Summary class collecting together vertex source information.
Inheritance: DisposableObject
VertexData Class Documentation
Ejemplo n.º 1
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 public static void GetSubmeshVertexData(out Vector3[] points, VertexData vertexData)
 {
     //				if (subMesh.operationType != RenderMode.TriangleList)
     //					continue;
     points = null;
     for (ushort bindIdx = 0; bindIdx < vertexData.vertexDeclaration.ElementCount; ++bindIdx) {
         VertexElement element = vertexData.vertexDeclaration.GetElement(bindIdx);
         HardwareVertexBuffer vBuffer = vertexData.vertexBufferBinding.GetBuffer(bindIdx);
         if (element.Semantic != VertexElementSemantic.Position)
             continue;
         points = new Vector3[vertexData.vertexCount];
         ReadBuffer(vBuffer, vertexData.vertexCount, element.Size, ref points);
         return;
     }
     Debug.Assert(points != null, "Unable to retrieve position vertex data");
 }
Ejemplo n.º 2
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        /// <summary>
        ///    Default constructor.
        /// </summary>
        public WireBoundingBox()
        {
            vertexData = new VertexData();
            vertexData.vertexCount = 24;
            vertexData.vertexStart = 0;

            // get a reference to the vertex declaration and buffer binding
            VertexDeclaration decl = vertexData.vertexDeclaration;
            VertexBufferBinding binding = vertexData.vertexBufferBinding;

            // add elements for position and color only
            decl.AddElement(POSITION, 0, VertexElementType.Float3, VertexElementSemantic.Position);
            decl.AddElement(COLOR, 0, VertexElementType.Color, VertexElementSemantic.Diffuse);

            // create a new hardware vertex buffer for the position data
            HardwareVertexBuffer buffer  =
                HardwareBufferManager.Instance.CreateVertexBuffer(
                decl.GetVertexSize(POSITION),
                vertexData.vertexCount,
                BufferUsage.StaticWriteOnly);

            // bind the position buffer
            binding.SetBinding(POSITION, buffer);

            // create a new hardware vertex buffer for the color data
            buffer  = 	HardwareBufferManager.Instance.CreateVertexBuffer(
                decl.GetVertexSize(COLOR),
                vertexData.vertexCount,
                BufferUsage.StaticWriteOnly);

            // bind the color buffer
            binding.SetBinding(COLOR, buffer);

            Material mat = MaterialManager.Instance.GetByName("Core/WireBB");

            if(mat == null) {
                mat = MaterialManager.Instance.GetByName("BaseWhite");
                mat = mat.Clone("Core/WireBB");
                mat.Lighting = false;
            }

            this.Material = mat;
        }
Ejemplo n.º 3
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        public GeometryBucket(MaterialBucket parent, string formatString, 
                              VertexData vData, IndexData iData)
        {
            // Clone the structure from the example
            this.parent = parent;
            this.formatString = formatString;
            vertexData = vData.Clone(false);
            indexData = iData.Clone(false);
            vertexData.vertexCount = 0;
            vertexData.vertexStart = 0;
            indexData.indexCount = 0;
            indexData.indexStart = 0;
            indexType = indexData.indexBuffer.Type;
            queuedGeometry = new List<QueuedGeometry>();
            // Derive the max vertices
            if (indexType == IndexType.Size32)
                maxVertexIndex = int.MaxValue;
            else
                maxVertexIndex = ushort.MaxValue;

            // Check to see if we have blend indices / blend weights
            // remove them if so, they can try to blend non-existent bones!
            VertexElement blendIndices =
                vertexData.vertexDeclaration.FindElementBySemantic(VertexElementSemantic.BlendIndices);
            VertexElement blendWeights =
                vertexData.vertexDeclaration.FindElementBySemantic(VertexElementSemantic.BlendWeights);
            if (blendIndices != null && blendWeights != null) {
                Debug.Assert(blendIndices.Source == blendWeights.Source,
                             "Blend indices and weights should be in the same buffer");
                // Get the source
                ushort source = blendIndices.Source;
                Debug.Assert(blendIndices.Size + blendWeights.Size ==
                    vertexData.vertexBufferBinding.GetBuffer(source).VertexSize,
                    "Blend indices and blend buffers should have buffer to themselves!");
                // Unset the buffer
                vertexData.vertexBufferBinding.UnsetBinding(source);
                // Remove the elements
                vertexData.vertexDeclaration.RemoveElement(VertexElementSemantic.BlendIndices);
                vertexData.vertexDeclaration.RemoveElement(VertexElementSemantic.BlendWeights);
            }
        }
Ejemplo n.º 4
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        public Rectangle2D(bool includeTextureCoordinates)
        {
            vertexData             = new VertexData();
            vertexData.vertexStart = 0;
            vertexData.vertexCount = 4;

            VertexDeclaration   decl    = vertexData.vertexDeclaration;
            VertexBufferBinding binding = vertexData.vertexBufferBinding;

            decl.AddElement(POSITION, 0, VertexElementType.Float3, VertexElementSemantic.Position);

            HardwareVertexBuffer buffer =
                HardwareBufferManager.Instance.CreateVertexBuffer(
                    decl.GetVertexSize(POSITION),
                    vertexData.vertexCount,
                    BufferUsage.StaticWriteOnly);

            binding.SetBinding(POSITION, buffer);

            if (includeTextureCoordinates)
            {
                decl.AddElement(TEXCOORD, 0, VertexElementType.Float2, VertexElementSemantic.TexCoords);

                buffer =
                    HardwareBufferManager.Instance.CreateVertexBuffer(
                        decl.GetVertexSize(TEXCOORD),
                        vertexData.vertexCount,
                        BufferUsage.StaticWriteOnly);

                binding.SetBinding(TEXCOORD, buffer);

                buffer.WriteData(0, buffer.Size, texCoords, true);
            }

            // TODO: Fix
            material          = MaterialManager.Instance.GetByName("BaseWhite");
            material.Lighting = false;
        }
Ejemplo n.º 5
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        public Rectangle2D(bool includeTextureCoordinates)
        {
            vertexData = new VertexData();
            vertexData.vertexStart = 0;
            vertexData.vertexCount = 4;

            VertexDeclaration decl = vertexData.vertexDeclaration;
            VertexBufferBinding binding = vertexData.vertexBufferBinding;

            decl.AddElement(POSITION, 0, VertexElementType.Float3, VertexElementSemantic.Position);

            HardwareVertexBuffer buffer =
                HardwareBufferManager.Instance.CreateVertexBuffer(
                    decl.GetVertexSize(POSITION),
                    vertexData.vertexCount,
                    BufferUsage.StaticWriteOnly);

            binding.SetBinding(POSITION, buffer);

            if(includeTextureCoordinates) {
                decl.AddElement(TEXCOORD, 0, VertexElementType.Float2, VertexElementSemantic.TexCoords);

                buffer =
                    HardwareBufferManager.Instance.CreateVertexBuffer(
                    decl.GetVertexSize(TEXCOORD),
                    vertexData.vertexCount,
                    BufferUsage.StaticWriteOnly);

                binding.SetBinding(TEXCOORD, buffer);

                buffer.WriteData(0, buffer.Size, texCoords, true);
            }

            // TODO: Fix
            material = MaterialManager.Instance.GetByName("BaseWhite");
            material.Lighting = false;
        }
Ejemplo n.º 6
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		/// <summary>
		///		Internal method to clone vertex data definitions but to remove blend buffers.
		/// </summary>
		/// <param name="source">Vertex data to clone.</param>
		/// <returns>A cloned instance of 'source' without blending information.</returns>
		protected internal VertexData CloneVertexDataRemoveBlendInfo( VertexData source )
		{
			// Clone without copying data
			var ret = source.Clone( false );
			var blendIndexElem = source.vertexDeclaration.FindElementBySemantic( VertexElementSemantic.BlendIndices );
			var blendWeightElem = source.vertexDeclaration.FindElementBySemantic( VertexElementSemantic.BlendWeights );

			// Remove blend index
			if ( blendIndexElem != null )
			{
				// Remove buffer reference
				ret.vertexBufferBinding.UnsetBinding( blendIndexElem.Source );
			}

			if ( blendWeightElem != null && blendWeightElem.Source != blendIndexElem.Source )
			{
				// Remove buffer reference
				ret.vertexBufferBinding.UnsetBinding( blendWeightElem.Source );
			}
			// remove elements from declaration
			ret.vertexDeclaration.RemoveElement( VertexElementSemantic.BlendIndices );
			ret.vertexDeclaration.RemoveElement( VertexElementSemantic.BlendWeights );

