Exemplo n.º 1
0
def clear(time):
    plasma_file = vtk_path + plasma_file_head + str(time) + '.vtk'
    paraxial_file = vtk_path + paraxial_file_head + str(time) + '.vtk'
    fullwave_file = vtk_path + fullwave_file_head + str(time) + '.vtk'

    vi.DeleteAllPlots()
    vi.CloseDatabase(plasma_file)
    vi.CloseDatabase(paraxial_file)
    vi.CloseDatabase(fullwave_file)
Exemplo n.º 2
0
 def test_plot_direct(self):
     w = Window()
     ult.plot(db)
     obase = pjoin(output_dir, "test.ult.plot.direct.render")
     w.render(obase=obase, res=[200, 200])
     self.assertTrue(os.path.isfile(obase + ".png"))
     WindowManager.cleanup_windows()
     visit.DeleteAllPlots()
     visit.CloseDatabase(db)
Exemplo n.º 3
0
 def test_python(self):
     visit.OpenDatabase(db)
     visit.AddPlot("Pseudocolor", "d")
     visit.DrawPlots()
     exprs.clear()
     exprs.define_python("test_vpe", file=vpe_file, args=["d"])
     visit.Query("Max")
     r1 = visit.GetQueryOutputValue()
     visit.ChangeActivePlotsVar("test_vpe")
     visit.Query("Max")
     r2 = visit.GetQueryOutputValue()
     visit.ChangeActivePlotsVar("d")
     self.assertTrue(r1 * r1 - r2 < 1e-2)
     exprs.clear()
     visit.DeleteAllPlots()
     visit.CloseDatabase(db)
Exemplo n.º 4
0
 def tearDown(self):
     # clean up
     visit.DeleteAllPlots()
     visit.CloseDatabase(self.data_path)
     visit.CloseComputeEngine()
Exemplo n.º 5
0
 def tearDown(self):
     visit.DeleteAllPlots()
     visit.CloseDatabase(db)
     visit.CloseComputeEngine()
Exemplo n.º 6
0
def make_distribution_movie(cellids,
                            rotated,
                            inputDirectory,
                            outputDirectory,
                            outputFileName,
                            zoom=1.0,
                            viewNormal=[0.488281, 0.382966, -0.784167],
                            minThreshold=1e-18,
                            maxThreshold=1e37):
    '''Makes a distribution movie of some given distribution data
      Example usage:
      make_distribution_movie(cellids=[18302, 19432, 19042], rotated=True, inputDirectory=\"/home/hannukse/meteo/stornext/field/vlasiator/2D/AAJ/silo_files/\", outputDirectory=\"/home/hannukse/MOVIES/\", outputFileName=\"testmovie\", zoom=0.8, viewNormal=[0.488281, 0.382966, -0.784167], minThreshold=1e-17, maxThreshold=1.2e37)
      Note: viewNormal determines the angle of view (straight from visit)
   '''
    if len(viewNormal) != 3:
        print "ERROR, INVALID VIEWNORMAL LENGTH, SHOULD BE 3"
        return
    for cell in sorted(cellids):
        # OPTIONS
        ###########################################################
        cellid = str(cell)
        #databaseName = "localhost:/home/hannukse/meteo/lustre/tmp/hannuksela/AAM/velgrid.rotated." + cellid + ".*.silo database"
        if rotated == True:
            rotateFix = "rotated."
        else:
            rotateFix = ""
        inputFileName = "velgrid." + rotateFix + cellid + ".*.silo"
        databaseName = "localhost:" + inputDirectory + inputFileName + " database"
        outputDir = outputDirectory
        fileName = outputFileName + "_" + cellid + "_"
        WIDTH = 3000
        HEIGHT = 3000
        # Threshold values:
        # TODO: USE VLSV READER TO AUTOMATE THIS
        minimumThreshold = minThreshold
        maximumThreshold = maxThreshold
        ###########################################################

        vis.OpenDatabase(databaseName, 0)
        #Load settings
        visSettings.load_visit_settings()
        #Make a plot
        vis.AddPlot("Pseudocolor", "avgs", 1, 1)
        vis.SetActivePlots(0)
        vis.AddOperator("Threshold", 1)
        vis.ThresholdAtts = vis.ThresholdAttributes()
        vis.ThresholdAtts.outputMeshType = 0
        vis.ThresholdAtts.listedVarNames = ("default")
        vis.ThresholdAtts.zonePortions = (1)
        vis.ThresholdAtts.lowerBounds = (minimumThreshold)
        vis.ThresholdAtts.upperBounds = (maximumThreshold)
        vis.ThresholdAtts.defaultVarName = "avgs"
        vis.ThresholdAtts.defaultVarIsScalar = 1
        vis.SetOperatorOptions(vis.ThresholdAtts, 1)
        vis.DrawPlots()
        # Begin spontaneous state
        vis.View3DAtts = vis.View3DAttributes()
        vis.View3DAtts.viewNormal = (viewNormal[0], viewNormal[1],
                                     viewNormal[2])
        vis.View3DAtts.focus = (-634.56, 91.3781, -13.7891)
        vis.View3DAtts.viewUp = (-0.102795, 0.917551, 0.3841)
        vis.View3DAtts.viewAngle = 30
        vis.View3DAtts.parallelScale = 1.45614e+06
        vis.View3DAtts.nearPlane = -2.91228e+06
        vis.View3DAtts.farPlane = 2.91228e+06
        vis.View3DAtts.imagePan = (0, 0)
        vis.View3DAtts.imageZoom = zoom
        vis.View3DAtts.perspective = 1
        vis.View3DAtts.eyeAngle = 2
        vis.View3DAtts.centerOfRotationSet = 0
        vis.View3DAtts.centerOfRotation = (-634.56, 91.3781, -13.7891)
        vis.View3DAtts.axis3DScaleFlag = 0
        vis.View3DAtts.axis3DScales = (1, 1, 1)
        vis.View3DAtts.shear = (0, 0, 1)
        vis.SetView3D(vis.View3DAtts)
        # End spontaneous state
        vis.ViewCurveAtts = vis.ViewCurveAttributes()
        vis.ViewCurveAtts.domainCoords = (0, 1)
        vis.ViewCurveAtts.rangeCoords = (0, 1)
        vis.ViewCurveAtts.viewportCoords = (0.2, 0.95, 0.15, 0.95)
        vis.ViewCurveAtts.domainScale = vis.ViewCurveAtts.LINEAR  # LINEAR, LOG
        vis.ViewCurveAtts.rangeScale = vis.ViewCurveAtts.LINEAR  # LINEAR, LOG
        vis.SetViewCurve(vis.ViewCurveAtts)
        vis.View2DAtts = vis.View2DAttributes()
        vis.View2DAtts.windowCoords = (0, 1, 0, 1)
        vis.View2DAtts.viewportCoords = (0.2, 0.95, 0.15, 0.95)
        vis.View2DAtts.fullFrameActivationMode = vis.View2DAtts.Auto  # On, Off, Auto
        vis.View2DAtts.fullFrameAutoThreshold = 100
        vis.View2DAtts.xScale = vis.View2DAtts.LINEAR  # LINEAR, LOG
        vis.View2DAtts.yScale = vis.View2DAtts.LINEAR  # LINEAR, LOG
        vis.View2DAtts.windowValid = 0
        vis.SetView2D(vis.View2DAtts)
        vis.View3DAtts = vis.View3DAttributes()
        vis.View3DAtts.viewNormal = (viewNormal[0], viewNormal[1],
                                     viewNormal[2])
        vis.View3DAtts.focus = (-634.56, 91.3781, -13.7891)
        vis.View3DAtts.viewUp = (-0.102795, 0.917551, 0.3841)
        vis.View3DAtts.viewAngle = 30
        vis.View3DAtts.parallelScale = 1.45614e+06
        vis.View3DAtts.nearPlane = -2.91228e+06
        vis.View3DAtts.farPlane = 2.91228e+06
        vis.View3DAtts.imagePan = (0, 0)
        vis.View3DAtts.imageZoom = zoom
        vis.View3DAtts.perspective = 1
        vis.View3DAtts.eyeAngle = 2
        vis.View3DAtts.centerOfRotationSet = 0
        vis.View3DAtts.centerOfRotation = (-634.56, 91.3781, -13.7891)
        vis.View3DAtts.axis3DScaleFlag = 0
        vis.View3DAtts.axis3DScales = (1, 1, 1)
        vis.View3DAtts.shear = (0, 0, 1)
        vis.SetView3D(vis.View3DAtts)
        vis.ViewAxisArrayAtts = vis.ViewAxisArrayAttributes()
        vis.ViewAxisArrayAtts.domainCoords = (0, 1)
        vis.ViewAxisArrayAtts.rangeCoords = (0, 1)
        vis.ViewAxisArrayAtts.viewportCoords = (0.15, 0.9, 0.1, 0.85)
        vis.SetViewAxisArray(vis.ViewAxisArrayAtts)
        for i in range(0, vis.GetDatabaseNStates()):
            vis.SetTimeSliderState(i)
            vis.SaveWindowAtts = vis.SaveWindowAttributes()
            vis.SaveWindowAtts.outputToCurrentDirectory = 0
            vis.SaveWindowAtts.outputDirectory = outputDir
            vis.SaveWindowAtts.fileName = fileName
            vis.SaveWindowAtts.family = 1
            vis.SaveWindowAtts.format = vis.SaveWindowAtts.PNG  # BMP, CURVE, JPEG, OBJ, PNG, POSTSCRIPT, POVRAY, PPM, RGB, STL, TIFF, ULTRA, VTK, PLY
            vis.SaveWindowAtts.width = WIDTH
            vis.SaveWindowAtts.height = HEIGHT
            vis.SaveWindowAtts.screenCapture = 0
            vis.SaveWindowAtts.saveTiled = 0
            vis.SaveWindowAtts.quality = 100
            vis.SaveWindowAtts.progressive = 0
            vis.SaveWindowAtts.binary = 0
            vis.SaveWindowAtts.stereo = 0
            vis.SaveWindowAtts.compression = vis.SaveWindowAtts.PackBits  # None, PackBits, Jpeg, Deflate
            vis.SaveWindowAtts.forceMerge = 0
            vis.SaveWindowAtts.resConstraint = vis.SaveWindowAtts.ScreenProportions  # NoConstraint, EqualWidthHeight, ScreenProportions
            vis.SaveWindowAtts.advancedMultiWindowSave = 0
            vis.SetSaveWindowAttributes(vis.SaveWindowAtts)
            vis.SaveWindow()
        vis.DeleteActivePlots()
        vis.CloseDatabase(databaseName)
        # Make the movie:
        framerate = 5
        subprocess.call([
            pythonLibDirectoryPath + pyVisitPath + "moviecompilescript.sh",
            outputDir, fileName, framerate
        ])
Exemplo n.º 7
0
def viewit():
    tl = visit.CreateAnnotationObject("Text2D")
    tl.position = (.08, .93)
    tl.height = .026
    tl.fontFamily = 0
    tl.fontBold = 1
    tl.fontShadow = 1

