sceneHeader.MeshCount; mesh_id++)
	{
		// Warning!!! In some cases MY3D exporter uncorrectly calculates
		// MeshCount (it's a problem, has to be solved) thats why
		// i added this code line
		if (id!=MY3D_MESH_HEADER_ID)
			break;

		if (id!=MY3D_MESH_HEADER_ID)
		{
			os::Printer::log("Can not find MY3D_MESH_HEADER_ID, loading failed!", ELL_ERROR);
			return 0;
		}

		SMyMeshHeader meshHeader;
		file->read(&meshHeader, sizeof(SMyMeshHeader));

		core::array <SMyVertex> Vertex;
		core::array <SMyFace> Face;
		core::array <SMyTVertex> TVertex1, TVertex2;
		core::array <SMyFace> TFace1, TFace2;

		s32 vertsNum=0;
		s32 facesNum=0;

		// vertices
		file->read(&id, sizeof(id));
#ifdef __BIG_ENDIAN__
	id = os::Byteswap::byteswap(id);
#endif
		if (id!=MY3D_VERTS_ID)
		{
			os::Printer::log("Can not find MY3D_VERTS_ID, loading failed!", ELL_ERROR);
			return 0;
		}

		file->read(&vertsNum, sizeof(vertsNum));
		Vertex.set_used(vertsNum);
		file->read(Vertex.pointer(), sizeof(SMyVertex)*vertsNum);

		// faces
		file->read(&id, sizeof(id));
#ifdef __BIG_ENDIAN__
		id = os::Byteswap::byteswap(id);
#endif
		if (id!=MY3D_FACES_ID)
		{
			os::Printer::log("Can not find MY3D_FACES_ID, loading failed!", ELL_ERROR);
			return 0;
		}

		file->read(&facesNum, sizeof(facesNum));
		Face.set_used(facesNum);
		file->read(Face.pointer(), sizeof(SMyFace)*facesNum);

		// reading texture channels
		for (s32 tex=0; tex<(s32)meshHeader.TChannelCnt; tex++)
		{
			// Max 2 texture channels allowed (but in format .my3d can be more)
			s32 tVertsNum=0, tFacesNum=0;

			// reading texture coords
			file->read(&id, sizeof(id));
#ifdef __BIG_ENDIAN__
			id = os::Byteswap::byteswap(id);
#endif

			if (id!=MY3D_TVERTS_ID)
			{
				core::stringc msg="Can not find MY3D_TVERTS_ID (";
				msg.append(core::stringc(tex));
				msg.append("texture channel), loading failed!");
				os::Printer::log(msg.c_str(), ELL_ERROR);
				return 0;
			}

			file->read(&tVertsNum, sizeof(tVertsNum));

			if (tex==0)
			{
				// 1st texture channel
				TVertex1.set_used(tVertsNum);
				file->read(TVertex1.pointer(), sizeof(SMyTVertex)*tVertsNum);
			}
			else
			if (tex==1)
			{
				// 2nd texture channel
				TVertex2.set_used(tVertsNum);
				file->read(TVertex2.pointer(), sizeof(SMyTVertex)*tVertsNum);
			}
			else
			{
				// skip other texture channels
				file->seek(file->getPos()+sizeof(SMyTVertex)*tVertsNum);
			}

			// reading texture faces
			file->read(&id, sizeof(id));
#ifdef __BIG_ENDIAN__
			id = os::Byteswap::byteswap(id);
#endif

			if (id!=MY3D_TFACES_ID)
			{
				core::stringc msg="Can not find MY3D_TFACES_ID (";
				msg.append(core::stringc(tex));
				msg.append("texture channel), loading failed!");
				os::Printer::log(msg.c_str(), ELL_ERROR);
				return 0;
			}

			file->read(&tFacesNum, sizeof(tFacesNum));

			if (tex==0)
			{
				// 1st texture channel
				TFace1.set_used(tFacesNum);
				file->read(TFace1.pointer(), sizeof(SMyFace)*tFacesNum);
			}
			else if (tex==1)
			{
				// 2nd texture channel
				TFace2.set_used(tFacesNum);
				file->read(TFace2.pointer(), sizeof(SMyFace)*tFacesNum);
			}
			else
			{
				// skip other texture channels
				file->seek(file->getPos()+sizeof(SMyFace)*tFacesNum);
			}
		}

		// trying to find material

		SMyMaterialEntry* matEnt = getMaterialEntryByIndex(meshHeader.MatIndex);

		// creating geometry for the mesh

		// trying to find mesh buffer for this material
		CMeshBuffer<video::S3DVertex2TCoords>* buffer = getMeshBufferByMaterialIndex(meshHeader.MatIndex);

		if (!buffer ||
			(buffer->getVertexBuffer()->getVertexCount()+vertsNum) > SceneManager->getVideoDriver()->getMaximalPrimitiveCount())
		{
			// creating new mesh buffer for this material
			buffer = new CMeshBuffer<video::S3DVertex2TCoords>(SceneManager->getVideoDriver()->getVertexDescriptor(1));

			buffer->Material.MaterialType = video::EMT_LIGHTMAP_M2; // EMT_LIGHTMAP_M4 also possible
			buffer->Material.Wireframe = false;
			buffer->Material.Lighting = false;

			if (matEnt)
			{
				buffer->Material.MaterialType = matEnt->MaterialType;

				if (buffer->Material.MaterialType == video::EMT_REFLECTION_2_LAYER)
				{
					buffer->Material.Lighting = true;
					buffer->Material.setTexture(1, matEnt->Texture1);
					buffer->Material.setTexture(0, matEnt->Texture2);
				}
				else
				{
					buffer->Material.setTexture(0, matEnt->Texture1);
					buffer->Material.setTexture(1, matEnt->Texture2);
				}