			// copy reference to w-coord buffer
			if ( source.hardwareShadowVolWBuffer != null )
			{
				ret.hardwareShadowVolWBuffer = source.hardwareShadowVolWBuffer;
			}

			return ret;
		}
Ejemplo n.º 7
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		/// <summary>
		///     Initialize the hardware animation elements for given vertex data
		/// </summary>
		private void InitHardwareAnimationElements( VertexData vdata, ushort numberOfElements )
		{
			if ( vdata.HWAnimationDataList.Count < numberOfElements )
			{
				vdata.AllocateHardwareAnimationElements( numberOfElements );
			}
			// Initialize parametrics incase we don't use all of them
			for ( var i = 0; i < vdata.HWAnimationDataList.Count; i++ )
			{
				vdata.HWAnimationDataList[ i ].Parametric = 0.0f;
			}
			// reset used count
			vdata.HWAnimDataItemsUsed = 0;
		}
Ejemplo n.º 8
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        private VertexData InitVertexBuffer(int numVerts)
        {
            vertexData = new VertexData();

            vertexData.vertexCount = numVerts;
            vertexData.vertexStart = 0;

            // set up the vertex declaration
            int vDecOffset = 0;
            vertexData.vertexDeclaration.AddElement(0, vDecOffset, VertexElementType.Float3, VertexElementSemantic.Position);
            vDecOffset += VertexElement.GetTypeSize(VertexElementType.Float3);

            vertexData.vertexDeclaration.AddElement(0, vDecOffset, VertexElementType.Float3, VertexElementSemantic.Normal);
            vDecOffset += VertexElement.GetTypeSize(VertexElementType.Float3);

            vertexData.vertexDeclaration.AddElement(0, vDecOffset, VertexElementType.Float2, VertexElementSemantic.TexCoords);
            vDecOffset += VertexElement.GetTypeSize(VertexElementType.Float2);

            // create the hardware vertex buffer and set up the buffer binding
            HardwareVertexBuffer hvBuffer = HardwareBufferManager.Instance.CreateVertexBuffer(
                vertexData.vertexDeclaration.GetVertexSize(0), vertexData.vertexCount,
                BufferUsage.StaticWriteOnly, false);

            vertexData.vertexBufferBinding.SetBinding(0, hvBuffer);

            return vertexData;
        }
Ejemplo n.º 9
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		protected override void ReadGeometryTexCoords( short bindIdx, BinaryReader reader, VertexData data, int coordSet )
		{
			// get the number of texture dimensions (1D, 2D, 3D, etc)
			var dim = ReadUShort( reader );

			// add a vertex element for the current tex coord set
			data.vertexDeclaration.AddElement( bindIdx, 0, VertexElement.MultiplyTypeCount( VertexElementType.Float1, dim ),
			                                   VertexElementSemantic.TexCoords, coordSet );

			// create the vertex buffer for the tex coords
			var vBuffer = HardwareBufferManager.Instance.CreateVertexBuffer( data.vertexDeclaration.Clone( bindIdx ),
			                                                                 data.vertexCount, mesh.VertexBufferUsage,
			                                                                 mesh.UseVertexShadowBuffer );

			// lock the vertex buffer
			var texCoords = vBuffer.Lock( BufferLocking.Discard );

			// blast the tex coord data into the buffer
			ReadFloats( reader, data.vertexCount*dim, texCoords );

			// Adjust individual v values to (1 - v)
			if ( dim == 2 )
			{
				var count = 0;

#if !AXIOM_SAFE_ONLY
				unsafe
#endif
				{
					var pTex = texCoords.ToFloatPointer();

					for ( var i = 0; i < data.vertexCount; i++ )
					{
						count++; // skip u
						pTex[ count ] = 1.0f - pTex[ count ]; // v = 1 - v
						count++;
					}
				}
			}

			// unlock the buffer to commit
			vBuffer.Unlock();

			// bind the tex coord buffer
			data.vertexBufferBinding.SetBinding( bindIdx, vBuffer );
		}
Ejemplo n.º 10
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		protected virtual void ReadGeometryColors( short bindIdx, BinaryReader reader, VertexData data )
		{
			// add an element for normals
			data.vertexDeclaration.AddElement( bindIdx, 0, VertexElementType.Color, VertexElementSemantic.Diffuse );

			var vBuffer = HardwareBufferManager.Instance.CreateVertexBuffer( data.vertexDeclaration.Clone( bindIdx ),
			                                                                 data.vertexCount, mesh.VertexBufferUsage,
			                                                                 mesh.UseVertexShadowBuffer );

			// lock the buffer for editing
			var colors = vBuffer.Lock( BufferLocking.Discard );

			// stuff the floats into the normal buffer
			ReadInts( reader, data.vertexCount, colors );

			// unlock the buffer to commit
			vBuffer.Unlock();

			// bind this buffer
			data.vertexBufferBinding.SetBinding( bindIdx, vBuffer );
		}
Ejemplo n.º 11
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		/// <summary>
		///		Internal method - given vertex data which could be from the <see cref="Mesh"/> or
		///		any <see cref="SubMesh"/>, finds the temporary blend copy.
		/// </summary>
		/// <param name="originalData"></param>
		/// <returns></returns>
		protected VertexData FindBlendedVertexData( VertexData originalData )
		{
			if ( originalData == this.mesh.SharedVertexData )
			{
				return HasSkeleton ? this.skelAnimVertexData : this.softwareVertexAnimVertexData;
			}

			foreach ( var se in this.subEntityList )
			{
				if ( originalData == se.SubMesh.vertexData )
				{
					return HasSkeleton ? se.SkelAnimVertexData : se.SoftwareVertexAnimVertexData;
				}
			}

			throw new Exception( "Cannot find blended version of the vertex data specified." );
		}
Ejemplo n.º 12
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        /// <summary>
        ///		Clones this vertex data, potentially including replicating any vertex buffers.
        /// </summary>
        /// <param name="copyData">
        ///		If true, makes a copy the vertex buffer in addition to the definition.
        ///		If false, the clone will refer to the same vertex buffer this object refers to.
        /// </param>
        /// <returns>A cloned vertex data object.</returns>
        public VertexData Clone(bool copyData)
        {
            var dest = new VertexData();

            // Copy vertex buffers in turn
            var bindings = this.vertexBufferBinding.Bindings;

            foreach (var source in bindings.Keys)
            {
                var srcbuf = bindings[source];
                HardwareVertexBuffer dstBuf;

                if (copyData)
                {
                    // create new buffer with the same settings
                    dstBuf = HardwareBufferManager.Instance.CreateVertexBuffer(srcbuf.VertexDeclaration, srcbuf.VertexCount,
                                                                               srcbuf.Usage, srcbuf.HasShadowBuffer);

                    // copy data
                    dstBuf.CopyTo(srcbuf, 0, 0, srcbuf.Size, true);
                }
                else
                {
                    // don't copy, point at existing buffer
                    dstBuf = srcbuf;
                }

                // Copy binding
                dest.vertexBufferBinding.SetBinding(source, dstBuf);
            }

            // Basic vertex info
            dest.vertexStart = this.vertexStart;
            dest.vertexCount = this.vertexCount;

            // Copy elements
            for (var i = 0; i < this.vertexDeclaration.ElementCount; i++)
            {
                var element = this.vertexDeclaration.GetElement(i);

                dest.vertexDeclaration.AddElement(element.Source, element.Offset, element.Type, element.Semantic, element.Index);
            }

            // Copy hardware shadow buffer if set up
            if (this.hardwareShadowVolWBuffer != null)
            {
                dest.hardwareShadowVolWBuffer =
                    HardwareBufferManager.Instance.CreateVertexBuffer(this.hardwareShadowVolWBuffer.VertexDeclaration,
                                                                      this.hardwareShadowVolWBuffer.VertexCount,
                                                                      this.hardwareShadowVolWBuffer.Usage,
                                                                      this.hardwareShadowVolWBuffer.HasShadowBuffer);

                // copy data
                dest.hardwareShadowVolWBuffer.CopyTo(this.hardwareShadowVolWBuffer, 0, 0, this.hardwareShadowVolWBuffer.Size, true);
            }

            // copy anim data
            dest.HWAnimationDataList = this.HWAnimationDataList;
            dest.HWAnimDataItemsUsed = this.HWAnimDataItemsUsed;

            return(dest);
        }
Ejemplo n.º 13
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        public unsafe void DebugLog(Log log)
        {
            log.Write("EdgeListBuilder Log");
            log.Write("-------------------");
            log.Write("Number of vertex sets: {0}", vertexDataList.Count);
            log.Write("Number of index sets: {0}", indexDataList.Count);

            int i, j;

