private void ReadFile(string inputFile)
{
TimeBufferer output = new TimeInterpolator();
TimeSet timeSet = output.TTimeSet;
IElementSet elementSet;
StreamReader reader = new StreamReader(inputFile);
// Read quantity and imply unit
string line = GetNextLine(reader).Trim(' ', '"');
Quantity quantity = new Quantity(line);
if (line.Equals("Flow", StringComparison.InvariantCultureIgnoreCase))
{
quantity.Unit = new Unit(PredefinedUnits.CubicMeterPerSecond);
}
else if (line.Equals("WaterLevel", StringComparison.InvariantCultureIgnoreCase))
{
quantity.Unit = new Unit(PredefinedUnits.Meter);
}
else
{
quantity.Unit = new Unit("Unspecified unit");
}
output.ValueDefinition = quantity;
// Read elementset
line = GetNextLine(reader);
string[] elements = line.Split(';');
string elementTypeString = elements[0].Trim('"');
if (elementTypeString.Equals("IdBased", StringComparison.InvariantCultureIgnoreCase))
{
var idelementSet = new ElementSet(inputFile + "-" + quantity.Caption, inputFile, ElementType.IdBased, "");
for (int i = 1; i < elements.Length; i++)
{
idelementSet.AddElement(new Element(elements[i].Trim('"')));
}
elementSet = idelementSet;
}
else if (elementTypeString.Equals("Points", StringComparison.InvariantCultureIgnoreCase))
{
var pelementSet = new ElementSet(inputFile + "-" + quantity.Caption, inputFile, ElementType.Point, "");
for (int i = 1; i < elements.Length; i++)
{
string[] coordinates = elements[i].Trim('"', '(', ')').Split(',');
if (coordinates.Length < 2)
{
throw new InvalidDataException("Invalid file format: only one coordinate for point: " + inputFile);
}
Element element = new Element();
double x = Double.Parse(coordinates[0], NumberFormatInfo.InvariantInfo);
double y = Double.Parse(coordinates[1], NumberFormatInfo.InvariantInfo);
Coordinate elmtCoor = new Coordinate(x, y);
element.Vertices = new Coordinate[] { elmtCoor };
pelementSet.AddElement(element);
}
elementSet = pelementSet;
}
else if (elementTypeString.Equals("RegularGrid", StringComparison.InvariantCultureIgnoreCase))
{
Spatial2DRegularGrid grid = new Spatial2DRegularGrid();
grid.IsNodeBased = false;
string[] parts = elements[1].Trim('"', '(', ')').Split(',');
grid.X0 = Double.Parse(parts[0], NumberFormatInfo.InvariantInfo);
grid.Y0 = Double.Parse(parts[1], NumberFormatInfo.InvariantInfo);
grid.Dx = Double.Parse(parts[2], NumberFormatInfo.InvariantInfo);
grid.Dy = Double.Parse(parts[3], NumberFormatInfo.InvariantInfo);
grid.XCount = Int32.Parse(parts[4], NumberFormatInfo.InvariantInfo);
grid.YCount = Int32.Parse(parts[5], NumberFormatInfo.InvariantInfo);
grid.Orientation = (parts.Length < 5) ? 0 : Int32.Parse(parts[6], NumberFormatInfo.InvariantInfo);
elementSet = new Spatial2DGridWrapper(grid);
}
else
{
throw new InvalidDataException("Invalid file format: Element type not reckognized: " + inputFile);
}
output.SpatialDefinition = elementSet;
// Read times and values. First element is time, following are element values.