    visit.DeleteAllPlots()

    k = 30000
    kMax = 40001

    while k < kMax:
        filename = "scalar" + str(k) + ".Point3D"
        print "opening database file:  " + filename
        status = visit.OpenDatabase(filename, 0, "Point3D")

        if status != 1:
            print "Could not open " + filename
            return

        status = visit.AddPlot("Pseudocolor", "density")
        visit.DrawPlots()
        pca = visit.GetPlotOptions()
        pca.colorTableName = "density"
        pca.invertColorTable = 1
        pca.minFlag = 1
        pca.maxFlag = 1
        pca.min = -.21
        pca.max = .21
        #     visit.SetPlotOptions(pca)

        names = visit.GetAnnotationObjectNames()
        print names
        lastName = names[-1]
        print "lastName = " + lastName

        legend = visit.GetAnnotationObject(lastName)
        legend.numTicks = 3
        legend.managePosition = 0
        legend.position = (.1, .88)
        legend.orientation = 1
        legend.drawMinMax = 0
        legend.drawTitle = 0
        legend.drawLabels = "Labels"
        legend.suppliedLabels = (" -.15", " 0.", " .15")
        legend.fontHeight = .024
        legend.numberFormat = "%#-9.2g"
        legend.fontFamily = 2
        legend.fontBold = 1

        tl.text = "Density Fluctuation  -  Step " + str(k)
        tl.visible = 1
        visit.SaveWindow()
        k = k + 1000

        if k < kMax:
            tl.visible = 0
            visit.DeleteAllPlots()
            visit.CloseDatabase(filename)
Exemplo n.º 8
0
 def unloadSources(self):
     v.DeleteAllPlots()
     if self.subsurface_src is not None:
         v.CloseDatabase(self.subsurface_src)
     if self.surface_src is not None:
         v.CloseDatabase(self.surface_src)
Exemplo n.º 9
0
def create_visit_point_movie(variableName,
                             minValue,
                             maxValue,
                             inputDirectory,
                             inputFileNames,
                             coordinates,
                             outputDirectory,
                             outputFileName,
                             colorTable="hot_desaturated"):
    '''
   Function for making a movie
   
   Arguments:
   :param variableName                  Name of the variable
   :param minValue                      Minimum value of the variable
   :param maxValue                      Maximum value of the variable
   :param inputDirectory                Path to input vlsv/silo files
   :param inputFileNames                Name of the files for example [\"bulk.00000.silo\", \"bulk.00001.silo\"]
   :param coordinates                   Coordinates corresponding to the files so for example [ [[0,0,0], [0,1,0]], [[2,1,2], [2,1,4]] ]
   :param outputDirectory               Path to output directory
   :param outputFileName                Name of the output file
   :param colorTable="hot_desaturated"  Color table for the plots
   '''
    coordinates = [coordinates]

    for i in range(len(inputFileNames)):
        # OPTIONS
        #################################################################

        # Input variable
        _variableName = variableName
        minVariableValue = minValue
        maxVariableValue = maxValue
        colorTableName = colorTable

        # Input directory and file names
        #_outputDir = "/home/hannukse/MOVINGFRAME_MOVIES/AAJ_BZ_REMAKE/" # Set the output directory (Where .png s are saved)
        _outputDir = outputDirectory
        #_outputFileName = "BZ_FORESHOCK_2_" # The file names for the png files. These for ex. will be saved visit0000.png, visit0001.png, ..
        _outputFileName = outputFileName  # The file names for the png files.
        #databaseName = "localhost:/home/hannukse/meteo/stornext/field/vlasiator/2D/AAJ/silo_files/bulk.*.silo database" # For navigating to the silo files
        inputFileName = inputFileNames[i]
        databaseName = "localhost:" + inputDirectory + inputFileName  # For navigating to the silo files
        # Note: a slice of the plot in z-axis is taken automatically
        #################################################################
        # LaunchNowin(vdir=visitBinDirectory)
        #dx = speedX * frameInSeconds # Note: This is in meters per frame!
        #dy = speedY * frameInSeconds # Note: This is in meters per frame!
        #LaunchNowin(vdir="/usr/local/visit/bin")
        #Set up window and annotations
        #vis.LaunchNowin(vdir="/usr/local/visit/bin")

        inputFileName2 = "point.vtk"
        databaseName2 = "localhost:" + os.getcwd() + "/" + inputFileName2

        vis.OpenDatabase(databaseName, 0)
        #vis.ActiveDatabase("localhost:" + inputDirectory + inputFileName)
        #Load settings
        visSettings.load_visit_settings()
        vis.AddPlot("Pseudocolor", _variableName, 1, 1)  #CONTINUE
        vis.SetActivePlots(1)
        vis.PseudocolorAtts = vis.PseudocolorAttributes()
        vis.PseudocolorAtts.legendFlag = 1
        vis.PseudocolorAtts.lightingFlag = 1
        vis.PseudocolorAtts.minFlag = 1
        vis.PseudocolorAtts.maxFlag = 1
        vis.PseudocolorAtts.centering = vis.PseudocolorAtts.Natural  # Natural, Nodal, Zonal
        vis.PseudocolorAtts.scaling = vis.PseudocolorAtts.Linear  # Linear, Log, Skew
        vis.PseudocolorAtts.limitsMode = vis.PseudocolorAtts.CurrentPlot  # OriginalData, CurrentPlot
        vis.PseudocolorAtts.min = minVariableValue
        vis.PseudocolorAtts.max = maxVariableValue
        vis.PseudocolorAtts.pointSize = 0.05
        vis.PseudocolorAtts.pointType = vis.PseudocolorAtts.Point  # Box, Axis, Icosahedron, Point, Sphere
        vis.PseudocolorAtts.skewFactor = 1
        vis.PseudocolorAtts.opacity = 1
        vis.PseudocolorAtts.colorTableName = colorTableName
        vis.PseudocolorAtts.invertColorTable = 0
        vis.PseudocolorAtts.smoothingLevel = 0
        vis.PseudocolorAtts.pointSizeVarEnabled = 0
        vis.PseudocolorAtts.pointSizeVar = "default"
        vis.PseudocolorAtts.pointSizePixels = 2
        vis.PseudocolorAtts.lineStyle = vis.PseudocolorAtts.SOLID  # SOLID, DASH, DOT, DOTDASH
        vis.PseudocolorAtts.lineWidth = 0
        vis.PseudocolorAtts.opacityType = vis.PseudocolorAtts.Explicit  # Explicit, ColorTable
        vis.SetPlotOptions(vis.PseudocolorAtts)

        vis.SetActivePlots(1)
        vis.AddOperator("Slice", 1)
        vis.SetActivePlots(1)
        vis.SliceAtts = vis.SliceAttributes()
        vis.SliceAtts.originType = vis.SliceAtts.Intercept  # Point, Intercept, Percent, Zone, Node
        vis.SliceAtts.originPoint = (0, 0, 0)
        vis.SliceAtts.originIntercept = 0
        vis.SliceAtts.originPercent = 0
        vis.SliceAtts.originZone = 0
        vis.SliceAtts.originNode = 0
        vis.SliceAtts.normal = (0, 0, 1)
        vis.SliceAtts.axisType = vis.SliceAtts.ZAxis  # XAxis, YAxis, ZAxis, Arbitrary, ThetaPhi
        vis.SliceAtts.upAxis = (0, 1, 0)
        vis.SliceAtts.project2d = 1
        vis.SliceAtts.interactive = 1
        vis.SliceAtts.flip = 0
        vis.SliceAtts.originZoneDomain = 0
        vis.SliceAtts.originNodeDomain = 0
        vis.SliceAtts.meshName = "SpatialGrid"
        vis.SliceAtts.theta = 0
        vis.SliceAtts.phi = 90
        vis.SetOperatorOptions(vis.SliceAtts, 1)
        vis.DrawPlots()
        vis.SetActivePlots(0)