            // Log original vertex data
            for (i = 0; i < vertexDataList.Count; i++)
            {
                VertexData vData = (VertexData)vertexDataList[i];
                log.Write(".");
                log.Write("Original vertex set {0} - vertex count {1}", i, vData.vertexCount);

                VertexElement posElem =
                    vData.vertexDeclaration.FindElementBySemantic(VertexElementSemantic.Position);
                HardwareVertexBuffer vbuf =
                    vData.vertexBufferBinding.GetBuffer(posElem.Source);

                // lock the buffer for reading
                IntPtr basePtr = vbuf.Lock(BufferLocking.ReadOnly);

                byte *pBaseVertex = (byte *)basePtr.ToPointer();

                float *pReal;

                for (j = 0; j < vData.vertexCount; j++)
                {
                    pReal = (float *)(pBaseVertex + posElem.Offset);

                    log.Write("Vertex {0}: ({1}, {2}, {3})", j, pReal[0], pReal[1], pReal[2]);

                    pBaseVertex += vbuf.VertexSize;
                }

                vbuf.Unlock();
            }

            // Log original index data
            for (i = 0; i < indexDataList.Count; i += 3)
            {
                IndexData iData = (IndexData)indexDataList[i];
                log.Write(".");
                log.Write("Original triangle set {0} - index count {1} - vertex set {2})",
                          i, iData.indexCount, indexDataVertexDataSetList[i]);

                // Get the indexes ready for reading
                short *p16Idx = null;
                int *  p32Idx = null;

                IntPtr idxPtr = iData.indexBuffer.Lock(BufferLocking.ReadOnly);

                if (iData.indexBuffer.Type == IndexType.Size32)
                {
                    p32Idx = (int *)idxPtr.ToPointer();
                }
                else
                {
                    p16Idx = (short *)idxPtr.ToPointer();
                }

                for (j = 0; j < iData.indexCount / 3; j++)
                {
                    if (iData.indexBuffer.Type == IndexType.Size32)
                    {
                        log.Write("Triangle {0}: ({1}, {2}, {3})", j, *p32Idx++, *p32Idx++, *p32Idx++);
                    }
                    else
                    {
                        log.Write("Triangle {0}: ({1}, {2}, {3})", j, *p16Idx++, *p16Idx++, *p16Idx++);
                    }
                }

                iData.indexBuffer.Unlock();

                // Log common vertex list
                log.Write(".");
                log.Write("Common vertex list - vertex count {0}", vertices.Count);

                for (i = 0; i < vertices.Count; i++)
                {
                    CommonVertex c = (CommonVertex)vertices[i];

                    log.Write("Common vertex {0}: (vertexSet={1}, originalIndex={2}, position={3}",
                              i, c.vertexSet, c.index, c.position);
                }
            }
        }
Ejemplo n.º 14
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        /// <summary>
        ///
        /// </summary>
        /// <param name="indexSet"></param>
        /// <param name="vertexSet"></param>
        protected void BuildTrianglesEdges(int indexSet, int vertexSet)
        {
            IndexData     indexData = (IndexData)indexDataList[indexSet];
            OperationType opType    = operationTypes[indexSet];

            int iterations = 0;

            switch (opType)
            {
            case OperationType.TriangleList:
                iterations = indexData.indexCount / 3;
                break;

            case OperationType.TriangleFan:
            case OperationType.TriangleStrip:
                iterations = indexData.indexCount - 2;
                break;
            }

            // locate postion element & the buffer to go with it
            VertexData    vertexData = (VertexData)vertexDataList[vertexSet];
            VertexElement posElem    =
                vertexData.vertexDeclaration.FindElementBySemantic(VertexElementSemantic.Position);

            HardwareVertexBuffer posBuffer = vertexData.vertexBufferBinding.GetBuffer(posElem.Source);
            IntPtr posPtr = posBuffer.Lock(BufferLocking.ReadOnly);
            IntPtr idxPtr = indexData.indexBuffer.Lock(BufferLocking.ReadOnly);

            unsafe {
                byte *pBaseVertex = (byte *)posPtr.ToPointer();

                short *p16Idx = null;
                int *  p32Idx = null;

                // counters used for pointer indexing
                int count16 = 0;
                int count32 = 0;

                if (indexData.indexBuffer.Type == IndexType.Size16)
                {
                    p16Idx = (short *)idxPtr.ToPointer();
                }
                else
                {
                    p32Idx = (int *)idxPtr.ToPointer();
                }

                float *pReal = null;

                int triStart = edgeData.triangles.Count;

                // iterate over all the groups of 3 indices
                edgeData.triangles.Capacity = triStart + iterations;

                for (int t = 0; t < iterations; t++)
                {
                    EdgeData.Triangle tri = new EdgeData.Triangle();
                    tri.indexSet  = indexSet;
                    tri.vertexSet = vertexSet;

                    int[]     index = new int[3];
                    Vector3[] v     = new Vector3[3];

                    for (int i = 0; i < 3; i++)
                    {
                        // Standard 3-index read for tri list or first tri in strip / fan
                        if (opType == OperationType.TriangleList || t == 0)
                        {
                            if (indexData.indexBuffer.Type == IndexType.Size32)
                            {
                                index[i] = p32Idx[count32++];
                            }
                            else
                            {
                                index[i] = p16Idx[count16++];
                            }
                        }
                        else
                        {
                            // Strips and fans are formed from last 2 indexes plus the
                            // current one for triangles after the first
                            if (indexData.indexBuffer.Type == IndexType.Size32)
                            {
                                index[i] = p32Idx[i - 2];
                            }
                            else
                            {
                                index[i] = p16Idx[i - 2];
                            }

                            // Perform single-index increment at the last tri index
                            if (i == 2)
                            {
                                if (indexData.indexBuffer.Type == IndexType.Size32)
                                {
                                    count32++;
                                }
                                else
                                {
                                    count16++;
                                }
                            }
                        }

                        // populate tri original vertex index
                        tri.vertIndex[i] = index[i];

                        // Retrieve the vertex position
                        byte *pVertex = pBaseVertex + (index[i] * posBuffer.VertexSize);
                        pReal  = (float *)(pVertex + posElem.Offset);
                        v[i].x = *pReal++;
                        v[i].y = *pReal++;
                        v[i].z = *pReal++;
                        // find this vertex in the existing vertex map, or create it
                        tri.sharedVertIndex[i] = FindOrCreateCommonVertex(v[i], vertexSet, indexSet, index[i]);
                    }

                    // Calculate triangle normal (NB will require recalculation for
                    // skeletally animated meshes)
                    tri.normal = MathUtil.CalculateFaceNormal(v[0], v[1], v[2]);

                    // Add triangle to list
                    edgeData.triangles.Add(tri);

                    try {
                        // create edges from common list
                        if (tri.sharedVertIndex[0] < tri.sharedVertIndex[1])
                        {
                            CreateEdge(vertexSet, triStart + t,
                                       tri.vertIndex[0], tri.vertIndex[1],
                                       tri.sharedVertIndex[0], tri.sharedVertIndex[1]);
                        }
                        if (tri.sharedVertIndex[1] < tri.sharedVertIndex[2])
                        {
                            CreateEdge(vertexSet, triStart + t,
                                       tri.vertIndex[1], tri.vertIndex[2],
                                       tri.sharedVertIndex[1], tri.sharedVertIndex[2]);
                        }
                        if (tri.sharedVertIndex[2] < tri.sharedVertIndex[0])
                        {
                            CreateEdge(vertexSet, triStart + t,
                                       tri.vertIndex[2], tri.vertIndex[0],
                                       tri.sharedVertIndex[2], tri.sharedVertIndex[0]);
                        }
                    }
                    catch (Exception ex) {
                        //Debug.WriteLine(ex.ToString());
                        //Debug.WriteLine(ex.StackTrace);
                        // unlock those buffers!
                        indexData.indexBuffer.Unlock();
                        posBuffer.Unlock();

                        throw ex;
                    }
                } // for iterations
            }     // unsafe

