view flys-artifacts/src/main/java/de/intevation/flys/artifacts/WINFOArtifact.java @ 1152:fc572b30f1b8

Added configuration to kick-in w-differences branch of winfo. flys-artifacts/trunk@2683 c6561f87-3c4e-4783-a992-168aeb5c3f6f
author Felix Wolfsteller <felix.wolfsteller@intevation.de>
date Fri, 09 Sep 2011 10:13:22 +0000
parents 302461d5d071
children 24b87650136f
line wrap: on
line source
package de.intevation.flys.artifacts;

import java.awt.geom.Point2D;

import de.intevation.artifactdatabase.ProtocolUtils;

import de.intevation.artifactdatabase.data.StateData;

import de.intevation.artifactdatabase.state.Facet;
import de.intevation.artifactdatabase.state.Output;
import de.intevation.artifactdatabase.state.State;
import de.intevation.artifactdatabase.state.StateEngine;

import de.intevation.artifactdatabase.transition.TransitionEngine;

import de.intevation.artifacts.CallContext;

import de.intevation.artifacts.common.ArtifactNamespaceContext;

import de.intevation.artifacts.common.utils.XMLUtils;
import de.intevation.artifacts.common.utils.XMLUtils.ElementCreator;

import de.intevation.flys.artifacts.context.FLYSContext;

import de.intevation.flys.artifacts.model.Calculation1;
import de.intevation.flys.artifacts.model.Calculation2;
import de.intevation.flys.artifacts.model.Calculation3;
import de.intevation.flys.artifacts.model.Calculation4;
import de.intevation.flys.artifacts.model.Calculation;
import de.intevation.flys.artifacts.model.CalculationResult;
import de.intevation.flys.artifacts.model.CrossSectionFactory;
import de.intevation.flys.artifacts.model.DischargeTables;
import de.intevation.flys.artifacts.model.MainValuesFactory;
import de.intevation.flys.artifacts.model.Segment;
import de.intevation.flys.artifacts.model.WQKms;
import de.intevation.flys.artifacts.model.WstValueTable;
import de.intevation.flys.artifacts.model.WstValueTableFactory;

import de.intevation.flys.artifacts.states.DefaultState;
import de.intevation.flys.artifacts.states.LocationDistanceSelect;

import de.intevation.flys.model.Gauge;
import de.intevation.flys.model.River;
import de.intevation.flys.model.CrossSection;
import de.intevation.flys.model.CrossSectionLine;
import de.intevation.flys.model.CrossSectionPoint;

import de.intevation.flys.utils.DoubleUtil;
import de.intevation.flys.utils.FLYSUtils;

import gnu.trove.TDoubleArrayList;

import java.util.ArrayList;
import java.util.Arrays;
import java.util.Collections;
import java.util.List;
import java.util.Map;

import org.apache.log4j.Logger;

import org.w3c.dom.Document;
import org.w3c.dom.Element;
import org.w3c.dom.Node;

import de.intevation.flys.artifacts.charts.CrossSectionApp;

/**
 * The default WINFO artifact.
 *
 * @author <a href="mailto:ingo.weinzierl@intevation.de">Ingo Weinzierl</a>
 */
public class WINFOArtifact extends FLYSArtifact {

    /** The logger for this class. */
    private static Logger logger = Logger.getLogger(WINFOArtifact.class);


    /** The name of the artifact. */
    public static final String ARTIFACT_NAME = "winfo";


    /** XPath */
    public static final String XPATH_STATIC_UI ="/art:result/art:ui/art:static";

    /** The default number of steps between the start end end of a selected Q
     * range. */
    public static final int DEFAULT_Q_STEPS = 30;

    /** The default step width between the start end end kilometer. */
    public static final double DEFAULT_KM_STEPS = 0.1;


    /**
     * The default constructor.
     */
    public WINFOArtifact() {
    }


    /**
     * This method returns a description of this artifact.
     *
     * @param data Some data.
     * @param context The CallContext.
     *
     * @return the description of this artifact.
     */
    public Document describe(Document data, CallContext context) {
        logger.debug("Describe: the current state is: " + getCurrentStateId());

        if (logger.isDebugEnabled()) {
            dumpArtifact();
        }

        FLYSContext flysContext = getFlysContext(context);

        StateEngine stateEngine = (StateEngine) flysContext.get(
            FLYSContext.STATE_ENGINE_KEY);

        TransitionEngine transitionEngine = (TransitionEngine) flysContext.get(
            FLYSContext.TRANSITION_ENGINE_KEY);

        List<State> reachable = transitionEngine.getReachableStates(
            this, getCurrentState(context), stateEngine);

        Document description            = XMLUtils.newDocument();
        XMLUtils.ElementCreator creator = new XMLUtils.ElementCreator(
            description,
            ArtifactNamespaceContext.NAMESPACE_URI,
            ArtifactNamespaceContext.NAMESPACE_PREFIX);

        Element root = ProtocolUtils.createRootNode(creator);
        description.appendChild(root);

        State current = getCurrentState(context);

        ProtocolUtils.appendDescribeHeader(creator, root, identifier(), hash());
        ProtocolUtils.appendState(creator, root, current);
        ProtocolUtils.appendReachableStates(creator, root, reachable);

        appendBackgroundActivity(creator, root, context);

