Ejemplo n.º 1
0
        /// <summary>
        /// This is the method that actually does the work.
        /// </summary>
        /// <param name="DA">The DA object is used to retrieve from inputs and store in outputs.</param>
        protected override void SolveInstance(IGH_DataAccess DA)
        {
            Plane plane    = Plane.WorldXY;
            Curve perimCrv = null;

            coreCrvs     = new List <Curve>();
            rectangles   = new List <Rectangle3d>();
            obstacleCrvs = new List <Curve>();
            DA.GetData(IN_autoColor, ref autoColor);

            DA.GetData(IN_plane, ref plane);
            DA.GetData(IN_perimCrv, ref perimCrv);
            DA.GetDataList(IN_voxelRects, rectangles);
            DA.GetDataList(IN_obstacleCrvs, obstacleCrvs);
            bool coreReceived = DA.GetDataList(IN_coreCrvs, coreCrvs);

            _plan = new SmartPlan(perimCrv, coreCrvs, rectangles, obstacleCrvs, plane);

            Rhino.RhinoDoc   doc    = Rhino.RhinoDoc.ActiveDoc;
            Rhino.UnitSystem system = doc.ModelUnitSystem;
            _plan.projectUnits = system.ToString() == "Meters" ? 0 : 1;

            _plan.ComputeCovid();

            compromisedMetric = _plan.GetCovidMetric();

            DA.SetDataList(OUT_hit, compromisedMetric);
            DA.SetDataTree(OUT_lines, _plan.covidLines);
        }
Ejemplo n.º 2
0
        /// <summary>
        /// This is the method that actually does the work.
        /// </summary>
        /// <param name="DA">The DA object can be used to retrieve data from input parameters and
        /// to store data in output parameters.</param>
        protected override void SolveInstance(IGH_DataAccess DA)
        {
            DA.GetData <double>(0, ref sensorElevation);
            DA.GetData <int>(1, ref waterLevel);
            DA.GetData <int>(2, ref leftColumns);
            DA.GetData <int>(3, ref rightColumns);
            DA.GetData <int>(4, ref topRows);
            DA.GetData <int>(5, ref bottomRows);
            DA.GetData <int>(6, ref tickRate);
            DA.GetData <int>(7, ref averageFrames);
            DA.GetData <int>(8, ref blurRadius);

            switch (units.ToString())
            {
            case "Kilometers":
                unitsMultiplier = 0.0001;
                break;

            case "Meters":
                unitsMultiplier = 0.001;
                break;

            case "Decimeters":
                unitsMultiplier = 0.01;
                break;

            case "Centimeters":
                unitsMultiplier = 0.1;
                break;

            case "Millimeters":
                unitsMultiplier = 1;
                break;

            case "Inches":
                unitsMultiplier = 0.0393701;
                break;

            case "Feet":
                unitsMultiplier = 0.0328084;
                break;
            }
            sensorElevation /= unitsMultiplier;     // Standardise to mm to match sensor units

            Stopwatch timer = Stopwatch.StartNew(); //debugging

            if (this.kinectSensor == null)
            {
                KinectController.AddRef();
                this.kinectSensor = KinectController.sensor;
            }

            if (this.kinectSensor != null)
            {
                if (KinectController.depthFrameData != null)
                {
                    int trimmedWidth  = KinectController.depthWidth - leftColumns - rightColumns;
                    int trimmedHeight = KinectController.depthHeight - topRows - bottomRows;

                    // initialize all arrays
                    pointCloud = new Point3d[trimmedWidth * trimmedHeight];
                    int[]    depthFrameDataInt      = new int[trimmedWidth * trimmedHeight];
                    double[] averagedDepthFrameData = new double[trimmedWidth * trimmedHeight];

                    // initialize outputs
                    outputMesh = new List <Mesh>();
                    output     = new List <string>(); //debugging

                    Point3d        tempPoint      = new Point3d();
                    Core.PixelSize depthPixelSize = Core.GetDepthPixelSpacing(sensorElevation);