            // unlock those buffers!
            indexData.indexBuffer.Unlock();
            posBuffer.Unlock();
        }
Ejemplo n.º 15
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			public EntityShadowRenderable( Entity parent, HardwareIndexBuffer indexBuffer, VertexData vertexData,
			                               bool createSeperateLightCap, SubEntity subEntity )
				: this( parent, indexBuffer, vertexData, createSeperateLightCap, subEntity, false )
			{
			}
Ejemplo n.º 16
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			/// <summary>
			///		Rebind the source positions for temp buffer users.
			/// </summary>
			public void RebindPositionBuffer( VertexData vertexData, bool force )
			{
				if ( force || this.currentVertexData != vertexData )
				{
					this.currentVertexData = vertexData;
					this.positionBuffer = this.currentVertexData.vertexBufferBinding.GetBuffer( this.originalPosBufferBinding );
					renderOperation.vertexData.vertexBufferBinding.SetBinding( 0, this.positionBuffer );
					if ( lightCap != null )
					{
						( (EntityShadowRenderable)lightCap ).RebindPositionBuffer( vertexData, force );
					}
				}
			}
Ejemplo n.º 17
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 /// <summary>
 /// Add a set of vertex geometry data to the edge builder.
 /// </summary>
 /// <remarks>
 /// You must add at least one set of vertex data to the builder before invoking the
 /// <see name="Build"/> method.
 /// </remarks>
 /// <param name="vertexData">Vertex data to consider for edge detection.</param>
 public void AddVertexData(VertexData vertexData)
 {
     this.vertexDataList.Add(vertexData);
 }
Ejemplo n.º 18
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		/// <summary>
		///		Clones this vertex data, potentially including replicating any vertex buffers.
		/// </summary>
		/// <param name="copyData">
		///		If true, makes a copy the vertex buffer in addition to the definition.
		///		If false, the clone will refer to the same vertex buffer this object refers to.
		/// </param>
		/// <returns>A cloned vertex data object.</returns>
		public VertexData Clone( bool copyData )
		{
			VertexData dest = new VertexData();

			// Copy vertex buffers in turn
			Dictionary<short, HardwareVertexBuffer> bindings = vertexBufferBinding.Bindings;

			foreach ( short source in bindings.Keys )
			{
				HardwareVertexBuffer srcbuf = bindings[ source ];
				HardwareVertexBuffer dstBuf;

				if ( copyData )
				{
					// create new buffer with the same settings
					dstBuf =
						HardwareBufferManager.Instance.CreateVertexBuffer( srcbuf.VertexDeclaration, srcbuf.VertexCount, srcbuf.Usage,	srcbuf.HasShadowBuffer );

					// copy data
					dstBuf.CopyData( srcbuf, 0, 0, srcbuf.Size, true );
				}
				else
				{
					// don't copy, point at existing buffer
					dstBuf = srcbuf;
				}

				// Copy binding
				dest.vertexBufferBinding.SetBinding( source, dstBuf );
			}

			// Basic vertex info
			dest.vertexStart = this.vertexStart;
			dest.vertexCount = this.vertexCount;

			// Copy elements
			for ( int i = 0; i < vertexDeclaration.ElementCount; i++ )
			{
				VertexElement element = vertexDeclaration.GetElement( i );

				dest.vertexDeclaration.AddElement( element.Source, element.Offset, element.Type, element.Semantic, element.Index );
			}

			// Copy hardware shadow buffer if set up
			if ( hardwareShadowVolWBuffer != null )
			{
				dest.hardwareShadowVolWBuffer =
					HardwareBufferManager.Instance.CreateVertexBuffer( hardwareShadowVolWBuffer.VertexDeclaration, hardwareShadowVolWBuffer.VertexCount, hardwareShadowVolWBuffer.Usage, hardwareShadowVolWBuffer.HasShadowBuffer );

				// copy data
				dest.hardwareShadowVolWBuffer.CopyData( hardwareShadowVolWBuffer, 0, 0, hardwareShadowVolWBuffer.Size,true );
			}

			// copy anim data
			dest.HWAnimationDataList = HWAnimationDataList;
			dest.HWAnimDataItemsUsed = HWAnimDataItemsUsed;

			return dest;
		}
Ejemplo n.º 19
0
        public List <TriangleVertices> Build()
        {
            List <TriangleVertices> triangles = new  List <TriangleVertices>();

            try {
                for (int ind = 0, indexSet = 0; ind < indexDataList.Count; ind++, indexSet++)
                {
                    int vertexSet = (int)indexDataVertexDataSetList[ind];

                    IndexData     indexData = (IndexData)indexDataList[indexSet];
                    OperationType opType    = operationTypes[indexSet];

                    int iterations = 0;

                    switch (opType)
                    {
                    case OperationType.TriangleList:
                        iterations = indexData.indexCount / 3;
                        break;

                    case OperationType.TriangleFan:
                    case OperationType.TriangleStrip:
                        iterations = indexData.indexCount - 2;
                        break;
                    }

                    // locate position element & the buffer to go with it
                    VertexData    vertexData = (VertexData)vertexDataList[vertexSet];
                    VertexElement posElem    =
                        vertexData.vertexDeclaration.FindElementBySemantic(VertexElementSemantic.Position);

                    HardwareVertexBuffer posBuffer = vertexData.vertexBufferBinding.GetBuffer(posElem.Source);
                    try {
                        IntPtr posPtr = posBuffer.Lock(BufferLocking.ReadOnly);
                        IntPtr idxPtr = indexData.indexBuffer.Lock(BufferLocking.ReadOnly);

                        unsafe {
                            byte *pBaseVertex = (byte *)posPtr.ToPointer();

                            ushort *p16Idx = null;
                            uint *  p32Idx = null;

                            // counters used for pointer indexing
                            int count16 = 0;
                            int count32 = 0;

                            if (indexData.indexBuffer.Type == IndexType.Size16)
                            {
                                p16Idx = (ushort *)idxPtr.ToPointer();
                            }
                            else
                            {
                                p32Idx = (uint *)idxPtr.ToPointer();
                            }

                            float *pReal = null;

                            int triStart = triangles.Count;

                            // iterate over all the groups of 3 indices
                            triangles.Capacity = triStart + iterations;

                            uint[] index = new uint[3];

                            for (int t = 0; t < iterations; t++)
                            {
                                Vector3[]        v      = new Vector3[3];
                                TriangleVertices tri    = new TriangleVertices(v);
                                bool             broken = false;
                                for (int i = 0; i < 3; i++)
                                {
                                    // Standard 3-index read for tri list or first tri in strip / fan
                                    if (opType == OperationType.TriangleList || t == 0)
                                    {
                                        if (indexData.indexBuffer.Type == IndexType.Size32)
                                        {
                                            index[i] = p32Idx[count32++];
                                        }
                                        else
                                        {
                                            index[i] = p16Idx[count16++];
                                        }
                                    }
                                    else
                                    {
                                        // Strips and fans are formed from last 2 indexes plus the
                                        // current one for triangles after the first
                                        if (indexData.indexBuffer.Type == IndexType.Size32)
                                        {
                                            index[i] = p32Idx[i - 2];
                                        }
                                        else
                                        {
                                            index[i] = p16Idx[i - 2];
                                        }

                                        // Perform single-index increment at the last tri index
                                        if (i == 2)
                                        {
                                            if (indexData.indexBuffer.Type == IndexType.Size32)
                                            {
                                                count32++;
                                            }
                                            else
                                            {
                                                count16++;
                                            }
                                        }
                                    }

                                    // Retrieve the vertex position
                                    if (index[i] >= posBuffer.VertexCount)
                                    {
                                        log.InfoFormat("TriangleListBuilder.Build: Error: index[i] {0} is not less than posBuffer.VertexCount {1}, iteration t {2}",
                                                       index[i], posBuffer.VertexCount, t);
                                        broken = true;
                                        break;
                                    }
                                    Debug.Assert(index[i] < posBuffer.VertexCount);
                                    byte *pVertex = pBaseVertex + (index[i] * posBuffer.VertexSize);
                                    pReal  = (float *)(pVertex + posElem.Offset);
                                    v[i].x = *pReal++;
                                    v[i].y = *pReal++;
                                    v[i].z = *pReal++;
                                }
                                if (!broken)
                                {
                                    // Put the points in in counter-clockwise order
                                    if (((v[0].x - v[2].x) * (v[1].y - v[2].y) - (v[1].x - v[2].x) * (v[0].y - v[2].y)) < 0)
                                    {
                                        // Clockwise, so reverse points 1 and 2
                                        Vector3 tmp = v[1];
                                        v[1] = v[2];
                                        v[2] = tmp;
                                    }
                                    // Debug.Assert(((v[0].x - v[2].x) * (v[1].y - v[2].y) - (v[1].x - v[2].x) * (v[0].y - v[2].y)) >= 0);
                                    // Add to the list of triangles
                                    triangles.Add(new TriangleVertices(v));
                                }
                            } // for iterations
                        }     // unsafe
                    }
                    finally {
                        // unlock those buffers!
                        indexData.indexBuffer.Unlock();
                        posBuffer.Unlock();
                    }
                }
                return(triangles);
            }
            catch (Exception e) {
                log.ErrorFormat("TriangleListBuilder.Build: Exception raised during triangle building: {0}", e.Message);
                triangles.Clear();
                return(triangles);
            }
        }
Ejemplo n.º 20
0
		protected virtual void ReadGeometryPositions( short bindIdx, BinaryReader reader, VertexData data )
		{
			data.vertexDeclaration.AddElement( bindIdx, 0, VertexElementType.Float3, VertexElementSemantic.Position );