				if (buffer->Material.MaterialType == video::EMT_TRANSPARENT_ALPHA_CHANNEL)
				{
					buffer->Material.BackfaceCulling = true;
					buffer->Material.Lighting  = true;
				}
				else
				if (buffer->Material.MaterialType == video::EMT_SPHERE_MAP)
				{
					buffer->Material.Lighting  = true;
				}

				buffer->Material.AmbientColor = video::SColor(
					matEnt->Header.AmbientColor.A, matEnt->Header.AmbientColor.R,
					matEnt->Header.AmbientColor.G, matEnt->Header.AmbientColor.B
					);
				buffer->Material.DiffuseColor =	video::SColor(
					matEnt->Header.DiffuseColor.A, matEnt->Header.DiffuseColor.R,
					matEnt->Header.DiffuseColor.G, matEnt->Header.DiffuseColor.B
					);
				buffer->Material.EmissiveColor = video::SColor(
					matEnt->Header.EmissiveColor.A, matEnt->Header.EmissiveColor.R,
					matEnt->Header.EmissiveColor.G, matEnt->Header.EmissiveColor.B
					);
				buffer->Material.SpecularColor = video::SColor(
					matEnt->Header.SpecularColor.A, matEnt->Header.SpecularColor.R,
					matEnt->Header.SpecularColor.G, matEnt->Header.SpecularColor.B
					);
			}
			else
			{
				buffer->Material.setTexture(0, 0);
				buffer->Material.setTexture(1, 0);

				buffer->Material.AmbientColor = video::SColor(255, 255, 255, 255);
				buffer->Material.DiffuseColor =	video::SColor(255, 255, 255, 255);
				buffer->Material.EmissiveColor = video::SColor(0, 0, 0, 0);
				buffer->Material.SpecularColor = video::SColor(0, 0, 0, 0);
			}

			if (matEnt && matEnt->Header.Transparency!=0)
			{
				if (buffer->Material.MaterialType == video::EMT_REFLECTION_2_LAYER )
				{
					buffer->Material.MaterialType = video::EMT_TRANSPARENT_REFLECTION_2_LAYER;
					buffer->Material.Lighting  = true;
					buffer->Material.BackfaceCulling = true;
				}
				else
				{
					buffer->Material.MaterialType = video::EMT_TRANSPARENT_VERTEX_ALPHA;
					buffer->Material.Lighting = false;
					buffer->Material.BackfaceCulling = false;
				}
			}
			else if (
				!buffer->Material.getTexture(1) &&
				buffer->Material.MaterialType != video::EMT_TRANSPARENT_ALPHA_CHANNEL &&
				buffer->Material.MaterialType != video::EMT_SPHERE_MAP)
			{
				buffer->Material.MaterialType = video::EMT_SOLID;
				buffer->Material.Lighting  = true;
			}

			MeshBufferEntry.push_back(
			SMyMeshBufferEntry(meshHeader.MatIndex, buffer));
		}

		video::S3DVertex2TCoords VertexA, VertexB, VertexC;

		// vertices (A, B, C) color
		video::SColor vert_color;
		if (matEnt &&
			(buffer->Material.MaterialType == video::EMT_TRANSPARENT_VERTEX_ALPHA ||
			buffer->Material.MaterialType == video::EMT_TRANSPARENT_REFLECTION_2_LAYER))
		{
			video::SColor color(
			matEnt->Header.DiffuseColor.A, matEnt->Header.DiffuseColor.R,
			matEnt->Header.DiffuseColor.G, matEnt->Header.DiffuseColor.B);

			vert_color = color.getInterpolated(video::SColor(0,0,0,0),
				1-matEnt->Header.Transparency);
		}
		else
		{
			vert_color = buffer->Material.DiffuseColor;
		}

		VertexA.Color = VertexB.Color = VertexC.Color = vert_color;

		if (buffer->Material.MaterialType == video::EMT_TRANSPARENT_ALPHA_CHANNEL)
		{
			buffer->getIndexBuffer()->reallocate(buffer->getIndexBuffer()->getIndexCount()+6*facesNum);
			buffer->getVertexBuffer()->reallocate(buffer->getVertexBuffer()->getVertexCount()+6*facesNum);
		}
		else
		{
			buffer->getIndexBuffer()->reallocate(buffer->getIndexBuffer()->getIndexCount()+3*facesNum);
			buffer->getVertexBuffer()->reallocate(buffer->getVertexBuffer()->getVertexCount()+3*facesNum);
		}
		for (int f=0; f<facesNum; f++)
		{
			// vertex A

			VertexA.Pos.X = Vertex[Face[f].C].Coord.X;
			VertexA.Pos.Y = Vertex[Face[f].C].Coord.Y;
			VertexA.Pos.Z = Vertex[Face[f].C].Coord.Z;

			VertexA.Normal.X = Vertex[Face[f].C].Normal.X;
			VertexA.Normal.Y = Vertex[Face[f].C].Normal.Y;
			VertexA.Normal.Z = Vertex[Face[f].C].Normal.Z;

			if (meshHeader.TChannelCnt>0)
			{
				VertexA.TCoords.X  = TVertex1[TFace1[f].C].TCoord.X;
				VertexA.TCoords.Y  = TVertex1[TFace1[f].C].TCoord.Y;
			}

			if (meshHeader.TChannelCnt>1)
			{
				VertexA.TCoords2.X = TVertex2[TFace2[f].C].TCoord.X;
				VertexA.TCoords2.Y = TVertex2[TFace2[f].C].TCoord.Y;
			}

			// vertex B

			VertexB.Pos.X = Vertex[Face[f].B].Coord.X;
			VertexB.Pos.Y = Vertex[Face[f].B].Coord.Y;
			VertexB.Pos.Z = Vertex[Face[f].B].Coord.Z;