ITimeSpaceValueSet valueSet = output.Values;
while ((line = GetNextLine(reader)) != null)
{
string[] fileValues = line.Split(';');
if (fileValues.Length - 1 != elementSet.ElementCount)
{
throw new InvalidDataException("Number of data does not match number of elements on line: \n" + line);
}
DateTime timestamp = DateTime.ParseExact(fileValues[0].Trim('"'), "yyyy-MM-dd HH:mm", CultureInfo.InvariantCulture);
Time time = new Time(timestamp);
double[] locationValues = new double[fileValues.Length - 1];
for (int i = 1; i < fileValues.Length; i++)
{
locationValues[i - 1] = Double.Parse(fileValues[i].Trim('"'), NumberFormatInfo.InvariantInfo);
}
timeSet.Times.Add(time);
valueSet.Values2D.Add(locationValues);
}
reader.Close();
timeSet.SetTimeHorizonFromTimes();
_outputs.Add(output);
}
public void CouplingGwRiver()
{
/// bit 1: Decides whether the timeInterpolator or grid-to-line adaptor comes first
/// bit 2: when true, using a 16x16 gw grid (instead of 2x2)
/// bit 3: when true, bi-directinal: adds a link from gwModel to river, with the gw-level
for (int runNumber = 0; runNumber < 8; runNumber++)
{
//if (runNumber != 3)
// continue;
Console.Out.WriteLine("runNumber: " + runNumber);
// Create trigger inputs
Input queryDischargeItem = CreateDischargeInput();
Input queryVolume = CreateVolumeInput();
// Create models
LinkableEngine riverModel = CreateRiverModel();
ITimeSpaceComponent gwModel = CreateGwModel();
// Add arguments and initialize
IDictionary <string, IArgument> gwArgs = gwModel.Arguments.Dictionary();
// Increasing model grid size (otherwise GW model runs full too fast)
gwArgs.UpdateValue("dx", 400.0);
gwArgs.UpdateValue("dy", 400.0);
gwArgs.UpdateValue("x0", 200.0);
gwArgs.UpdateValue("y0", 200.0);
int gwGridSize = 2 * 2;
if ((runNumber & 2) == 2) // set 16 x 16 grid
{
gwArgs.UpdateValue("dx", 50.0);
gwArgs.UpdateValue("dy", 50.0);
gwArgs.UpdateValue("XCount", 16);
gwArgs.UpdateValue("ycount", 16);
gwGridSize = 16 * 16;
}
gwModel.Initialize();
IDictionary <string, IArgument> riverArgs = riverModel.Arguments.Dictionary();
// Increasing model grid size (otherwise GW model runs full too fast)
riverArgs.UpdateValue("xyscale", 100.0);
riverModel.Initialize();
// Connect triggering inputs
ITimeSpaceOutput flowOnBranch = UTHelper.FindOutputItem(riverModel, "Branch:2:Flow");
TimeInterpolator flowOnBranch2 = new TimeInterpolator(flowOnBranch);
flowOnBranch.AddAdaptedOutput(flowOnBranch2);
flowOnBranch2.AddConsumer(queryDischargeItem);
ITimeSpaceOutput storageInGw = UTHelper.FindOutputItem(gwModel, "Grid.Storage");
TimeInterpolator storageInGw2 = new TimeInterpolator(storageInGw);
storageInGw.AddAdaptedOutput(storageInGw2);
storageInGw2.AddConsumer(queryVolume);
//========== Couple leakage items ==========
// put leakage from river into ground water model
{
ITimeSpaceOutput riverLeakageOutput = UTHelper.FindOutputItem(riverModel, "WholeRiver:Leakage");
ITimeSpaceInput gwInflowInput = UTHelper.FindInputItem(gwModel, "Grid.Inflow");
// Two adaptors are added: Time buffer and line-to-grid adaptor
// they can be added in any order (though time buffer first will use less memory)
if ((runNumber & 1) == 1)
{
// Time interpolator
TimeInterpolator riverLeakageOutput2 = new TimeInterpolator(riverLeakageOutput);
riverLeakageOutput.AddAdaptedOutput(riverLeakageOutput2);
// Element mapper from polyline to polygon, weighted sum version
ElementMapperAdaptedOutput riverLeakageOutputGrid =
new ElementMapperAdaptedOutput(new Identifier("ElementMapper501"), riverLeakageOutput2,
gwInflowInput.ElementSet());
riverLeakageOutput2.AddAdaptedOutput(riverLeakageOutputGrid);
