Create and add features whose attribute values satisfy a predefined set of contingencies.
Use case
Contingent values are a data design feature that allow you to make values in one field dependent on values in another field. Your choice for a value on one field further constrains the domain values that can be placed on another field. In this way, contingent values enforce data integrity by applying additional constraints to reduce the number of valid field inputs.
For example, a field crew working in a sensitive habitat area may be required to stay a certain distance away from occupied bird nests, but the size of that exclusion area differs depending on the bird's level of protection according to presiding laws. Surveyors can add points of bird nests in the work area and their selection of the size of the exclusion area will be contingent on the values in other attribute fields.
How to use the sample
Tap on the map to add a feature symbolizing a bird's nest. Then choose values describing the nest's status, protection, and buffer size. Notice how different values are available depending on the values of preceding fields. Once the contingent values are validated, tap "Done" to add the feature to the map.
How it works
- Create and load the
Geodatabasefrom the mobile geodatabase location on file. - Load the
GeodatabaseFeatureTable. - Load the
ContingentValuesDefinitionfrom the feature table withGeodatabaseFeatureTable.ContingentValuesDefinition.LoadAsync(). - Create a new
FeatureLayerfrom the feature table and add it to the map. - Create a new
ArcGISFeatureusingGeodatabaseFeatureTable.CreateFeature(). - Add the new
ArcGISFeatureto the feature table usingGeodatabaseFeatureTable.AddFeatureAsync(newFeature). - After selecting a value from the initial coded values for the first field, retrieve the remaining valid contingent values for each field as you select the values for the attributes.
i. Get theContingentValueResults by usingGeodatabaseFeatureTable.GetContingentValues(newFeature, fieldName)with the feature and the target field by name.
ii. Get a list of validContingentValuesfromContingentValuesResult.ContingentValuesByFieldGroupdictionary with the name of the relevant field group.
iii. Iterate through the list of valid contingent values to create a list ofContingentCodedValuenames or the minimum and maximum values of aContingentRangeValuedepending on the type ofContingentValuereturned. - Set the
ArcGISFeatureattribute values by name withArcGISFeature.SetAttributeValue(fieldName, fieldValue). - Validate the feature's contingent values by using
GeodatabaseFeatureTable.ValidateContingencyConstraints(newFeature)with the created feature. If the resulting list is empty, the selected values are valid.
Relevant API
- CodedValue
- CodedValueDomain
- ContingencyConstraintViolation
- ContingentCodedValue
- ContingentRangeValue
- ContingentValuesDefinition
- ContingentValuesResult
- FeatureTable
Offline data
This sample uses the Contingent values birds nests mobile geodatabase and the Fillmore topographic map vector tile package for the basemap.
About the data
The mobile geodatabase contains birds nests in the Fillmore area, defined with contingent values. Each feature contains information about its status, protection, and buffer size.
Additional information
Learn more about contingent values and how to utilize them on the ArcGIS Pro documentation.
Tags
coded values, contingent values, feature table, geodatabase
Sample Code
// Copyright 2022 Esri.
//
// Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except in compliance with the License.
// You may obtain a copy of the License at: http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an
// "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific
// language governing permissions and limitations under the License.
using ArcGIS.Samples.Managers;
using Esri.ArcGISRuntime.Data;
using Esri.ArcGISRuntime.Geometry;
using Esri.ArcGISRuntime.Mapping;
using Esri.ArcGISRuntime.Symbology;
using Esri.ArcGISRuntime.UI;
using Esri.ArcGISRuntime.UI.Controls;
using Microsoft.UI.Xaml;
using System;
using System.Collections.Generic;
using System.Linq;
using System.Threading.Tasks;
namespace ArcGIS.WinUI.Samples.AddFeaturesWithContingentValues
{
[ArcGIS.Samples.Shared.Attributes.Sample(
name: "Add features with contingent values",
category: "Data",
description: "Create and add features whose attribute values satisfy a predefined set of contingencies.",
instructions: "Tap on the map to add a feature symbolizing a bird's nest. Then choose values describing the nest's status, protection, and buffer size. Notice how different values are available depending on the values of preceding fields. Once the contingent values are validated, tap \"Done\" to add the feature to the map.",
tags: new[] { "coded values", "contingent values", "feature table", "geodatabase" })]
[ArcGIS.Samples.Shared.Attributes.OfflineData("e12b54ea799f4606a2712157cf9f6e41", "b5106355f1634b8996e634c04b6a930a")]
public partial class AddFeaturesWithContingentValues
{
// The coded value domains in this sample are hardcoded for simplicity, but can be retrieved from the GeodatabaseFeatureTable's Field's Domains.
