public void Include_2D() { var bound = new BoundingWorldExtent3D(0, 0, 0, 0, 0, 0); bound.Include(10, 11); bound.Should().BeEquivalentTo(new BoundingWorldExtent3D(0, 0, 10, 11, 0, 0)); bound.Include(-10, -11); bound.Should().BeEquivalentTo(new BoundingWorldExtent3D(-10, -11, 10, 11, 0, 0)); }
/// <summary> /// Combine this aggregator with another aggregator and store the result in this aggregator /// </summary> /// <param name="other"></param> /// <returns></returns> public ElevationStatisticsAggregator AggregateWith(ElevationStatisticsAggregator other) { CellSize = other.CellSize; if (other.MinElevation < MinElevation) { MinElevation = other.MinElevation; } if (other.MaxElevation > MaxElevation) { MaxElevation = other.MaxElevation; } CellsUsed += other.CellsUsed; CellsScanned += other.CellsScanned; BoundingExtents.Include(other.BoundingExtents); return(this); }
/// <summary> /// Combine this simple volumes response with another simple volumes response and store the result in this response /// </summary> /// <param name="other"></param> public SimpleVolumesResponse AggregateWith(SimpleVolumesResponse other) { Cut = AggregateValue(Cut, other.Cut); Fill = AggregateValue(Fill, other.Fill); TotalCoverageArea = AggregateValue(TotalCoverageArea, other.TotalCoverageArea); CutArea = AggregateValue(CutArea, other.CutArea); FillArea = AggregateValue(FillArea, other.FillArea); BoundingExtentGrid.Include(other.BoundingExtentGrid); // Note: WGS84 bounding rectangle is not enlarged - it is computed after all aggregations have occurred. return(this); }
private BoundingWorldExtent3D DataStoreExtents(DecimationElevationSubGridTree dataStore) { BoundingWorldExtent3D ComputedGridExtent = BoundingWorldExtent3D.Inverted(); dataStore.ScanAllSubGrids(subGrid => { SubGridUtilities.SubGridDimensionalIterator((x, y) => { float elev = ((GenericLeafSubGrid <float>)subGrid).Items[x, y]; if (elev != 0) { ComputedGridExtent.Include((int)(subGrid.OriginX + x), (int)(subGrid.OriginY + y), elev); } else { ((GenericLeafSubGrid <float>)subGrid).Items[x, y] = TRex.Common.Consts.NullHeight; } }); return(true); }); if (ComputedGridExtent.IsValidPlanExtent) { ComputedGridExtent.Offset(-(int)SubGridTreeConsts.DefaultIndexOriginOffset, -(int)SubGridTreeConsts.DefaultIndexOriginOffset); } // Convert the grid rectangle to a world rectangle BoundingWorldExtent3D ComputedWorldExtent = new BoundingWorldExtent3D ((ComputedGridExtent.MinX - 0.01) * dataStore.CellSize, (ComputedGridExtent.MinY - 0.01) * dataStore.CellSize, (ComputedGridExtent.MaxX + 1 + 0.01) * dataStore.CellSize, (ComputedGridExtent.MaxY + 1 + 0.01) * dataStore.CellSize, ComputedGridExtent.MinZ, ComputedGridExtent.MaxZ); return(ComputedWorldExtent); }
// These SaveToStream/LoadFromStream methods implement GENERIC save/load functionality // NOT NFF save/load functionality // Procedure SaveToStream(Stream : TStream); Overload; override; // Procedure LoadFromStream(Stream : TStream); Overload; override; public override BoundingWorldExtent3D BoundingBox() { if (Vertices.Count == 0) { return(new BoundingWorldExtent3D(Consts.NullDouble, Consts.NullDouble, Consts.NullDouble, Consts.NullDouble)); } if (Vertices.Count == 1) { return(new BoundingWorldExtent3D(Vertices.First().X, Vertices.First().Y, Vertices.First().X, Vertices.First().Y)); } var Result = new BoundingWorldExtent3D(Math.Min(Vertices[0].X, Vertices[1].X), Math.Min(Vertices[0].Y, Vertices[1].Y), Math.Max(Vertices[0].X, Vertices[1].X), Math.Max(Vertices[0].Y, Vertices[1].Y)); for (int I = 1; I < Vertices.Count; I++) { Result.Include(Vertices[I].X, Vertices[I].Y); } return(Result); }
