示例#1
0
        public void DrawLine( ref PixelBuffer pb, ref RasterLine line, bool useFixed )
        {
            if( useFixed == true )
                throw new NotImplementedException( "fixed math not implemented" );

            int x0 = ( int )( line.Vertices[ line.v0 ].PX + 0.5f );
            int y0 = ( int )( line.Vertices[ line.v0 ].PY + 0.5f );
            int x1 = ( int )( line.Vertices[ line.v1 ].PX + 0.5f );
            int y1 = ( int )( line.Vertices[ line.v1 ].PY + 0.5f );
            if( ClipLine( ref pb, ref x0, ref y0, ref x1, ref y1 ) == false )
                return;
            if( ( line.VertexFormat & RasterVertexFormat.Color ) == RasterVertexFormat.Color )
            {
            #if false
                this.DrawLineVaryColor( ref pb, ref line );
            #else
                line.Color[ 0 ] = line.Vertices[ line.v0 ].R;
                line.Color[ 1 ] = line.Vertices[ line.v0 ].G;
                line.Color[ 2 ] = line.Vertices[ line.v0 ].B;
                line.Color[ 3 ] = line.Vertices[ line.v0 ].A;
                this.DrawLineSolidColor( ref pb, ref line, x0, y0, x1, y1 );
            #endif
            }
            else
            {
                this.DrawLineSolidColor( ref pb, ref line, x0, y0, x1, y1 );
            }
        }
示例#2
0
 private void DrawLineVaryColor( ref PixelBuffer pb, ref RasterLine line, int x0, int y0, int x1, int y1 )
 {
 }
示例#3
0
        private void DrawLineSolidColor( ref PixelBuffer pb, ref RasterLine line, int x0, int y0, int x1, int y1 )
        {
            byte[] color = new byte[ 4 ]{
                ( byte )( line.Color[ 0 ] * 255.0f ),
                ( byte )( line.Color[ 1 ] * 255.0f ),
                ( byte )( line.Color[ 2 ] * 255.0f ),
                ( byte )( line.Color[ 3 ] * 255.0f ),
            };

            // pre-compute first pixel address in video buffer based on 16bit data
            int pbOffset = pb.Offset + ( y0 * pb.Stride ) + ( x0 * pb.BytesPerPixel );