private readonly Dictionary<string, string> _statusValues = new Dictionary<string, string>() { { "Occupied", "OCCUPIED" }, { "Unoccupied", "UNOCCUPIED" } };
private readonly Dictionary<string, string> _protectionValues = new Dictionary<string, string>() { { "Endangered", "ENDANGERED" }, { "Not endangered", "NOT_ENDANGERED" }, { "N/A", "NA" } };
// Hold references for use in event handlers.
private GeodatabaseFeatureTable _geodatabaseFeatureTable;
private GraphicsOverlay _graphicsOverlay;
private ArcGISFeature _newFeature;
public AddFeaturesWithContingentValues()
{
InitializeComponent();
_ = Initialize();
}
private async Task Initialize()
{
#region Basemap
// Get the full path for the vector tile package.
string vectorTilePackagePath = DataManager.GetDataFolder("b5106355f1634b8996e634c04b6a930a", "FillmoreTopographicMap.vtpk");
// Open the vector tile package.
ArcGISVectorTiledLayer fillmoreVectorTiledLayer = new ArcGISVectorTiledLayer(new Uri(vectorTilePackagePath));
// Load the basemap from the ArcGISVectorTiledLayer.
Basemap fillmoreBasemap = new Basemap(fillmoreVectorTiledLayer);
// Add the base map to the map view.
MyMapView.Map = new Map(fillmoreBasemap);
#endregion Basemap
#region FeatureLayer
// Get the full path for the mobile geodatabase.
string geodatabasePath = DataManager.GetDataFolder("e12b54ea799f4606a2712157cf9f6e41", "ContingentValuesBirdNests.geodatabase");
// Load the geodatabase.
Geodatabase geodatabase = await Geodatabase.OpenAsync(geodatabasePath);
// Load the Geodatabase, GeodatabaseFeatureTable and the ContingentValuesDefinition.
// Get the 'BirdNests' geodatabase feature table from the mobile geodatabase.
_geodatabaseFeatureTable = geodatabase.GetGeodatabaseFeatureTable("BirdNests");
// Asynchronously load the 'BirdNests' geodatabase feature table.
await _geodatabaseFeatureTable.LoadAsync();
// Asynchronously load the contingent values definition.
await _geodatabaseFeatureTable.ContingentValuesDefinition.LoadAsync();
// Create a FeatureLayer based on the GeoDatabaseFeatureTable.
FeatureLayer nestLayer = new FeatureLayer(_geodatabaseFeatureTable);
// Add the FeatureLayer to the OperationalLayers.
MyMapView.Map.OperationalLayers.Add(nestLayer);
#endregion FeatureLayer
#region GraphicsOverlay
// Create the GraphicsOverlay with which to display the nest buffer exclusion areas.
_graphicsOverlay = new GraphicsOverlay();
Symbol bufferSymbol = new SimpleFillSymbol(SimpleFillSymbolStyle.ForwardDiagonal, System.Drawing.Color.Red, new SimpleLineSymbol(SimpleLineSymbolStyle.Solid, System.Drawing.Color.Black, 2));
_graphicsOverlay.Renderer = new SimpleRenderer(bufferSymbol);
MyMapView.GraphicsOverlays.Add(_graphicsOverlay);
// Query all the features that have a buffer size greater than zero and render a graphic that depicts the buffer.
await QueryAndBufferFeatures();
#endregion GraphicsOverlay
#region Initialize UI components
// Zoom the map to the extent of the FeatureLayer.
await MyMapView.SetViewpointGeometryAsync(nestLayer.FullExtent, 50);
StatusCombo.ItemsSource = _statusValues.Keys;
FeatureAttributesPanel.Visibility = Visibility.Collapsed;
FeatureAttributesPanel.RegisterPropertyChangedCallback(UIElement.VisibilityProperty, FeatureAttributesPanel_IsVisibleChanged);
#endregion Initialize UI components
}
#region AddFeature
private async Task QueryAndBufferFeatures()
{
if (_geodatabaseFeatureTable == null || _geodatabaseFeatureTable.LoadStatus != Esri.ArcGISRuntime.LoadStatus.Loaded) return;
try
{
// Clear the existing buffer graphics.
_graphicsOverlay.Graphics.Clear();
// Get all the features that have buffer size greater than zero.