			VertexB.Normal.X = Vertex[Face[f].B].Normal.X;
			VertexB.Normal.Y = Vertex[Face[f].B].Normal.Y;
			VertexB.Normal.Z = Vertex[Face[f].B].Normal.Z;

			if (meshHeader.TChannelCnt>0)
			{
				VertexB.TCoords.X  = TVertex1[TFace1[f].B].TCoord.X;
				VertexB.TCoords.Y  = TVertex1[TFace1[f].B].TCoord.Y;
			}

			if (meshHeader.TChannelCnt>1)
			{
				VertexB.TCoords2.X = TVertex2[TFace2[f].B].TCoord.X;
				VertexB.TCoords2.Y = TVertex2[TFace2[f].B].TCoord.Y;
			}

			// vertex C

			VertexC.Pos.X = Vertex[Face[f].A].Coord.X;
			VertexC.Pos.Y = Vertex[Face[f].A].Coord.Y;
			VertexC.Pos.Z = Vertex[Face[f].A].Coord.Z;

			VertexC.Normal.X = Vertex[Face[f].A].Normal.X;
			VertexC.Normal.Y = Vertex[Face[f].A].Normal.Y;
			VertexC.Normal.Z = Vertex[Face[f].A].Normal.Z;

			if (meshHeader.TChannelCnt>0)
			{
				VertexC.TCoords.X  = TVertex1[TFace1[f].A].TCoord.X;
				VertexC.TCoords.Y  = TVertex1[TFace1[f].A].TCoord.Y;
			}
			if (meshHeader.TChannelCnt>1)
			{
				VertexC.TCoords2.X = TVertex2[TFace2[f].A].TCoord.X;
				VertexC.TCoords2.Y = TVertex2[TFace2[f].A].TCoord.Y;
			}

			// store 3d data in mesh buffer

			buffer->getIndexBuffer()->addIndex(buffer->getVertexBuffer()->getVertexCount());
			buffer->getVertexBuffer()->addVertex(&VertexA);

			buffer->getIndexBuffer()->addIndex(buffer->getVertexBuffer()->getVertexCount());
			buffer->getVertexBuffer()->addVertex(&VertexB);

			buffer->getIndexBuffer()->addIndex(buffer->getVertexBuffer()->getVertexCount());
			buffer->getVertexBuffer()->addVertex(&VertexC);

			//*****************************************************************
			//          !!!!!! W A R N I N G !!!!!!!
			//*****************************************************************
			// For materials with alpha channel we duplicate all faces.
			// This has be done for proper lighting calculation of the back faces.
			// So you must remember this while you creating your models !!!!!
			//*****************************************************************
			//          !!!!!! W A R N I N G !!!!!!!
			//*****************************************************************

			if (buffer->Material.MaterialType == video::EMT_TRANSPARENT_ALPHA_CHANNEL)
			{
				VertexA.Normal = core::vector3df(-VertexA.Normal.X, -VertexA.Normal.Y, -VertexA.Normal.Z);
				VertexB.Normal = core::vector3df(-VertexB.Normal.X, -VertexB.Normal.Y, -VertexB.Normal.Z);
				VertexC.Normal = core::vector3df(-VertexC.Normal.X, -VertexC.Normal.Y, -VertexC.Normal.Z);

				buffer->getIndexBuffer()->addIndex(buffer->getVertexBuffer()->getVertexCount());
				buffer->getVertexBuffer()->addVertex(&VertexC);

				buffer->getIndexBuffer()->addIndex(buffer->getVertexBuffer()->getVertexCount());
				buffer->getVertexBuffer()->addVertex(&VertexB);

				buffer->getIndexBuffer()->addIndex(buffer->getVertexBuffer()->getVertexCount());
				buffer->getVertexBuffer()->addVertex(&VertexA);
			}
		}
		file->read(&id, sizeof(id));
#ifdef __BIG_ENDIAN__
		id = os::Byteswap::byteswap(id);
#endif
	}

	// creating mesh
	SMesh* mesh = new SMesh();

	for (u32 num=0; num<MeshBufferEntry.size(); ++num)
	{
		CMeshBuffer<video::S3DVertex2TCoords>* buffer = MeshBufferEntry[num].MeshBuffer;

		if (!buffer)
			continue;

		mesh->addMeshBuffer(buffer);

		buffer->recalculateBoundingBox();
		buffer->drop();
	}

	mesh->recalculateBoundingBox();

	if (id != MY3D_FILE_END_ID)
		os::Printer::log("Loading finished, but can not find MY3D_FILE_END_ID token.", ELL_WARNING);

	SAnimatedMesh* am = new SAnimatedMesh();

	am->addMesh(mesh);
	mesh->drop();
	am->recalculateBoundingBox();

	return am;
}
Example #12
0
/**Creates/loads an animated mesh from the file.
 \return Pointer to the created mesh. Returns 0 if loading failed.
 If you no longer need the mesh, you should call IAnimatedMesh::drop().
 See IReferenceCounted::drop() for more information.*/
IAnimatedMesh* CDMFLoader::createMesh(io::IReadFile* file)
{
	if (!file)
		return 0;
	video::IVideoDriver* driver = SceneMgr->getVideoDriver();

	//Load stringlist
	StringList dmfRawFile;
	LoadFromFile(file, dmfRawFile);

	if (dmfRawFile.size()==0)
		return 0;

	SMesh * mesh = new SMesh();

	u32 i;

	dmfHeader header;

	//load header
	core::array<dmfMaterial> materiali;
	if (GetDMFHeader(dmfRawFile, header))
	{
		//let's set ambient light
		SceneMgr->setAmbientLight(header.dmfAmbient);

		//let's create the correct number of materials, vertices and faces
		dmfVert *verts=new dmfVert[header.numVertices];
		dmfFace *faces=new dmfFace[header.numFaces];

		//let's get the materials
#ifdef _IRR_DMF_DEBUG_
		os::Printer::log("Loading materials", core::stringc(header.numMaterials).c_str());
#endif
		GetDMFMaterials(dmfRawFile, materiali, header.numMaterials);

		//let's get vertices and faces
#ifdef _IRR_DMF_DEBUG_
		os::Printer::log("Loading geometry");
#endif
		GetDMFVerticesFaces(dmfRawFile, verts, faces);