                    // trim the depth array and cast ushort values to int
                    Core.CopyAsIntArray(KinectController.depthFrameData, depthFrameDataInt, leftColumns, rightColumns, topRows, bottomRows, KinectController.depthHeight, KinectController.depthWidth);

                    averageFrames = averageFrames < 1 ? 1 : averageFrames; //make sure there is at least one frame in the render buffer

                    // reset everything when resizing Kinect's field of view or changing the amounts of frame to average across
                    if (renderBuffer.Count > averageFrames || quadMesh.Faces.Count != (trimmedWidth - 2) * (trimmedHeight - 2))
                    {
                        renderBuffer.Clear();
                        Array.Clear(runningSum, 0, runningSum.Length);
                        renderBuffer.AddLast(depthFrameDataInt);
                    }
                    else
                    {
                        renderBuffer.AddLast(depthFrameDataInt);
                    }

                    output.Add("Render buffer length:".PadRight(30, ' ') + renderBuffer.Count + " frames"); //debugging

                    // average across multiple frames
                    for (int pixel = 0; pixel < depthFrameDataInt.Length; pixel++)
                    {
                        if (depthFrameDataInt[pixel] > 200 && depthFrameDataInt[pixel] <= lookupTable.Length) //We have a valid pixel. TODO remove reference to the lookup table
                        {
                            runningSum[pixel] += depthFrameDataInt[pixel];
                        }
                        else
                        {
                            if (pixel > 0) //pixel is invalid and we have a neighbor to steal information from
                            {
                                runningSum[pixel] += depthFrameDataInt[pixel - 1];
                                renderBuffer.Last.Value[pixel] = depthFrameDataInt[pixel - 1]; //replace the zero value from the depth array with the one from the neighboring pixel
                            }
                            else //pixel is invalid and it is the first one in the list. (No neighbor on the left hand side, so we set it to the lowest point on the table)
                            {
                                runningSum[pixel] += (int)sensorElevation;
                                renderBuffer.Last.Value[pixel] = (int)sensorElevation;
                            }
                        }

                        averagedDepthFrameData[pixel] = runningSum[pixel] / renderBuffer.Count; //calculate average values

                        if (renderBuffer.Count >= averageFrames)
                        {
                            runningSum[pixel] -= renderBuffer.First.Value[pixel]; //subtract the oldest value from the sum
                        }
                    }

                    timer.Stop();
                    output.Add("Frames averaging: ".PadRight(30, ' ') + timer.ElapsedMilliseconds.ToString() + " ms");
                    timer.Restart();    //debugging

                    if (blurRadius > 1) //apply gaussian blur
                    {
                        GaussianBlurProcessor gaussianBlurProcessor = new GaussianBlurProcessor(blurRadius, trimmedWidth, trimmedHeight);
                        gaussianBlurProcessor.Apply(averagedDepthFrameData);
                        timer.Stop();
                        output.Add("Gaussian blurring: ".PadRight(30, ' ') + timer.ElapsedMilliseconds.ToString() + " ms");
                        timer.Restart(); //debugging
                    }

                    // Setup variables for the coloring process
                    Analysis.AnalysisManager.ComputeLookupTables(sensorElevation); // First-run computing of tables
                    var enabledMeshColoring = Analysis.AnalysisManager.GetEnabledMeshColoring();
                    var enabledColorTable   = enabledMeshColoring.lookupTable;
                    var hasColorTable       = enabledColorTable.Length > 0;                     // Setting the 'no analysis' option == empty table
                    vertexColors = new Color[hasColorTable ? trimmedWidth * trimmedHeight : 0]; // A 0-length array wont be used in meshing
                    var pixelsForAnalysis = new Point3d[4];

                    // Setup variables for per-pixel loop
                    pointCloud = new Point3d[trimmedWidth * trimmedHeight];
                    int arrayIndex = 0;
                    for (int rows = 0; rows < trimmedHeight; rows++)
                    {
                        for (int columns = 0; columns < trimmedWidth; columns++)
                        {
                            depthPoint  = averagedDepthFrameData[arrayIndex];
                            tempPoint.X = columns * -unitsMultiplier * depthPixelSize.x;
                            tempPoint.Y = rows * -unitsMultiplier * depthPixelSize.y;
                            tempPoint.Z = (depthPoint - sensorElevation) * -unitsMultiplier;