QueryParameters parameters = new QueryParameters();
parameters.WhereClause = "BufferSize > 0";
FeatureQueryResult results = await _geodatabaseFeatureTable.QueryFeaturesAsync(parameters);
// Add a buffer graphic for each feature based on the above query.
foreach (Feature feature in results.ToList())
{
double bufferDistance = Convert.ToDouble(feature.GetAttributeValue("BufferSize"));
Geometry buffer = feature.Geometry.Buffer(bufferDistance);
MyMapView.GraphicsOverlays[0].Graphics.Add(new Graphic(buffer));
}
}
catch (Exception e)
{
await new MessageDialog2(e.Message, "Error").ShowAsync();
}
}
private async Task CreateNewEmptyFeature(GeoViewInputEventArgs e)
{
try
{
// Create a new empty feature to define attributes for.
_newFeature = (ArcGISFeature)_geodatabaseFeatureTable.CreateFeature();
// Get the normalized geometry for the tapped location and use it as the feature's geometry.
MapPoint tappedPoint = (MapPoint)e.Location.NormalizeCentralMeridian();
_newFeature.Geometry = tappedPoint;
// Add the feature to the table.
await _geodatabaseFeatureTable.AddFeatureAsync(_newFeature);
// Update the feature to get the updated objectid - a temporary ID is used before the feature is added.
_newFeature.Refresh();
if (FeatureAttributesPanel.Visibility != Visibility.Visible)
{
FeatureAttributesPanel.Visibility = Visibility.Visible;
}
}
catch (Exception ex)
{
await new MessageDialog2(ex.Message, "Error").ShowAsync();
}
}
private async Task<List<string>> GetContingentValues(string field, string fieldGroupName)
{
// Create an empty list with which to return the valid contingent values.
List<string> contingentValuesNamesList = new List<string>();
if (_geodatabaseFeatureTable.ContingentValuesDefinition.LoadStatus != Esri.ArcGISRuntime.LoadStatus.Loaded) return contingentValuesNamesList;
try
{
// Instantiate a dictionary containing all possible values for a field in the context of the contingent field groups it participates in.
ContingentValuesResult contingentValuesResult = _geodatabaseFeatureTable.GetContingentValues(_newFeature, field);
// Loop through the contingent values.
foreach (ContingentValue contingentValue in contingentValuesResult.ContingentValuesByFieldGroup[fieldGroupName])
{
// Contingent coded values are contingent values defined from a coded value domain.
// There are often multiple results returned by the ContingentValuesResult.
if (contingentValue is ContingentCodedValue contingentCodedValue)
{
contingentValuesNamesList.Add(contingentCodedValue.CodedValue.Name);
}
else if (contingentValue is ContingentRangeValue contingentRangeValue)
{
contingentValuesNamesList.Add(contingentRangeValue.MinValue.ToString());
contingentValuesNamesList.Add(contingentRangeValue.MaxValue.ToString());
}
}
}
catch (Exception e)
{
await new MessageDialog2(e.Message, "Error").ShowAsync();
}
return contingentValuesNamesList;
}
private bool ValidateContingentValues(out List<string> fieldGroupNames, out int numberOfViolations)
{
fieldGroupNames = new List<string>();
numberOfViolations = 0;
if (_geodatabaseFeatureTable.ContingentValuesDefinition.LoadStatus != Esri.ArcGISRuntime.LoadStatus.Loaded || _newFeature == null) return false;
IReadOnlyList<ContingencyConstraintViolation> contingencyConstraintViolations = _geodatabaseFeatureTable.ValidateContingencyConstraints(_newFeature);
numberOfViolations = contingencyConstraintViolations.Count;
// If the number of contingency constraint violations is zero the attribute map satisfies all contingencies.
if (numberOfViolations.Equals(0))
{
return true;
}
else
{
foreach (ContingencyConstraintViolation violation in contingencyConstraintViolations)
{
fieldGroupNames.Add(violation.FieldGroup.Name);
}
}
return false;
}
private async Task CreateNewNest()
{
// Once the attribute map is filled and validated, save the feature to the geodatabase feature table.
await _geodatabaseFeatureTable.UpdateFeatureAsync(_newFeature);
_ = QueryAndBufferFeatures();
_newFeature = null;
}
private async Task DiscardFeature()
{
try
{
// Delete the newly created feature from the geodatabase feature table.
await _geodatabaseFeatureTable.DeleteFeatureAsync(_newFeature);
_newFeature = null;
}
catch (Exception e)
{
await new MessageDialog2(e.Message, "Error").ShowAsync();
}
}
private async Task UpdateField(string field, object value)
{
try
{
// Update the feature's appropriate attribute based on a given field name and a value.