        for coordinate in coordinates[i]:
            print(str(coordinate))
            create_point_vtk(fileName=inputFileName2, coordinates=coordinate)
            vis.OpenDatabase(databaseName2, 0)
            vis.AddPlot("Mesh", "mesh", 1, 1)
            vis.SetActivePlots(vis.GetNumPlots())
            vis.MeshAtts = vis.MeshAttributes()
            vis.MeshAtts.legendFlag = 1
            vis.MeshAtts.lineStyle = vis.MeshAtts.SOLID  # SOLID, DASH, DOT, DOTDASH
            vis.MeshAtts.lineWidth = 0
            vis.MeshAtts.meshColor = (0, 0, 0, 255)
            vis.MeshAtts.outlineOnlyFlag = 0
            vis.MeshAtts.errorTolerance = 0.01
            vis.MeshAtts.meshColorSource = vis.MeshAtts.Foreground  # Foreground, MeshCustom
            vis.MeshAtts.opaqueColorSource = vis.MeshAtts.Background  # Background, OpaqueCustom
            vis.MeshAtts.opaqueMode = vis.MeshAtts.Auto  # Auto, On, Off
            vis.MeshAtts.pointSize = 0.05
            vis.MeshAtts.opaqueColor = (255, 255, 255, 255)
            vis.MeshAtts.smoothingLevel = vis.MeshAtts.None  # None, Fast, High
            vis.MeshAtts.pointSizeVarEnabled = 0
            vis.MeshAtts.pointSizeVar = "default"
            vis.MeshAtts.pointType = vis.MeshAtts.Point  # Box, Axis, Icosahedron, Point, Sphere
            vis.MeshAtts.showInternal = 0
            vis.MeshAtts.pointSizePixels = 10
            vis.MeshAtts.opacity = 1
            vis.SetPlotOptions(vis.MeshAtts)
            vis.DrawPlots()
            # Iterate through frames
            vis.SaveWindowAtts = vis.SaveWindowAttributes()
            vis.SaveWindowAtts.outputToCurrentDirectory = 0
            vis.SaveWindowAtts.outputDirectory = _outputDir
            vis.SaveWindowAtts.fileName = _outputFileName
            vis.SaveWindowAtts.family = 1
            vis.SaveWindowAtts.format = vis.SaveWindowAtts.PNG  # BMP, CURVE, JPEG, OBJ, PNG, POSTSCRIPT, POVRAY, PPM, RGB, STL, TIFF, ULTRA, VTK, PLY
            vis.SaveWindowAtts.width = 3000
            vis.SaveWindowAtts.height = 3000
            vis.SaveWindowAtts.screenCapture = 0
            vis.SaveWindowAtts.saveTiled = 0
            vis.SaveWindowAtts.quality = 100
            vis.SaveWindowAtts.progressive = 0
            vis.SaveWindowAtts.binary = 0
            vis.SaveWindowAtts.stereo = 0
            vis.SaveWindowAtts.compression = vis.SaveWindowAtts.PackBits  # None, PackBits, Jpeg, Deflate
            vis.SaveWindowAtts.forceMerge = 0
            vis.SaveWindowAtts.resConstraint = vis.SaveWindowAtts.ScreenProportions  # NoConstraint, EqualWidthHeight, ScreenProportions
            vis.SaveWindowAtts.advancedMultiWindowSave = 0
            vis.SetSaveWindowAttributes(vis.SaveWindowAtts)
            vis.SaveWindow()
            vis.DeleteActivePlots()
        vis.DeleteActivePlots()
        vis.CloseDatabase(databaseName)
    vis.CloseDatabase(databaseName2)
    # Make the movie:
    #subprocess.call("./moviecompilescript.sh " + _outputDir + " " + _outputFileName)
    pyVisitPath = "pyVisit/"
    #subprocess.call(pythonLibDirectoryPath + pyVisitPath + "moviecompilescript.sh")
    #subprocess.call(pythonLibDirectoryPath + pyVisitPath + "moviecompilescript.sh " + _outputDir + " " + _outputFileName)
    framerate = "10"
    subprocess.call([
        pythonLibDirectoryPath + pyVisitPath + "moviecompilescript.sh",
        _outputDir, _outputFileName, framerate
    ])
    # Delete the point vtk file:
    os.remove(os.getcwd() + "/" + inputFileName2)
Exemplo n.º 10
0
def make_moving_frame_of_reference_movie(x_begin,
                                         x_end,
                                         y_begin,
                                         y_end,
                                         speed_x,
                                         speed_y,
                                         variable_name,
                                         minThreshold,
                                         maxThreshold,
                                         input_directory,
                                         input_file_name,
                                         output_directory,
                                         output_file_name,
                                         color_table="hot_desaturated",
                                         start_frame=-1,
                                         end_frame=-1,
                                         frame_skip_dt=1.0):
    '''
   Function for making a movie with a moving frame of reference.
   :param x_begin             The starting frame's beginning x-coordinate
   :param x_end               The starting frame's ending x-coordinate
   :param y_begin             The starting frame's beginning x-coordinate
   :param y_end               The starting frame's ending y-coordinate
   :param speed_x             The speed at which the frame moves in the x direction
   :param speed_y             The speed at which the frame moves in the y direction
   :param variable_name       Name of the variable (For ex \"rho\")
   :param minThreshold        Minimum threshold for the variable
   :param maxThreshold        Maximum threshold for the variable
   :param input_directory     The path to the directory where the files are
   :param input_file_name     Name of the files (For ex \"bulk.*.silo\")
   :param output_directory    Directory where to output the movie
   :param output_file_name    Name of the outputted file (For ex \"RHOMOVIE\")
   :param color_table         Name of the color table (\"hot_desaturated\" by default)
   :param start_frame         Starting frame for the movie (if -1, equals 0, -1 by default)
   :param end_frame           Ending frame for the movie (if -1, equals the last frame, -1 by default)
   :param frame_skip_dt       The number of seconds one skip in frame equals (1.0 by default) (Note: This may change depending on the run and should always be checked)
   '''
    # OPTIONS
    #################################################################
    # Input the boundary box for starting coordinates (Starting values)
    startX = x_begin  # The left x-boundary of the box
    endX = x_end  # The right x-boundary of the box
    startY = y_begin  # The bottom y-boundary of the box
    endY = y_end  # The upper y-boundary of the box

    # Input frame properties
    startFrame = start_frame  # Note: if startFrame is set to -1 the start frame gets set to 0
    endFrame = end_frame  # Note: if endFrame is set to -1 the endFrame is automatically the number of frames in the database
    frameInSeconds = frame_skip_dt  # Set how many seconds one frame skip is

    # Input speed in x and y direction
    speedX = speed_x  # Meters per second
    speedY = speed_y  # Meters per second

    # Input variable
    variableName = variable_name
    minVariableValue = minThreshold
    maxVariableValue = maxThreshold
    colorTableName = color_table

    # Input directory and file names
    outputDir = output_directory  # Set the output directory (Where .png s are saved)
    outputFileName = output_file_name  # The file names for the png files. These for ex. will be saved visit0000.png, visit0001.png, .
    databaseName = "localhost:" + input_directory + input_file_name + " database"  # For navigating to the silo files
    # visitBinDirectory = "/usr/local/visit/bin" #Nevermind this
    # Note: a slice of the plot in z-axis is taken automatically
    #################################################################

    # Launch visit
    visitBinDirectory = '/home/htest/visit/bin'
    vis.LaunchNowin(vdir=visitBinDirectory)
    dx = speedX * frameInSeconds  # Note: This is in meters per frame!
    dy = speedY * frameInSeconds  # Note: This is in meters per frame!
    #Set up window and annotations
    vis.OpenDatabase(databaseName, 0)
    #Load settings
    visSettings.load_visit_settings()

    vis.AddPlot("Pseudocolor", variableName, 1, 1)
    vis.SetActivePlots(0)
    vis.PseudocolorAtts = vis.PseudocolorAttributes()
    vis.PseudocolorAtts.legendFlag = 1
    vis.PseudocolorAtts.lightingFlag = 1
    vis.PseudocolorAtts.minFlag = 1
    vis.PseudocolorAtts.maxFlag = 1
    vis.PseudocolorAtts.centering = vis.PseudocolorAtts.Natural  # Natural, Nodal, Zonal
    vis.PseudocolorAtts.scaling = vis.PseudocolorAtts.Linear  # Linear, Log, Skew
    vis.PseudocolorAtts.limitsMode = vis.PseudocolorAtts.CurrentPlot  # OriginalData, CurrentPlot
    vis.PseudocolorAtts.min = minVariableValue
    vis.PseudocolorAtts.max = maxVariableValue
    vis.PseudocolorAtts.pointSize = 0.05
    vis.PseudocolorAtts.pointType = vis.PseudocolorAtts.Point  # Box, Axis, Icosahedron, Point, Sphere
    vis.PseudocolorAtts.skewFactor = 1
    vis.PseudocolorAtts.opacity = 1
    vis.PseudocolorAtts.colorTableName = color_table
    vis.PseudocolorAtts.invertColorTable = 0
    vis.PseudocolorAtts.smoothingLevel = 0
    vis.PseudocolorAtts.pointSizeVarEnabled = 0
    vis.PseudocolorAtts.pointSizeVar = "default"
    vis.PseudocolorAtts.pointSizePixels = 2
    vis.PseudocolorAtts.lineStyle = vis.PseudocolorAtts.SOLID  # SOLID, DASH, DOT, DOTDASH
    vis.PseudocolorAtts.lineWidth = 0
    vis.PseudocolorAtts.opacityType = vis.PseudocolorAtts.Explicit  # Explicit, ColorTable
    vis.SetPlotOptions(vis.PseudocolorAtts)
    vis.SetActivePlots(0)
    vis.AddOperator("Slice", 1)
    vis.AddOperator("Threshold", 1)
    vis.ThresholdAtts = vis.ThresholdAttributes()
    vis.ThresholdAtts.outputMeshType = 0
    vis.ThresholdAtts.listedVarNames = ("Boundary_type")
    vis.ThresholdAtts.zonePortions = (1)
    vis.ThresholdAtts.lowerBounds = (1)
    vis.ThresholdAtts.upperBounds = (1)
    vis.ThresholdAtts.defaultVarName = variableName
    vis.ThresholdAtts.defaultVarIsScalar = 1
    vis.SetOperatorOptions(vis.ThresholdAtts, 1)
    vis.ThresholdAtts = vis.ThresholdAttributes()
    vis.ThresholdAtts.outputMeshType = 0
    vis.ThresholdAtts.listedVarNames = ("Boundary_type")
    vis.ThresholdAtts.zonePortions = (1)
    vis.ThresholdAtts.lowerBounds = (1)
    vis.ThresholdAtts.upperBounds = (1)
    vis.ThresholdAtts.defaultVarName = variableName
    vis.ThresholdAtts.defaultVarIsScalar = 1
    vis.SetOperatorOptions(vis.ThresholdAtts, 1)
    vis.SetActivePlots(0)
    vis.SliceAtts = vis.SliceAttributes()
    vis.SliceAtts.originType = vis.SliceAtts.Intercept  # Point, Intercept, Percent, Zone, Node
    vis.SliceAtts.originPoint = (0, 0, 0)
    vis.SliceAtts.originIntercept = 0
    vis.SliceAtts.originPercent = 0
    vis.SliceAtts.originZone = 0
    vis.SliceAtts.originNode = 0
    vis.SliceAtts.normal = (0, 0, 1)
    vis.SliceAtts.axisType = vis.SliceAtts.ZAxis  # XAxis, YAxis, ZAxis, Arbitrary, ThetaPhi
    vis.SliceAtts.upAxis = (0, 1, 0)
    vis.SliceAtts.project2d = 1
    vis.SliceAtts.interactive = 1
    vis.SliceAtts.flip = 0
    vis.SliceAtts.originZoneDomain = 0
    vis.SliceAtts.originNodeDomain = 0
    vis.SliceAtts.meshName = "SpatialGrid"
    vis.SliceAtts.theta = 0
    vis.SliceAtts.phi = 90
    vis.SetOperatorOptions(vis.SliceAtts, 1)
    vis.DrawPlots()

