Exemplo n.º 1
0
	//-----------------------------------------------------------------------------
	void ManualObject::copyTempVertexToBuffer(void)
	{
		mTempVertexPending = false;
		RenderOperation* rop = mCurrentSection->getRenderOperation();
		if (rop->vertexData->vertexCount == 0 && !mCurrentUpdating)
		{
			// first vertex, autoorganise decl
			VertexDeclaration* oldDcl = rop->vertexData->vertexDeclaration;
			rop->vertexData->vertexDeclaration =
				oldDcl->getAutoOrganisedDeclaration(false, false);
			HardwareBufferManager::getSingleton().destroyVertexDeclaration(oldDcl);
		}
		resizeTempVertexBufferIfNeeded(++rop->vertexData->vertexCount);

		// get base pointer
		char* pBase = mTempVertexBuffer + (mDeclSize * (rop->vertexData->vertexCount-1));
		const VertexDeclaration::VertexElementList& elemList =
			rop->vertexData->vertexDeclaration->getElements();
		for (VertexDeclaration::VertexElementList::const_iterator i = elemList.begin();
			i != elemList.end(); ++i)
		{
			float* pFloat = 0;
			RGBA* pRGBA = 0;
			const VertexElement& elem = *i;
			switch(elem.getType())
			{
			case VET_FLOAT1:
			case VET_FLOAT2:
			case VET_FLOAT3:
			case VET_FLOAT4:
				elem.baseVertexPointerToElement(pBase, &pFloat);
				break;
			case VET_COLOUR:
			case VET_COLOUR_ABGR:
			case VET_COLOUR_ARGB:
				elem.baseVertexPointerToElement(pBase, &pRGBA);
				break;
			default:
				// nop ?
				break;
			};


			RenderSystem* rs;
			unsigned short dims;
			switch(elem.getSemantic())
			{
			case VES_POSITION:
				*pFloat++ = mTempVertex.position.x;
				*pFloat++ = mTempVertex.position.y;
				*pFloat++ = mTempVertex.position.z;
				break;
			case VES_NORMAL:
				*pFloat++ = mTempVertex.normal.x;
				*pFloat++ = mTempVertex.normal.y;
				*pFloat++ = mTempVertex.normal.z;
				break;
			case VES_TANGENT:
				*pFloat++ = mTempVertex.tangent.x;
				*pFloat++ = mTempVertex.tangent.y;
				*pFloat++ = mTempVertex.tangent.z;
				break;
			case VES_TEXTURE_COORDINATES:
				dims = VertexElement::getTypeCount(elem.getType());
				for (ushort t = 0; t < dims; ++t)
					*pFloat++ = mTempVertex.texCoord[elem.getIndex()][t];
				break;
			case VES_DIFFUSE:
				rs = Root::getSingleton().getRenderSystem();
				if (rs)
					rs->convertColourValue(mTempVertex.colour, pRGBA++);
				else
					*pRGBA++ = mTempVertex.colour.getAsRGBA(); // pick one!
				break;
			default:
				// nop ?
				break;
			};

		}

	}
Exemplo n.º 2
0
void Tile::_generateSubMesh(MeshPtr& mesh)
{
	// Create a submesh to the given mesh.
	SubMesh* tileMesh = mesh->createSubMesh();

	// Define the vertices.
	size_t index = 0;
	size_t vertCount = this->mCorners.size() + 1; // corner count + center corner

	Real* vertices = new Real[vertCount*3*2];    // (number of verts)*(x, y, z)*(coord, normal) -or- vertCount*3*2

	// Manually add center vertex.
	// -- Position (ord: x, y, z)
	vertices[index++] = this->mPosition.x;
	vertices[index++] = (Ogre::Real)(this->elevation);
	vertices[index++] = this->mPosition.y;

	// -- Normal (ord: x, y, z)
	Vector3 norm = Vector3::UNIT_Y;

	vertices[index++] = norm.x;
	vertices[index++] = norm.y;
	vertices[index++] = norm.z;

	// Add the rest of the vertices to data buffer.
    for(std::vector<Corner*>::iterator it = this->mCorners.begin(); it != this->mCorners.end(); ++it) {
		// Add to the next point to the array.
		// -- Position
		Vector3 vector = (*it)->vec3();

		vertices[index++] = vector.x;
		vertices[index++] = vector.y;
		vertices[index++] = vector.z;