riverLeakageOutputGrid.AddConsumer(gwInflowInput);
}
else
{
// Element mapper from polyline to polygon, weighted sum version
ElementMapperAdaptedOutput riverLeakageOutputGrid =
new ElementMapperAdaptedOutput(new Identifier("ElementMapper501"), riverLeakageOutput,
gwInflowInput.ElementSet());
riverLeakageOutput.AddAdaptedOutput(riverLeakageOutputGrid);
// Time interpolator
TimeInterpolator riverLeakageOutput2 = new TimeInterpolator(riverLeakageOutputGrid);
riverLeakageOutputGrid.AddAdaptedOutput(riverLeakageOutput2);
riverLeakageOutput2.AddConsumer(gwInflowInput);
}
}
//========== Couple ground water level items ==========
if ((runNumber & 4) == 4)
{
// put ground water level from ground water model into river
ITimeSpaceInput riverGwleveInput = UTHelper.FindInputItem(riverModel, "WholeRiver:GroundWaterLevel");
ITimeSpaceOutput gwLevelOutput = UTHelper.FindOutputItem(gwModel, "Grid.gwLevel");
// Two adaptors are added: Time buffer and grid-to-line adaptor
// they can be added in any order (though time buffer last will use less memory)
if ((runNumber & 1) == 1)
{
// Time interpolator
var gwLevelOutput2 = new TimeExtrapolator(gwLevelOutput);
gwLevelOutput.AddAdaptedOutput(gwLevelOutput2);
// Element mapper from polyline to polygon, weighted sum version
var gwLevelOutputLine =
new ElementMapperAdaptedOutput(new Identifier("ElementMapper700"), gwLevelOutput2,
riverGwleveInput.ElementSet());
gwLevelOutput2.AddAdaptedOutput(gwLevelOutputLine);
gwLevelOutputLine.AddConsumer(riverGwleveInput);
}
else
{
// Element mapper from polyline to polygon, weighted sum version
var gwLevelOutputLine =
new ElementMapperAdaptedOutput(new Identifier("ElementMapper700"), gwLevelOutput,
riverGwleveInput.ElementSet());
gwLevelOutput.AddAdaptedOutput(gwLevelOutputLine);
// Time interpolator
var gwLevelOutput2 = new TimeExtrapolator(gwLevelOutputLine);
gwLevelOutputLine.AddAdaptedOutput(gwLevelOutput2);
gwLevelOutput2.AddConsumer(riverGwleveInput);
}
}
//========== Run ==========
// Validate
riverModel.Validate();
Assert.IsTrue(riverModel.Status == LinkableComponentStatus.Valid);
gwModel.Validate();
Assert.IsTrue(gwModel.Status == LinkableComponentStatus.Valid);
// Prepare
riverModel.Prepare();
Assert.IsTrue(riverModel.Status == LinkableComponentStatus.Updated);
gwModel.Prepare();
Assert.IsTrue(gwModel.Status == LinkableComponentStatus.Updated);
// specify query times
double triggerTime0 = riverModel.CurrentTime.StampAsModifiedJulianDay;
double triggerTime1 = triggerTime0 + 1;
double triggerTime2 = triggerTime0 + 2;
double triggerTime3 = triggerTime0 + 12.1;
double triggerTime4 = triggerTime0 + 16.7;
/// Properties of the river, without gw-level input
/// Inflow into each node from rainfall runoff is 10 L/s
/// Inflow to node 1: 10 L/s - leaking 5 L/s on branch 1
/// Inflow to node 2: 10 + 5 L/s - leaking 15/2 L/s on branch 2
/// Inflow to node 3: 10 + 15/2 L/s - leaking 35/4 L/s on branch 3
/// Total leakage 5+15/2+35/4 = (20+30+35)/4 = 85/4 L/s
///
/// Number of seconds in a day: 60*60*24 = 86400
// check initial values
Assert.AreEqual(1, ValueSet.GetElementCount(flowOnBranch.Values), "#values for " + flowOnBranch.Id);
Assert.AreEqual(7.0, (double)flowOnBranch.Values.GetValue(0, 0), "Value[0] as property");
Assert.AreEqual(gwGridSize, ValueSet.GetElementCount(storageInGw.Values), "#values for " + storageInGw.Id);
Assert.AreEqual(0, SumTimeStep(storageInGw.Values, 0));
// get values for specified query times, 1 days
// Totally leaking: 86400 * 85/4 = 1.836e6
// For the bi-directional coupling:
// the entire first day the river uses extrapolated values from the
