Exemple #1
0
        /// <summary>
        /// Generate Tangent BiNormal from an existing vertex/index buffer.
        /// </summary>
        /// <param name="vertexDeclaration">The vertex declaration of the vertex buffer passed by parameters.</param>
        /// <param name="vertexBufferData">The vertex buffer.</param>
        /// <param name="vertexCount">The vertex count.</param>
        /// <param name="vertexOffset">The vertex offset.</param>
        /// <param name="vertexStride">The vertex stride. If 0, It takes the stride from the vertex declaration</param>
        /// <param name="indexData">The index data.</param>
        /// <param name="is32BitIndex">if set to <c>true</c> [is32 bit index].</param>
        /// <param name="indexCountArg">The index count argument.</param>
        /// <returns>A new vertex buffer with its new layout.</returns>
        public static unsafe VertexTransformResult GenerateTangentBinormal(VertexDeclaration vertexDeclaration, IntPtr vertexBufferData, int vertexCount, int vertexOffset, int vertexStride, IntPtr indexData, bool is32BitIndex, int indexCountArg)
        {
            if (vertexDeclaration == null)
            {
                throw new ArgumentNullException("vertexDeclaration");
            }
            if (vertexBufferData == IntPtr.Zero)
            {
                throw new ArgumentNullException("vertexBufferData");
            }
            if (vertexCount <= 0)
            {
                throw new ArgumentOutOfRangeException("vertexCount", "vertexCount must be > 0");
            }
            if (vertexStride < 0)
            {
                throw new ArgumentOutOfRangeException("vertexStride", "vertexStride must be >= 0");
            }
            if (indexData != IntPtr.Zero && indexCountArg < 0)
            {
                throw new ArgumentOutOfRangeException("indexCountArg", "indexCountArg must be >= 0");
            }

            // Get the stride from the vertex declaration if necessary
            if (vertexStride == 0)
            {
                vertexStride = vertexDeclaration.VertexStride;
            }

            var indexBufferBinding = indexData;

            var oldVertexStride = vertexStride;
            var bufferData      = vertexBufferData;

            // TODO: Usage index in key
            var offsetMapping = vertexDeclaration
                                .EnumerateWithOffsets()
                                .ToDictionary(x => x.VertexElement.SemanticAsText, x => x.Offset);

            var positionOffset = offsetMapping["POSITION"];
            var uvOffset       = offsetMapping[VertexElementUsage.TextureCoordinate];
            var normalOffset   = offsetMapping[VertexElementUsage.Normal];

            // Add tangent to vertex declaration
            var vertexElements = vertexDeclaration.VertexElements.ToList();

            if (!offsetMapping.ContainsKey(VertexElementUsage.Tangent))
            {
                vertexElements.Add(VertexElement.Tangent <Vector4>());
            }
            var newVertexDeclaration = new VertexDeclaration(vertexElements.ToArray());
            var newVertexStride      = newVertexDeclaration.VertexStride;

            // Update mapping
            offsetMapping = newVertexDeclaration
                            .EnumerateWithOffsets()
                            .ToDictionary(x => x.VertexElement.SemanticAsText, x => x.Offset);

            var tangentOffset = offsetMapping[VertexElementUsage.Tangent];

            var newBufferData = new byte[vertexCount * newVertexStride];

            var tangents   = new Vector3[vertexCount];
            var bitangents = new Vector3[vertexCount];

            byte *indexBufferStart = (byte *)indexData;
            byte *oldBuffer        = (byte *)bufferData + vertexOffset;

            fixed(byte *newBuffer = newBufferData)
            {
                var indexBuffer32 = indexBufferBinding != IntPtr.Zero && is32BitIndex ? (int *)indexBufferStart : null;
                var indexBuffer16 = indexBufferBinding != IntPtr.Zero && !is32BitIndex ? (short *)indexBufferStart : null;

                var indexCount = indexBufferBinding != IntPtr.Zero ? indexCountArg : vertexCount;

                for (int i = 0; i < indexCount; i += 3)
                {
                    // Get indices
                    int index1 = i + 0;
                    int index2 = i + 1;
                    int index3 = i + 2;

                    if (indexBuffer32 != null)
                    {
                        index1 = indexBuffer32[index1];
                        index2 = indexBuffer32[index2];
                        index3 = indexBuffer32[index3];
                    }
                    else if (indexBuffer16 != null)
                    {
                        index1 = indexBuffer16[index1];
                        index2 = indexBuffer16[index2];
                        index3 = indexBuffer16[index3];
                    }

                    int vertexOffset1 = index1 * oldVertexStride;
                    int vertexOffset2 = index2 * oldVertexStride;
                    int vertexOffset3 = index3 * oldVertexStride;