		// -- Normal
		Vector3 normal = Vector3::UNIT_Y;

		vertices[index++] = normal.x;
		vertices[index++] = normal.y;
		vertices[index++] = normal.z;
	}

	// Define vertices color.
	RenderSystem* rs = Root::getSingleton().getRenderSystem();
	RGBA* colors = new RGBA[vertCount];

	for(size_t i = 0; i < vertCount; ++i)
		rs->convertColourValue(ColourValue(0.0f + 0.175f*i, 0.2f, 1.0f - 0.175f*i), colors + i);

	// Define the triangles.
	size_t faceCount = vertCount - 1; // Face count = vertCount - cent

	size_t center = 0;
	size_t last   = 1; //collin was here
	size_t curr   = 2;

	unsigned short* faces = new unsigned short[faceCount*3];

	index = 0;

	for(size_t i = 0; i < faceCount; ++i) {
		assert(last < vertCount && curr < vertCount); // Panic check

		faces[index++] = center;
		faces[index++] = curr;
		faces[index++] = last;

		last = curr++;

		if(curr >= vertCount) curr = 1;
	}

	// All information has been generated, move into mesh structures.
	//   Note: Currently does not implement or used any sort of shared
	//     vertices. This is intentional and should be changed at the 
	//     soonest conveienence. IE -- Never. ;P
	tileMesh->useSharedVertices = false;
	tileMesh->vertexData = new VertexData();
	tileMesh->vertexData->vertexCount = vertCount;

	// Create memory footprint for vertex data.
	size_t offset = 0;
	VertexDeclaration* decl = tileMesh->vertexData->vertexDeclaration;

	// Position and normal buffer.
	// -- Position
	decl->addElement(0, offset, VET_FLOAT3, VES_POSITION);
	offset += VertexElement::getTypeSize(VET_FLOAT3);

	// -- Normal
	decl->addElement(0, offset, VET_FLOAT3, VES_NORMAL);
	offset += VertexElement::getTypeSize(VET_FLOAT3);

	// Allocate a vertex buffer for a number of vertices and vertex size.
	HardwareVertexBufferSharedPtr vertBuff = 
		HardwareBufferManager::getSingleton().createVertexBuffer(
			offset, // Size of a vertex, in bytes.
			tileMesh->vertexData->vertexCount,
			HardwareBuffer::HBU_STATIC_WRITE_ONLY);

	// Write our data to vertex buffer.
	vertBuff->writeData(0, vertBuff->getSizeInBytes(), vertices, true);

	// Set the buffer's bind location.
	VertexBufferBinding* vertBind = tileMesh->vertexData->vertexBufferBinding;
	vertBind->setBinding(0, vertBuff);

	// Color buffer for vertices
	offset = 0;
	decl->addElement(1, offset, VET_COLOUR, VES_DIFFUSE);
	offset += VertexElement::getTypeSize(VET_COLOUR);

	// Allocate a new buffer for colors.
	vertBuff = HardwareBufferManager::getSingleton().createVertexBuffer(
			offset, // Size of a vertex, in bytes.
			tileMesh->vertexData->vertexCount,
			HardwareBuffer::HBU_STATIC_WRITE_ONLY);

	// Write color data to buffer.
	vertBuff->writeData(0, vertBuff->getSizeInBytes(), colors, true);

	// Set the color buffer's bind location
	vertBind->setBinding(1, vertBuff);

	// Allocate a buffer for the index information
	HardwareIndexBufferSharedPtr indexBuff = HardwareBufferManager::getSingleton().createIndexBuffer(
		HardwareIndexBuffer::IT_16BIT,
		faceCount*3,
		HardwareBuffer::HBU_STATIC_WRITE_ONLY);

	// Write data to the buffer.
	indexBuff->writeData(0, indexBuff->getSizeInBytes(), faces, true);

	// Finalize submesh.
	tileMesh->indexData->indexBuffer = indexBuff;
	tileMesh->indexData->indexCount = faceCount*3;
	tileMesh->indexData->indexStart = 0;

	// Deallocate the vertex and face arrays.
	if(vertices) delete[] vertices;
	if(faces) delete[] faces;
}
Exemplo n.º 3
0
// Convert Nif::NiTriShape to Ogre::SubMesh, attached to the given
// mesh.
static void createOgreMesh(Mesh *mesh, NiTriShape *shape, const String &material)
{
  NiTriShapeData *data = shape->data.getPtr();
  SubMesh *sub = mesh->createSubMesh(shape->name.toString());

  int nextBuf = 0;

  // This function is just one long stream of Ogre-barf, but it works
  // great.