// gwModel, which gives a gwLevel of -10, hence same value as for the uni-directional
queryDischargeItem.TimeSet.SetSingleTimeStamp(triggerTime1);
ITimeSpaceValueSet valuesV = storageInGw2.GetValues(queryDischargeItem);
ITimeSpaceValueSet valuesQ = flowOnBranch2.GetValues(queryDischargeItem);
Assert.AreEqual(35.0 / 4.0, (double)valuesQ.GetValue(0, 0));
Assert.AreEqual(1.836e6, SumTimeStep(valuesV, 0), 1e-4);
// Print out, to load in a plotting program for verification
//StringBuilder b = new StringBuilder();
//foreach (double val in valuesV.GetElementValuesForTime(0))
// b.AppendLine(val.ToString(NumberFormatInfo.InvariantInfo));
//Console.Out.WriteLine(b.ToString());
// get values for specified query times, 2 days
// 2 * 86400 * 85/4 = 3.672e6
queryDischargeItem.TimeSet.SetSingleTimeStamp(triggerTime2);
valuesV = storageInGw2.GetValues(queryDischargeItem);
valuesQ = flowOnBranch2.GetValues(queryDischargeItem);
if ((runNumber & 4) != 4) // unidirectional
{
Assert.AreEqual(35.0 / 4.0, (double)valuesQ.GetValue(0, 0));
Assert.AreEqual(3.672e6, SumTimeStep(valuesV, 0), 1e-4);
}
else if ((runNumber & 2) != 2) // bi-directional 2x2 grid
{
Assert.AreEqual(8.843648, (double)valuesQ.GetValue(0, 0), 1e-4);
Assert.AreEqual(3.66390879366e6, SumTimeStep(valuesV, 0), 1e-4);
}
else // bi-directional 16x16 grid
{
Assert.AreEqual(9.65307, (double)valuesQ.GetValue(0, 0), 1e-4);
Assert.AreEqual(3.59397465219e6, SumTimeStep(valuesV, 0), 1e-4);
}
// get values for specified query times, 12.1 days
// 12.1 * 86400 * 85/4 = 2.22156e7
queryDischargeItem.TimeSet.SetSingleTimeStamp(triggerTime3);
valuesV = storageInGw2.GetValues(queryDischargeItem);
valuesQ = flowOnBranch2.GetValues(queryDischargeItem);
if ((runNumber & 4) != 4) // unidirectional
{
Assert.AreEqual(35.0 / 4.0, (double)valuesQ.GetValue(0, 0));
Assert.AreEqual(2.22156e7, SumTimeStep(valuesV, 0), 1e-4);
}
else if ((runNumber & 2) != 2) // bi-directional 2x2 grid
{
Assert.AreEqual(9.87828, (double)valuesQ.GetValue(0, 0), 1e-4);
Assert.AreEqual(2.16704019338e7, SumTimeStep(valuesV, 0), 1e-4);
}
else // bi-directional 16x16 grid
{
Assert.AreEqual(18.546999, (double)valuesQ.GetValue(0, 0), 1e-4);
Assert.AreEqual(1.722400002557e7, SumTimeStep(valuesV, 0), 1e-4);
}
// get values for specified query times, 16.7 days
// 16.7 * 86400 * 85/4 = 3.06612e7
queryDischargeItem.TimeSet.SetSingleTimeStamp(triggerTime4);
valuesV = storageInGw2.GetValues(queryDischargeItem);
valuesQ = flowOnBranch2.GetValues(queryDischargeItem);
if ((runNumber & 4) != 4) // unidirectional
{
Assert.AreEqual(35.0 / 4.0, (double)valuesQ.GetValue(0, 0));
Assert.AreEqual(3.06612e7, SumTimeStep(valuesV, 0), 1e-4);
}
else if ((runNumber & 2) != 2) // bi-directional 2x2 grid
{
Assert.AreEqual(10.255535, (double)valuesQ.GetValue(0, 0), 1e-4);
Assert.AreEqual(2.9595872035072e7, SumTimeStep(valuesV, 0), 1e-4);
}
else // bi-directional 16x16 grid
{
Assert.AreEqual(20.98699, (double)valuesQ.GetValue(0, 0), 1e-4);
Assert.AreEqual(2.12991179998e7, SumTimeStep(valuesV, 0), 1e-4);
}
}
}
public void CouplingGwRiver2()
{
/// runNumber 0: Using MultiInput
/// runNumber 1: Using MultiInputAdaptor
/// runNumber 2: Using MultiInputAdaptorFactory
for (int runNumber = 0; runNumber < 3; runNumber++)
{
Console.Out.WriteLine("runNumber: " + runNumber);
// Create trigger inputs
Input queryDischargeItem = CreateDischargeInput();
Input queryVolume = CreateVolumeInput();
// Create models
LinkableEngine riverModel = CreateRiverModel();
LinkableEngine riverModel2 = CreateRiverModel();
ITimeSpaceComponent gwModel = CreateGwModel();