                            pointCloud[arrayIndex] = tempPoint; // Add new point to point cloud itself
                            if (hasColorTable)                  // Perform analysis as needed and lookup result in table
                            {
                                var pixelIndex = enabledMeshColoring.GetPixelIndexForAnalysis(tempPoint, pixelsForAnalysis);
                                vertexColors[arrayIndex] = enabledColorTable[pixelIndex];
                            }
                            arrayIndex++;
                        }
                    }

                    //keep only the desired amount of frames in the buffer
                    while (renderBuffer.Count >= averageFrames)
                    {
                        renderBuffer.RemoveFirst();
                    }

                    //debugging
                    timer.Stop();
                    output.Add("Point cloud generation/color: ".PadRight(30, ' ') + timer.ElapsedMilliseconds.ToString() + " ms");
                    timer.Restart(); //debugging

                    quadMesh = Core.CreateQuadMesh(quadMesh, pointCloud, vertexColors, trimmedWidth, trimmedHeight);
                    outputMesh.Add(quadMesh);

                    timer.Stop(); //debugging
                    output.Add("Meshing: ".PadRight(30, ' ') + timer.ElapsedMilliseconds.ToString() + " ms");
                }

                DA.SetDataList(0, outputMesh);
                DA.SetDataList(1, output); //debugging
            }

            if (tickRate > 0) // Allow users to force manual recalculation
            {
                base.OnPingDocument().ScheduleSolution(tickRate, new GH_Document.GH_ScheduleDelegate(ScheduleDelegate));
            }
        }
Ejemplo n.º 3
0
        public GHScale GetScale(Rhino.RhinoDoc rhinoDoc)
        {
            // Scale factor is based on assumption of feet based units.

            double scale = 1.0;

            Rhino.UnitSystem us    = rhinoDoc.ModelUnitSystem;
            string           units = us.ToString();

            scale = 1.0;
            switch (units)
            {
            case "None":
                scale = 1;
                break;

            case "Microns":
                scale = 1000000;
                break;

            case "Millimeters":
                scale = 1000;
                break;

            case "Centimeters":
                scale = 100;
                break;

            case "Meters":
                scale = 1;
                break;

            case "Kilometers":
                scale = 0.001;
                break;

            case "Microinches":
                scale = 39370100;
                break;

            case "Mils":
                scale = 39370.0787;
                break;

            case "Inches":
                scale = 39.3701;
                break;

            case "Feet":
                scale = 3.28084;
                break;

            case "Miles":
                scale = 0.000621371;
                break;

            case "Angstroms":
                scale = 10000000000;
                break;

            case "Nanometers":
                scale = 1000000000;
                break;

            case "Decimeters":
                scale = 10;
                break;

            case "Dekameters":
                scale = 0.1;
                break;

            case "Hectometers":
                scale = 0.01;
                break;

            case "Megameters":
                scale = 0.000001;
                break;

            case "Gigameters":
                scale = 0.000000001;
                break;

            case "Yards":
                scale = 1.09361;
                break;

            case "PrinterPoint":
                scale = 1;
                break;

            case "PrinterPica":
                scale = 1;
                break;

            case "NauticalMile":
                scale = 0.000539957;
                break;

            case "Astronomical":
                scale = 0.00000000000668458712;
                break;

            case "Lightyears":
                scale = 0.000000000000000105702341;
                break;

            case "Parsecs":
                scale = 0.0000000000000000324077929;
                break;

            default:
                break;
            }

            GHScale ghScale = new GHScale(units, scale);

            return(ghScale);
        }
Ejemplo n.º 4
0
        /// <summary>
        /// This is the method that actually does the work.
        /// </summary>
        /// <param name="DA">The DA object is used to retrieve from inputs and store in outputs.</param>
        protected override void SolveInstance(IGH_DataAccess DA)
        {
            double inputValue    = 1.0;
            double targetUnitSys = 0;
            double convType      = 0;