  // Add vertices
  int numVerts = data->vertices.length / 3;
  sub->vertexData = new VertexData();
  sub->vertexData->vertexCount = numVerts;
  sub->useSharedVertices = false;
  VertexDeclaration *decl = sub->vertexData->vertexDeclaration;
  decl->addElement(nextBuf, 0, VET_FLOAT3, VES_POSITION);
  HardwareVertexBufferSharedPtr vbuf =
    HardwareBufferManager::getSingleton().createVertexBuffer(
      VertexElement::getTypeSize(VET_FLOAT3),
      numVerts, HardwareBuffer::HBU_STATIC_WRITE_ONLY);
  vbuf->writeData(0, vbuf->getSizeInBytes(), data->vertices.ptr, true);
  VertexBufferBinding* bind = sub->vertexData->vertexBufferBinding;
  bind->setBinding(nextBuf++, vbuf);

  // Vertex normals
  if(data->normals.length)
    {
      decl->addElement(nextBuf, 0, VET_FLOAT3, VES_NORMAL);
      vbuf = HardwareBufferManager::getSingleton().createVertexBuffer(
          VertexElement::getTypeSize(VET_FLOAT3),
          numVerts, HardwareBuffer::HBU_STATIC_WRITE_ONLY);
      vbuf->writeData(0, vbuf->getSizeInBytes(), data->normals.ptr, true);
      bind->setBinding(nextBuf++, vbuf);
    }

  // Vertex colors
  if(data->colors.length)
    {
      const float *colors = data->colors.ptr;
      RenderSystem* rs = Root::getSingleton().getRenderSystem();
      std::vector<RGBA> colorsRGB(numVerts);
      RGBA *pColour = &colorsRGB.front();
      for(int i=0; i<numVerts; i++)
	{
	  rs->convertColourValue(ColourValue(colors[0],colors[1],colors[2],
                                             colors[3]),pColour++);
	  colors += 4;
	}
      decl->addElement(nextBuf, 0, VET_COLOUR, VES_DIFFUSE);
      vbuf = HardwareBufferManager::getSingleton().createVertexBuffer(
          VertexElement::getTypeSize(VET_COLOUR),
	  numVerts, HardwareBuffer::HBU_STATIC_WRITE_ONLY);
      vbuf->writeData(0, vbuf->getSizeInBytes(), &colorsRGB.front(), true);
      bind->setBinding(nextBuf++, vbuf);
    }

  // Texture UV coordinates
  if(data->uvlist.length)
    {
      decl->addElement(nextBuf, 0, VET_FLOAT2, VES_TEXTURE_COORDINATES);
      vbuf = HardwareBufferManager::getSingleton().createVertexBuffer(
          VertexElement::getTypeSize(VET_FLOAT2),
          numVerts, HardwareBuffer::HBU_STATIC_WRITE_ONLY);

      vbuf->writeData(0, vbuf->getSizeInBytes(), data->uvlist.ptr, true);
      bind->setBinding(nextBuf++, vbuf);
    }

  // Triangle faces
  int numFaces = data->triangles.length;
  if(numFaces)
    {
      HardwareIndexBufferSharedPtr ibuf = HardwareBufferManager::getSingleton().
	createIndexBuffer(HardwareIndexBuffer::IT_16BIT,
			  numFaces,
			  HardwareBuffer::HBU_STATIC_WRITE_ONLY);
      ibuf->writeData(0, ibuf->getSizeInBytes(), data->triangles.ptr, true);
      sub->indexData->indexBuffer = ibuf;
      sub->indexData->indexCount = numFaces;
      sub->indexData->indexStart = 0;
    }

  // Set material if one was given
  if(!material.empty()) sub->setMaterialName(material);

  /* Old commented D code. Might be useful when reimplementing
     animation.
  // Assign this submesh to the given bone
  VertexBoneAssignment v;
  v.boneIndex = ((Bone*)bone)->getHandle();
  v.weight = 1.0;

  std::cerr << "+ Assigning bone index " << v.boneIndex << "\n";

  for(int i=0; i < numVerts; i++)
    {
      v.vertexIndex = i;
      sub->addBoneAssignment(v);
    }
  */
}
Exemplo n.º 4
0
void BasicTutorial2::createColourCube()
{
    /// Create the mesh via the MeshManager
    Ogre::MeshPtr msh = MeshManager::getSingleton().createManual("ColourCube", "General");
 