		//create a meshbuffer for each material, then we'll remove empty ones
#ifdef _IRR_DMF_DEBUG_
		os::Printer::log("Creating meshbuffers.");
#endif
		for (i=0; i<header.numMaterials; i++)
		{
			//create a new SMeshBufferLightMap for each material
			SSkinMeshBuffer* buffer = new SSkinMeshBuffer();
			buffer->Material.MaterialType = video::EMT_LIGHTMAP_LIGHTING;
			buffer->Material.Wireframe = false;
			buffer->Material.Lighting = true;
			mesh->addMeshBuffer(buffer);
			buffer->drop();
		}

		// Build the mesh buffers
#ifdef _IRR_DMF_DEBUG_
		os::Printer::log("Adding geometry to mesh.");
#endif
		for (i = 0; i < header.numFaces; i++)
		{
#ifdef _IRR_DMF_DEBUG_
		os::Printer::log("Polygon with #vertices", core::stringc(faces[i].numVerts).c_str());
#endif
			if (faces[i].numVerts < 3)
				continue;

			const core::vector3df normal =
				core::triangle3df(verts[faces[i].firstVert].pos,
						verts[faces[i].firstVert+1].pos,
						verts[faces[i].firstVert+2].pos).getNormal().normalize();

			SSkinMeshBuffer* meshBuffer = (SSkinMeshBuffer*)mesh->getMeshBuffer(
					faces[i].materialID);

			const bool use2TCoords = meshBuffer->Vertices_2TCoords.size() ||
				materiali[faces[i].materialID].lightmapName.size();
			if (use2TCoords && meshBuffer->Vertices_Standard.size())
				meshBuffer->convertTo2TCoords();
			const u32 base = meshBuffer->Vertices_2TCoords.size()?meshBuffer->Vertices_2TCoords.size():meshBuffer->Vertices_Standard.size();

			// Add this face's verts
			if (use2TCoords)
			{
				// make sure we have the proper type set
				meshBuffer->VertexType=video::EVT_2TCOORDS;
				for (u32 v = 0; v < faces[i].numVerts; v++)
				{
					const dmfVert& vv = verts[faces[i].firstVert + v];
					video::S3DVertex2TCoords vert(vv.pos,
						normal, video::SColor(255,255,255,255), vv.tc, vv.lc);
					if (materiali[faces[i].materialID].textureBlend==4 &&
							SceneMgr->getParameters()->getAttributeAsBool(DMF_FLIP_ALPHA_TEXTURES))
					{
						vert.TCoords.set(vv.tc.X,-vv.tc.Y);
					}
					meshBuffer->Vertices_2TCoords.push_back(vert);
				}
			}
			else
			{
				for (u32 v = 0; v < faces[i].numVerts; v++)
				{
					const dmfVert& vv = verts[faces[i].firstVert + v];
					video::S3DVertex vert(vv.pos,
						normal, video::SColor(255,255,255,255), vv.tc);
					if (materiali[faces[i].materialID].textureBlend==4 &&
							SceneMgr->getParameters()->getAttributeAsBool(DMF_FLIP_ALPHA_TEXTURES))
					{
						vert.TCoords.set(vv.tc.X,-vv.tc.Y);
					}
					meshBuffer->Vertices_Standard.push_back(vert);
				}
			}

			// Now add the indices
			// This weird loop turns convex polygons into triangle strips.
			// I do it this way instead of a simple fan because it usually
			// looks a lot better in wireframe, for example.
			u32 h = faces[i].numVerts - 1, l = 0, c; // High, Low, Center
			for (u32 v = 0; v < faces[i].numVerts - 2; v++)
			{
				if (v & 1) // odd
					c = h - 1;
				else // even
					c = l + 1;

				meshBuffer->Indices.push_back(base + h);
				meshBuffer->Indices.push_back(base + l);
				meshBuffer->Indices.push_back(base + c);

				if (v & 1) // odd
					h--;
				else // even
					l++;
			}
		}

		delete [] verts;
		delete [] faces;
	}

	// delete all buffers without geometry in it.
#ifdef _IRR_DMF_DEBUG_
	os::Printer::log("Cleaning meshbuffers.");
#endif
	i = 0;
	while(i < mesh->MeshBuffers.size())
	{
		if (mesh->MeshBuffers[i]->getVertexCount() == 0 ||
			mesh->MeshBuffers[i]->getIndexCount() == 0)
		{
			// Meshbuffer is empty -- drop it
			mesh->MeshBuffers[i]->drop();
			mesh->MeshBuffers.erase(i);
			materiali.erase(i);
		}
		else
		{
			i++;
		}
	}


	{
		//load textures and lightmaps in materials.
		//don't worry if you receive a could not load texture, cause if you don't need
		//a particular material in your scene it will be loaded and then destroyed.
#ifdef _IRR_DMF_DEBUG_
		os::Printer::log("Loading textures.");
#endif
		const bool use_mat_dirs=!SceneMgr->getParameters()->getAttributeAsBool(DMF_IGNORE_MATERIALS_DIRS);

		core::stringc path;
		if ( SceneMgr->getParameters()->existsAttribute(DMF_TEXTURE_PATH) )
			path = SceneMgr->getParameters()->getAttributeAsString(DMF_TEXTURE_PATH);
		else
			path = FileSystem->getFileDir(file->getFileName());
		path += ('/');

		for (i=0; i<mesh->getMeshBufferCount(); i++)
		{
			//texture and lightmap
			video::ITexture *tex = 0;
			video::ITexture *lig = 0;

			//current buffer to apply material
			video::SMaterial& mat = mesh->getMeshBuffer(i)->getMaterial();