    if endFrame == -1:
        endFrame = vis.TimeSliderGetNStates() - 1

    if startFrame == -1:
        startFrame = 0

    # Iterate through frames
    for i in xrange(startFrame, endFrame + 1):
        vis.SetTimeSliderState(i)
        frame = i - startFrame
        vis.View2DAtts = vis.View2DAttributes()
        vis.View2DAtts.windowCoords = (startX + frame * dx, endX + frame * dx,
                                       startY + frame * dy, endY + frame * dy)
        vis.View2DAtts.viewportCoords = (0.2, 0.95, 0.15, 0.95)
        vis.View2DAtts.fullFrameActivationMode = vis.View2DAtts.Auto  # On, Off, Auto
        vis.View2DAtts.fullFrameAutoThreshold = 100
        vis.View2DAtts.xScale = vis.View2DAtts.LINEAR  # LINEAR, LOG
        vis.View2DAtts.yScale = vis.View2DAtts.LINEAR  # LINEAR, LOG
        vis.View2DAtts.windowValid = 1
        vis.SetView2D(vis.View2DAtts)
        vis.SaveWindowAtts = vis.SaveWindowAttributes()
        vis.SaveWindowAtts.outputToCurrentDirectory = 0
        vis.SaveWindowAtts.outputDirectory = outputDir
        vis.SaveWindowAtts.fileName = outputFileName
        vis.SaveWindowAtts.family = 1
        vis.SaveWindowAtts.format = vis.SaveWindowAtts.PNG  # BMP, CURVE, JPEG, OBJ, PNG, POSTSCRIPT, POVRAY, PPM, RGB, STL, TIFF, ULTRA, VTK, PLY
        vis.SaveWindowAtts.width = 1024
        vis.SaveWindowAtts.height = 1024
        vis.SaveWindowAtts.screenCapture = 0
        vis.SaveWindowAtts.saveTiled = 0
        vis.SaveWindowAtts.quality = 100
        vis.SaveWindowAtts.progressive = 0
        vis.SaveWindowAtts.binary = 0
        vis.SaveWindowAtts.stereo = 0
        vis.SaveWindowAtts.compression = vis.SaveWindowAtts.PackBits  # None, PackBits, Jpeg, Deflate
        vis.SaveWindowAtts.forceMerge = 0
        vis.SaveWindowAtts.resConstraint = vis.SaveWindowAtts.ScreenProportions  # NoConstraint, EqualWidthHeight, ScreenProportions
        vis.SaveWindowAtts.advancedMultiWindowSave = 0
        vis.SetSaveWindowAttributes(vis.SaveWindowAtts)
        vis.SaveWindow()
    vis.DeleteActivePlots()
    vis.CloseDatabase(databaseName)
    # Make the movie:
    framerate = 7
    subprocess.call([
        pythonLibDirectoryPath + pyVisitPath + "moviecompilescript.sh",
        outputDir, outputFileName, framerate
    ])
Exemplo n.º 11
0
def make_moving_frame_of_reference_line_plot(point1,
                                             point2,
                                             velocity,
                                             variable_name,
                                             input_directory,
                                             input_file_name,
                                             output_directory,
                                             output_file_name,
                                             start_frame=-1,
                                             end_frame=-1,
                                             frame_skip_dt=1.0):
    '''
   Function for making a line plot of some variable with a moving frame of reference
   :param point1              The starting point of the line (must be an array of size 3)
   :param point2              The ending point of the line (must be an array of size 3)
   :param velocity            The velocity vector of the frame of reference (must be an array of size 3)
   :param variable_name       Name of the variable (For ex \"rho\")
   :param input_directory     The path to the directory where the files are
   :param input_file_name     Name of the files (For ex \"bulk.*.silo\")
   :param output_directory    Directory where to output the movie
   :param output_file_name    Name of the outputted file (For ex \"RHOMOVIE\")
   :param start_frame         Starting frame for the movie (if -1, equals 0, -1 by default)
   :param end_frame           Ending frame for the movie (if -1, equals the last frame, -1 by default)
   :param frame_skip_dt       The number of seconds one skip in frame equals (1.0 by default) (Note: This may change depending on the run and should always be checked)
   '''
    if len(point1) != 3 or len(point2) != 3 or len(velocity) != 3:
        print "BAD INPUT IN make_moving_frame_of_reference_line_plot, POINT1, POINT2 AND VELOCITY MUST BE ARRAYS OF SIZE 3"

    # OPTIONS
    #################################################################
    # Input the boundary box for starting coordinates (Starting values)
    startX = point1[0]  # The left x-boundary of the box
    endX = point2[0]  # The right x-boundary of the box
    startY = point1[1]  # The bottom y-boundary of the box
    endY = point2[1]  # The upper y-boundary of the box
    startZ = poin1[2]  # The left z-boundary of the box
    endZ = point2[2]  # The right z-boundary of the box

    # Input frame properties
    startFrame = start_frame  # Note: if startFrame is set to -1 the start frame gets set to 0
    endFrame = end_frame  # Note: if endFrame is set to -1 the endFrame is automatically the number of frames in the database
    frameInSeconds = frame_skip_dt  # Set how many seconds one frame skip is

    screenWidth = 3000
    screenHeight = 3000

    # Input speed in x and y direction
    speedX = velocity[0]  # Meters per second
    speedY = velocity[1]  # Meters per second
    speedZ = velocity[2]  # Meters per second

    # Input variable name
    # Note: needs to have operators/Lineout/ for visit to recognize it as line plot. Additionally, visit does not accept any '/' in the variable name which is why they're removed. The curve definitions are in loadvisitsettings.py and in there the curve expressions are defined so that there's no '/' in the variable name
    variableName = "operators/Lineout/" + variable_name.replace("/", "")

    # Input directory and file names
    outputDir = output_directory  # Set the output directory (Where .png s are saved)
    outputFileName = output_file_name  # The file names for the png files. These for ex. will be saved visit0000.png, visit0001.png, ..
    databaseName = "localhost:" + input_directory + input_file_name + " database"  # For navigating to the silo files
    # visitBinDirectory = "/usr/lvariableNameocal/visit/bin" #Nevermind this
    # Note: a slice of the plot in z-axis is taken automatically
    #################################################################

    dx = speedX * frameInSeconds  # Note: This is in meters per frame!
    dy = speedY * frameInSeconds  # Note: This is in meters per frame!
    dz = speedZ * frameInSeconds  # Note: This is in meters per frame!

    vis.OpenDatabase(databaseName, 0)
    #Load settings
    visSettings.load_visit_settings()

    vis.AddPlot("Curve", variableName, 1, 1)
    vis.LineoutAtts = vis.LineoutAttributes()
    vis.LineoutAtts.point1 = (startX, startY, 0)
    vis.LineoutAtts.point2 = (endX, endY, 0)
    vis.LineoutAtts.interactive = 0
    vis.LineoutAtts.ignoreGlobal = 0
    vis.LineoutAtts.samplingOn = 0
    vis.LineoutAtts.numberOfSamplePoints = 50
    vis.LineoutAtts.reflineLabels = 0
    vis.SetOperatorOptions(vis.LineoutAtts, 1)
    vis.CurveAtts = vis.CurveAttributes()
    vis.CurveAtts.showLines = 1
    vis.CurveAtts.lineStyle = vis.CurveAtts.SOLID  # SOLID, DASH, DOT, DOTDASH
    vis.CurveAtts.lineWidth = 2
    vis.CurveAtts.showPoints = 1
    vis.CurveAtts.symbol = vis.CurveAtts.Point  # Point, TriangleUp, TriangleDown, Square, Circle, Plus, X
    vis.CurveAtts.pointSize = 5
    vis.CurveAtts.pointFillMode = vis.CurveAtts.Static  # Static, Dynamic
    vis.CurveAtts.pointStride = 1
    vis.CurveAtts.symbolDensity = 50
    vis.CurveAtts.curveColorSource = vis.CurveAtts.Custom  # Cycle, Custom
    vis.CurveAtts.curveColor = (0, 0, 0, 255)
    vis.CurveAtts.showLegend = 1
    vis.CurveAtts.showLabels = 0
    vis.CurveAtts.designator = ""
    vis.CurveAtts.doBallTimeCue = 0
    vis.CurveAtts.ballTimeCueColor = (0, 0, 0, 255)
    vis.CurveAtts.timeCueBallSize = 0.01
    vis.CurveAtts.doLineTimeCue = 0
    vis.CurveAtts.lineTimeCueColor = (0, 0, 0, 255)
    vis.CurveAtts.lineTimeCueWidth = 0
    vis.CurveAtts.doCropTimeCue = 0
    vis.CurveAtts.timeForTimeCue = 0
    vis.SetPlotOptions(vis.CurveAtts)
    vis.DrawPlots()

    # Iterate through frames
    for i in xrange(startFrame, endFrame + 1):
        vis.SetTimeSliderState(i)
        frame = i - startFrame
        vis.LineoutAtts = vis.LineoutAttributes()
        vis.LineoutAtts.point1 = (startX + frame * dx, startY + frame * dy, 0)
        vis.LineoutAtts.point2 = (endX + frame * dx, endY + frame * dy, 0)
        vis.LineoutAtts.interactive = 0
        vis.LineoutAtts.ignoreGlobal = 0
        vis.LineoutAtts.samplingOn = 0
        vis.LineoutAtts.numberOfSamplePoints = 50
        vis.LineoutAtts.reflineLabels = 0
        vis.SetOperatorOptions(vis.LineoutAtts, 1)
        vis.SaveWindowAtts = vis.SaveWindowAttributes()
        vis.SaveWindowAtts.outputToCurrentDirectory = 0
        vis.SaveWindowAtts.outputDirectory = outputDir
        vis.SaveWindowAtts.fileName = outputFileName
        vis.SaveWindowAtts.family = 1
        vis.SaveWindowAtts.format = vis.SaveWindowAtts.PNG  # BMP, CURVE, JPEG, OBJ, PNG, POSTSCRIPT, POVRAY, PPM, RGB, STL, TIFF, ULTRA, VTK, PLY
        vis.SaveWindowAtts.width = screenWidth
        vis.SaveWindowAtts.height = screenHeight
        vis.SaveWindowAtts.screenCapture = 0
        vis.SaveWindowAtts.saveTiled = 0
        vis.SaveWindowAtts.quality = 80
        vis.SaveWindowAtts.progressive = 0
        vis.SaveWindowAtts.binary = 0
        vis.SaveWindowAtts.stereo = 0
        vis.SaveWindowAtts.compression = vis.SaveWindowAtts.PackBits  # None, PackBits, Jpeg, Deflate
        vis.SaveWindowAtts.forceMerge = 0
        vis.SaveWindowAtts.resConstraint = vis.SaveWindowAtts.ScreenProportions  # NoConstraint, EqualWidthHeight, ScreenProportions
        vis.SaveWindowAtts.advancedMultiWindowSave = 0
        vis.SetSaveWindowAttributes(vis.SaveWindowAtts)
        vis.SaveWindow()
    vis.DeleteActivePlots()
    vis.CloseDatabase(databaseName)
    # Make the movie:
    framerate = 5
    subprocess.call([
        pythonLibDirectoryPath + pyVisitPath + "moviecompilescript.sh",
        outputDir, outputFileName, framerate
    ])
Exemplo n.º 12
0
 def cleanup_windows(self):
     WindowManager.cleanup_windows()
     visit.CloseDatabase(db)
     visit.CloseComputeEngine()
Exemplo n.º 13
0
def make_movie( variableName, minValue, maxValue, inputDirectory, inputFileName, outputDirectory, outputFileName, colorTable="hot_desaturated", startFrame=-1, endFrame=-1 ):
   '''
   Function for making a movie
   