/// <summary> /// Expands a set 3D ordinate limits by the location of this vertex /// </summary> /// <param name="boundingExtent"></param> public void AdjustLimits(BoundingWorldExtent3D boundingExtent) { boundingExtent.Include(X, Y, Z); }
/// <summary> /// Executor that implements requesting and rendering sub grid information to create the rendered tile /// </summary> public async Task <SKBitmap> ExecuteAsync() { // WorkingColorPalette : TICDisplayPaletteBase; _log.LogInformation($"Performing Execute for DataModel:{DataModelID}, Mode={Mode}"); ApplicationServiceRequestStatistics.Instance.NumMapTileRequests.Increment(); /* * if Assigned(ASNodeImplInstance.RequestCancellations) and * ASNodeImplInstance.RequestCancellations.IsRequestCancelled(FExternalDescriptor) then * begin * if ...SvcLocations.Debug_LogDebugRequestCancellationToFile then * SIGLogMessage.PublishNoODS(Self, 'Request cancelled: ' + FExternalDescriptor.ToString, ...Debug); * * ResultStatus = ...RequestHasBeenCancelled; * InterlockedIncrement64(ASNodeRequestStats.NumMapTileRequestsCancelled); * Exit; * end; * * // The governor is intended to restrict the numbers of heavy weight processes * // such as pipelines that interact with the PC layer to request sub grids * ScheduledWithGovernor = ASNodeImplInstance.Governor.Schedule(FExternalDescriptor, Self, gqWMS, ResultStatus); * if not ScheduledWithGovernor then * Exit; */ var RequestDescriptor = Guid.NewGuid(); if (_log.IsDebugEnabled()) { if (CoordsAreGrid) { _log.LogDebug($"RenderPlanViewTiles Execute: Performing render for request={RequestDescriptor} Args: Project={DataModelID}, Mode={Mode}, CutFillDesign=''{CutFillDesign}'' " + $"Bound[BL/TR:X/Y]=({BLPoint.X} {BLPoint.Y}, {TRPoint.X} {TRPoint.Y}), Width={NPixelsX}, Height={NPixelsY}"); } else { _log.LogDebug($"RenderPlanViewTiles Execute: Performing render for request={RequestDescriptor} Args: Project={DataModelID}, Mode={Mode}, CutFillDesign=''{CutFillDesign}'' " + $"Bound[BL/TR:Lon/Lat]=({BLPoint.X} {BLPoint.Y}, {TRPoint.X} {TRPoint.Y}), Width={NPixelsX}, Height={NPixelsY}"); } // Include the details of the filters with the logged tile parameters if (Filters != null) { for (var i = 0; i < Filters.Filters.Length; i++) { _log.LogDebug($"Filter({i}): {Filters.Filters[i]}"); } } } // Determine the grid (NEE) coordinates of the bottom/left, top/right WGS-84 positions // given the project's coordinate system. If there is no coordinate system then exit. var SiteModel = DIContext.Obtain <ISiteModels>().GetSiteModel(DataModelID); if (SiteModel == null) { _log.LogWarning($"Failed to locate site model {DataModelID}"); return(null); } _log.LogInformation($"Got Site model {DataModelID}, production data extents are {SiteModel.SiteModelExtent}"); LLHCoords = new[] { new XYZ(BLPoint.X, BLPoint.Y, 0), new XYZ(TRPoint.X, TRPoint.Y, 0), new XYZ(BLPoint.X, TRPoint.Y, 0), new XYZ(TRPoint.X, BLPoint.Y, 0) }; _log.LogInformation($"LLHCoords for tile request {string.Concat(LLHCoords)}, CoordsAreGrid {CoordsAreGrid}"); if (CoordsAreGrid) { NEECoords = LLHCoords; } else { NEECoords = DIContext .Obtain <ICoreXWrapper>() .LLHToNEE(SiteModel.CSIB(), LLHCoords.ToCoreX_XYZ(), CoreX.Types.InputAs.Radians) .ToTRex_XYZ(); } _log.LogInformation($"After conversion NEECoords are {string.Concat(NEECoords)}"); WorldTileHeight = MathUtilities.Hypot(NEECoords[0].X - NEECoords[2].X, NEECoords[0].Y - NEECoords[2].Y); WorldTileWidth = MathUtilities.Hypot(NEECoords[0].X - NEECoords[3].X, NEECoords[0].Y - NEECoords[3].Y); var dx = NEECoords[2].X - NEECoords[0].X; var dy = NEECoords[2].Y - NEECoords[0].Y; // Calculate the tile rotation as the mathematical angle turned from 0 (due east) to the vector defined by dy/dx TileRotation = Math.Atan2(dy, dx); // Convert TileRotation to represent the angular deviation rather than a bearing TileRotation = (Math.PI / 2) - TileRotation; RotatedTileBoundingExtents.SetInverted(); NEECoords.ForEach(xyz => RotatedTileBoundingExtents.Include(xyz.X, xyz.Y)); _log.LogInformation($"Tile render executing across tile: [Rotation:{TileRotation}, {MathUtilities.RadiansToDegrees(TileRotation)} degrees] " + $" [BL:{NEECoords[0].X}, {NEECoords[0].Y}, TL:{NEECoords[2].X},{NEECoords[2].Y}, " + $"TR:{NEECoords[1].X}, {NEECoords[1].Y}, BR:{NEECoords[3].X}, {NEECoords[3].Y}] " + $"World Width, Height: {WorldTileWidth}, {WorldTileHeight}, Rotated bounding extents: {RotatedTileBoundingExtents}"); // Construct the renderer, configure it, and set it on its way // WorkingColorPalette = Nil; using (var Renderer = new PlanViewTileRenderer()) { try { // Intersect the site model extents with the extents requested by the caller var adjustedSiteModelExtents = SiteModel.GetAdjustedDataModelSpatialExtents(null); _log.LogInformation($"Calculating intersection of bounding box and site model {DataModelID}:{adjustedSiteModelExtents}"); var dataSelectionExtent = new BoundingWorldExtent3D(RotatedTileBoundingExtents); dataSelectionExtent.Intersect(adjustedSiteModelExtents); if (!dataSelectionExtent.IsValidPlanExtent) { ResultStatus = RequestErrorStatus.InvalidCoordinateRange; _log.LogInformation($"Site model extents {adjustedSiteModelExtents}, do not intersect RotatedTileBoundingExtents {RotatedTileBoundingExtents}"); using var mapView = new MapSurface(); mapView.SetBounds(NPixelsX, NPixelsY); var canvas = mapView.BitmapCanvas; mapView.BitmapCanvas = null; return(canvas); } // Compute the override cell boundary to be used when processing cells in the sub grids // selected as a part of this pipeline // Increase cell boundary by one cell to allow for cells on the boundary that cross the boundary SubGridTree.CalculateIndexOfCellContainingPosition(dataSelectionExtent.MinX, dataSelectionExtent.MinY, SiteModel.CellSize, SubGridTreeConsts.DefaultIndexOriginOffset, out var CellExtents_MinX, out var CellExtents_MinY); SubGridTree.CalculateIndexOfCellContainingPosition(dataSelectionExtent.MaxX, dataSelectionExtent.MaxY, SiteModel.CellSize, SubGridTreeConsts.DefaultIndexOriginOffset, out var CellExtents_MaxX, out var CellExtents_MaxY); var CellExtents = new BoundingIntegerExtent2D(CellExtents_MinX, CellExtents_MinY, CellExtents_MaxX, CellExtents_MaxY); CellExtents.Expand(1); var filterSet = FilterUtilities.ConstructFilters(Filters, VolumeType); // Construct PipelineProcessor using var processor = DIContext.Obtain <IPipelineProcessorFactory>().NewInstanceNoBuild <SubGridsRequestArgument>( RequestDescriptor, DataModelID, GridDataFromModeConverter.Convert(Mode), new SubGridsPipelinedResponseBase(), filterSet, CutFillDesign, DIContext.Obtain <Func <PipelineProcessorTaskStyle, ITRexTask> >()(PipelineProcessorTaskStyle.PVMRendering), DIContext.Obtain <Func <PipelineProcessorPipelineStyle, ISubGridPipelineBase> >()(PipelineProcessorPipelineStyle.DefaultProgressive), DIContext.Obtain <IRequestAnalyser>(), Utilities.DisplayModeRequireSurveyedSurfaceInformation(Mode) && Utilities.FilterRequireSurveyedSurfaceInformation(Filters), requestRequiresAccessToDesignFileExistenceMap: Utilities.RequestRequiresAccessToDesignFileExistenceMap(Mode, CutFillDesign), CellExtents, LiftParams ); if (filterSet.Filters.Length == 3) { var pipeline = processor.Pipeline as SubGridPipelineProgressive <SubGridsRequestArgument, SubGridRequestsResponse>; pipeline.SubGridsRequestComputeStyle = SubGridsRequestComputeStyle.SimpleVolumeThreeWayCoalescing; } // Set the PVM rendering rexTask parameters for progressive processing processor.Task.TRexNodeID = RequestingTRexNodeID; ((IPVMRenderingTask)processor.Task).TileRenderer = Renderer; // Set the spatial extents of the tile boundary rotated into the north reference frame of the cell coordinate system to act as // a final restriction of the spatial extent used to govern data requests processor.OverrideSpatialExtents.Assign(RotatedTileBoundingExtents); // Prepare the processor if (!processor.Build()) { _log.LogError($"Failed to build pipeline processor for request to model {SiteModel.ID}"); ResultStatus = RequestErrorStatus.FailedToConfigureInternalPipeline; return(null); } // Test to see if the tile can be satisfied with a representational render indicating where // data is but not what it is (this is useful when the zoom level is far enough away that we // cannot meaningfully render the data). If the size of s sub grid is smaller than // the size of a pixel in the requested tile then do this. Just check the X dimension // as the data display is isotropic. // TODO: Could this be done before creation of the pipeline processor? if (Utilities.SubGridShouldBeRenderedAsRepresentationalDueToScale(WorldTileWidth, WorldTileHeight, NPixelsX, NPixelsY, processor.OverallExistenceMap.CellSize)) { return(RenderTileAsRepresentationalDueToScale(processor.OverallExistenceMap)); // There is no need to do anything else } /* TODO - Create a scaled palette to use when rendering the data * // Create a scaled palette to use when rendering the data * if not CreateAndInitialiseWorkingColorPalette then * begin * SIGLogMessage.PublishNoODS(Self, Format('Failed to create and initialise working color palette for data: %s in datamodel %d', [TypInfo.GetEnumName(TypeInfo(TICDisplayMode), Ord(FMode)), FDataModelID]), ...Warning); * Exit; * end; */ // Renderer.WorkingPalette = WorkingColorPalette; Renderer.IsWhollyInTermsOfGridProjection = true; // Ensure the renderer knows we are using grid projection coordinates Renderer.SetBounds(RotatedTileBoundingExtents.CenterX - WorldTileWidth / 2, RotatedTileBoundingExtents.CenterY - WorldTileHeight / 2, WorldTileWidth, WorldTileHeight, NPixelsX, NPixelsY); Renderer.TileRotation = TileRotation; var performRenderStopWatch = Stopwatch.StartNew(); ResultStatus = Renderer.PerformRender(Mode, processor, ColorPalettes, Filters, LiftParams); _log.LogInformation($"Renderer.PerformRender completed in {performRenderStopWatch.Elapsed}"); if (processor.Response.ResultStatus == RequestErrorStatus.OK) { var canvas = Renderer.Displayer.MapView.BitmapCanvas; Renderer.Displayer.MapView.BitmapCanvas = null; return(canvas); } } catch (Exception e) { _log.LogError(e, "Exception occurred"); ResultStatus = RequestErrorStatus.Exception; } } return(null); }
/// <summary> /// Setup pipeline for tile request /// </summary> /// <param name="siteModelExtent">Site Model Extent</param> /// <param name="cellSize">Cell Size</param> /// <returns></returns> private async Task <bool> SetupPipelineTask(BoundingWorldExtent3D siteModelExtent, double cellSize) { var requestDescriptor = Guid.NewGuid(); if (DisplayMode == QMConstants.DisplayModeStandard) { // Note coords are always supplied lat long if (SiteModel.CSIB() == string.Empty) { ResultStatus = RequestErrorStatus.EmptyCoordinateSystem; _log.LogError($"Failed