            // compute horizontal and vertical deltas
            int dx = x1 - x0; // diff in x's
            int dy = y1 - y0; // diff in y's
            // test which direction the line is going in i.e. slope angle
            int x_inc; // step along x
            if( dx >= 0 )
            {
                // moving right
                x_inc = pb.BytesPerPixel;
            }
            else
            {
                // moving left
                x_inc = -pb.BytesPerPixel;
                dx = -dx;  // need absolute value
            }
            // test y component of slope
            int y_inc; // step along y
            if( dy >= 0 )
            {
                // moving down
                y_inc = pb.Stride;
            }
            else
            {
                // moving up
                y_inc = -pb.Stride;
                dy = -dy;  // need absolute value
            }
            // compute (dx,dy) * 2
            int dx2 = dx * 2;
            int dy2 = dy * 2;
            // now based on which delta is greater we can draw the line
            if( dx > dy )
            {
                int error = dy2 - dx; // the discriminant i.e. error i.e. decision variable
                // draw the line
                if( pb.BytesPerPixel == 3 )
                {
                    for( int index = 0; index <= dx; index++ )
                    {
                        // set the pixel
                        pb.Buffer[ pbOffset ] = color[ 0 ];
                        pb.Buffer[ pbOffset + 1 ] = color[ 1 ];
                        pb.Buffer[ pbOffset + 2 ] = color[ 2 ];
                        // test if error has overflowed
                        if( error >= 0 )
                        {
                            error -= dx2;
                            // move to next line
                            pbOffset += y_inc;
                        }
                        // adjust the error term
                        error += dy2;
                        // move to the next pixel
                        pbOffset += x_inc;
                    }
                }
                else
                {
                    for( int index = 0; index <= dx; index++ )
                    {
                        pb.Buffer[ pbOffset ] = color[ 0 ];
                        pb.Buffer[ pbOffset + 1 ] = color[ 1 ];
                        pb.Buffer[ pbOffset + 2 ] = color[ 2 ];
                        pb.Buffer[ pbOffset + 3 ] = color[ 3 ];
                        if( error >= 0 )
                        {
                            error -= dx2;
                            pbOffset += y_inc;
                        }
                        error += dy2;
                        pbOffset += x_inc;
                    }
                }
            }
            else
            {
                int error = dx2 - dy; // the discriminant i.e. error i.e. decision variable
                // draw the line
                if( pb.BytesPerPixel == 3 )
                {
                    for( int index = 0; index <= dy; index++ )
                    {
                        // set the pixel
                        pb.Buffer[ pbOffset ] = color[ 0 ];
                        pb.Buffer[ pbOffset + 1 ] = color[ 1 ];
                        pb.Buffer[ pbOffset + 2 ] = color[ 2 ];
                        // test if error overflowed
                        if( error >= 0 )
                        {
                            error -= dy2;
                            // move to next line
                            pbOffset += x_inc;
                        }
                        // adjust the error term
                        error += dx2;
                        // move to the next pixel
                        pbOffset += y_inc;
                    }
                }
                else
                {
                    for( int index = 0; index <= dy; index++ )
                    {
                        pb.Buffer[ pbOffset ] = color[ 0 ];
                        pb.Buffer[ pbOffset + 1 ] = color[ 1 ];
                        pb.Buffer[ pbOffset + 2 ] = color[ 2 ];
                        pb.Buffer[ pbOffset + 3 ] = color[ 3 ];
                        if( error >= 0 )
                        {
                            error -= dy2;
                            pbOffset += x_inc;
                        }
                        error += dx2;
                        pbOffset += y_inc;
                    }
                }
            }
        }
示例#4
0
        public void glDrawElements( int mode, int count, ushort[] indices, int offset )
        {
            if( Ptr_VertexEnabled == false )
                return;

            float viewportWidthHalf = Viewport_Width / 2.0f;
            float viewportHeightHalf = Viewport_Height / 2.0f;
            float viewportAspectRatio = Viewport_Width / ( float )Viewport_Height;
            Matrix projectionMatrix = M_Proj[ M_ProjIndex ];
            bool projectionIsAffine = projectionMatrix.IsAffine;
            Matrix modelViewMatrix = M_ModelView[ M_ModelViewIndex ];
            bool modelViewIsIdentity = modelViewMatrix.IsIdentity;
            bool modelViewIsAffine = modelViewMatrix.IsAffine;
            Matrix textureMatrix = M_Texture[ M_TextureIndex ];
            bool textureIsIdentity = textureMatrix.IsIdentity;
            bool textureIsAffine = textureMatrix.IsAffine;
            Matrix modelProjMatrix;
            Matrix.Multiply( ref modelViewMatrix, ref projectionMatrix, out modelProjMatrix );
            bool modelProjMatrixIsAffine = modelProjMatrix.IsAffine;
            Matrix finalProjectionMatrix;
            Matrix.Multiply( ref projectionMatrix, ref M_Viewport, out finalProjectionMatrix );

            RasterVertexFormat vertexFormat = RasterVertexFormat.Position | RasterVertexFormat.Normal;
            if( ( State_ShadeModel == GL_SMOOTH ) && ( Ptr_ColorEnabled == true ) )
                vertexFormat |= RasterVertexFormat.Color;
            if( ( State_Texture[ 0 ] != null ) && ( Ptr_TexCoordEnabled == true ) ) // TODO: something with tex coord state?
                vertexFormat |= RasterVertexFormat.Texture;

            RasterPolygon polygon = new RasterPolygon();
            polygon.VertexFormat = vertexFormat;
            polygon.Vertices = _vertices;
            polygon.Color = ( float[] )State_Color.Clone();
            polygon.PerspectiveTexturing = ( State_PerspectiveCorrection == GL_NICEST );
            polygon.Textures = new TextureObject[ RasterPolygon.MaximumTextureStages ]{
                State_Texture[ 0 ],
                State_Texture[ 1 ]
            };