            //get the model units from the rhino document
            Rhino.RhinoDoc doc = Rhino.RhinoDoc.ActiveDoc;

            // create variables to hold the input and target unit system
            Rhino.UnitSystem docUnits    = doc.ModelUnitSystem;
            Rhino.UnitSystem targetUnits = doc.ModelUnitSystem;


            String outMessage       = "";
            String sourceUnitName   = docUnits.ToString();
            String targetUnitName   = "";
            String unitTypeConvName = "";
            String userUnitName     = "";

            double conversionNumber = 1;


            //create a a value for raising the number to an expoenet
            //what are you meausuring which translates in power 1 = length, 2 = area, 3 = volume

            //update baseed based on the selection of the menu
            double convExp = conversionExp;


            //read in the values from sliders/ other components
            bool success1 = DA.GetData(0, ref inputValue);
            bool success2 = DA.GetData(1, ref targetUnitSys);
            bool success3 = DA.GetData(2, ref convType);

            //initialize a value
            double convertedValue = 1;



            if (targetUnitSys == 0)
            {
            }
            else if (targetUnitSys == 1)
            {
                targetUnits = (Rhino.UnitSystem)UnitSystem.Microns;
            }
            else if (targetUnitSys == 2)
            {
                //update the unit system
                targetUnits = (Rhino.UnitSystem)UnitSystem.Millimeters;
            }
            else if (targetUnitSys == 3)
            {
                //update the unit system
                targetUnits = (Rhino.UnitSystem)UnitSystem.Centimeters;
            }
            else if (targetUnitSys == 4)
            {
                //update the unit system
                targetUnits = (Rhino.UnitSystem)UnitSystem.Meters;
            }
            else if (targetUnitSys == 5)
            {
                //update the unit system
                targetUnits = (Rhino.UnitSystem)UnitSystem.Kilometers;
            }
            else if (targetUnitSys == 6)
            {
                //update the unit system
                targetUnits = (Rhino.UnitSystem)UnitSystem.Microinches;
            }
            else if (targetUnitSys == 7)
            {
                //update the unit system
                targetUnits = (Rhino.UnitSystem)UnitSystem.Mils;
            }
            else if (targetUnitSys == 8)
            {
                //update the unit system
                targetUnits = (Rhino.UnitSystem)UnitSystem.Inches;
            }
            else if (targetUnitSys == 9)
            {
                //update the unit system
                targetUnits = (Rhino.UnitSystem)UnitSystem.Feet;
            }
            else if (targetUnitSys == 10)
            {
                //update the unit system
                targetUnits = (Rhino.UnitSystem)UnitSystem.Miles;
            }
            else
            {
                //give an error
                AddRuntimeMessage(GH_RuntimeMessageLevel.Error, "Check again your inputs");
            }

            // get the name of the target conversion system
            targetUnitName = targetUnits.ToString();

            // Don't worry about where the Absolute property comes from, we'll get to it soon.
            if (convType == 0)
            {
                //convert from Model Unit System to User Defined
                conversionNumber = Rhino.RhinoMath.UnitScale(docUnits, targetUnits);
                // write a message
                outMessage = "Conversion Done! The Document's Units System is: " + sourceUnitName + " /You are converting TO: " + targetUnitName + " / The unit conversion number is: " + conversionNumber;
                //convert the value
                convertedValue = Math.Pow(inputValue * conversionNumber, convExp);
            }
            else
            {
                // converting from User Defined to Model Units
                conversionNumber = Rhino.RhinoMath.UnitScale(targetUnits, docUnits);
                // write a message
                outMessage = "Conversion Done! The Document's Units System is: " + sourceUnitName + " /You are converting FROM: " + targetUnitName + " / The unit conversion number is: " + conversionNumber;
                //convert the value
                convertedValue = Math.Pow(inputValue * conversionNumber, convExp);
            }



            DA.SetData(0, convertedValue);
            DA.SetData(1, outMessage);
        }