                    // Get positions
                    var position1 = (Vector3 *)&oldBuffer[vertexOffset1 + positionOffset];
                    var position2 = (Vector3 *)&oldBuffer[vertexOffset2 + positionOffset];
                    var position3 = (Vector3 *)&oldBuffer[vertexOffset3 + positionOffset];

                    // Get texture coordinates
                    var uv1 = (Vector2 *)&oldBuffer[vertexOffset1 + uvOffset];
                    var uv2 = (Vector2 *)&oldBuffer[vertexOffset2 + uvOffset];
                    var uv3 = (Vector2 *)&oldBuffer[vertexOffset3 + uvOffset];

                    // Calculate position and UV vectors from vertex 1 to vertex 2 and 3
                    var edge1   = *position2 - *position1;
                    var edge2   = *position3 - *position1;
                    var uvEdge1 = *uv2 - *uv1;
                    var uvEdge2 = *uv3 - *uv1;

                    var dR = uvEdge1.X * uvEdge2.Y - uvEdge2.X * uvEdge1.Y;

                    // Workaround to handle degenerated case
                    // TODO: We need to understand more how we can handle this more accurately
                    if (MathUtil.IsZero(dR))
                    {
                        dR = 1;
                    }

                    var r = 1.0f / dR;
                    var t = (uvEdge2.Y * edge1 - uvEdge1.Y * edge2) * r;
                    var b = (uvEdge1.X * edge2 - uvEdge2.X * edge1) * r;

                    // Contribute to every vertex
                    tangents[index1] += t;
                    tangents[index2] += t;
                    tangents[index3] += t;

                    bitangents[index1] += b;
                    bitangents[index2] += b;
                    bitangents[index3] += b;
                }

                var oldVertexOffset = 0;
                var newVertexOffset = 0;

                for (int i = 0; i < vertexCount; ++i)
                {
                    Utilities.CopyMemory(new IntPtr(&newBuffer[newVertexOffset]), new IntPtr(&oldBuffer[oldVertexOffset]), oldVertexStride);

                    var normal        = *(Vector3 *)&oldBuffer[oldVertexOffset + normalOffset];
                    var newTangentPtr = ((float *)(&newBuffer[newVertexOffset + tangentOffset]));

                    var tangent   = -tangents[i];
                    var bitangent = bitangents[i];

                    // Gram-Schmidt orthogonalize
                    var newTangentUnormalized = tangent - normal * Vector3.Dot(normal, tangent);
                    var length = newTangentUnormalized.Length();

                    // Workaround to handle degenerated case
                    // TODO: We need to understand more how we can handle this more accurately
                    if (MathUtil.IsZero(length))
                    {
                        tangent = Vector3.Cross(normal, Vector3.UnitX);
                        if (MathUtil.IsZero(tangent.Length()))
                        {
                            tangent = Vector3.Cross(normal, Vector3.UnitY);
                        }
                        tangent.Normalize();
                        *((Vector3 *)newTangentPtr) = tangent;
                        bitangent = Vector3.Cross(normal, tangent);
                    }
                    else
                    {
                        *((Vector3 *)newTangentPtr) = newTangentUnormalized / length;
                    }

                    // Calculate handedness
                    newTangentPtr[3] = Vector3.Dot(Vector3.Cross(normal, tangent), bitangent) < 0.0f ? -1.0f : 1.0f;

                    oldVertexOffset += oldVertexStride;
                    newVertexOffset += newVertexStride;
                }