            #if DRAW_LINE
            RasterLine line = new RasterLine();
            line.VertexFormat = polygon.VertexFormat;
            line.Vertices = polygon.Vertices;
            line.Color = ( float[] )State_Color.Clone();
            #endif

            // Build RasterVertex buffer from input
            // TODO: maybe have different loops for different modes - depends on if this is a bottleneck with all the compares/etc
            for( int n = offset, v = 0; n < offset + count; n++, v++ )
            {
                int index = indices[ n ];
                {
                    int idx = Ptr_Vertex.Offset + ( index * ( Ptr_Vertex.Stride + Ptr_Vertex.Size ) );
                    _vertices[ v ].W = 1.0f;
                    _vertices[ v ].X = Ptr_Vertex.Floats[ idx ];
                    _vertices[ v ].Y = Ptr_Vertex.Floats[ idx + 1 ];
                    // TODO: make this faster - eliminate switch
                    if( Ptr_Vertex.Size >= 3 )
                    {
                        _vertices[ v ].Z = Ptr_Vertex.Floats[ idx + 2 ];
                        if( Ptr_Vertex.Size == 4 )
                            _vertices[ v ].W = Ptr_Vertex.Floats[ idx + 3 ];
                    }
                }
                if( Ptr_NormalEnabled == true )
                {
                    int idx = Ptr_Normal.Offset + ( index * ( Ptr_Normal.Stride + Ptr_Normal.Size ) );
                    _vertices[ v ].NX = Ptr_Normal.Floats[ idx ];
                    _vertices[ v ].NY = Ptr_Normal.Floats[ idx + 1 ];
                    _vertices[ v ].NZ = Ptr_Normal.Floats[ idx + 2 ];
                }
                else
                {
                    _vertices[ v ].NX = State_Normal.X; _vertices[ v ].NY = State_Normal.Y; _vertices[ v ].NZ = State_Normal.Z;
                }
                if( Ptr_ColorEnabled == true )
                {
                    int idx = Ptr_Color.Offset + ( index * ( Ptr_Color.Stride + Ptr_Color.Size ) );
                    _vertices[ v ].R = Ptr_Color.Floats[ idx ];
                    _vertices[ v ].G = Ptr_Color.Floats[ idx + 1 ];
                    _vertices[ v ].B = Ptr_Color.Floats[ idx + 2 ];
                    _vertices[ v ].A = Ptr_Color.Floats[ idx + 3 ];
                }
                if( Ptr_TexCoordEnabled == true )
                {
                    int idx = Ptr_TexCoord[ 0 ].Offset + ( index * ( Ptr_TexCoord[ 0 ].Stride + Ptr_TexCoord[ 0 ].Size ) );
                    _vertices[ v ].S = Ptr_TexCoord[ 0 ].Floats[ idx ];
                    _vertices[ v ].T = Ptr_TexCoord[ 0 ].Floats[ idx + 1 ];
            #if false
                    if( Ptr_TexCoord[ 0 ].Size >= 3 )
                    {
                        _vertices[ v ].R = Ptr_TexCoord[ 0 ].Floats[ idx + 2 ];
                        if( Ptr_TexCoord[ 0 ].Size == 4 )
                            _vertices[ v ].Q = Ptr_TexCoord[ 0 ].Floats[ idx + 3 ];
                        else
                            _vertices[ v ].Q = 1.0f;
                    }
                    else
                    {
                        _vertices[ v ].R = 0.0f;
                        _vertices[ v ].Q = 1.0f;
                    }
            #endif
                }
                else
                {
                    _vertices[ v ].S = State_TexCoord[ 0 ][ 0 ]; _vertices[ v ].T = State_TexCoord[ 0 ][ 1 ];
            #if false
                    _vertices[ v ].R = State_TexCoord[ 0 ][ 2 ]; _vertices[ v ].Q = State_TexCoord[ 0 ][ 3 ];
            #endif
                }
                if( ( vertexFormat & RasterVertexFormat.Texture ) == RasterVertexFormat.Texture )
                {
                    if( textureIsIdentity == false )
                    {
                        float v0 = _vertices[ v ].S;
                        float v1 = _vertices[ v ].T;
            #if true
                        _vertices[ v ].S = v0 * textureMatrix.M11 + v1 * textureMatrix.M21 + textureMatrix.M41;
                        _vertices[ v ].T = v0 * textureMatrix.M12 + v1 * textureMatrix.M22 + textureMatrix.M42;
            #else
                        float v2 = v.R;
                        float v3 = v.Q;
                        _vertices[ v ].S = v0 * textureMatrix.M11 + v1 * textureMatrix.M21 + v2 * textureMatrix.M31 + v3 * textureMatrix.M41;
                        _vertices[ v ].T = v0 * textureMatrix.M12 + v1 * textureMatrix.M22 + v2 * textureMatrix.M32 + v3 * textureMatrix.M42;
                        _vertices[ v ].R = v0 * tmat.M13 + v1 * tmat.M23 + v2 * tmat.M33 + v3 * tmat.M42;
                        _vertices[ v ].Q = v0 * tmat.M14 + v1 * tmat.M24 + v2 * tmat.M34 + v3 * tmat.M43;
            #endif
                    }
                    // RasterVertex expects texture coordinates multiplied out
                    _vertices[ v ].S *= State_Texture[ 0 ].Width;
                    _vertices[ v ].T *= State_Texture[ 0 ].Height;
                    // TODO: clamp texture coords here?
                }