// Add arguments and initialize
IDictionary <string, IArgument> gwArgs = gwModel.Arguments.Dictionary();
// Increasing model grid size (otherwise GW model runs full too fast)
gwArgs.UpdateValue("dx", 50.0);
gwArgs.UpdateValue("dy", 50.0);
gwArgs.UpdateValue("x0", 0.0);
gwArgs.UpdateValue("y0", 200.0);
gwArgs.UpdateValue("XCount", 24);
gwArgs.UpdateValue("ycount", 16);
if (runNumber == 0)
{
gwArgs.UpdateValue("UseMultiInput", true);
}
gwModel.Initialize();
int gwGridSize = 24 * 16;
IDictionary <string, IArgument> riverArgs = riverModel.Arguments.Dictionary();
// Increasing model grid size (otherwise GW model runs full too fast)
riverArgs.UpdateValue("xyscale", 100.0);
riverModel.Initialize();
IDictionary <string, IArgument> river2Args = riverModel2.Arguments.Dictionary();
// Increasing model grid size (otherwise GW model runs full too fast)
river2Args.UpdateValue("xyscale", 100.0);
// Move river2 sligthly away from river1
river2Args.UpdateValue("xoffset", -220.0);
river2Args.UpdateValue("yoffset", 180.0);
riverModel2.Initialize();
// Connect triggering inputs
ITimeSpaceOutput flowOnBranch = UTHelper.FindOutputItem(riverModel, "Branch:2:Flow");
TimeInterpolator flowOnBranch2 = new TimeInterpolator(flowOnBranch);
flowOnBranch.AddAdaptedOutput(flowOnBranch2);
flowOnBranch2.AddConsumer(queryDischargeItem);
ITimeSpaceOutput storageInGw = UTHelper.FindOutputItem(gwModel, "Grid.Storage");
TimeInterpolator storageInGw2 = new TimeInterpolator(storageInGw);
storageInGw.AddAdaptedOutput(storageInGw2);
storageInGw2.AddConsumer(queryVolume);
//========== Couple leakage items ==========
ITimeSpaceInput gwInflowInput = UTHelper.FindInputItem(gwModel, "Grid.Inflow");
//========== IBaseMultiInput linking ==========
if (runNumber == 0)
{
/// Example of adding up two outputs into one input, by the use of
/// an IBaseMultiInput implementation
Assert.IsTrue(gwInflowInput is IBaseMultiInput);
Assert.IsTrue(gwInflowInput is ITimeSpaceMultiInput);
// put leakage from river1 into ground water model
{
ITimeSpaceOutput riverLeakageOutput = UTHelper.FindOutputItem(riverModel, "WholeRiver:Leakage");
// Two adaptors are added: Time buffer and line-to-grid adaptor
// they can be added in any order (though time buffer first will use less memory)
// Time interpolator
TimeInterpolator riverLeakageOutput2 = new TimeInterpolator(riverLeakageOutput);
riverLeakageOutput.AddAdaptedOutput(riverLeakageOutput2);
// Element mapper from polyline to polygon, weighted sum version
ElementMapperAdaptedOutput riverLeakageOutputGrid =
new ElementMapperAdaptedOutput(new Identifier("ElementMapper501"), riverLeakageOutput2,
gwInflowInput.ElementSet());
riverLeakageOutput2.AddAdaptedOutput(riverLeakageOutputGrid);
// Note !!!: No special action
riverLeakageOutputGrid.AddConsumer(gwInflowInput);
}
// put leakage from river2 into ground water model
{
ITimeSpaceOutput riverLeakageOutput = UTHelper.FindOutputItem(riverModel2, "WholeRiver:Leakage");
// Two adaptors are added: Time buffer and line-to-grid adaptor
// they can be added in any order (though time buffer first will use less memory)
// Time interpolator
TimeInterpolator riverLeakageOutput2 = new TimeInterpolator(riverLeakageOutput);
riverLeakageOutput.AddAdaptedOutput(riverLeakageOutput2);
// Element mapper from polyline to polygon, weighted sum version
ElementMapperAdaptedOutput riverLeakageOutputGrid =
new ElementMapperAdaptedOutput(new Identifier("ElementMapper501"), riverLeakageOutput2,
gwInflowInput.ElementSet());
riverLeakageOutput2.AddAdaptedOutput(riverLeakageOutputGrid);
// Note !!!: No special action