                return(new VertexTransformResult(newVertexDeclaration, newBufferData));
            }
        }
Exemple #2
0
        /// <summary>
        /// Generates multi texture coordinates for an existing vertex buffer. See remarks.
        /// </summary>
        /// <param name="vertexDeclaration">The vertex declaration.</param>
        /// <param name="vertexBufferData">The vertex buffer data.</param>
        /// <param name="vertexCount">The vertex count.</param>
        /// <param name="vertexOffset">The vertex offset.</param>
        /// <param name="vertexStride">The vertex stride.</param>
        /// <param name="maxTexcoord">The maximum texcoord.</param>
        /// <returns>A new vertex buffer with additional texture coordinates.</returns>
        /// <exception cref="System.ArgumentNullException">
        /// vertexDeclaration
        /// or
        /// vertexBufferData
        /// </exception>
        /// <exception cref="System.ArgumentOutOfRangeException">
        /// vertexCount;vertexCount must be > 0
        /// or
        /// vertexStride;vertexStride must be >= 0
        /// or
        /// maxTexcoord;maxTexcoord must be > 0
        /// </exception>
        /// <exception cref="System.InvalidOperationException">The vertex buffer must contain at least the TEXCOORD</exception>
        /// <remarks>
        /// The original vertex buffer must contain at least a TEXCOORD[0-9] attribute in order for this method to work.
        /// This method will copy the value of the first existing TEXCOORD found in the vertex buffer to the newly created TEXCOORDS.
        /// </remarks>
        public unsafe static VertexTransformResult GenerateMultiTextureCoordinates(VertexDeclaration vertexDeclaration, IntPtr vertexBufferData, int vertexCount, int vertexOffset, int vertexStride, int maxTexcoord = 9)
        {
            if (vertexDeclaration == null)
            {
                throw new ArgumentNullException("vertexDeclaration");
            }
            if (vertexBufferData == IntPtr.Zero)
            {
                throw new ArgumentNullException("vertexBufferData");
            }
            if (vertexCount <= 0)
            {
                throw new ArgumentOutOfRangeException("vertexCount", "vertexCount must be > 0");
            }
            if (vertexStride < 0)
            {
                throw new ArgumentOutOfRangeException("vertexStride", "vertexStride must be >= 0");
            }
            if (maxTexcoord < 0)
            {
                throw new ArgumentOutOfRangeException("maxTexcoord", "maxTexcoord must be > 0");
            }

            // Get the stride from the vertex declaration if necessary
            if (vertexStride == 0)
            {
                vertexStride = vertexDeclaration.VertexStride;
            }

            // TODO: Usage index in key
            var offsetMapping = vertexDeclaration
                                .EnumerateWithOffsets()
                                .ToDictionary(x => x.VertexElement.SemanticAsText, x => x.Offset);

            var newVertexElements = new List <VertexElement>();

            int vertexUVOffset = -1;

            // Use R16G16_SNorm as it is supported from HW Level 9.1
            // See https://msdn.microsoft.com/en-us/library/windows/desktop/ff471324%28v=vs.85%29.aspx
            const PixelFormat DefaultUVFormat = PixelFormat.R16G16_SNorm;
            var newUvSize = DefaultUVFormat.SizeInBytes();

            for (int i = 0; i <= maxTexcoord; i++)
            {
                var vertexElement = VertexElement.TextureCoordinate(i, DefaultUVFormat);
                var semantic      = vertexElement.SemanticAsText;
                if (offsetMapping.ContainsKey(semantic))
                {
                    if (vertexUVOffset < 0)
                    {
                        vertexUVOffset = offsetMapping[semantic];
                    }
                }
                else
                {
                    newVertexElements.Add(vertexElement);
                }
            }

            if (vertexUVOffset < 0)
            {
                throw new InvalidOperationException("The vertex buffer must contain at least the TEXCOORD");
            }

            var newVertexStride = vertexStride + newVertexElements.Count * newUvSize;
            var newVertexBuffer = new byte[newVertexStride * vertexCount];

            byte *oldBuffer = (byte *)vertexBufferData + vertexOffset;

            fixed(byte *newBuffer = newVertexBuffer)
            {
                var oldVertexOffset = 0;
                var newVertexOffset = 0;

                for (int i = 0; i < vertexCount; ++i)
                {
                    Utilities.CopyMemory(new IntPtr(&newBuffer[newVertexOffset]), new IntPtr(&oldBuffer[oldVertexOffset]), vertexStride);

                    var textureCoord = *(Vector2 *)&oldBuffer[oldVertexOffset + vertexUVOffset];
                    for (int j = 0; j < newVertexElements.Count; j++)
                    {
                        var target = ((Half2 *)(&newBuffer[newVertexOffset + vertexStride + j * newUvSize]));
                        *   target = (Half2)textureCoord;
                    }

                    oldVertexOffset += vertexStride;
                    newVertexOffset += newVertexStride;
                }
            }

            var allVertexElements = new List <VertexElement>(vertexDeclaration.VertexElements);

            allVertexElements.AddRange(newVertexElements);

            return(new VertexTransformResult(new VertexDeclaration(allVertexElements.ToArray()), newVertexBuffer));
        }