                // Transform
                Viewport_Far = 100.0f;
                Viewport_Near = 0.1f;
                {
                    // World -> Model/View
                    //Vector4 vec_w = new Vector4()
                    Vector3 vec_w = new Vector3()
                    {
                        X = _vertices[ v ].X,
                        Y = _vertices[ v ].Y,
                        Z = _vertices[ v ].Z,
                        //W = 1.0f,
                    };
                    //Vector4 vec_c;
                    Vector3 vec_c;
                    Matrix.TransformAffine( ref modelViewMatrix, modelViewIsAffine, ref vec_w, out vec_c );
                    //Matrix.Multiply( ref modelViewMatrix, ref vec_w, out vec_c );
                    // Clip against near/far plane
                    if( ( vec_c.Z > Viewport_Far ) || ( vec_c.Z < Viewport_Near ) )
                        _vertices[ v ].State = RasterVertexState.Clipped;
                    else
                    {
                        // Clip against view frustum
                        // TODO: clipping of vertices
                        _vertices[ v ].State = RasterVertexState.Normal;
                    }

                    _vertices[ v ].X = vec_c.X;
                    _vertices[ v ].Y = vec_c.Y;
                    _vertices[ v ].Z = vec_c.Z;

                    // Model/View -> Screen
                    Vector3 vec_s;
                    Matrix.TransformAffine( ref projectionMatrix, projectionIsAffine, ref vec_c, out vec_s );
                    //Vector4 vec_s;
                    //Matrix.Multiply( ref projectionMatrix, ref vec_c, out vec_s );
                    //Matrix.TransformAffine( ref modelProjMatrix, modelProjMatrixIsAffine, ref vec_w, out vec_s );
                    _vertices[ v ].PX = vec_s.X;
                    _vertices[ v ].PY = vec_s.Y;
                    //_vertices[ v ].Z = vec_s.Z;
                    //float det = 1.0f / ( vec_c.Z * projectionMatrix.M34 );
                    //_vertices[ v ].PX = ( vec_c.X * projectionMatrix.M11 ) * det;
                    //_vertices[ v ].PY = ( vec_c.Y * projectionMatrix.M22 ) * det;

                    // Adjust to screen space
                    _vertices[ v ].PX = ( _vertices[ v ].PX + viewportWidthHalf );
                    _vertices[ v ].PY = -_vertices[ v ].PY * viewportAspectRatio + viewportHeightHalf;
                }
            }

            /*
            //Matrix.TransformAffine( ref _projectionMatrix, false, ref cp, out tp );
            // UNSAFE: no clue if this works for anything but the settings I had when I wrote it
            float det = 1.0f / ( cp.Z * projectionMatrix.M34 );
            tp.X = ( cp.X * projectionMatrix.M11 ) * det;
            tp.Y = ( cp.Y * projectionMatrix.M22 ) * det;