riverLeakageOutputGrid.AddConsumer(gwInflowInput);
}
}
//========== MultiInputAdaptor linking ==========
if (runNumber == 1)
{
/// Example of adding up two outputs into one input, by the use of
/// a MultiInputAdaptor class
// Note !!!: Creating a MultiInputAdaptor
MultiInputAdaptor sourceAdder = new MultiInputAdaptor("SomeId")
{
SpatialDefinition = gwInflowInput.SpatialDefinition
};
// put leakage from river1 into ground water model
// Two adaptors are added: Time buffer and line-to-grid adaptor
{
ITimeSpaceOutput riverLeakageOutput = UTHelper.FindOutputItem(riverModel, "WholeRiver:Leakage");
// Time interpolator
TimeInterpolator riverLeakageOutput2 = new TimeInterpolator(riverLeakageOutput);
riverLeakageOutput.AddAdaptedOutput(riverLeakageOutput2);
// Element mapper from polyline to polygon, weighted sum version
ElementMapperAdaptedOutput riverLeakageOutputGrid =
new ElementMapperAdaptedOutput(new Identifier("ElementMapper501"), riverLeakageOutput2,
gwInflowInput.ElementSet());
riverLeakageOutput2.AddAdaptedOutput(riverLeakageOutputGrid);
// Note !!!: Adding to the list of adaptees
sourceAdder.Adaptees.Add(riverLeakageOutputGrid);
riverLeakageOutputGrid.AddAdaptedOutput(sourceAdder);
}
// put leakage from river2 into ground water model
// Two adaptors are added: Time buffer and line-to-grid adaptor
{
ITimeSpaceOutput riverLeakageOutput = UTHelper.FindOutputItem(riverModel2, "WholeRiver:Leakage");
// Time interpolator
TimeInterpolator riverLeakageOutput2 = new TimeInterpolator(riverLeakageOutput);
riverLeakageOutput.AddAdaptedOutput(riverLeakageOutput2);
// Element mapper from polyline to polygon, weighted sum version
ElementMapperAdaptedOutput riverLeakageOutputGrid =
new ElementMapperAdaptedOutput(new Identifier("ElementMapper501"), riverLeakageOutput2,
gwInflowInput.ElementSet());
riverLeakageOutput2.AddAdaptedOutput(riverLeakageOutputGrid);
// Note !!!: Adding to the list of adaptees
sourceAdder.Adaptees.Add(riverLeakageOutputGrid);
riverLeakageOutputGrid.AddAdaptedOutput(sourceAdder);
}
// Note !!!: Connect the gwInflowInput and the multiInputAdaptor
sourceAdder.AddConsumer(gwInflowInput);
}
//========== MultiInputAdaptorFactory linking ==========
if (runNumber == 2)
{
/// Example of adding up two outputs into one input, by the use of
/// an MultiInputAdaptorFactory implementation
var factory = new MultiInputAdaptorFactory(gwModel);
// put leakage from river1 into ground water model
// Two adaptors are added: Time buffer and line-to-grid adaptor
{
ITimeSpaceOutput riverLeakageOutput = UTHelper.FindOutputItem(riverModel, "WholeRiver:Leakage");
// Time interpolator
TimeInterpolator riverLeakageOutput2 = new TimeInterpolator(riverLeakageOutput);
riverLeakageOutput.AddAdaptedOutput(riverLeakageOutput2);
// Element mapper from polyline to polygon, weighted sum version
ElementMapperAdaptedOutput riverLeakageOutputGrid =
new ElementMapperAdaptedOutput(new Identifier("ElementMapper501"), riverLeakageOutput2,
gwInflowInput.ElementSet());
riverLeakageOutput2.AddAdaptedOutput(riverLeakageOutputGrid);
// Note !!!: Creating a new AdaptedOutput and adding it
IIdentifiable[] identifiables = factory.GetAvailableAdaptedOutputIds(riverLeakageOutputGrid, gwInflowInput);
IBaseAdaptedOutput myOutput = factory.CreateAdaptedOutput(identifiables[0], riverLeakageOutputGrid, gwInflowInput);
myOutput.AddConsumer(gwInflowInput);
}
// put leakage from river2 into ground water model
// Two adaptors are added: Time buffer and line-to-grid adaptor
{
ITimeSpaceOutput riverLeakageOutput = UTHelper.FindOutputItem(riverModel2, "WholeRiver:Leakage");
// Time interpolator