   Arguments:
   :param variableName                  Name of the variable
   :param minValue                      Minimum value of the variable
   :param maxValue                      Maximum value of the variable
   :param inputDirectory                Path to input vlsv/silo files
   :param inputFileName                 Name of the file(s) so for example if the filenames are bulk.0000.silo, bulk.0001.silo, .. then inputFileName=\"bulk.*.silo\""
   :param outputDirectory               Path to output directory
   :param outputFileName                Name of the output file
   :param colorTable="hot_desaturated"  Color table for the plots
   :param startFrame=-1                 Starting frame of the movie (-1 equals 0)
   :param endFrame=-1                   Starting frame of the movie (-1 equals last frame)
   '''
   # OPTIONS
   #################################################################
   # Input frame properties
   _startFrame = startFrame # Note: if _startFrame is set to -1 the start frame gets set to 0
   _endFrame = endFrame # Note: if _endFrame is set to -1 the _endFrame is automatically the number of frames in the database
   
   # Input variable
   _variableName = variableName
   minVariableValue = minValue
   maxVariableValue = maxValue
   colorTableName = colorTable
   
   # Input directory and file names
   #_outputDir = "/home/hannukse/MOVINGFRAME_MOVIES/AAJ_BZ_REMAKE/" # Set the output directory (Where .png s are saved)
   _outputDir = outputDirectory
   #_outputFileName = "BZ_FORESHOCK_2_" # The file names for the png files. These for ex. will be saved visit0000.png, visit0001.png, ..
   _outputFileName = outputFileName # The file names for the png files.
   #databaseName = "localhost:/home/hannukse/meteo/stornext/field/vlasiator/2D/AAJ/silo_files/bulk.*.silo database" # For navigating to the silo files
   databaseName = "localhost:" + inputDirectory + inputFileName + " database" # For navigating to the silo files
   # Note: a slice of the plot in z-axis is taken automatically
   #################################################################

   # LaunchNowin(vdir=visitBinDirectory)
   #dx = speedX * frameInSeconds # Note: This is in meters per frame!
   #dy = speedY * frameInSeconds # Note: This is in meters per frame!
   #LaunchNowin(vdir="/usr/local/visit/bin")
   #Set up window and annotations
   #vis.LaunchNowin(vdir="/usr/local/visit/bin")
   vis.OpenDatabase(databaseName, 0)

   #Load settings
   visSettings.load_visit_settings()

   vis.AddPlot("Pseudocolor", _variableName, 1, 1) #CONTINUE
   vis.SetActivePlots(0)
   vis.PseudocolorAtts = vis.PseudocolorAttributes()
   vis.PseudocolorAtts.legendFlag = 1
   vis.PseudocolorAtts.lightingFlag = 1
   vis.PseudocolorAtts.minFlag = 1
   vis.PseudocolorAtts.maxFlag = 1
   vis.PseudocolorAtts.centering = vis.PseudocolorAtts.Natural  # Natural, Nodal, Zonal
   vis.PseudocolorAtts.scaling = vis.PseudocolorAtts.Linear  # Linear, Log, Skew
   vis.PseudocolorAtts.limitsMode = vis.PseudocolorAtts.CurrentPlot  # OriginalData, CurrentPlot
   vis.PseudocolorAtts.min = minVariableValue
   vis.PseudocolorAtts.max = maxVariableValue
   vis.PseudocolorAtts.pointSize = 0.05
   vis.PseudocolorAtts.pointType = vis.PseudocolorAtts.Point  # Box, Axis, Icosahedron, Point, Sphere
   vis.PseudocolorAtts.skewFactor = 1
   vis.PseudocolorAtts.opacity = 1
   vis.PseudocolorAtts.colorTableName = colorTableName
   vis.PseudocolorAtts.invertColorTable = 0
   vis.PseudocolorAtts.smoothingLevel = 0
   vis.PseudocolorAtts.pointSizeVarEnabled = 0
   vis.PseudocolorAtts.pointSizeVar = "default"
   vis.PseudocolorAtts.pointSizePixels = 2
   vis.PseudocolorAtts.lineStyle = vis.PseudocolorAtts.SOLID  # SOLID, DASH, DOT, DOTDASH
   vis.PseudocolorAtts.lineWidth = 0
   vis.PseudocolorAtts.opacityType = vis.PseudocolorAtts.Explicit  # Explicit, ColorTable
   vis.SetPlotOptions(vis.PseudocolorAtts)

   
   vis.SetActivePlots(0)
   vis.AddOperator("Slice", 1)
   vis.SetActivePlots(0)
   vis.SliceAtts = vis.SliceAttributes()
   vis.SliceAtts.originType = vis.SliceAtts.Intercept  # Point, Intercept, Percent, Zone, Node
   vis.SliceAtts.originPoint = (0, 0, 0)
   vis.SliceAtts.originIntercept = 0
   vis.SliceAtts.originPercent = 0
   vis.SliceAtts.originZone = 0
   vis.SliceAtts.originNode = 0
   vis.SliceAtts.normal = (0, 0, 1)
   vis.SliceAtts.axisType = vis.SliceAtts.ZAxis  # XAxis, YAxis, ZAxis, Arbitrary, ThetaPhi
   vis.SliceAtts.upAxis = (0, 1, 0)
   vis.SliceAtts.project2d = 1
   vis.SliceAtts.interactive = 1
   vis.SliceAtts.flip = 0
   vis.SliceAtts.originZoneDomain = 0
   vis.SliceAtts.originNodeDomain = 0
   vis.SliceAtts.meshName = "SpatialGrid"
   vis.SliceAtts.theta = 0
   vis.SliceAtts.phi = 90
   vis.SetOperatorOptions(vis.SliceAtts, 1)
   vis.DrawPlots()
   
   if _endFrame == -1:
      _endFrame = vis.TimeSliderGetNStates() - 1
   
   if _startFrame == -1:
      _startFrame = 0
   
   # Iterate through frames
   for i in range(_startFrame, _endFrame+1):
      vis.SetTimeSliderState(i)
      frame = i - _startFrame
      vis.SaveWindowAtts = vis.SaveWindowAttributes()
      vis.SaveWindowAtts.outputToCurrentDirectory = 0
      vis.SaveWindowAtts.outputDirectory = _outputDir
      vis.SaveWindowAtts.fileName = _outputFileName
      vis.SaveWindowAtts.family = 1
      vis.SaveWindowAtts.format = vis.SaveWindowAtts.PNG  # BMP, CURVE, JPEG, OBJ, PNG, POSTSCRIPT, POVRAY, PPM, RGB, STL, TIFF, ULTRA, VTK, PLY
      vis.SaveWindowAtts.width = 3000
      vis.SaveWindowAtts.height = 3000
      vis.SaveWindowAtts.screenCapture = 0
      vis.SaveWindowAtts.saveTiled = 0
      vis.SaveWindowAtts.quality = 100
      vis.SaveWindowAtts.progressive = 0
      vis.SaveWindowAtts.binary = 0
      vis.SaveWindowAtts.stereo = 0
      vis.SaveWindowAtts.compression = vis.SaveWindowAtts.PackBits  # None, PackBits, Jpeg, Deflate
      vis.SaveWindowAtts.forceMerge = 0
      vis.SaveWindowAtts.resConstraint = vis.SaveWindowAtts.ScreenProportions  # NoConstraint, EqualWidthHeight, ScreenProportions
      vis.SaveWindowAtts.advancedMultiWindowSave = 0
      vis.SetSaveWindowAttributes(vis.SaveWindowAtts)
      vis.SaveWindow()
   vis.DeleteActivePlots()
   vis.CloseDatabase(databaseName)
   # Make the movie:
   #subprocess.call("./moviecompilescript.sh " + _outputDir + " " + _outputFileName)
   pyVisitPath = "pyVisit/"
   #subprocess.call(pythonLibDirectoryPath + pyVisitPath + "moviecompilescript.sh")
   #subprocess.call(pythonLibDirectoryPath + pyVisitPath + "moviecompilescript.sh " + _outputDir + " " + _outputFileName)
   framerate = "10"
   subprocess.call([pythonLibDirectoryPath + pyVisitPath + "moviecompilescript.sh", _outputDir, _outputFileName, framerate])
Exemplo n.º 14
0
            timestep = str(aux[-1]).zfill(6)

            visit.OpenDatabase(db)

            for variable in variables:

                i = 0

                for location in locations:

                    i += 1

                    LineoutAtts = visit.LineoutAttributes()
                    LineoutAtts.point1 = location[0]
                    LineoutAtts.point2 = location[1]
                    LineoutAtts.samplingOn = 1
                    LineoutAtts.numberOfSamplePoints = 1000

                    visit.AddPlot("Curve", "operators/Lineout/" + variable)
                    visit.SetOperatorOptions(LineoutAtts, 1)
                    visit.DrawPlots()
                    e = visit.ExportDBAttributes()
                    e.filename = sim + '_' + case + '_' + timestep + '_' + variable
                    e.dirname = output_folder
                    e.db_type = "Curve2D"
                    visit.ExportDatabase(e)

                    visit.DeleteAllPlots()

            visit.CloseDatabase(db)
Exemplo n.º 15
0
def make_movie_auto(variableName,
                    boundaryBox,
                    vlsvFileName,
                    inputDirectory,
                    inputFileName,
                    outputDirectory,
                    outputFileName,
                    colorTableName="hot_desaturated",
                    startFrame=-1,
                    endFrame=-1,
                    thresholdCoefficient=0.6):
    '''
   Function for making a movie
   