			//Primary texture is normal
			if (materiali[i].textureFlag==0)
			{
				if (materiali[i].textureBlend==4)
					driver->setTextureCreationFlag(video::ETCF_ALWAYS_32_BIT,true);
				findFile(use_mat_dirs, path, materiali[i].pathName, materiali[i].textureName);
				tex = driver->getTexture(materiali[i].textureName);
			}
			//Primary texture is just a colour
			else if(materiali[i].textureFlag==1)
			{
				video::SColor color(axtoi(materiali[i].textureName.c_str()));

				//just for compatibility with older Irrlicht versions
				//to support transparent materials
				if (color.getAlpha()!=255 && materiali[i].textureBlend==4)
					driver->setTextureCreationFlag(video::ETCF_ALWAYS_32_BIT,true);

				video::IImage *immagine= driver->createImage(video::ECF_A8R8G8B8,
					core::dimension2d<u32>(8,8));
				immagine->fill(color);
				tex = driver->addTexture("", immagine);
				immagine->drop();

				//to support transparent materials
				if (color.getAlpha()!=255 && materiali[i].textureBlend==4)
				{
					mat.MaterialType = video::EMT_TRANSPARENT_ALPHA_CHANNEL;
					mat.MaterialTypeParam =(((f32) (color.getAlpha()-1))/255.0f);
				}
			}

			//Lightmap is present
			if (materiali[i].lightmapFlag == 0)
			{
				findFile(use_mat_dirs, path, materiali[i].pathName, materiali[i].lightmapName);
				lig = driver->getTexture(materiali[i].lightmapName);
			}
			else //no lightmap
			{
				mat.MaterialType = video::EMT_SOLID;
				const f32 mult = 100.0f - header.dmfShadow;
				mat.AmbientColor=header.dmfAmbient.getInterpolated(video::SColor(255,0,0,0),mult/100.f);
			}

			if (materiali[i].textureBlend==4)
			{
				mat.MaterialType = video::EMT_TRANSPARENT_ALPHA_CHANNEL;
				mat.MaterialTypeParam =
					SceneMgr->getParameters()->getAttributeAsFloat(DMF_ALPHA_CHANNEL_REF);
			}

			//if texture is present mirror vertically owing to DeleD representation
			if (tex && header.dmfVersion<1.1)
			{
				const core::dimension2d<u32> texsize = tex->getSize();
				void* pp = tex->lock();
				if (pp)
				{
					const video::ECOLOR_FORMAT format = tex->getColorFormat();
					if (format == video::ECF_A1R5G5B5)
					{
						s16* p = (s16*)pp;
						s16 tmp=0;
						for (u32 x=0; x<texsize.Width; x++)
							for (u32 y=0; y<texsize.Height/2; y++)
							{
								tmp=p[y*texsize.Width + x];
								p[y*texsize.Width + x] = p[(texsize.Height-y-1)*texsize.Width + x];
								p[(texsize.Height-y-1)*texsize.Width + x]=tmp;
							}
					}
					else
					if (format == video::ECF_A8R8G8B8)
					{
						s32* p = (s32*)pp;
						s32 tmp=0;
						for (u32 x=0; x<texsize.Width; x++)
							for (u32 y=0; y<texsize.Height/2; y++)
							{
								tmp=p[y*texsize.Width + x];
								p[y*texsize.Width + x] = p[(texsize.Height-y-1)*texsize.Width + x];
								p[(texsize.Height-y-1)*texsize.Width + x]=tmp;
							}
					}
				}
				tex->unlock();
				tex->regenerateMipMapLevels();
			}

			//if lightmap is present mirror vertically owing to DeleD rapresentation
			if (lig && header.dmfVersion<1.1)
			{
				const core::dimension2d<u32> ligsize=lig->getSize();
				void* pp = lig->lock();
				if (pp)
				{
					video::ECOLOR_FORMAT format = lig->getColorFormat();
					if (format == video::ECF_A1R5G5B5)
					{
						s16* p = (s16*)pp;
						s16 tmp=0;
						for (u32 x=0; x<ligsize.Width; x++)
						{
							for (u32 y=0; y<ligsize.Height/2; y++)
							{
								tmp=p[y*ligsize.Width + x];
								p[y*ligsize.Width + x] = p[(ligsize.Height-y-1)*ligsize.Width + x];
								p[(ligsize.Height-y-1)*ligsize.Width + x]=tmp;
							}
						}
					}
					else if (format == video::ECF_A8R8G8B8)
					{
						s32* p = (s32*)pp;
						s32 tmp=0;
						for (u32 x=0; x<ligsize.Width; x++)
						{
							for (u32 y=0; y<ligsize.Height/2; y++)
							{
								tmp=p[y*ligsize.Width + x];
								p[y*ligsize.Width + x] = p[(ligsize.Height-y-1)*ligsize.Width + x];
								p[(ligsize.Height-y-1)*ligsize.Width + x]=tmp;
							}
						}
					}
				}
				lig->unlock();
				lig->regenerateMipMapLevels();
			}

			mat.setTexture(0, tex);
			mat.setTexture(1, lig);
		}
	}

	// create bounding box
	for (i = 0; i < mesh->MeshBuffers.size(); ++i)
	{
		mesh->MeshBuffers[i]->recalculateBoundingBox();
	}
	mesh->recalculateBoundingBox();

	// Set up an animated mesh to hold the mesh
	SAnimatedMesh* AMesh = new SAnimatedMesh();
	AMesh->Type = EAMT_UNKNOWN;
	AMesh->addMesh(mesh);
	AMesh->recalculateBoundingBox();
	mesh->drop();

	return AMesh;
}
// creates a hill plane
IAnimatedMesh* CGeometryCreator::createHillPlaneMesh(const core::dimension2d<f32>& tileSize, const core::dimension2d<s32>& tc,
        video::SMaterial* material,     f32 hillHeight, const core::dimension2d<f32>& ch,
        const core::dimension2d<f32>& textureRepeatCount)
{
    core::dimension2d<s32> tileCount = tc;
    tileCount.Height += 1;
    tileCount.Width += 1;

    core::dimension2d<f32> countHills = ch;