			// vertex buffers
			var vBuffer = HardwareBufferManager.Instance.CreateVertexBuffer( data.vertexDeclaration.Clone( bindIdx ),
			                                                                 data.vertexCount, mesh.VertexBufferUsage,
			                                                                 mesh.UseVertexShadowBuffer );

			var posData = vBuffer.Lock( BufferLocking.Discard );

			// ram the floats into the buffer data
			ReadFloats( reader, data.vertexCount*3, posData );

			// unlock the buffer
			vBuffer.Unlock();

			// bind the position data
			data.vertexBufferBinding.SetBinding( bindIdx, vBuffer );
		}
Ejemplo n.º 21
0
        public Rectangle2D(bool includeTextureCoordinates)
        {
            // use identity projection and view matrices
            vertexData = new VertexData();
            renderOperation.vertexData             = vertexData;
            renderOperation.vertexData.vertexStart = 0;
            renderOperation.vertexData.vertexCount = 4;
            renderOperation.useIndices             = false;
            renderOperation.operationType          = OperationType.TriangleStrip;

            var decl    = vertexData.vertexDeclaration;
            var binding = vertexData.vertexBufferBinding;

            decl.AddElement(POSITION, 0, VertexElementType.Float3, VertexElementSemantic.Position);

            var buffer = HardwareBufferManager.Instance.CreateVertexBuffer(decl.Clone(POSITION), vertexData.vertexCount,
                                                                           BufferUsage.StaticWriteOnly);

            binding.SetBinding(POSITION, buffer);

            decl.AddElement(NORMAL, 0, VertexElementType.Float3, VertexElementSemantic.Normal);

            buffer = HardwareBufferManager.Instance.CreateVertexBuffer(decl.Clone(NORMAL),
                                                                       renderOperation.vertexData.vertexCount,
                                                                       BufferUsage.StaticWriteOnly);

            binding.SetBinding(NORMAL, buffer);

#if !AXIOM_SAFE_ONLY
            unsafe
#endif
            {
                var pNormBuf = buffer.Lock(BufferLocking.Discard).ToFloatPointer();
                var pNorm    = 0;
                pNormBuf[pNorm++] = 0.0f;
                pNormBuf[pNorm++] = 0.0f;
                pNormBuf[pNorm++] = 1.0f;

                pNormBuf[pNorm++] = 0.0f;
                pNormBuf[pNorm++] = 0.0f;
                pNormBuf[pNorm++] = 1.0f;

                pNormBuf[pNorm++] = 0.0f;
                pNormBuf[pNorm++] = 0.0f;
                pNormBuf[pNorm++] = 1.0f;

                pNormBuf[pNorm++] = 0.0f;
                pNormBuf[pNorm++] = 0.0f;
                pNormBuf[pNorm]   = 1.0f;

                buffer.Unlock();
            }
            if (includeTextureCoordinates)
            {
                decl.AddElement(TEXCOORD, 0, VertexElementType.Float2, VertexElementSemantic.TexCoords);

                buffer = HardwareBufferManager.Instance.CreateVertexBuffer(decl.Clone(TEXCOORD), vertexData.vertexCount,
                                                                           BufferUsage.StaticWriteOnly);

                binding.SetBinding(TEXCOORD, buffer);

                buffer.WriteData(0, buffer.Size, texCoords, true);
            }

            // TODO: Fix
            material          = (Material)MaterialManager.Instance["BaseWhite"];
            material.Lighting = false;
        }
Ejemplo n.º 22
0
		protected virtual void ReadGeometryTexCoords( short bindIdx, BinaryReader reader, VertexData data, int coordSet )
		{
			// get the number of texture dimensions (1D, 2D, 3D, etc)
			var dim = ReadShort( reader );

			// add a vertex element for the current tex coord set
			data.vertexDeclaration.AddElement( bindIdx, 0, VertexElement.MultiplyTypeCount( VertexElementType.Float1, dim ),
			                                   VertexElementSemantic.TexCoords, coordSet );

			// create the vertex buffer for the tex coords
			var vBuffer = HardwareBufferManager.Instance.CreateVertexBuffer( data.vertexDeclaration.Clone( bindIdx ),
			                                                                 data.vertexCount, mesh.VertexBufferUsage,
			                                                                 mesh.UseVertexShadowBuffer );

			// lock the vertex buffer
			var texCoords = vBuffer.Lock( BufferLocking.Discard );

			// blast the tex coord data into the buffer
			ReadFloats( reader, data.vertexCount*dim, texCoords );

			// unlock the buffer to commit
			vBuffer.Unlock();

			// bind the tex coord buffer
			data.vertexBufferBinding.SetBinding( bindIdx, vBuffer );
		}
Ejemplo n.º 23
0
        /// <summary>
        ///		Utility method, extract info from the given VertexData
        /// </summary>
        public void ExtractFrom(VertexData sourceData)
        {
            // Release old buffer copies first
            HardwareBufferManager mgr = HardwareBufferManager.Instance;

            if (destPositionBuffer != null)
            {
                mgr.ReleaseVertexBufferCopy(destPositionBuffer);
                Debug.Assert(destPositionBuffer == null);
            }
            if (destNormalBuffer != null)
            {
                mgr.ReleaseVertexBufferCopy(destNormalBuffer);
                Debug.Assert(destNormalBuffer == null);
            }

            VertexDeclaration   decl       = sourceData.vertexDeclaration;
            VertexBufferBinding bind       = sourceData.vertexBufferBinding;
            VertexElement       posElem    = decl.FindElementBySemantic(VertexElementSemantic.Position);
            VertexElement       normElem   = decl.FindElementBySemantic(VertexElementSemantic.Normal);
            VertexElement       tanElem    = decl.FindElementBySemantic(VertexElementSemantic.Tangent);
            VertexElement       binormElem = decl.FindElementBySemantic(VertexElementSemantic.Binormal);

            Debug.Assert(posElem != null, "Positions are required");

            posBindIndex      = posElem.Source;
            srcPositionBuffer = bind.GetBuffer(posBindIndex);

            if (normElem == null)
            {
                posNormalShareBuffer = false;
                srcNormalBuffer      = null;
            }
            else
            {
                normBindIndex = normElem.Source;
                if (normBindIndex == posBindIndex)
                {
                    posNormalShareBuffer = true;
                    srcNormalBuffer      = null;
                }
                else
                {
                    posNormalShareBuffer = false;
                    srcNormalBuffer      = bind.GetBuffer(normBindIndex);
                }
            }
            if (tanElem == null)
            {
                srcTangentBuffer = null;
            }
            else
            {
                tanBindIndex     = tanElem.Source;
                srcTangentBuffer = bind.GetBuffer(tanBindIndex);
            }

            if (binormElem == null)
            {
                srcBinormalBuffer = null;
            }
            else
            {
                binormBindIndex   = binormElem.Source;
                srcBinormalBuffer = bind.GetBuffer(binormBindIndex);
            }
        }
Ejemplo n.º 24
0
		protected void WriteGeometry( BinaryWriter writer, VertexData vertexData )
		{
			var start_offset = writer.Seek( 0, SeekOrigin.Current );
			WriteChunk( writer, MeshChunkID.Geometry, 0 );

			WriteUInt( writer, (uint)vertexData.vertexCount );
			WriteGeometryVertexDeclaration( writer, vertexData.vertexDeclaration );
			for ( short i = 0; i < vertexData.vertexBufferBinding.BindingCount; ++i )
			{
				WriteGeometryVertexBuffer( writer, i, vertexData.vertexBufferBinding.GetBuffer( i ) );
			}

			var end_offset = writer.Seek( 0, SeekOrigin.Current );
			writer.Seek( (int)start_offset, SeekOrigin.Begin );
			WriteChunk( writer, MeshChunkID.Geometry, (int)( end_offset - start_offset ) );
			writer.Seek( (int)end_offset, SeekOrigin.Begin );
		}
Ejemplo n.º 25
0
		/// <summary>
		///     Allocate / reallocate vertex data
		///     Note that we allocate enough space for ALL the billboards in the pool, but only issue
		///     rendering operations for the sections relating to the active billboards
		/// </summary>
		private void CreateBuffers()
		{
			/* Alloc positions   ( 1 or 4 verts per billboard, 3 components )
					 colours     ( 1 x RGBA per vertex )
					 indices     ( 6 per billboard ( 2 tris ) if not point rendering )
					 tex. coords ( 2D coords, 1 or 4 per billboard )
			*/