TimeInterpolator riverLeakageOutput2 = new TimeInterpolator(riverLeakageOutput);
riverLeakageOutput.AddAdaptedOutput(riverLeakageOutput2);
// Element mapper from polyline to polygon, weighted sum version
ElementMapperAdaptedOutput riverLeakageOutputGrid =
new ElementMapperAdaptedOutput(new Identifier("ElementMapper501"), riverLeakageOutput2,
gwInflowInput.ElementSet());
riverLeakageOutput2.AddAdaptedOutput(riverLeakageOutputGrid);
// Note !!!: Creating a new AdaptedOutput and adding it
IIdentifiable[] identifiables = factory.GetAvailableAdaptedOutputIds(riverLeakageOutputGrid, gwInflowInput);
IBaseAdaptedOutput myOutput = factory.CreateAdaptedOutput(identifiables[0], riverLeakageOutputGrid, gwInflowInput);
myOutput.AddConsumer(gwInflowInput);
}
}
//========== Run ==========
// Validate
riverModel.Validate();
Assert.IsTrue(riverModel.Status == LinkableComponentStatus.Valid);
riverModel2.Validate();
Assert.IsTrue(riverModel2.Status == LinkableComponentStatus.Valid);
gwModel.Validate();
Assert.IsTrue(gwModel.Status == LinkableComponentStatus.Valid);
// Prepare
riverModel.Prepare();
Assert.IsTrue(riverModel.Status == LinkableComponentStatus.Updated);
riverModel2.Prepare();
Assert.IsTrue(riverModel2.Status == LinkableComponentStatus.Updated);
gwModel.Prepare();
Assert.IsTrue(gwModel.Status == LinkableComponentStatus.Updated);
// specify query times
double triggerTime0 = riverModel.CurrentTime.StampAsModifiedJulianDay;
double triggerTime1 = triggerTime0 + 1;
double triggerTime2 = triggerTime0 + 2;
double triggerTime3 = triggerTime0 + 12.1;
double triggerTime4 = triggerTime0 + 16.7;
/// Properties of the river, without gw-level input
/// Inflow into each node from rainfall runoff is 10 L/s
/// Inflow to node 1: 10 L/s - leaking 5 L/s on branch 1
/// Inflow to node 2: 10 + 5 L/s - leaking 15/2 L/s on branch 2
/// Inflow to node 3: 10 + 15/2 L/s - leaking 35/4 L/s on branch 3
/// Total leakage 5+15/2+35/4 = (20+30+35)/4 = 85/4 L/s
///
/// Number of seconds in a day: 60*60*24 = 86400
// check initial values
Assert.AreEqual(1, ValueSet.GetElementCount(flowOnBranch.Values), "#values for " + flowOnBranch.Id);
Assert.AreEqual(7.0, (double)flowOnBranch.Values.GetValue(0, 0), "Value[0] as property");
Assert.AreEqual(gwGridSize, ValueSet.GetElementCount(storageInGw.Values), "#values for " + storageInGw.Id);
Assert.AreEqual(0, SumTimeStep(storageInGw.Values, 0));
// get values for specified query times, 1 days
// Totally leaking: 86400 * 85/4 = 1.836e6
// For the bi-directional coupling:
// the entire first day the river uses extrapolated values from the
// gwModel, which gives a gwLevel of -10, hence same value as for the uni-directional
queryDischargeItem.TimeSet.SetSingleTimeStamp(triggerTime1);
ITimeSpaceValueSet valuesV = storageInGw2.GetValues(queryDischargeItem);
ITimeSpaceValueSet valuesQ = flowOnBranch2.GetValues(queryDischargeItem);
Assert.AreEqual(35.0 / 4.0, (double)valuesQ.GetValue(0, 0));
Assert.AreEqual(2 * 1.836e6, SumTimeStep(valuesV, 0), 1e-4);
// Print out, to load in a plotting program for verification
StringBuilder b = new StringBuilder();
IList valV = valuesV.GetElementValuesForTime(0);
int ivalvV = 0;
for (int i = 0; i < 16; i++)
{
for (int j = 0; j < 24; j++)
{
b.Append(((double)valV[ivalvV++]).ToString(NumberFormatInfo.InvariantInfo));
b.Append(" ");
}
b.AppendLine();
}
//Console.Out.WriteLine(b.ToString());
// get values for specified query times, 2 days
// 2 * 86400 * 85/4 = 3.672e6
queryDischargeItem.TimeSet.SetSingleTimeStamp(triggerTime2);
valuesV = storageInGw2.GetValues(queryDischargeItem);