    /// Create one submesh
    SubMesh* sub = msh->createSubMesh();
 
    const float sqrt13 = 0.577350269f; /* sqrt(1/3) */
 
    /// Define the vertices (8 vertices, each have 3 floats for position and 3 for normal)
    const size_t nVertices = 8;
    const size_t vbufCount = 3*2*nVertices;
    float vertices[vbufCount] = {
            -100.0,100.0,-100.0,        //0 position
            -sqrt13,sqrt13,-sqrt13,     //0 normal
            100.0,100.0,-100.0,         //1 position
            sqrt13,sqrt13,-sqrt13,      //1 normal
            100.0,-100.0,-100.0,        //2 position
            sqrt13,-sqrt13,-sqrt13,     //2 normal
            -100.0,-100.0,-100.0,       //3 position
            -sqrt13,-sqrt13,-sqrt13,    //3 normal
            -100.0,100.0,100.0,         //4 position
            -sqrt13,sqrt13,sqrt13,      //4 normal
            100.0,100.0,100.0,          //5 position
            sqrt13,sqrt13,sqrt13,       //5 normal
            100.0,-100.0,100.0,         //6 position
            sqrt13,-sqrt13,sqrt13,      //6 normal
            -100.0,-100.0,100.0,        //7 position
            -sqrt13,-sqrt13,sqrt13,     //7 normal
    };
 
    RenderSystem* rs = Root::getSingleton().getRenderSystem();
    RGBA colours[nVertices];
    RGBA *pColour = colours;
    // Use render system to convert colour value since colour packing varies
    rs->convertColourValue(ColourValue(1.0,0.0,0.0), pColour++); //0 colour
    rs->convertColourValue(ColourValue(1.0,1.0,0.0), pColour++); //1 colour
    rs->convertColourValue(ColourValue(0.0,1.0,0.0), pColour++); //2 colour
    rs->convertColourValue(ColourValue(0.0,0.0,0.0), pColour++); //3 colour
    rs->convertColourValue(ColourValue(1.0,0.0,1.0), pColour++); //4 colour
    rs->convertColourValue(ColourValue(1.0,1.0,1.0), pColour++); //5 colour
    rs->convertColourValue(ColourValue(0.0,1.0,1.0), pColour++); //6 colour
    rs->convertColourValue(ColourValue(0.0,0.0,1.0), pColour++); //7 colour
 
    /// Define 12 triangles (two triangles per cube face)
    /// The values in this table refer to vertices in the above table
    const size_t ibufCount = 36;
    unsigned short faces[ibufCount] = {
            0,2,3,
            0,1,2,
            1,6,2,
            1,5,6,
            4,6,5,
            4,7,6,
            0,7,4,
            0,3,7,
            0,5,1,
            0,4,5,
            2,7,3,
            2,6,7
    };
 
    /// Create vertex data structure for 8 vertices shared between submeshes
    msh->sharedVertexData = new VertexData();
    msh->sharedVertexData->vertexCount = nVertices;
 
    /// Create declaration (memory format) of vertex data
    VertexDeclaration* decl = msh->sharedVertexData->vertexDeclaration;
    size_t offset = 0;
    // 1st buffer
    decl->addElement(0, offset, VET_FLOAT3, VES_POSITION);
    offset += VertexElement::getTypeSize(VET_FLOAT3);
    decl->addElement(0, offset, VET_FLOAT3, VES_NORMAL);
    offset += VertexElement::getTypeSize(VET_FLOAT3);
    /// Allocate vertex buffer of the requested number of vertices (vertexCount) 
    /// and bytes per vertex (offset)
    HardwareVertexBufferSharedPtr vbuf = 
        HardwareBufferManager::getSingleton().createVertexBuffer(
        offset, msh->sharedVertexData->vertexCount, HardwareBuffer::HBU_STATIC_WRITE_ONLY);
    /// Upload the vertex data to the card
    vbuf->writeData(0, vbuf->getSizeInBytes(), vertices, true);
 
    /// Set vertex buffer binding so buffer 0 is bound to our vertex buffer
    VertexBufferBinding* bind = msh->sharedVertexData->vertexBufferBinding; 
    bind->setBinding(0, vbuf);
 