			//             LogManager.Instance.Write(string.Format("BillBoardSet.CreateBuffers entered; vertexData {0}, indexData {1}, mainBuffer {2}",
			//                     vertexData == null ? "null" : vertexData.ToString(),
			//                     indexData == null ? "null" : indexData.ToString(),
			//                     mainBuffer == null ? "null" : mainBuffer.ToString()));

			// Warn if user requested an invalid setup
			// Do it here so it only appears once
			if ( this.pointRendering && this.billboardType != BillboardType.Point )
			{
				LogManager.Instance.Write(
						"Warning: BillboardSet {0} has point rendering enabled but is using a type " +
						"other than BillboardType.Point, this may not give you the results you " +
						"expect.",
						this.name );
			}

			this.vertexData = new VertexData();
			if ( this.pointRendering )
			{
				this.vertexData.vertexCount = this.poolSize;
			}
			else
			{
				this.vertexData.vertexCount = this.poolSize * 4;
			}

			this.vertexData.vertexStart = 0;

			// Vertex declaration
			VertexDeclaration decl = this.vertexData.vertexDeclaration;
			VertexBufferBinding binding = this.vertexData.vertexBufferBinding;

			int offset = 0;
			decl.AddElement( 0, offset, VertexElementType.Float3, VertexElementSemantic.Position );
			offset += VertexElement.GetTypeSize( VertexElementType.Float3 );
			decl.AddElement( 0, offset, VertexElementType.Color, VertexElementSemantic.Diffuse );
			offset += VertexElement.GetTypeSize( VertexElementType.Color );
			// Texture coords irrelevant when enabled point rendering (generated
			// in point sprite mode, and unused in standard point mode)
			if ( !this.pointRendering )
			{
				decl.AddElement( 0, offset, VertexElementType.Float2, VertexElementSemantic.TexCoords, 0 );
			}

			this.mainBuffer =
					HardwareBufferManager.Instance.CreateVertexBuffer( decl.Clone( 0 ), this.vertexData.vertexCount, BufferUsage.DynamicWriteOnlyDiscardable );

			// bind position and diffuses
			binding.SetBinding( 0, this.mainBuffer );

			if ( !this.pointRendering )
			{
				this.indexData = new IndexData();

				// calc index buffer size
				this.indexData.indexStart = 0;
				this.indexData.indexCount = this.poolSize * 6;

				// create the index buffer
				this.indexData.indexBuffer =
						HardwareBufferManager.Instance.CreateIndexBuffer(
								IndexType.Size16,
								this.indexData.indexCount,
								BufferUsage.StaticWriteOnly );

				/* Create indexes (will be the same every frame)
				   Using indexes because it means 1/3 less vertex transforms (4 instead of 6)

				   Billboard layout relative to camera:

					0-----1
					|    /|
					|  /  |
					|/    |
					2-----3
				*/

				// lock the index buffer
				IntPtr idxPtr = this.indexData.indexBuffer.Lock( BufferLocking.Discard );

				unsafe
				{
					ushort* pIdx = (ushort*)idxPtr.ToPointer();

					for ( int idx, idxOffset, bboard = 0; bboard < this.poolSize; ++bboard )
					{
						// Do indexes
						idx = bboard * 6;
						idxOffset = bboard * 4;

						pIdx[ idx ] = (ushort)idxOffset; // + 0;, for clarity
						pIdx[ idx + 1 ] = (ushort)( idxOffset + 2 );
						pIdx[ idx + 2 ] = (ushort)( idxOffset + 1 );
						pIdx[ idx + 3 ] = (ushort)( idxOffset + 1 );
						pIdx[ idx + 4 ] = (ushort)( idxOffset + 2 );
						pIdx[ idx + 5 ] = (ushort)( idxOffset + 3 );
					} // for
				} // unsafe

				// unlock the buffers
				this.indexData.indexBuffer.Unlock();
			}
			this.buffersCreated = true;
		}
Ejemplo n.º 26
0
		public Rectangle2D( bool includeTextureCoordinates )
		{
			// use identity projection and view matrices
			vertexData = new VertexData();
			renderOperation.vertexData = vertexData;
			renderOperation.vertexData.vertexStart = 0;
			renderOperation.vertexData.vertexCount = 4;
			renderOperation.useIndices = false;
			renderOperation.operationType = OperationType.TriangleStrip;

			var decl = vertexData.vertexDeclaration;
			var binding = vertexData.vertexBufferBinding;

			decl.AddElement( POSITION, 0, VertexElementType.Float3, VertexElementSemantic.Position );

			var buffer = HardwareBufferManager.Instance.CreateVertexBuffer( decl.Clone( POSITION ), vertexData.vertexCount,
			                                                                BufferUsage.StaticWriteOnly );

			binding.SetBinding( POSITION, buffer );

			decl.AddElement( NORMAL, 0, VertexElementType.Float3, VertexElementSemantic.Normal );

			buffer = HardwareBufferManager.Instance.CreateVertexBuffer( decl.Clone( NORMAL ),
			                                                            renderOperation.vertexData.vertexCount,
			                                                            BufferUsage.StaticWriteOnly );

			binding.SetBinding( NORMAL, buffer );

#if !AXIOM_SAFE_ONLY
			unsafe
#endif
			{
				var pNormBuf = buffer.Lock( BufferLocking.Discard ).ToFloatPointer();
				var pNorm = 0;
				pNormBuf[ pNorm++ ] = 0.0f;
				pNormBuf[ pNorm++ ] = 0.0f;
				pNormBuf[ pNorm++ ] = 1.0f;

				pNormBuf[ pNorm++ ] = 0.0f;
				pNormBuf[ pNorm++ ] = 0.0f;
				pNormBuf[ pNorm++ ] = 1.0f;

				pNormBuf[ pNorm++ ] = 0.0f;
				pNormBuf[ pNorm++ ] = 0.0f;
				pNormBuf[ pNorm++ ] = 1.0f;

				pNormBuf[ pNorm++ ] = 0.0f;
				pNormBuf[ pNorm++ ] = 0.0f;
				pNormBuf[ pNorm ] = 1.0f;

				buffer.Unlock();
			}
			if ( includeTextureCoordinates )
			{
				decl.AddElement( TEXCOORD, 0, VertexElementType.Float2, VertexElementSemantic.TexCoords );

				buffer = HardwareBufferManager.Instance.CreateVertexBuffer( decl.Clone( TEXCOORD ), vertexData.vertexCount,
				                                                            BufferUsage.StaticWriteOnly );

				binding.SetBinding( TEXCOORD, buffer );

				buffer.WriteData( 0, buffer.Size, texCoords, true );
			}

			// TODO: Fix
			material = (Material)MaterialManager.Instance[ "BaseWhite" ];
			material.Lighting = false;
		}
Ejemplo n.º 27
0
		private void DestroyBuffers()
		{
			//             LogManager.Instance.Write(string.Format("BillBoardSet.DestroyBuffers entered; vertexData {0}, indexData {1}, mainBuffer {2}",
			//                     vertexData == null ? "null" : vertexData.ToString(),
			//                     indexData == null ? "null" : indexData.ToString(),
			//                     mainBuffer == null ? "null" : mainBuffer.ToString()));
			this.vertexData = null;
			this.indexData = null;
			this.mainBuffer = null;
			this.buffersCreated = false;
		}
Ejemplo n.º 28
0
		/// <summary>
		///		Internal method for preparing this Entity for use in animation.
		/// </summary>
		protected internal void PrepareTempBlendedBuffers()
		{
			if ( this.skelAnimVertexData != null )
			{
				this.skelAnimVertexData = null;
			}
			if ( this.softwareVertexAnimVertexData != null )
			{
				this.softwareVertexAnimVertexData = null;
			}
			if ( this.hardwareVertexAnimVertexData != null )
			{
				this.hardwareVertexAnimVertexData = null;
			}

			if ( this.mesh.HasVertexAnimation )
			{
				// Shared data
				if ( this.mesh.SharedVertexData != null && this.mesh.SharedVertexDataAnimationType != VertexAnimationType.None &&
				     this.tempVertexAnimInfo != null )
				{
					// Create temporary vertex blend info
					// Prepare temp vertex data if needed
					// Clone without copying data, don't remove any blending info
					// (since if we skeletally animate too, we need it)
					this.softwareVertexAnimVertexData = this.mesh.SharedVertexData.Clone( false );
					ExtractTempBufferInfo( this.softwareVertexAnimVertexData, this.tempVertexAnimInfo );