to obtain site model coordinate system CSIB file for Project:{DataModelUid}"); return(false); } } LLHCoords = new[] { new XYZ(MapUtils.Deg2Rad(TileBoundaryLL.West), MapUtils.Deg2Rad(TileBoundaryLL.South), 0), new XYZ(MapUtils.Deg2Rad(TileBoundaryLL.East), MapUtils.Deg2Rad(TileBoundaryLL.North), 0), new XYZ(MapUtils.Deg2Rad(TileBoundaryLL.West), MapUtils.Deg2Rad(TileBoundaryLL.North), 0), new XYZ(MapUtils.Deg2Rad(TileBoundaryLL.East), MapUtils.Deg2Rad(TileBoundaryLL.South), 0) }; // This will change in Part3 once development is complete var strCSIB = DisplayMode == QMConstants.DisplayModeStandard ? SiteModel.CSIB() : DIMENSIONS_2012_DC_CSIB; var NEECoords = DIContext.Obtain <ICoreXWrapper>().LLHToNEE(strCSIB, LLHCoords.ToCoreX_XYZ(), CoreX.Types.InputAs.Radians).ToTRex_XYZ(); GridIntervalX = (NEECoords[1].X - NEECoords[0].X) / (TileGridSize - 1); GridIntervalY = (NEECoords[1].Y - NEECoords[0].Y) / (TileGridSize - 1); _log.LogDebug($"#Tile#.({TileX},{TileY}) TileInfo: Zoom:{TileZ}, TileSizeXY:{Math.Round(NEECoords[1].X - NEECoords[0].X, 3)}m x {Math.Round(NEECoords[2].Y - NEECoords[0].Y, 3)}m, GridInterval(m) X:{Math.Round(GridIntervalX, 3)}, Y:{Math.Round(GridIntervalY, 3)}, GridSize:{TileGridSize}"); var WorldTileHeight = MathUtilities.Hypot(NEECoords[0].X - NEECoords[2].X, NEECoords[0].Y - NEECoords[2].Y); var WorldTileWidth = MathUtilities.Hypot(NEECoords[0].X - NEECoords[3].X, NEECoords[0].Y - NEECoords[3].Y); double dx = NEECoords[2].X - NEECoords[0].X; CenterX = NEECoords[2].X + dx / 2; double dy = NEECoords[2].Y - NEECoords[0].Y; CenterY = NEECoords[0].Y + dy / 2; // Calculate the tile rotation as the mathematical angle turned from 0 (due east) to the vector defined by dy/dx TileRotation = Math.Atan2(dy, dx); // Convert TileRotation to represent the angular deviation rather than a bearing TileRotation = (Math.PI / 2) - TileRotation; SetRotation(TileRotation); _log.LogDebug($"QMTile render executing across tile: [Rotation:{ MathUtilities.RadiansToDegrees(TileRotation)}] " + $" [BL:{NEECoords[0].X}, {NEECoords[0].Y}, TL:{NEECoords[2].X},{NEECoords[2].Y}, " + $"TR:{NEECoords[1].X}, {NEECoords[1].Y}, BR:{NEECoords[3].X}, {NEECoords[3].Y}] " + $"World Width, Height: {WorldTileWidth}, {WorldTileHeight}"); RotatedTileBoundingExtents.SetInverted(); foreach (var xyz in NEECoords) { RotatedTileBoundingExtents.Include(xyz.X, xyz.Y); } // Intersect the site model extents with the extents requested by the caller _log.LogDebug($"Tile.({TileX},{TileY}) Calculating intersection of bounding box and site model {DataModelUid}:{siteModelExtent}"); var dataSelectionExtent = new BoundingWorldExtent3D(RotatedTileBoundingExtents); dataSelectionExtent.Intersect(siteModelExtent); if (!dataSelectionExtent.IsValidPlanExtent) { ResultStatus = RequestErrorStatus.InvalidCoordinateRange; _log.LogInformation($"Tile.({TileX},{TileY}) Site model extents {siteModelExtent}, do not intersect RotatedTileBoundingExtents {RotatedTileBoundingExtents}"); return(false); } // Compute the override cell boundary to be used when processing cells in the sub grids // selected as a part of this pipeline // Increase cell boundary by one cell to allow for cells on the boundary that cross the boundary SubGridTree.CalculateIndexOfCellContainingPosition(dataSelectionExtent.MinX, dataSelectionExtent.MinY, cellSize, SubGridTreeConsts.DefaultIndexOriginOffset, out var CellExtents_MinX, out var CellExtents_MinY); SubGridTree.CalculateIndexOfCellContainingPosition(dataSelectionExtent.MaxX, dataSelectionExtent.MaxY, cellSize, SubGridTreeConsts.DefaultIndexOriginOffset, out