valuesQ = flowOnBranch2.GetValues(queryDischargeItem);
Assert.AreEqual(35.0 / 4.0, (double)valuesQ.GetValue(0, 0));
Assert.AreEqual(2 * 3.672e6, SumTimeStep(valuesV, 0), 1e-4);
// get values for specified query times, 12.1 days
// 12.1 * 86400 * 85/4 = 2.22156e7
queryDischargeItem.TimeSet.SetSingleTimeStamp(triggerTime3);
valuesV = storageInGw2.GetValues(queryDischargeItem);
valuesQ = flowOnBranch2.GetValues(queryDischargeItem);
Assert.AreEqual(35.0 / 4.0, (double)valuesQ.GetValue(0, 0));
Assert.AreEqual(2 * 2.22156e7, SumTimeStep(valuesV, 0), 1e-4);
// get values for specified query times, 16.7 days
// 16.7 * 86400 * 85/4 = 3.06612e7
queryDischargeItem.TimeSet.SetSingleTimeStamp(triggerTime4);
valuesV = storageInGw2.GetValues(queryDischargeItem);
valuesQ = flowOnBranch2.GetValues(queryDischargeItem);
Assert.AreEqual(35.0 / 4.0, (double)valuesQ.GetValue(0, 0));
Assert.AreEqual(2 * 3.06612e7, SumTimeStep(valuesV, 0), 1e-4);
}
}
public void GetValues()
{
IQuantity riverModelOutflowQuantity = simpleRiver.Outputs[0].ValueDefinition as IQuantity;
IElementSet riverModelNodeElement = ((ITimeSpaceOutput)simpleRiver.Outputs[0]).ElementSet();
Input queryItem1;
var dischargeQuantity = new Quantity(new Unit(PredefinedUnits.CubicMeterPerSecond), null, "Discharge");
var waterlevelQuantity = new Quantity(new Unit(PredefinedUnits.Meter), null, "Water Level");
var idBasedElementSetA = new ElementSet(null, "ElmSet-A", ElementType.IdBased);
idBasedElementSetA.AddElement(new Element("elm-1"));
queryItem1 = new Input("discharge, to be retrieved from some output item", dischargeQuantity, idBasedElementSetA);
queryItem1.TimeSet = new TimeSet();
// Connect the queryItem with the first output item using a time interpolator
TimeBufferer buffer = new TimeInterpolator((ITimeSpaceOutput)simpleRiver.Outputs[0]);
simpleRiver.Outputs[0].AddAdaptedOutput(buffer);
buffer.AddConsumer(queryItem1);
simpleRiver.Validate();
simpleRiver.Prepare();
//IListener eventListener = new EventListener();
//for (int i = 0; i < eventListener.GetAcceptedEventTypeCount(); i++)
//{
// for (int n = 0; n < simpleRiver.GetPublishedEventTypeCount(); n++)
// {
// if (eventListener.GetAcceptedEventType(i) == simpleRiver.GetPublishedEventType(n))
// {
// simpleRiver.Subscribe(eventListener, eventListener.GetAcceptedEventType(i));
// }
// }
//}
double startTime = simpleRiver.TimeExtent.TimeHorizon.StampAsModifiedJulianDay;
ITime[] times = new ITime[5];
times[0] = new Time(startTime + 1);
times[1] = new Time(startTime + 2);
times[2] = new Time(startTime + 3);
times[3] = new Time(startTime + 4);
times[4] = new Time(startTime + 5);
ITimeSpaceValueSet values;
queryItem1.TimeSet.SetSingleTimeStamp(times[0].StampAsModifiedJulianDay);
values = ((ITimeSpaceOutput)queryItem1.Provider).GetValues(queryItem1);
Assert.AreEqual(0.55, values.GetValue(0, 0));
queryItem1.TimeSet.SetSingleTimeStamp(times[1].StampAsModifiedJulianDay);
values = ((ITimeSpaceOutput)queryItem1.Provider).GetValues(queryItem1);
Assert.AreEqual(1.1, values.GetValue(0, 0));
queryItem1.TimeSet.SetSingleTimeStamp(times[2].StampAsModifiedJulianDay);
values = ((ITimeSpaceOutput)queryItem1.Provider).GetValues(queryItem1);
Assert.AreEqual(1.6, values.GetValue(0, 0));
queryItem1.TimeSet.SetSingleTimeStamp(times[3].StampAsModifiedJulianDay);
values = ((ITimeSpaceOutput)queryItem1.Provider).GetValues(queryItem1);
Assert.AreEqual(2.1, values.GetValue(0, 0));
queryItem1.TimeSet.SetSingleTimeStamp(times[4].StampAsModifiedJulianDay);
values = ((ITimeSpaceOutput)queryItem1.Provider).GetValues(queryItem1);
Assert.AreEqual(2.6, values.GetValue(0, 0));
}