switch (field)
{
case "Status":
_newFeature.SetAttributeValue(field, _statusValues[value.ToString()]);
break;
case "Protection":
_newFeature.SetAttributeValue(field, _protectionValues[value.ToString()]);
break;
case "BufferSize":
_newFeature.SetAttributeValue(field, Convert.ToInt32(value));
break;
default:
await new MessageDialog2($"{field} not found in any of the data dictionaries.", "Error").ShowAsync();
break;
}
}
catch (Exception e)
{
await new MessageDialog2(e.Message, "Error").ShowAsync();
}
}
private async Task SetProtectionComboItems()
{
List<string> protectionItems = await GetContingentValues("Protection", "ProtectionFieldGroup");
// Get the appropriate contingent values for populating the protection combo component.
if (protectionItems.Any())
{
ProtectionCombo.SelectionChanged -= ProtectionCombo_Selected;
ProtectionCombo.ItemsSource = protectionItems;
ProtectionCombo.SelectionChanged += ProtectionCombo_Selected;
}
}
private async Task SetBufferSizeSliderRange()
{
// Get the valid contingent range values for the subsequent buffer size slider.
List<string> minMax = await GetContingentValues("BufferSize", "BufferSizeFieldGroup");
if (minMax[0] != "")
{
// Set the minimum and maximum slider values based on the valid contingent value buffer size range.
BufferSizeSlider.Minimum = int.Parse(minMax[0]);
BufferSizeSlider.Maximum = int.Parse(minMax[1]);
BufferSizeSlider.Value = BufferSizeSlider.Minimum;
// If the max value in the range is 0, set the buffer size to 0.
if (minMax[1] == "0")
{
// Update the feature's buffer size with the selected value.
await UpdateField("BufferSize", 0);
}
}
}
private async Task SaveFeature()
{
List<string> fieldGroupNames = new List<string>();
int numberOfViolations = 0;
// If the contingent values are valid, save the data and hide the attribute panel.
if (ValidateContingentValues(out fieldGroupNames, out numberOfViolations))
{
_ = CreateNewNest();
FeatureAttributesPanel.Visibility = Visibility.Collapsed;
}
else
{
await new MessageDialog2($"Error saving feature. {numberOfViolations} violation(s) in field group(s) {string.Join(", ", fieldGroupNames)}.", "Error").ShowAsync();
}
}
#endregion AddFeature
#region EventHandlers
private void MyMapView_GeoViewTapped(object sender, GeoViewInputEventArgs e)
{
// If a new feature is currently being created do not create another one.
if (_newFeature == null)
{
_ = CreateNewEmptyFeature(e);
}
}
private void StatusCombo_Selected(object sender, RoutedEventArgs e)
{
// Update the feature's attribute map with the selection.
_ = UpdateField("Status", StatusCombo.SelectedItem);
_ = SetProtectionComboItems();
}
private void ProtectionCombo_Selected(object sender, RoutedEventArgs e)
{
// Update the feature's attribute map with the selection.
_ = UpdateField("Protection", ProtectionCombo.SelectedItem);
_ = SetBufferSizeSliderRange();
}
private void BufferSizeSlider_ValueChanged(object sender, Microsoft.UI.Xaml.Controls.Primitives.RangeBaseValueChangedEventArgs e)
{
// Update the feature's buffer size with the selected value.
_ = UpdateField("BufferSize", BufferSizeSlider.Value);
}
private void DiscardButton_Click(object sender, RoutedEventArgs e)
{
_ = DiscardFeature();
FeatureAttributesPanel.Visibility = Visibility.Collapsed;
}
private void SaveButton_Click(object sender, RoutedEventArgs e)
{
_ = SaveFeature();
}
private void FeatureAttributesPanel_IsVisibleChanged(DependencyObject sender, DependencyProperty dp)
{
// Disable event handlers when the attribute panel is hidden.
if (FeatureAttributesPanel.Visibility != Visibility.Visible)
{
StatusCombo.SelectionChanged -= StatusCombo_Selected;
ProtectionCombo.SelectionChanged -= ProtectionCombo_Selected;
BufferSizeSlider.ValueChanged -= BufferSizeSlider_ValueChanged;
return;
}
// Reset attribute panel values when the panel opens.
StatusCombo.SelectedIndex = -1;
ProtectionCombo.SelectedIndex = -1;
BufferSizeSlider.Value = BufferSizeSlider.Minimum;
// Add the event handlers to the attribute panel.
StatusCombo.SelectionChanged += StatusCombo_Selected;
ProtectionCombo.SelectionChanged += ProtectionCombo_Selected;
BufferSizeSlider.ValueChanged += BufferSizeSlider_ValueChanged;
}
#endregion EventHandlers
}
}