    // 2nd buffer
    offset = 0;
    decl->addElement(1, offset, VET_COLOUR, VES_DIFFUSE);
    offset += VertexElement::getTypeSize(VET_COLOUR);
    /// Allocate vertex buffer of the requested number of vertices (vertexCount) 
    /// and bytes per vertex (offset)
    vbuf = HardwareBufferManager::getSingleton().createVertexBuffer(
        offset, msh->sharedVertexData->vertexCount, HardwareBuffer::HBU_STATIC_WRITE_ONLY);
    /// Upload the vertex data to the card
    vbuf->writeData(0, vbuf->getSizeInBytes(), colours, true);
 
    /// Set vertex buffer binding so buffer 1 is bound to our colour buffer
    bind->setBinding(1, vbuf);
 
    /// Allocate index buffer of the requested number of vertices (ibufCount) 
    HardwareIndexBufferSharedPtr ibuf = HardwareBufferManager::getSingleton().
        createIndexBuffer(
        HardwareIndexBuffer::IT_16BIT, 
        ibufCount, 
        HardwareBuffer::HBU_STATIC_WRITE_ONLY);
 
    /// Upload the index data to the card
    ibuf->writeData(0, ibuf->getSizeInBytes(), faces, true);
 
    /// Set parameters of the submesh
    sub->useSharedVertices = true;
    sub->indexData->indexBuffer = ibuf;
    sub->indexData->indexCount = ibufCount;
    sub->indexData->indexStart = 0;
 
    /// Set bounding information (for culling)
    msh->_setBounds(AxisAlignedBox(-100,-100,-100,100,100,100));
    msh->_setBoundingSphereRadius(Math::Sqrt(3*100*100));
 
    /// Notify -Mesh object that it has been loaded
    msh->load();
}
Exemplo n.º 5
0
// Convert Nif::NiTriShape to Ogre::SubMesh, attached to the given
// mesh.
void NIFLoader::createOgreSubMesh(NiTriShape *shape, const String &material, std::list<VertexBoneAssignment> &vertexBoneAssignments)
{
    //  cout << "s:" << shape << "\n";
    NiTriShapeData *data = shape->data.getPtr();
    SubMesh *sub = mesh->createSubMesh(shape->name.toString());

    int nextBuf = 0;

    // This function is just one long stream of Ogre-barf, but it works
    // great.

    // Add vertices
    int numVerts = data->vertices.length / 3;
    sub->vertexData = new VertexData();
    sub->vertexData->vertexCount = numVerts;
    sub->useSharedVertices = false;

    VertexDeclaration *decl = sub->vertexData->vertexDeclaration;
    decl->addElement(nextBuf, 0, VET_FLOAT3, VES_POSITION);

    HardwareVertexBufferSharedPtr vbuf =
        HardwareBufferManager::getSingleton().createVertexBuffer(
            VertexElement::getTypeSize(VET_FLOAT3),
            numVerts, HardwareBuffer::HBU_DYNAMIC_WRITE_ONLY, false);

    if(flip)
	{
		float *datamod = new float[data->vertices.length];
		//std::cout << "Shape" << shape->name.toString() << "\n";
		for(int i = 0; i < numVerts; i++)
		{
			int index = i * 3;
			const float *pos = data->vertices.ptr + index;
		    Ogre::Vector3 original = Ogre::Vector3(*pos  ,*(pos+1), *(pos+2));
			original = mTransform * original;
			mBoundingBox.merge(original);
			datamod[index] = original.x;
			datamod[index+1] = original.y;
			datamod[index+2] = original.z;
		}
        vbuf->writeData(0, vbuf->getSizeInBytes(), datamod, false);
        delete [] datamod;
	}
	else
	{
		vbuf->writeData(0, vbuf->getSizeInBytes(), data->vertices.ptr, false);
	}


    VertexBufferBinding* bind = sub->vertexData->vertexBufferBinding;
    bind->setBinding(nextBuf++, vbuf);

    if (data->normals.length)
    {
        decl->addElement(nextBuf, 0, VET_FLOAT3, VES_NORMAL);
        vbuf = HardwareBufferManager::getSingleton().createVertexBuffer(
                   VertexElement::getTypeSize(VET_FLOAT3),
                   numVerts, HardwareBuffer::HBU_STATIC_WRITE_ONLY, false);

		if(flip)
		{
			Quaternion rotation = mTransform.extractQuaternion();
			rotation.normalise();

			float *datamod = new float[data->normals.length];
			for(int i = 0; i < numVerts; i++)
		    {
			    int index = i * 3;
			    const float *pos = data->normals.ptr + index;
		        Ogre::Vector3 original = Ogre::Vector3(*pos  ,*(pos+1), *(pos+2));
				original = rotation * original;
				if (mNormaliseNormals)
			    {
                    original.normalise();
				}


			    datamod[index] = original.x;
			    datamod[index+1] = original.y;
			    datamod[index+2] = original.z;
		    }
			vbuf->writeData(0, vbuf->getSizeInBytes(), datamod, false);
            delete [] datamod;
		}
		else
		{
            vbuf->writeData(0, vbuf->getSizeInBytes(), data->normals.ptr, false);
		}
        bind->setBinding(nextBuf++, vbuf);
    }