					// Also clone for hardware usage, don't remove blend info since we'll
					// need it if we also hardware skeletally animate
					this.hardwareVertexAnimVertexData = this.mesh.SharedVertexData.Clone( false );
				}
			}

			if ( HasSkeleton )
			{
				// shared data
				if ( this.mesh.SharedVertexData != null )
				{
					// Create temporary vertex blend info
					// Prepare temp vertex data if needed
					// Clone without copying data, remove blending info
					// (since blend is performed in software)
					this.skelAnimVertexData = CloneVertexDataRemoveBlendInfo( this.mesh.SharedVertexData );
					ExtractTempBufferInfo( this.skelAnimVertexData, this.tempSkelAnimInfo );
				}
			}

			// prepare temp blending buffers for subentites as well
			foreach ( var se in this.subEntityList )
			{
				se.PrepareTempBlendBuffers();
			}
		}
Ejemplo n.º 29
0
		protected virtual void ReadGeometry( BinaryReader reader, VertexData data )
		{
			data.vertexStart = 0;
			data.vertexCount = ReadInt( reader );

			// find optional geometry chunks
			if ( !IsEOF( reader ) )
			{
				var chunkID = ReadChunk( reader );

				while ( !IsEOF( reader ) &&
				        ( chunkID == MeshChunkID.GeometryVertexDeclaration || chunkID == MeshChunkID.GeometryVertexBuffer ) )
				{
					switch ( chunkID )
					{
						case MeshChunkID.GeometryVertexDeclaration:
							ReadGeometryVertexDeclaration( reader, data );
							break;

						case MeshChunkID.GeometryVertexBuffer:
							ReadGeometryVertexBuffer( reader, data );
							break;
					}

					// get the next chunk
					if ( !IsEOF( reader ) )
					{
						chunkID = ReadChunk( reader );
					}
				}

				if ( !IsEOF( reader ) )
				{
					// backpedal to start of non-submesh chunk
					Seek( reader, -ChunkOverheadSize );
				}

				// TODO : Implement color conversions
				// Perform any necessary color conversion for an active rendersystem
				//if ( Root.Instance != null && Root.Instance.RenderSystem != null )
				//{
				//    // We don't know the source type if it's VET_COLOUR, but assume ARGB
				//    // since that's the most common. Won't get used unless the mesh is
				//    // ambiguous anyway, which will have been warned about in the log
				//    data.ConvertPackedColor( VertexElementType.Color, VertexElement.BestColorVertexElementType );
				//}
			}
		}
Ejemplo n.º 30
0
		/// <summary>
		///		Internal method for extracting metadata out of source vertex data
		///		for fast assignment of temporary buffers later.
		/// </summary>
		/// <param name="sourceData"></param>
		/// <param name="info"></param>
		protected internal void ExtractTempBufferInfo( VertexData sourceData, TempBlendedBufferInfo info )
		{
			info.ExtractFrom( sourceData );
		}
Ejemplo n.º 31
0
		protected virtual void ReadGeometryVertexDeclaration( BinaryReader reader, VertexData data )
		{
			// find optional geometry chunks
			if ( !IsEOF( reader ) )
			{
				var chunkID = ReadChunk( reader );

				while ( !IsEOF( reader ) && ( chunkID == MeshChunkID.GeometryVertexElement ) )
				{
					switch ( chunkID )
					{
						case MeshChunkID.GeometryVertexElement:
							ReadGeometryVertexElement( reader, data );
							break;
					}

					// get the next chunk
					if ( !IsEOF( reader ) )
					{
						chunkID = ReadChunk( reader );
					}
				}

				if ( !IsEOF( reader ) )
				{
					// backpedal to start of non-submesh chunk
					Seek( reader, -ChunkOverheadSize );
				}
			}
		}
Ejemplo n.º 32
0
			public EntityShadowRenderable( Entity parent, HardwareIndexBuffer indexBuffer, VertexData vertexData,
			                               bool createSeparateLightCap, SubEntity subEntity, bool isLightCap )
			{
				this.parent = parent;

				// Save link to vertex data
				this.currentVertexData = vertexData;

				// Initialize render op
				renderOperation.indexData = new IndexData();
				renderOperation.indexData.indexBuffer = indexBuffer;
				renderOperation.indexData.indexStart = 0;
				// index start and count are sorted out later

				// Create vertex data which just references position component (and 2 component)
				renderOperation.vertexData = new VertexData();
				renderOperation.vertexData.vertexDeclaration = HardwareBufferManager.Instance.CreateVertexDeclaration();
				renderOperation.vertexData.vertexBufferBinding = HardwareBufferManager.Instance.CreateVertexBufferBinding();

				// Map in position data
				renderOperation.vertexData.vertexDeclaration.AddElement( 0, 0, VertexElementType.Float3,
				                                                         VertexElementSemantic.Position );
				this.originalPosBufferBinding =
					vertexData.vertexDeclaration.FindElementBySemantic( VertexElementSemantic.Position ).Source;

				this.positionBuffer = vertexData.vertexBufferBinding.GetBuffer( this.originalPosBufferBinding );
				renderOperation.vertexData.vertexBufferBinding.SetBinding( 0, this.positionBuffer );

				// Map in w-coord buffer (if present)
				if ( vertexData.hardwareShadowVolWBuffer != null )
				{
					renderOperation.vertexData.vertexDeclaration.AddElement( 1, 0, VertexElementType.Float1,
					                                                         VertexElementSemantic.TexCoords, 0 );
					this.wBuffer = vertexData.hardwareShadowVolWBuffer;
					renderOperation.vertexData.vertexBufferBinding.SetBinding( 1, this.wBuffer );
				}

				// Use same vertex start as input
				renderOperation.vertexData.vertexStart = vertexData.vertexStart;

				if ( isLightCap )
				{
					// Use original vertex count, no extrusion
					renderOperation.vertexData.vertexCount = vertexData.vertexCount;
				}
				else
				{
					// Vertex count must take into account the doubling of the buffer,
					// because second half of the buffer is the extruded copy
					renderOperation.vertexData.vertexCount = vertexData.vertexCount*2;

					if ( createSeparateLightCap )
					{
						// Create child light cap
						lightCap = new EntityShadowRenderable( parent, indexBuffer, vertexData, false, subEntity, true );
					}
				}
			}
Ejemplo n.º 33
0
		protected virtual void ReadGeometryVertexElement( BinaryReader reader, VertexData data )
		{
			var source = ReadShort( reader );
			var type = (VertexElementType)ReadUShort( reader );
			var semantic = (VertexElementSemantic)ReadUShort( reader );
			var offset = ReadShort( reader );
			var index = ReadShort( reader );

			// add the element to the declaration for the current vertex data
			data.vertexDeclaration.AddElement( source, offset, type, semantic, index );

			if ( type == VertexElementType.Color )
			{
				LogManager.Instance.Write(
					"Warning: VET_COLOUR element type is deprecated, you should use " +
					"one of the more specific types to indicate the byte order. " + "Use OgreMeshUpgrade on {0} as soon as possible. ",
					this.mesh.Name );
			}
		}
Ejemplo n.º 34
0
			/// <summary>
			/// 
			/// </summary>
			/// <param name="disposeManagedResources"></param>
			protected override void dispose( bool disposeManagedResources )
			{
				if ( !IsDisposed )
				{
					if ( disposeManagedResources )
					{
						// Dispose managed resources.
						if ( lightCap != null )
						{
							if ( !lightCap.IsDisposed )
							{
								lightCap.Dispose();
							}

							lightCap = null;
						}

						if ( this.wBuffer != null )
						{
							if ( !this.wBuffer.IsDisposed )
							{
								this.wBuffer.Dispose();
							}

							this.wBuffer = null;
						}

						if ( this.positionBuffer != null )
						{
							if ( !this.positionBuffer.IsDisposed )
							{
								this.positionBuffer.Dispose();
							}

							this.positionBuffer = null;
						}

						if ( this.subEntity != null )
						{
							if ( !this.subEntity.IsDisposed )
							{
								this.subEntity.Dispose();
							}

							this.subEntity = null;
						}

						if ( this.currentVertexData != null )
						{
							if ( !this.currentVertexData.IsDisposed )
							{
								this.currentVertexData.Dispose();
							}

							this.currentVertexData = null;
						}
					}

					// There are no unmanaged resources to release, but
					// if we add them, they need to be released here.
				}