   Arguments:
   :param variableName                  Name of the variable
   :param boundaryBox                   Box for collecting min and max threshold (The movie will focus on that area)
   :param vlsvFileName                  Name of a vlsv file where the function collects the threshold for the boundary box
   :param inputDirectory                Path to input vlsv/silo files
   :param inputFileName                 Name of the file(s) so for example if the filenames are bulk.0000.silo, bulk.0001.silo, .. then inputFileName=\"bulk.*.silo\""
   :param outputDirectory               Path to output directory
   :param outputFileName                Name of the output file
   :param colorTableName="hot_desaturated"  Color table for the plots
   :param thresholdCoefficient          Sets the coefficient for a covariant collected from the values from boundary box. The lower this is, the more focused the movie will be on the boundary box area
   :param startFrame=-1                 Starting frame of the movie (-1 equals 0)
   :param endFrame=-1                   Starting frame of the movie (-1 equals last frame)
   '''
    if thresholdCoefficient < 0:
        print("thresholdCoefficient must be non-negative!")
        return
    # OPTIONS
    #################################################################
    # Input frame properties
    _startFrame = startFrame  # Note: if _startFrame is set to -1 the start frame gets set to 0
    _endFrame = endFrame  # Note: if _endFrame is set to -1 the _endFrame is automatically the number of frames in the database

    # Input variable
    _variableName = variableName

    # Input directory and file names
    #_outputDir = "/home/hannukse/MOVINGFRAME_MOVIES/AAJ_BZ_REMAKE/" # Set the output directory (Where .png s are saved)
    _outputDir = outputDirectory
    #_outputFileName = "BZ_FORESHOCK_2_" # The file names for the png files. These for ex. will be saved visit0000.png, visit0001.png, ..
    _outputFileName = outputFileName  # The file names for the png files.
    #databaseName = "localhost:/home/hannukse/meteo/stornext/field/vlasiator/2D/AAJ/silo_files/bulk.*.silo database" # For navigating to the silo files
    databaseName = "localhost:" + inputDirectory + inputFileName + " database"  # For navigating to the silo files
    # Note: a slice of the plot in z-axis is taken automatically
    #################################################################

    # Get the min and max values:
    # Get all cell ids within the boundary box:
    vlsvReader = VlsvReader(vlsvFileName)
    # Get global boundaries:
    # Get xmax, xmin and xcells_ini
    xmax = vlsvReader.read_parameter(name="xmax")
    xmin = vlsvReader.read_parameter(name="xmin")
    xcells = vlsvReader.read_parameter(name="xcells_ini")
    # Do the same for y
    ymax = vlsvReader.read_parameter(name="ymax")
    ymin = vlsvReader.read_parameter(name="ymin")
    ycells = vlsvReader.read_parameter(name="ycells_ini")
    # And for z
    zmax = vlsvReader.read_parameter(name="zmax")
    zmin = vlsvReader.read_parameter(name="zmin")
    zcells = vlsvReader.read_parameter(name="zcells_ini")
    #Calculate cell lengths:
    cell_lengths = np.array([(xmax - xmin) / (float)(xcells),
                             (ymax - ymin) / (float)(ycells),
                             (zmax - zmin) / (float)(zcells)])
    # Get cell indices:
    cell_indice_bounds = np.array([
        (int)(((float)(boundaryBox[0]) - xmin) / (float)(cell_lengths[0])),
        (int)(((float)(boundaryBox[1]) - xmin) / (float)(cell_lengths[0])),
        (int)(((float)(boundaryBox[2]) - ymin) / (float)(cell_lengths[1])),
        (int)(((float)(boundaryBox[3]) - ymin) / (float)(cell_lengths[1])),
        (int)(((float)(boundaryBox[4]) - zmin) / (float)(cell_lengths[2])),
        (int)(((float)(boundaryBox[5]) - zmin) / (float)(cell_lengths[2]))
    ])
    # Get every cell id within the boundary box:
    cellids = []
    cell_indice = np.array(
        [cell_indice_bounds[0], cell_indice_bounds[2], cell_indice_bounds[4]])
    while True:
        cellids.append(cell_indice[0] + cell_indice[1] * xcells +
                       cell_indice[2] * xcells * ycells + 1)
        if cell_indice[0] < cell_indice_bounds[1]:
            cell_indice[0] = cell_indice[0] + 1
        elif cell_indice[1] < cell_indice_bounds[3]:
            cell_indice[1] = cell_indice[1] + 1
            cell_indice[0] = cell_indice_bounds[0]
        elif cell_indice[2] < cell_indice_bounds[5]:
            cell_indice[2] = cell_indice[2] + 1
            cell_indice[1] = cell_indice_bounds[1]
            cell_indice[0] = cell_indice_bounds[0]
        else:
            # Indice out of bounds -- got all cell ids
            break
    # Convert cell ids into set:
    cellids = Set(cellids)
    cellidlocations = []
    # Get all of the cell ids locations:
    allcellids = vlsvReader.read(name="SpatialGrid", tag="MESH")
    for i in range(len(allcellids)):
        if allcellids[i] in cellids:
            #This cell id is within the user-given boundary
            cellidlocations.append(allcellids[i])
    # Get all of the values:
    allvalues = vlsvReader.read_variables(name=_variableName)
    values = []
    # Get the values of the cell ids within the boundary
    for i in cellidlocations:
        values.append(allvalues[i])
    # We now have all the cell ids (and their locations in the arrays) from the area, set min and max thresholds:
    meanValue = np.mean(values)
    standardDeviationValue = np.std(values)
    maxValue = meanValue + (
        float)(thresholdCoefficient) * standardDeviationValue
    minValue = meanValue - (
        float)(thresholdCoefficient) * standardDeviationValue
    # Put threshold values:
    minVariableValue = minValue
    maxVariableValue = maxValue

    # LaunchNowin(vdir=visitBinDirectory)
    #dx = speedX * frameInSeconds # Note: This is in meters per frame!
    #dy = speedY * frameInSeconds # Note: This is in meters per frame!
    #LaunchNowin(vdir="/usr/local/visit/bin")
    #Set up window and annotations
    #vis.LaunchNowin(vdir="/usr/local/visit/bin")
    vis.OpenDatabase(databaseName, 0)

    #Load settings
    visSettings.load_visit_settings()

    vis.AddPlot("Pseudocolor", _variableName, 1, 1)  #CONTINUE
    vis.SetActivePlots(0)
    vis.PseudocolorAtts = vis.PseudocolorAttributes()
    vis.PseudocolorAtts.legendFlag = 1
    vis.PseudocolorAtts.lightingFlag = 1
    vis.PseudocolorAtts.minFlag = 1
    vis.PseudocolorAtts.maxFlag = 1
    vis.PseudocolorAtts.centering = vis.PseudocolorAtts.Natural  # Natural, Nodal, Zonal
    vis.PseudocolorAtts.scaling = vis.PseudocolorAtts.Linear  # Linear, Log, Skew
    vis.PseudocolorAtts.limitsMode = vis.PseudocolorAtts.CurrentPlot  # OriginalData, CurrentPlot
    vis.PseudocolorAtts.min = minVariableValue
    vis.PseudocolorAtts.max = maxVariableValue
    vis.PseudocolorAtts.pointSize = 0.05
    vis.PseudocolorAtts.pointType = vis.PseudocolorAtts.Point  # Box, Axis, Icosahedron, Point, Sphere
    vis.PseudocolorAtts.skewFactor = 1
    vis.PseudocolorAtts.opacity = 1
    vis.PseudocolorAtts.colorTableName = colorTableName
    vis.PseudocolorAtts.invertColorTable = 0
    vis.PseudocolorAtts.smoothingLevel = 0
    vis.PseudocolorAtts.pointSizeVarEnabled = 0
    vis.PseudocolorAtts.pointSizeVar = "default"
    vis.PseudocolorAtts.pointSizePixels = 2
    vis.PseudocolorAtts.lineStyle = vis.PseudocolorAtts.SOLID  # SOLID, DASH, DOT, DOTDASH
    vis.PseudocolorAtts.lineWidth = 0
    vis.PseudocolorAtts.opacityType = vis.PseudocolorAtts.Explicit  # Explicit, ColorTable
    vis.SetPlotOptions(vis.PseudocolorAtts)

    vis.SetActivePlots(0)
    vis.AddOperator("Slice", 1)
    vis.SetActivePlots(0)
    vis.SliceAtts = vis.SliceAttributes()
    vis.SliceAtts.originType = vis.SliceAtts.Intercept  # Point, Intercept, Percent, Zone, Node
    vis.SliceAtts.originPoint = (0, 0, 0)
    vis.SliceAtts.originIntercept = 0
    vis.SliceAtts.originPercent = 0
    vis.SliceAtts.originZone = 0
    vis.SliceAtts.originNode = 0
    vis.SliceAtts.normal = (0, 0, 1)
    vis.SliceAtts.axisType = vis.SliceAtts.ZAxis  # XAxis, YAxis, ZAxis, Arbitrary, ThetaPhi
    vis.SliceAtts.upAxis = (0, 1, 0)
    vis.SliceAtts.project2d = 1
    vis.SliceAtts.interactive = 1
    vis.SliceAtts.flip = 0
    vis.SliceAtts.originZoneDomain = 0
    vis.SliceAtts.originNodeDomain = 0
    vis.SliceAtts.meshName = "SpatialGrid"
    vis.SliceAtts.theta = 0
    vis.SliceAtts.phi = 90
    vis.SetOperatorOptions(vis.SliceAtts, 1)
    vis.DrawPlots()

    if _endFrame == -1:
        _endFrame = vis.TimeSliderGetNStates() - 1

    if _startFrame == -1:
        _startFrame = 0

    # Iterate through frames
    for i in range(_startFrame, _endFrame + 1):
        vis.SetTimeSliderState(i)
        frame = i - _startFrame
        vis.SaveWindowAtts = vis.SaveWindowAttributes()
        vis.SaveWindowAtts.outputToCurrentDirectory = 0
        vis.SaveWindowAtts.outputDirectory = _outputDir
        vis.SaveWindowAtts.fileName = _outputFileName
        vis.SaveWindowAtts.family = 1
        vis.SaveWindowAtts.format = vis.SaveWindowAtts.PNG  # BMP, CURVE, JPEG, OBJ, PNG, POSTSCRIPT, POVRAY, PPM, RGB, STL, TIFF, ULTRA, VTK, PLY
        vis.SaveWindowAtts.width = 3000
        vis.SaveWindowAtts.height = 300
        vis.SaveWindowAtts.screenCapture = 0
        vis.SaveWindowAtts.saveTiled = 0
        vis.SaveWindowAtts.quality = 100
        vis.SaveWindowAtts.progressive = 0
        vis.SaveWindowAtts.binary = 0
        vis.SaveWindowAtts.stereo = 0
        vis.SaveWindowAtts.compression = vis.SaveWindowAtts.PackBits  # None, PackBits, Jpeg, Deflate
        vis.SaveWindowAtts.forceMerge = 0
        vis.SaveWindowAtts.resConstraint = vis.SaveWindowAtts.ScreenProportions  # NoConstraint, EqualWidthHeight, ScreenProportions
        vis.SaveWindowAtts.advancedMultiWindowSave = 0
        vis.SetSaveWindowAttributes(vis.SaveWindowAtts)
        vis.SaveWindow()
    vis.DeleteActivePlots()
    vis.CloseDatabase(databaseName)
    # Make the movie:
    #subprocess.call("./moviecompilescript.sh " + _outputDir + " " + _outputFileName)
    pyVisitPath = "pyVisit/"
    #subprocess.call(pythonLibDirectoryPath + pyVisitPath + "moviecompilescript.sh")
    #subprocess.call(pythonLibDirectoryPath + pyVisitPath + "moviecompilescript.sh " + _outputDir + " " + _outputFileName)
    frameRate = "10"
    subprocess.call([
        pythonLibDirectoryPath + pyVisitPath + "moviecompilescript.sh",
        _outputDir, _outputFileName, frameRate
    ])
Exemplo n.º 16
0
def run(conf):
    '''
    Visualises clusters of a given run.
    :param conf:
    :return:
    '''
    #pp = pprint.PrettyPrinter()
    #pp.pprint(conf)