    
    // Vertex colors
    if (data->colors.length)
    {
        const float *colors = data->colors.ptr;
        RenderSystem* rs = Root::getSingleton().getRenderSystem();
        std::vector<RGBA> colorsRGB(numVerts);
        RGBA *pColour = &colorsRGB.front();
        for (int i=0; i<numVerts; i++)
        {
            rs->convertColourValue(ColourValue(colors[0],colors[1],colors[2],
                                               colors[3]),pColour++);
            colors += 4;
        }
        decl->addElement(nextBuf, 0, VET_COLOUR, VES_DIFFUSE);
        vbuf = HardwareBufferManager::getSingleton().createVertexBuffer(
                   VertexElement::getTypeSize(VET_COLOUR),
                   numVerts, HardwareBuffer::HBU_STATIC_WRITE_ONLY);
        vbuf->writeData(0, vbuf->getSizeInBytes(), &colorsRGB.front(), true);
        bind->setBinding(nextBuf++, vbuf);
    }

     if (data->uvlist.length)
    {

        decl->addElement(nextBuf, 0, VET_FLOAT2, VES_TEXTURE_COORDINATES);
        vbuf = HardwareBufferManager::getSingleton().createVertexBuffer(
                   VertexElement::getTypeSize(VET_FLOAT2),
                   numVerts, HardwareBuffer::HBU_STATIC_WRITE_ONLY,false);

		if(flip)
		{
		    float *datamod = new float[data->uvlist.length];

		    for(unsigned int i = 0; i < data->uvlist.length; i+=2){
			    float x = *(data->uvlist.ptr + i);

			    float y = *(data->uvlist.ptr + i + 1);

			    datamod[i] =x;
				datamod[i + 1] =y;
		    }
			vbuf->writeData(0, vbuf->getSizeInBytes(), datamod, false);
            delete [] datamod;
		}
		else
			vbuf->writeData(0, vbuf->getSizeInBytes(), data->uvlist.ptr, false);
        bind->setBinding(nextBuf++, vbuf);
    }

   // Triangle faces - The total number of triangle points
    int numFaces = data->triangles.length;

    if (numFaces)
    {

		sub->indexData->indexCount = numFaces;
        sub->indexData->indexStart = 0;
        HardwareIndexBufferSharedPtr ibuf = HardwareBufferManager::getSingleton().
                                            createIndexBuffer(HardwareIndexBuffer::IT_16BIT,
                                                              numFaces,
                                                              HardwareBuffer::HBU_STATIC_WRITE_ONLY, true);

		if(flip && mFlipVertexWinding && sub->indexData->indexCount % 3 == 0){

			sub->indexData->indexBuffer = ibuf;

			uint16 *datamod = new uint16[numFaces];
			int index = 0;
			for (size_t i = 0; i < sub->indexData->indexCount; i+=3)
			{

			     const short *pos = data->triangles.ptr + index;
				uint16 i0 = (uint16) *(pos+0);
				uint16 i1 = (uint16) *(pos+1);
				uint16 i2 = (uint16) *(pos+2);

				//std::cout << "i0: " << i0 << "i1: " << i1 << "i2: " << i2 << "\n";


				datamod[index] = i2;
				datamod[index+1] = i1;
				datamod[index+2] = i0;

				index += 3;
			}

            ibuf->writeData(0, ibuf->getSizeInBytes(), datamod, false);
            delete [] datamod;

		}
		else
            ibuf->writeData(0, ibuf->getSizeInBytes(), data->triangles.ptr, false);
        sub->indexData->indexBuffer = ibuf;
    }

    // Set material if one was given
    if (!material.empty()) sub->setMaterialName(material);

    //add vertex bone assignments

    for (std::list<VertexBoneAssignment>::iterator it = vertexBoneAssignments.begin();
        it != vertexBoneAssignments.end(); it++)
    {
            sub->addBoneAssignment(*it);
    }
    if(mSkel.isNull())
       needBoneAssignments.push_back(sub);
}