    SMeshBuffer* buffer = new SMeshBuffer();
    SMesh* mesh = new SMesh();
    video::S3DVertex vtx;
    vtx.Color.set(255,255,255,255);
    vtx.Normal.set(0,0,0);

    if (countHills.Width < 0.01f) countHills.Width = 1;
    if (countHills.Height < 0.01f) countHills.Height = 1;

    f32 halfX = (tileSize.Width * tileCount.Width) / 2;
    f32 halfY = (tileSize.Height * tileCount.Height) / 2;

    // create vertices

    s32 x = 0;
    s32 y = 0;

    core::dimension2d<f32> tx;
    tx.Width = 1.0f / (tileCount.Width / textureRepeatCount.Width);
    tx.Height = 1.0f / (tileCount.Height / textureRepeatCount.Height);


    for (x=0; x<tileCount.Width; ++x)
        for (y=0; y<tileCount.Height; ++y)
        {
            vtx.Pos.set(tileSize.Width * x - halfX, 0, tileSize.Height * y - halfY);
            vtx.TCoords.set(-(f32)x * tx.Width, (f32)y * tx.Height);

            if (hillHeight)
                vtx.Pos.Y = (f32)(sin(vtx.Pos.X * countHills.Width * engine::core::PI / halfX) *
                                  cos(vtx.Pos.Z * countHills.Height * engine::core::PI / halfY))
                            *hillHeight;

            buffer->Vertices.push_back(vtx);
        }

    // create indices

    for (x=0; x<tileCount.Width-1; ++x)
        for (y=0; y<tileCount.Height-1; ++y)
        {
            s32 current = y*tileCount.Width + x;

            buffer->Indices.push_back(current);
            buffer->Indices.push_back(current + 1);
            buffer->Indices.push_back(current + tileCount.Width);

            buffer->Indices.push_back(current + 1);
            buffer->Indices.push_back(current + 1 + tileCount.Width);
            buffer->Indices.push_back(current + tileCount.Width);
        }

    // recalculate normals
    for (s32 i=0; i<(s32)buffer->Indices.size(); i+=3)
    {
        core::plane3d<f32> p(
            buffer->Vertices[buffer->Indices[i+0]].Pos,
            buffer->Vertices[buffer->Indices[i+1]].Pos,
            buffer->Vertices[buffer->Indices[i+2]].Pos);

        p.Normal.normalize();

        buffer->Vertices[buffer->Indices[i+0]].Normal = p.Normal;
        buffer->Vertices[buffer->Indices[i+1]].Normal = p.Normal;
        buffer->Vertices[buffer->Indices[i+2]].Normal = p.Normal;
    }

    if (material)
        buffer->Material = *material;

    buffer->recalculateBoundingBox();

    SAnimatedMesh* animatedMesh = new SAnimatedMesh();
    mesh->addMeshBuffer(buffer);
    mesh->recalculateBoundingBox();
    animatedMesh->addMesh(mesh);
    animatedMesh->recalculateBoundingBox();

    mesh->drop();
    buffer->drop();

    return animatedMesh;
}
IAnimatedMesh* CGeometryCreator::createTerrainMesh(video::IImage* texture,
        video::IImage* heightmap, const core::dimension2d<f32>& stretchSize,
        f32 maxHeight, video::IVideoDriver* driver,
        const core::dimension2d<s32> maxVtxBlockSize,
        bool debugBorders)
{
    u32 tm = os::Timer::getRealTime()/1000;

    if (!texture || !heightmap)
        return 0;

    video::SMaterial material;
    c8 textureName[64];
    c8 tmp[255];


    // debug border
    s32 borderSkip = debugBorders ? 0 : 1;

    video::S3DVertex vtx;
    vtx.Color.set(255,255,255,255);

    SMesh* mesh = new SMesh();

    core::dimension2d<s32> hMapSize= heightmap->getDimension();
    core::dimension2d<s32> tMapSize= texture->getDimension();
    core::position2d<f32> thRel((f32)tMapSize.Width / (s32)hMapSize.Width, (f32)tMapSize.Height / (s32)hMapSize.Height);
    core::position2d<s32> processed(0,0);

    while (processed.Y<hMapSize.Height)
    {
        while(processed.X<hMapSize.Width)
        {
            core::dimension2d<s32> blockSize = maxVtxBlockSize;
            if (processed.X + blockSize.Width > hMapSize.Width)
                blockSize.Width = hMapSize.Width - processed.X;
            if (processed.Y + blockSize.Height > hMapSize.Height)
                blockSize.Height = hMapSize.Height - processed.Y;

            SMeshBuffer* buffer = new SMeshBuffer();
            s32 x,y;

            // add vertices of vertex block
            for (y=0; y<blockSize.Height; ++y)
                for (x=0; x<blockSize.Width; ++x)
                {
                    video::SColor clr = heightmap->getPixel(x+processed.X, y+processed.Y);
                    f32 height = ((clr.getRed() + clr.getGreen() + clr.getBlue()) / 3.0f)/255.0f * maxHeight;

                    vtx.Pos.set((f32)(x+processed.X) * stretchSize.Width,
                                height, (f32)(y+processed.Y) * stretchSize.Height);

                    vtx.TCoords.set((f32)(x+0.5f) / ((f32)blockSize.Width),
                                    (f32)(y+0.5f) / ((f32)blockSize.Height));

                    buffer->Vertices.push_back(vtx);
                }

            // add indices of vertex block
            for (y=0; y<blockSize.Height-1; ++y)
                for (x=0; x<blockSize.Width-1; ++x)
                {
                    s32 c = (y*blockSize.Width) + x;

                    buffer->Indices.push_back(c);
                    buffer->Indices.push_back(c + blockSize.Width);
                    buffer->Indices.push_back(c + 1);

                    buffer->Indices.push_back(c + 1);
                    buffer->Indices.push_back(c + blockSize.Width);
                    buffer->Indices.push_back(c + 1 + blockSize.Width);
                }