    # Make sure the global configuration is in place
    utils.run_global_visit_configuration(conf)
    #pdb.set_trace()

    clusterConf = utils.getValueForKeyPath(conf, 'postprocessing.clusters')
    if not clusterConf:
        print "No configuration for cluster postprocessing. Nothing to do."
        return 0

    visitConf = utils.getValueForKeyPath(clusterConf, 'visit')
    if not visitConf:
        print "No configuration for visuals. Nothing to do."
        return 0

    views = utils.getValueForKeyPath(visitConf, 'views')

    # Set up background gradient, axis labels etc.
    utils.setAnnotations(visitConf, 'annotationAttributes')

    # Set view and annotation attributes
    utils.setAnnotations(conf, 'postprocessing.clusters.visit.annotations')

    if not utils.getValueForKeyPath(conf, 'resume'):
        print "Removing results from previous runs"
        subprocess.call(
            "rm -rf images movies *.vtk *.vtr *tracking*.png *source*.png",
            shell=True)
    else:
        print "Removing intermediary files from previous runs"
        subprocess.call("rm -f *.vtk *.vtr *.vtu", shell=True)

    # Figure out the ending for the cluster vtk files
    conversion_config = utils.getValueForKeyPath(
        conf, 'postprocessing.clusters.meanie3D-cfm2vtk')
    if "--write-as-xml" in conversion_config:
        cluster_vtk_extension = ".vtu"
    else:
        cluster_vtk_extension = ".vtk"

    # Glob the netcdf directory or find the single file
    uses_time = utils.getValueForKeyPath(conf, 'uses_time')

    print "Current work directory: " + os.path.abspath(os.getcwd())
    if uses_time:
        print "Processing file " + conf['source_directory']
        netcdf_file = conf['source_directory']
    else:
        print "Processing files in directory " + conf['source_directory']
        netcdf_files = sorted(glob.glob(conf['source_directory'] + "/*.nc"))

    # Keep track of number of images to allow
    # forced re-set in time to circumvent the
    # Visit memory leak
    image_count = 0

    index_range = []
    if uses_time:
        t1 = int(utils.getValueForKeyPath(conf, 'start_time_index'))
        t2 = int(utils.getValueForKeyPath(conf, 'end_time_index'))
        index_range = range(t1, t2 + 1)
    else:
        index_range = range(len(netcdf_files))
        time_index = -1

    for index in index_range:

        # construct the cluster filename and find it
        # in the cluster directory
        if not uses_time:
            netcdf_file = netcdf_files[index]
        else:
            time_index = index

        netcdf_path, filename = os.path.split(netcdf_file)
        basename = os.path.splitext(filename)[0]
        if uses_time:
            basename = basename + "-" + str(time_index)
        cluster_file = conf[
            'cluster_directory'] + os.path.sep + basename + "-clusters.nc"

        # cluster file gets it's basename from the input file rather than the cluster file
        cluster_vtk_file = os.path.splitext(
            filename)[0] + "-clusters" + cluster_vtk_extension

        # label and displacement files are based on the cluster file name
        label_vtk_file = basename + "-clusters-centers.vtk"
        displacement_vtk_file = basename + "-clusters-displacements.vtk"

        print "netcdf_file  = " + netcdf_file
        print "cluster_file = " + cluster_file

        # check if the files both exist
        if not os.path.exists(cluster_file):
            print "Cluster file does not exist. Skipping."
            continue

        # predict the filenames for checking on resume
        number_postfix = str(image_count).rjust(4, '0')

        source_open = False
        skip_source = False

        if conf['resume'] == True:
            exists = utils.images_exist(visitConf['views'], "source",
                                        image_count)
            if exists == "all":
                print "Source visualization " + number_postfix + " exists. Skipping."
                skip_source = True
            elif exists == "partial":
                print "Deleting partial visualization " + number_postfix
                utils.delete_images(conf, "source", image_count)

        if skip_source == False:

            if utils.getValueForKeyPath(clusterConf, 'createSourceMovie'):

                # Add ancillary background data
                utils.plotMapdata(visitConf, 'map')

                # Add timestamp
                if utils.getValueForKeyPath(clusterConf, 'showDateTime'):
                    utils.add_datetime(clusterConf, netcdf_file, time_index)

                # Add source data and threshold it
                print "Plotting source data ..."
                start_time = time.time()

                utils.addPseudocolorPlots(netcdf_file, visitConf,
                                          'source.plots', time_index)
                source_open = True
                visit.DrawPlots()

                utils.saveImagesForViews(views, "source")

                visit.DeleteAllPlots()
                visit.ClearWindow()

                print "    done. (%.2f seconds)" % (time.time() - start_time)

        if utils.getValueForKeyPath(clusterConf, 'visualiseClusters'):

            skip = False
            if conf['resume'] == True:

                exists = utils.images_exist(visitConf['views'], "tracking",
                                            image_count)
                if exists == "all":
                    print "Cluster visualization " + number_postfix + " exists. Skipping."
                    skip = True
                elif exists == "partial":
                    print "Deleting partial cluster visualization " + number_postfix
                    utils.delete_images(conf, "tracking", image_count)

            if skip == False:

                # Run the conversion
                print "-- Converting clusters to .vtr --"
                start_time = time.time()
                params = "-f %s %s" \
                         % (cluster_file,utils.getValueForKeyPath(conf,'postprocessing.clusters.meanie3D-cfm2vtk'))
                if utils.getValueForKeyPath(
                        conf,
                        'postprocessing.clusters.showDisplacementVectors'):
                    params += " --write-displacement-vectors"

                if utils.getValueForKeyPath(conf, 'data.vtkDimensions'):
                    vtkDimString = ",".join(
                        utils.getValueForKeyPath(conf, 'data.vtkDimensions'))
                    params += " --vtk-dimensions=%s" % vtkDimString

                # pdb.set_trace();
                print "meanie3D-cfm2vtk %s" % params
                meanie3D.app.external.execute_command('meanie3D-cfm2vtk',
                                                      params)
                print "    done. (%.2f seconds)" % (time.time() - start_time)

                # Move cluster output file to individual file
                if uses_time:
                    cluster_vtk_file_dst = basename + "-clusters.vtk"
                    os.rename(cluster_vtk_file, cluster_vtk_file_dst)
                    cluster_vtk_file = cluster_vtk_file_dst

                print "-- Rendering cluster scene --"
                start_time = time.time()

                # Add ancillary background data
                utils.plotMapdata(visitConf, 'map')

                # Add timestamp
                if utils.getValueForKeyPath(clusterConf, 'showDateTime'):
                    utils.add_datetime(clusterConf, netcdf_file, time_index)

                # Add background source data
                if utils.getValueForKeyPath(clusterConf,
                                            'showSourceBackground'):
                    utils.addPseudocolorPlots(netcdf_file, visitConf,
                                              'sourceBackground.plots',
                                              time_index)
                    source_open = True

                # Add the clusters
                add_clusters(cluster_vtk_file, conf)

                # Add modes as labels
                labelConf = utils.getValueForKeyPath(visitConf, 'label')
                if labelConf:
                    utils.addLabelPlot(label_vtk_file, labelConf)

                # Add displacement vectors
                if utils.getValueForKeyPath(clusterConf,
                                            'showDisplacementVectors'):
                    vectorConf = utils.getValueForKeyPath(
                        visitConf, 'displacementVectors')
                    if vectorConf:
                        utils.addVectorPlot(displacement_vtk_file, vectorConf)

                visit.DrawPlots()
                utils.saveImagesForViews(views, "tracking")

                print "    done. (%.2f seconds)" % (time.time() - start_time)

        # clean up

        visit.DeleteAllPlots()
        visit.ClearWindow()
        if source_open:
            visit.CloseDatabase(netcdf_file)
            visit.CloseDatabase(label_vtk_file)
        utils.close_pattern(basename + "*.vtr")
        utils.close_pattern(basename + "*.vtk")
        utils.close_pattern(basename + "*.vtu")

        if utils.getValueForKeyPath(conf, 'cleanup_vtk'):
            subprocess.call("rm -f *.vt*", shell=True)

        # periodically kill computing engine to
        # work around the memory leak fix
        image_count = image_count + 1

        # TODO: check if this is still necessary and re-implement if it is.
        #if image_count % 100 == 0:
        #    visit.CloseComputeEngine()

    # close mapstuff
    # TODO: might need to keep track of open database files and
    # close them.

    # Use imagemagick to use image sequences to make movies

    movieFormats = utils.getValueForKeyPath(clusterConf, 'movieFormats')
    if utils.getValueForKeyPath(clusterConf, 'createSourceMovie'):
        utils.createMoviesForViews(views, "source", movieFormats)

    if utils.getValueForKeyPath(clusterConf, 'createClusterMovie'):
        utils.createMoviesForViews(views, "tracking", movieFormats)

    # clean up
    print "Cleaning up ..."
    subprocess.call("mkdir images", shell=True)
    subprocess.call("mv *tracking_*.png images", shell=True)
    subprocess.call("mv *source_*.png images", shell=True)
    subprocess.call("mkdir movies", shell=True)
    subprocess.call("mv *source*.gif *tracking*.gif *.m4v movies", shell=True)
    if utils.getValueForKeyPath(conf, 'cleanup_vtk'):
        subprocess.call("rm -f *.vt* visitlog.py", shell=True)
    return
Exemplo n.º 17
0
def draw_point_picture(variableName,
                       minValue,
                       maxValue,
                       inputDirectory,
                       inputFileName,
                       coordinate,
                       outputDirectory,
                       outputFileName,
                       colorTable="hot_desaturated"):
    '''
   Function for making a visit plot with a point
   