var CellExtents_MaxX, out var CellExtents_MaxY); var CellExtents = new BoundingIntegerExtent2D(CellExtents_MinX, CellExtents_MinY, CellExtents_MaxX, CellExtents_MaxY); CellExtents.Expand(1); // Setup Task task = DIContext.Obtain <Func <PipelineProcessorTaskStyle, ITRexTask> >()(PipelineProcessorTaskStyle.QuantizedMesh) as QuantizedMeshTask; processor = DIContext.Obtain <IPipelineProcessorFactory>().NewInstanceNoBuild <SubGridsRequestArgument>(requestDescriptor: requestDescriptor, dataModelID: DataModelUid, gridDataType: GridDataType.Height, response: GriddedElevationsResponse, filters: Filters, cutFillDesign: new DesignOffset(), task: task, pipeline: DIContext.Obtain <Func <PipelineProcessorPipelineStyle, ISubGridPipelineBase> >()(PipelineProcessorPipelineStyle.DefaultProgressive), requestAnalyser: DIContext.Obtain <IRequestAnalyser>(), requireSurveyedSurfaceInformation: true, //Rendering.Utilities.DisplayModeRequireSurveyedSurfaceInformation(DisplayMode.Height) && Rendering.Utilities.FilterRequireSurveyedSurfaceInformation(Filters), requestRequiresAccessToDesignFileExistenceMap: false, overrideSpatialCellRestriction: CellExtents, liftParams: LiftParams ); // Set the grid TRexTask parameters for progressive processing processor.Task.RequestDescriptor = requestDescriptor; processor.Task.TRexNodeID = RequestingTRexNodeID; processor.Task.GridDataType = GridDataType.Height; // Set the spatial extents of the tile boundary rotated into the north reference frame of the cell coordinate system to act as // a final restriction of the spatial extent used to govern data requests processor.OverrideSpatialExtents.Assign(RotatedTileBoundingExtents); // Setup new grid array for results GriddedElevDataArray = new GriddedElevDataRow[TileGridSize, TileGridSize]; // build up a data sample grid from SW to NE for (int y = 0; y < TileGridSize; y++) { for (int x = 0; x < TileGridSize; x++) { var x1 = NEECoords[0].X + (GridIntervalX * x); var y1 = NEECoords[0].Y + (GridIntervalY * y); if (Rotating) { Rotate_point(x1, y1, out x1, out y1); } GriddedElevDataArray[x, y].Easting = x1; GriddedElevDataArray[x, y].Northing = y1; GriddedElevDataArray[x, y].Elevation = CellPassConsts.NullHeight; } } _log.LogDebug($"Tile.({TileX},{TileY}) Boundary grid coords:{string.Concat(NEECoords)}"); _log.LogDebug($"Tile.({TileX},{TileY}) First Easting:{GriddedElevDataArray[0, 0].Easting} Northing:{GriddedElevDataArray[0, 0].Northing}"); _log.LogDebug($"Tile.({TileX},{TileY}) Last Easting:{GriddedElevDataArray[TileGridSize - 1, TileGridSize - 1].Easting} Northing:{GriddedElevDataArray[TileGridSize - 1, TileGridSize - 1].Northing}"); // point to container for results task.GriddedElevDataArray = GriddedElevDataArray; task.GridIntervalX = GridIntervalX; task.GridIntervalY = GridIntervalY; task.GridSize = TileGridSize; // Tile boundary task.TileMinX = NEECoords[0].X; task.TileMinY = NEECoords[0].Y; task.TileMaxX = NEECoords[1].X; task.TileMaxY = NEECoords[1].Y; task.LowestElevation = LowestElevation; Azimuth = 0; StartNorthing = NEECoords[0].Y; StartEasting = NEECoords[0].X; // Commented out for purposes of demo until relationship between TRex mediated skip/step selection and the quantised mesh tile vertex based selection are better understood // processor.Pipeline.AreaControlSet = // new AreaControlSet(false, GridIntervalX, GridIntervalY, StartEasting, StartNorthing, Azimuth); if (!processor.Build()) { _log.LogError($"Tile.({TileX},{TileY}) Failed to build pipeline processor for request to model {DataModelUid}"); return(false); } return(true); }