            // recalculate normals
            for (s32 i=0; i<(s32)buffer->Indices.size(); i+=3)
            {
                core::plane3d<f32> p(
                    buffer->Vertices[buffer->Indices[i+0]].Pos,
                    buffer->Vertices[buffer->Indices[i+1]].Pos,
                    buffer->Vertices[buffer->Indices[i+2]].Pos);
                p.Normal.normalize();

                buffer->Vertices[buffer->Indices[i+0]].Normal = p.Normal;
                buffer->Vertices[buffer->Indices[i+1]].Normal = p.Normal;
                buffer->Vertices[buffer->Indices[i+2]].Normal = p.Normal;
            }

            if (buffer->Vertices.size())
            {
                // create texture for this block
                video::IImage* img = new video::CImage(texture,
                                                       core::position2d<s32>((s32)(processed.X*thRel.X), (s32)(processed.Y*thRel.Y)),
                                                       core::dimension2d<s32>((s32)(blockSize.Width*thRel.X), (s32)(blockSize.Height*thRel.Y)));

                sprintf(textureName, "terrain%d_%d", tm, mesh->getMeshBufferCount());

                material.Texture1 = driver->addTexture(textureName, img);

                if (material.Texture1)
                {
                    sprintf(tmp, "Generated terrain texture (%dx%d): %s",
                            material.Texture1->getSize().Width,
                            material.Texture1->getSize().Height,
                            textureName);
                    os::Printer::log(tmp);
                }
                else
                    os::Printer::log("Could not create terrain texture.", textureName, ELL_ERROR);

                buffer->Material = material;
                img->drop();
            }

            buffer->recalculateBoundingBox();
            mesh->addMeshBuffer(buffer);
            buffer->drop();

            // keep on processing
            processed.X += maxVtxBlockSize.Width - borderSkip;
        }

        // keep on processing
        processed.X = 0;
        processed.Y += maxVtxBlockSize.Height - borderSkip;
    }

    SAnimatedMesh* animatedMesh = new SAnimatedMesh();
    mesh->recalculateBoundingBox();
    animatedMesh->addMesh(mesh);
    animatedMesh->recalculateBoundingBox();

    mesh->drop();

    return animatedMesh;
}
Example #15
0
//! creates/loads an animated mesh from the file.
//! \return Pointer to the created mesh. Returns 0 if loading failed.
//! If you no longer need the mesh, you should call IAnimatedMesh::drop().
//! See IReferenceCounted::drop() for more information.
IAnimatedMesh* COCTLoader::createMesh(io::IReadFile* file) 
{
	if (!file)
		return 0;

	octHeader header;
	file->read(&header, sizeof(octHeader));

	octVert * verts = new octVert[header.numVerts];
	octFace * faces = new octFace[header.numFaces];
	octTexture * textures = new octTexture[header.numTextures];
	octLightmap * lightmaps = new octLightmap[header.numLightmaps];
	octLight * lights = new octLight[header.numLights];

	file->read(verts, sizeof(octVert) * header.numVerts);
	file->read(faces, sizeof(octFace) * header.numFaces);
	//TODO: Make sure id is in the legal range for Textures and Lightmaps

	u32 i;
	for (i = 0; i < header.numTextures; i++) {
		octTexture t;
		file->read(&t, sizeof(octTexture));
		textures[t.id] = t;
	}	
	for (i = 0; i < header.numLightmaps; i++) {
		octLightmap t;
		file->read(&t, sizeof(octLightmap));
		lightmaps[t.id] = t;
	}
	file->read(lights, sizeof(octLight) * header.numLights);

	//TODO: Now read in my extended OCT header (flexible lightmaps and vertex normals)
	

	// This is the method Nikolaus Gebhardt used in the Q3 loader -- create a
	// meshbuffer for every possible combination of lightmap and texture including
	// a "null" texture and "null" lightmap.  Ones that end up with nothing in them
	// will be removed later.

	SMesh * Mesh = new SMesh();
	for (i=0; i<(header.numTextures+1) * (header.numLightmaps+1); ++i)
	{
		scene::SMeshBufferLightMap* buffer = new scene::SMeshBufferLightMap();

		buffer->Material.MaterialType = video::EMT_LIGHTMAP;
		buffer->Material.Lighting = false;
		Mesh->addMeshBuffer(buffer);
		buffer->drop();
	}

	
	// Build the mesh buffers
	for (i = 0; i < header.numFaces; i++)
	{
		if (faces[i].numVerts < 3)
			continue;

		const core::vector3df normal =
			GetFaceNormal(verts[faces[i].firstVert].pos,
					verts[faces[i].firstVert+1].pos,
					verts[faces[i].firstVert+2].pos);

		const u32 textureID = core::min_(s32(faces[i].textureID), s32(header.numTextures - 1)) + 1;
		const u32 lightmapID = core::min_(s32(faces[i].lightmapID),s32(header.numLightmaps - 1)) + 1;
		SMeshBufferLightMap * meshBuffer = (SMeshBufferLightMap*)Mesh->getMeshBuffer(lightmapID * (header.numTextures + 1) + textureID);
		const u32 base = meshBuffer->Vertices.size();
		