   Arguments:
   :param variableName                  Name of the variable
   :param minValue                      Minimum value of the variable
   :param maxValue                      Maximum value of the variable
   :param inputDirectory                Path to input vlsv/silo files
   :param inputFileName                Name of the file, for example \"bulk.00000.silo\"
   :param coordinates                   Coordinates corresponding to the files so for example [ [[0,0,0], [0,1,0]], [[2,1,2], [2,1,4]] ]
   :param outputDirectory               Path to output directory
   :param outputFileName                Name of the output file
   :param colorTable="hot_desaturated"  Color table for the plots
   '''
    # OPTIONS
    #################################################################

    # Input variable
    _variableName = variableName
    minVariableValue = minValue
    maxVariableValue = maxValue
    colorTableName = colorTable

    # Input directory and file names
    _outputDir = outputDirectory
    _outputFileName = outputFileName  # The file names for the png files.
    databaseName = "localhost:" + inputDirectory + inputFileName  # For navigating to the silo files
    # Note: a slice of the plot in z-axis is taken automatically
    #################################################################

    inputFileName2 = "point.vtk"
    databaseName2 = "localhost:" + os.getcwd() + "/" + inputFileName2

    currentPlot = 0

    vis.OpenDatabase(databaseName, 0)
    #vis.ActiveDatabase("localhost:" + inputDirectory + inputFileName)
    #Load settings
    visSettings.load_visit_settings()
    vis.AddPlot("Pseudocolor", _variableName, 1, 1)  #CONTINUE
    vis.SetActivePlots(currentPlot)
    vis.PseudocolorAtts = vis.PseudocolorAttributes()
    vis.PseudocolorAtts.legendFlag = 1
    vis.PseudocolorAtts.lightingFlag = 1
    vis.PseudocolorAtts.minFlag = 1
    vis.PseudocolorAtts.maxFlag = 1
    vis.PseudocolorAtts.centering = vis.PseudocolorAtts.Natural  # Natural, Nodal, Zonal
    vis.PseudocolorAtts.scaling = vis.PseudocolorAtts.Linear  # Linear, Log, Skew
    vis.PseudocolorAtts.limitsMode = vis.PseudocolorAtts.CurrentPlot  # OriginalData, CurrentPlot
    vis.PseudocolorAtts.min = minVariableValue
    vis.PseudocolorAtts.max = maxVariableValue
    vis.PseudocolorAtts.pointSize = 0.05
    vis.PseudocolorAtts.pointType = vis.PseudocolorAtts.Point  # Box, Axis, Icosahedron, Point, Sphere
    vis.PseudocolorAtts.skewFactor = 1
    vis.PseudocolorAtts.opacity = 1
    vis.PseudocolorAtts.colorTableName = colorTableName
    vis.PseudocolorAtts.invertColorTable = 0
    vis.PseudocolorAtts.smoothingLevel = 0
    vis.PseudocolorAtts.pointSizeVarEnabled = 0
    vis.PseudocolorAtts.pointSizeVar = "default"
    vis.PseudocolorAtts.pointSizePixels = 2
    vis.PseudocolorAtts.lineStyle = vis.PseudocolorAtts.SOLID  # SOLID, DASH, DOT, DOTDASH
    vis.PseudocolorAtts.lineWidth = 0
    vis.PseudocolorAtts.opacityType = vis.PseudocolorAtts.Explicit  # Explicit, ColorTable
    vis.SetPlotOptions(vis.PseudocolorAtts)

    vis.AddOperator("Slice", 1)
    vis.SliceAtts = vis.SliceAttributes()
    vis.SliceAtts.originType = vis.SliceAtts.Intercept  # Point, Intercept, Percent, Zone, Node
    vis.SliceAtts.originPoint = (0, 0, 0)
    vis.SliceAtts.originIntercept = 0
    vis.SliceAtts.originPercent = 0
    vis.SliceAtts.originZone = 0
    vis.SliceAtts.originNode = 0
    vis.SliceAtts.normal = (0, 0, 1)
    vis.SliceAtts.axisType = vis.SliceAtts.ZAxis  # XAxis, YAxis, ZAxis, Arbitrary, ThetaPhi
    vis.SliceAtts.upAxis = (0, 1, 0)
    vis.SliceAtts.project2d = 1
    vis.SliceAtts.interactive = 1
    vis.SliceAtts.flip = 0
    vis.SliceAtts.originZoneDomain = 0
    vis.SliceAtts.originNodeDomain = 0
    vis.SliceAtts.meshName = "SpatialGrid"
    vis.SliceAtts.theta = 0
    vis.SliceAtts.phi = 90
    vis.SetOperatorOptions(vis.SliceAtts, 1)
    vis.DrawPlots()

    create_point_vtk(fileName=inputFileName2, coordinates=coordinate)
    vis.OpenDatabase(databaseName2, 0)
    currentPlot = currentPlot + 1
    vis.SetActivePlots(currentPlot)
    vis.AddPlot("Mesh", "mesh", 1, 1)
    vis.MeshAtts = vis.MeshAttributes()
    vis.MeshAtts.legendFlag = 1
    vis.MeshAtts.lineStyle = vis.MeshAtts.SOLID  # SOLID, DASH, DOT, DOTDASH
    vis.MeshAtts.lineWidth = 0
    vis.MeshAtts.meshColor = (0, 0, 0, 255)
    vis.MeshAtts.outlineOnlyFlag = 0
    vis.MeshAtts.errorTolerance = 0.01
    vis.MeshAtts.meshColorSource = vis.MeshAtts.Foreground  # Foreground, MeshCustom
    vis.MeshAtts.opaqueColorSource = vis.MeshAtts.Background  # Background, OpaqueCustom
    vis.MeshAtts.opaqueMode = vis.MeshAtts.Auto  # Auto, On, Off
    vis.MeshAtts.pointSize = 0.05
    vis.MeshAtts.opaqueColor = (255, 255, 255, 255)
    vis.MeshAtts.smoothingLevel = vis.MeshAtts.None  # None, Fast, High
    vis.MeshAtts.pointSizeVarEnabled = 0
    vis.MeshAtts.pointSizeVar = "default"
    vis.MeshAtts.pointType = vis.MeshAtts.Point  # Box, Axis, Icosahedron, Point, Sphere
    vis.MeshAtts.showInternal = 0
    vis.MeshAtts.pointSizePixels = 25
    vis.MeshAtts.opacity = 1
    vis.SetPlotOptions(vis.MeshAtts)
    vis.DrawPlots()
    vis.SaveWindowAtts = vis.SaveWindowAttributes()
    vis.SaveWindowAtts.outputToCurrentDirectory = 0
    vis.SaveWindowAtts.outputDirectory = _outputDir
    vis.SaveWindowAtts.fileName = _outputFileName
    vis.SaveWindowAtts.family = 1
    vis.SaveWindowAtts.format = vis.SaveWindowAtts.PNG  # BMP, CURVE, JPEG, OBJ, PNG, POSTSCRIPT, POVRAY, PPM, RGB, STL, TIFF, ULTRA, VTK, PLY
    vis.SaveWindowAtts.width = 3000
    vis.SaveWindowAtts.height = 3000
    vis.SaveWindowAtts.screenCapture = 0
    vis.SaveWindowAtts.saveTiled = 0
    vis.SaveWindowAtts.quality = 100
    vis.SaveWindowAtts.progressive = 0
    vis.SaveWindowAtts.binary = 0
    vis.SaveWindowAtts.stereo = 0
    vis.SaveWindowAtts.compression = vis.SaveWindowAtts.PackBits  # None, PackBits, Jpeg, Deflate
    vis.SaveWindowAtts.forceMerge = 0
    vis.SaveWindowAtts.resConstraint = vis.SaveWindowAtts.ScreenProportions  # NoConstraint, EqualWidthHeight, ScreenProportions
    vis.SaveWindowAtts.advancedMultiWindowSave = 0
    vis.SetSaveWindowAttributes(vis.SaveWindowAtts)
    vis.SaveWindow()
    vis.SetActivePlots((0, 1))
    vis.DeleteActivePlots()
    vis.CloseDatabase(databaseName2)
    vis.CloseDatabase(databaseName)
Exemplo n.º 18
0
    f.write(response.read())

print("Successfully downloaded example silo")

visit.LaunchNowin()
saveatts = visit.SaveWindowAttributes()
saveatts.fileName = 'result-visit.png'
saveatts.family = 0
saveatts.width = 1024
saveatts.height = 768
saveatts.resConstraint = saveatts.NoConstraint
saveatts.outputToCurrentDirectory = 1
visit.SetSaveWindowAttributes(saveatts)
visit.OpenDatabase('example.silo')
visit.AddPlot('Contour', 'density')
c = visit.ContourAttributes()
c.colorType = c.ColorByColorTable
c.colorTableName = "hot"
visit.SetPlotOptions(c)
visit.DrawPlots()
v = visit.GetView3D()
v.viewNormal = (-0.554924, 0.703901, 0.443377)
v.viewUp = (0.272066, -0.3501, 0.896331)
visit.SetView3D(v)
visit.SaveWindow()

visit.DeleteAllPlots()
visit.CloseDatabase('example.silo')

print("Successfully rendered output raster")
print("All done!")
Exemplo n.º 19
0
print("Results saved in result.silo")


# Visualise result.silo using VisIt
import visit
visit.LaunchNowin()
saveatts = visit.SaveWindowAttributes()
saveatts.fileName = 'result-visit.png'
saveatts.family = 0
saveatts.width = 1024
saveatts.height = 768
saveatts.resConstraint = saveatts.NoConstraint
saveatts.outputToCurrentDirectory = 1
visit.SetSaveWindowAttributes(saveatts)
visit.OpenDatabase('result.silo')
visit.AddPlot('Contour', 'susceptibility')
c=visit.ContourAttributes()
c.colorType=c.ColorByColorTable
c.colorTableName = "hot"
visit.SetPlotOptions(c)
visit.DrawPlots()
v=visit.GetView3D()
v.viewNormal=(-0.554924, 0.703901, 0.443377)
v.viewUp=(0.272066, -0.3501, 0.896331)
visit.SetView3D(v)
visit.SaveWindow()
subprocess.call(["cloud", "upload", "result-visit.png", "result-visit.png", "--set-acl=public-read"])
visit.DeleteAllPlots()
visit.CloseDatabase('result.silo')