				// If it is available, make the call to the
				// base class's Dispose(Boolean) method
				base.dispose( disposeManagedResources );
			}
Ejemplo n.º 35
0
		protected virtual void ReadGeometryVertexBuffer( BinaryReader reader, VertexData data )
		{
			// Index to bind this buffer to
			var bindIdx = ReadShort( reader );

			// Per-vertex size, must agree with declaration at this index
			var vertexSize = ReadShort( reader );

			// check for vertex data header
			var chunkID = ReadChunk( reader );

			if ( chunkID != MeshChunkID.GeometryVertexBufferData )
			{
				throw new AxiomException( "Can't find vertex buffer data area!" );
			}

			// check that vertex size agrees
			if ( data.vertexDeclaration.GetVertexSize( bindIdx ) != vertexSize )
			{
				throw new AxiomException( "Vertex buffer size does not agree with vertex declaration!" );
			}

			// create/populate vertex buffer
			var buffer = HardwareBufferManager.Instance.CreateVertexBuffer( data.vertexDeclaration.Clone( bindIdx ),
			                                                                data.vertexCount, this.mesh.VertexBufferUsage,
			                                                                this.mesh.UseVertexShadowBuffer );

			var bufferPtr = buffer.Lock( BufferLocking.Discard );

			ReadBytes( reader, data.vertexCount*vertexSize, bufferPtr );

			buffer.Unlock();

			// set binding
			data.vertexBufferBinding.SetBinding( bindIdx, buffer );
		}
Ejemplo n.º 36
0
		/// <summary>
		///		Internal method - given vertex data which could be from the	Mesh or
		///		any SubMesh, finds the corresponding SubEntity.
		/// </summary>
		/// <param name="original"></param>
		/// <returns></returns>
		protected SubEntity FindSubEntityForVertexData( VertexData original )
		{
			if ( original == this.mesh.SharedVertexData )
			{
				return null;
			}

			foreach ( var subEnt in this.subEntityList )
			{
				if ( original == subEnt.SubMesh.vertexData )
				{
					return subEnt;
				}
			}

			// none found
			return null;
		}
Ejemplo n.º 37
0
		protected override void ReadGeometry( BinaryReader reader, VertexData data )
		{
			short texCoordSet = 0;

			short bindIdx = 0;

			data.vertexStart = 0;
			data.vertexCount = ReadInt( reader );

			ReadGeometryPositions( bindIdx++, reader, data );

			if ( !IsEOF( reader ) )
			{
				// check out the next chunk
				var chunkID = ReadChunk( reader );

				// keep going as long as we have more optional buffer chunks
				while ( !IsEOF( reader ) &&
				        ( chunkID == MeshChunkID.GeometryNormals || chunkID == MeshChunkID.GeometryColors ||
				          chunkID == MeshChunkID.GeometryTexCoords ) )
				{
					switch ( chunkID )
					{
						case MeshChunkID.GeometryNormals:
							ReadGeometryNormals( bindIdx++, reader, data );
							break;

						case MeshChunkID.GeometryColors:
							ReadGeometryColors( bindIdx++, reader, data );
							break;

						case MeshChunkID.GeometryTexCoords:
							ReadGeometryTexCoords( bindIdx++, reader, data, texCoordSet++ );
							break;
					} // switch

					// read the next chunk
					if ( !IsEOF( reader ) )
					{
						chunkID = ReadChunk( reader );
					}
				} // while

				if ( !IsEOF( reader ) )
				{
					// skip back so the continuation of the calling loop can look at the next chunk
					// since we already read past it
					Seek( reader, -ChunkOverheadSize );
				}
			}
		}
Ejemplo n.º 38
0
		/// <summary>
		/// Add a set of vertex geometry data to the edge builder.
		/// </summary>
		/// <remarks>
		/// You must add at least one set of vertex data to the builder before invoking the
		/// <see name="Build"/> method.
		/// </remarks>
		/// <param name="vertexData">Vertex data to consider for edge detection.</param>
		public void AddVertexData( VertexData vertexData )
		{
			vertexDataList.Add( vertexData );
		}
Ejemplo n.º 39
0
        protected void SetPointsImpl(List <Vector3> points, List <ColorEx> colors, List <List <VertexBoneAssignment> > boneAssignments)
        {
            if (colors != null && points.Count != colors.Count)
            {
                throw new Exception("Invalid parameters to SetPoints.  Point list length does not match colors list length");
            }
            Vector3 min = Vector3.Zero;
            Vector3 max = Vector3.Zero;

            // set up vertex data
            vertexData = new VertexData();

            // set up vertex declaration
            VertexDeclaration vertexDeclaration = vertexData.vertexDeclaration;
            int currentOffset = 0;

            // always need positions
            vertexDeclaration.AddElement(0, currentOffset, VertexElementType.Float3, VertexElementSemantic.Position);
            currentOffset += VertexElement.GetTypeSize(VertexElementType.Float3);
            int colorOffset = currentOffset / sizeof(float);

            if (colors != null)
            {
                vertexDeclaration.AddElement(0, currentOffset, VertexElementType.Color, VertexElementSemantic.Diffuse);
                currentOffset += VertexElement.GetTypeSize(VertexElementType.Color);
            }
            int boneIndexOffset = currentOffset / sizeof(float);

            if (boneAssignments != null)
            {
                vertexDeclaration.AddElement(0, currentOffset, VertexElementType.UByte4, VertexElementSemantic.BlendIndices);
                currentOffset += VertexElement.GetTypeSize(VertexElementType.UByte4);
            }
            int boneWeightOffset = currentOffset / sizeof(float);

            if (boneAssignments != null)
            {
                vertexDeclaration.AddElement(0, currentOffset, VertexElementType.Float4, VertexElementSemantic.BlendWeights);
                currentOffset += VertexElement.GetTypeSize(VertexElementType.Float4);
            }
            int stride = currentOffset / sizeof(float);

            vertexData.vertexCount = points.Count;

            // allocate vertex buffer
            HardwareVertexBuffer vertexBuffer = HardwareBufferManager.Instance.CreateVertexBuffer(vertexDeclaration.GetVertexSize(0), vertexData.vertexCount, BufferUsage.StaticWriteOnly);

            // set up the binding, one source only
            VertexBufferBinding binding = vertexData.vertexBufferBinding;

            binding.SetBinding(0, vertexBuffer);

            // Generate vertex data
            unsafe {
                // lock the vertex buffer
                IntPtr data = vertexBuffer.Lock(BufferLocking.Discard);

                byte * pData  = (byte *)data.ToPointer();
                float *pFloat = (float *)pData;
                uint * pInt   = (uint *)pData;
                for (int i = 0; i < points.Count; ++i)
                {
                    Vector3 vec = points[i];
                    // assign to geometry
                    pFloat[stride * i]     = vec.x;
                    pFloat[stride * i + 1] = vec.y;
                    pFloat[stride * i + 2] = vec.z;
                    if (colors != null)
                    {
                        // assign to diffuse
                        pInt[stride * i + colorOffset] = Root.Instance.RenderSystem.ConvertColor(colors[i]);
                    }
                    if (boneAssignments != null)
                    {
                        for (int j = 0; j < 4; ++j)
                        {
                            pData[4 * (stride * i + boneIndexOffset) + j] = (byte)(boneAssignments[i][j].boneIndex);
                            pFloat[stride * i + boneWeightOffset + j]     = boneAssignments[i][j].weight;
                        }
                    }
                }
                // unlock the buffer
                vertexBuffer.Unlock();
            } // unsafe

            for (int i = 0; i < points.Count; ++i)
            {
                Vector3 vec = points[i];
                // Also update the bounding sphere radius
                float len = vec.Length;
                if (len > boundingSphereRadius)
                {
                    boundingSphereRadius = len;
                }
                // Also update the bounding box
                if (vec.x < min.x)
                {
                    min.x = vec.x;
                }
                if (vec.y < min.y)
                {
                    min.y = vec.y;
                }
                if (vec.z < min.z)
                {
                    min.z = vec.z;
                }
                if (vec.x > max.x)
                {
                    max.x = vec.x;
                }
                if (vec.y > max.y)
                {
                    max.y = vec.y;
                }
                if (vec.z > max.z)
                {
                    max.z = vec.z;
                }
            }

            // Set the SimpleRenderable bounding box
            box = new AxisAlignedBox(min, max);
        }