		// Add this face's verts
		u32 v;
		for (v = 0; v < faces[i].numVerts; ++v)
		{
			octVert * vv = &verts[faces[i].firstVert + v];
			video::S3DVertex2TCoords vert;
			vert.Pos.set(vv->pos[0], vv->pos[1], vv->pos[2]);
			vert.Color = video::SColor(0,255,255,255);
			vert.Normal.set(normal);

			if (textureID == 0)
			{
				// No texture -- just a lightmap.  Thus, use lightmap coords for texture 1.
				// (the actual texture will be swapped later)
				vert.TCoords.set(vv->lc[0], vv->lc[1]);
			}
			else
			{
				vert.TCoords.set(vv->tc[0], vv->tc[1]);
				vert.TCoords2.set(vv->lc[0], vv->lc[1]);
			}

			meshBuffer->Vertices.push_back(vert);
		}

		// Now add the indices
		// This weird loop turns convex polygons into triangle strips.
		// I do it this way instead of a simple fan because it usually looks a lot better in wireframe, for example.
		u32 h = faces[i].numVerts - 1, l = 0, c; // High, Low, Center
		for (v = 0; v < faces[i].numVerts - 2; ++v)
		{
			if (v & 1)
				c = h - 1;
			else
				c = l + 1;

			meshBuffer->Indices.push_back(base + h);
			meshBuffer->Indices.push_back(base + l);
			meshBuffer->Indices.push_back(base + c);

			if (v & 1)
				--h;
			else
				++l;
		}
	} 


	// load textures
	core::array<video::ITexture*> tex;
	tex.set_used(header.numTextures + 1);
	tex[0] = 0;
	
	for (i = 1; i < (header.numTextures + 1); i++)
	{
		tex[i] = Driver->getTexture(textures[i-1].fileName);
	}


	// prepare lightmaps
	core::array<video::ITexture*> lig;
	lig.set_used(header.numLightmaps + 1);

	u32 lightmapWidth = 128, lightmapHeight = 128;
	lig[0] = 0;
	core::dimension2d<s32> lmapsize(lightmapWidth, lightmapHeight);

	bool oldMipMapState = Driver->getTextureCreationFlag(video::ETCF_CREATE_MIP_MAPS);
	Driver->setTextureCreationFlag(video::ETCF_CREATE_MIP_MAPS, false);

	for (i = 1; i < (header.numLightmaps + 1); i++)
	{
		core::stringc lightmapname = file->getFileName();
		lightmapname += ".lightmap.";
		lightmapname += (int)i;
		lig[i] = Driver->addTexture(lmapsize, lightmapname.c_str());

		if (lig[i]->getSize() != lmapsize)
			os::Printer::log("OCTLoader: Created lightmap is not of the requested size", ELL_ERROR);

		if (lig[i])
		{
			void* pp = lig[i]->lock();

			if (pp)
			{
				video::ECOLOR_FORMAT format = lig[i]->getColorFormat();
				if (format == video::ECF_A1R5G5B5)
				{
					s16* p = (s16*)pp;

					octLightmap * lm;					
					lm = &lightmaps[i-1];

					for (u32 x=0; x<lightmapWidth; ++x)
						for (u32 y=0; y<lightmapHeight; ++y)
						{
							p[x*128 + y] = video::RGB16(
								lm->data[x][y][2],
								lm->data[x][y][1],
								lm->data[x][y][0]);
						}
				}
				else
				if (format == video::ECF_A8R8G8B8)
				{
					s32* p = (s32*)pp;

					octLightmap* lm;
					lm = &lightmaps[i-1];

					for (u32 x=0; x<lightmapWidth; ++x)
						for (u32 y=0; y<lightmapHeight; ++y)
						{
							p[x*128 + y] = video::SColor(255,
								lm->data[x][y][2],
								lm->data[x][y][1],
								lm->data[x][y][0]).color;
						}
				}
				else
					os::Printer::log(
						"OCTLoader: Could not create lightmap, unsupported texture format.", ELL_ERROR);
			}

			lig[i]->unlock();
		}
		else
			os::Printer::log("OCTLoader: Could not create lightmap, driver created no texture.", ELL_ERROR);
	}
	Driver->setTextureCreationFlag(video::ETCF_CREATE_MIP_MAPS, oldMipMapState);


	// Free stuff
	delete [] verts;
	delete [] faces;
	delete [] textures;
	delete [] lightmaps;
	delete [] lights;


	// attach materials
	for (i = 0; i < header.numLightmaps + 1; i++)
	{
		for (u32 j = 0; j < header.numTextures + 1; j++)
		{
			u32 mb = i * (header.numTextures + 1) + j;
			SMeshBufferLightMap * meshBuffer = (SMeshBufferLightMap*)Mesh->getMeshBuffer(mb);
			meshBuffer->Material.setTexture(0, tex[j]);
			meshBuffer->Material.setTexture(1, lig[i]);

			if (meshBuffer->Material.getTexture(0) == 0)
			{
				// This material has no texture, so we'll just show the lightmap if there is one.
				// We swapped the texture coordinates earlier.
				meshBuffer->Material.setTexture(0, meshBuffer->Material.getTexture(1));
				meshBuffer->Material.setTexture(1, 0);
			}
			if (meshBuffer->Material.getTexture(1) == 0)
			{
				// If there is only one texture, it should be solid and lit.
				// Among other things, this way you can preview OCT lights.
				meshBuffer->Material.MaterialType = video::EMT_SOLID;
				meshBuffer->Material.Lighting = true;
			}
		}
	}


	// delete all buffers without geometry in it.
	i = 0;
	while(i < Mesh->MeshBuffers.size())
	{
		if (Mesh->MeshBuffers[i]->getVertexCount() == 0 ||
			Mesh->MeshBuffers[i]->getIndexCount() == 0 ||
			Mesh->MeshBuffers[i]->getMaterial().getTexture(0) == 0)
		{
			// Meshbuffer is empty -- drop it
			Mesh->MeshBuffers[i]->drop();
			Mesh->MeshBuffers.erase(i);		
		}
		else
		{
			++i;
		}
	}


	// create bounding box
	for (i = 0; i < Mesh->MeshBuffers.size(); ++i)
	{
		Mesh->MeshBuffers[i]->recalculateBoundingBox();
	}
	Mesh->recalculateBoundingBox();


	// Set up an animated mesh to hold the mesh
	SAnimatedMesh* AMesh = new SAnimatedMesh();
	AMesh->Type = EAMT_OCT;
	AMesh->addMesh(Mesh);
	AMesh->recalculateBoundingBox();
	Mesh->drop();

	return AMesh;
}