            //// World->Screen
            //Vector3 tp;
            //Matrix.TransformAffine( ref finalProjectionMatrix, finalProjectionMatrix.IsAffine, ref tx, out tp );
            //// UNSAFE: no clue if this works for anything but the settings I had when I wrote it
            ////float det = 1.0f / ( tx.Z * projectionMatrix.M34 );
            ////tp.X = ( tx.X * projectionMatrix.M11 ) * det;
            ////tp.Y = ( tx.Y * projectionMatrix.M22 ) * det;
            ////tp.Z = ( tx.Z * projectionMatrix.M33 ) * det;
             */

            PixelBuffer pb;
            this.RasterBuffer.LockPixels( out pb );
            switch( mode )
            {
                case GL_POINTS:
                    break;
                case GL_LINES:
                    break;
                case GL_LINE_STRIP:
                case GL_LINE_LOOP:
                    break;
                case GL_TRIANGLES:
                    for( int n = offset; n < offset + count; n += 3 )
                    {
                        polygon.v0 = indices[ n ];
                        polygon.v1 = indices[ n + 1 ];
                        polygon.v2 = indices[ n + 2 ];

                        // Clipping
                        // NOTE: vertices that are clipped will have clip flags set already
                        if( ( _vertices[ polygon.v0 ].State == RasterVertexState.Clipped ) && ( _vertices[ polygon.v1 ].State == RasterVertexState.Clipped ) && ( _vertices[ polygon.v2 ].State == RasterVertexState.Clipped ) )
                            continue;

                        // Backface culling
                        if( State_CullFace == true )
                        {
                            // TODO: inline this math?
                            // u = v0->v1, v = v0->v2, n = u x v
                            Vector3 u = new Vector3()
                            {
                                X = _vertices[ polygon.v1 ].X - _vertices[ polygon.v0 ].X,
                                Y = _vertices[ polygon.v1 ].Y - _vertices[ polygon.v0 ].Y,
                                Z = _vertices[ polygon.v1 ].Z - _vertices[ polygon.v0 ].Z,
                            };
                            Vector3 v = new Vector3()
                            {
                                X = _vertices[ polygon.v2 ].X - _vertices[ polygon.v0 ].X,
                                Y = _vertices[ polygon.v2 ].Y - _vertices[ polygon.v0 ].Y,
                                Z = _vertices[ polygon.v2 ].Z - _vertices[ polygon.v0 ].Z,
                            };
                            Vector3 normal;
                            Vector3.CrossProduct( ref u, ref v, out normal );
                            float dot = ( normal.X * _vertices[ polygon.v0 ].X ) + ( normal.Y * _vertices[ polygon.v0 ].Y ) + ( normal.Z * _vertices[ polygon.v0 ].Z );
                            if( State_FrontFace == GL_CCW )
                                dot *= -1.0f;
                            if( State_CullFaceMode == GL_FRONT )
                                dot *= -1.0f;
                            // > 0 = visible, 0 = scathing, < 0 = invisible
                            if( dot <= 0.0f )
                            {
                                polygon.State = RasterPolygonState.BackfaceCulled;
                                continue;
                            }
                        }
                        else
                            polygon.State = RasterPolygonState.Valid;

                        // etc

                        this.RasterBuffer.DrawTriangle( ref pb, ref polygon, false );

            #if DRAW_LINE
                        line.v0 = polygon.v0; line.v1 = polygon.v1;
                        this.RasterBuffer.DrawLine( ref pb, ref line, false );
                        line.v0 = polygon.v1; line.v1 = polygon.v2;
                        this.RasterBuffer.DrawLine( ref pb, ref line, false );
                        line.v0 = polygon.v2; line.v1 = polygon.v0;
                        this.RasterBuffer.DrawLine( ref pb, ref line, false );
            #endif
                    }
                    break;
                case GL_TRIANGLE_STRIP:
                    break;
                case GL_TRIANGLE_FAN:
                    break;
            }
            this.RasterBuffer.UnlockPixels();
        }