        Element name = ProtocolUtils.createArtNode(
            creator, "name",
            new String[] { "value" },
            new String[] { getName() });

        Element ui = ProtocolUtils.createArtNode(
            creator, "ui", null, null);

        Element staticUI  = ProtocolUtils.createArtNode(
            creator, "static", null, null);

        Element outs = ProtocolUtils.createArtNode(
            creator, "outputmodes", null, null);
        appendOutputModes(description, outs, context, identifier());

        appendStaticUI(description, staticUI, context, identifier());

        Element dynamic = current.describe(
            this,
            description,
            root,
            context,
            identifier());

        if (dynamic != null) {
            ui.appendChild(dynamic);
        }

        ui.appendChild(staticUI);

        root.appendChild(name);
        root.appendChild(ui);
        root.appendChild(outs);

        return description;
    }


    /**
     * Returns the name of the concrete artifact.
     *
     * @return the name of the concrete artifact.
     */
    public String getName() {
        return ARTIFACT_NAME;
    }


    protected void appendBackgroundActivity(
        ElementCreator cr,
        Element        root,
        CallContext    context
    ) {
        Element inBackground = cr.create("background-processing");

        cr.addAttr(
            inBackground,
            "value",
            String.valueOf(context.isInBackground()),
            true);

        root.appendChild(inBackground);
    }


    protected void appendOutputModes(
        Document    doc,
        Element     outs,
        CallContext context,
        String      uuid)
    {
        List<String> stateIds = getPreviousStateIds();

        XMLUtils.ElementCreator creator = new XMLUtils.ElementCreator(
            doc,
            ArtifactNamespaceContext.NAMESPACE_URI,
            ArtifactNamespaceContext.NAMESPACE_PREFIX);

        FLYSContext flysContext = getFlysContext(context);
        StateEngine engine      = (StateEngine) flysContext.get(
            FLYSContext.STATE_ENGINE_KEY);

        for (String stateId: stateIds) {
            logger.debug("Append output modes for state: " + stateId);
            DefaultState state = (DefaultState) engine.getState(stateId);

            List<Output> list = state.getOutputs();
            if (list == null || list.size() == 0) {
                logger.debug("-> No output modes for this state.");
                continue;
            }

            List<Facet>  fs = facets.get(stateId);
            if (fs == null || fs.size() == 0) {
                logger.debug("No facets for previous state found.");
                continue;
            }

            logger.debug("Found " + fs.size() + " facets in previous states.");

            List<Output> generated = generateOutputs(list, fs);

            ProtocolUtils.appendOutputModes(doc, outs, generated);
        }

        try {
            DefaultState cur = (DefaultState) getCurrentState(context);
            if (cur.validate(this)) {
                List<Output> list = cur.getOutputs();
                if (list != null && list.size() > 0) {
                    logger.debug(
                        "Append output modes for current state: " + cur.getID());

                    List<Facet>  fs = facets.get(cur.getID());
                    if (fs != null && fs.size() > 0) {
                        List<Output> generated = generateOutputs(list, fs);

                        logger.debug("Found " + fs.size() + " current facets.");
                        if (!generated.isEmpty()) {
                            ProtocolUtils.appendOutputModes(
                                doc, outs, generated);
                        }
                    }
                    else {
                        logger.debug("No facets found for the current state.");
                    }

                }
            }
        }
        catch (IllegalArgumentException iae) {
            // state is not valid, so we do not append its outputs.
        }
    }


    /**
     * This method appends the static data - that has already been inserted by
     * the user - to the static node of the DESCRIBE document.
     *
     * @param doc The document.
     * @param ui The root node.
     * @param context The CallContext.
     * @param uuid The identifier of the artifact.
     */
    protected void appendStaticUI(
        Document    doc,
        Node        ui,
        CallContext context,
        String uuid)
    {
        List<String> stateIds = getPreviousStateIds();

        FLYSContext flysContext = getFlysContext(context);
        StateEngine engine      = (StateEngine) flysContext.get(
            FLYSContext.STATE_ENGINE_KEY);

        for (String stateId: stateIds) {
            logger.debug("Append static data for state: " + stateId);
            DefaultState state = (DefaultState) engine.getState(stateId);

            ui.appendChild(state.describeStatic(this, doc, ui, context, uuid));
        }
    }


    //
    // METHODS FOR RETRIEVING COMPUTED DATA FOR DIFFERENT CHART TYPES
    //

    /**
     * Returns the data that is computed by a waterlevel computation.
     *
     * @return an array of data triples that consist of W, Q and Kms.
     */
    public CalculationResult getWaterlevelData()
    {
        logger.debug("WINFOArtifact.getWaterlevelData");

        River river = FLYSUtils.getRiver(this);
        if (river == null) {
            return error(new WQKms[0], "No river selected.");
        }

        double[] kms = getKms();
        if (kms == null) {
            return error(new WQKms[0], "No Kms selected.");
        }

        double[] qs   = getQs();
        double[] ws   = null;
        boolean  qSel = true;

        if (qs == null) {
            logger.debug("Determine Q values based on a set of W values.");
            qSel = false;
            ws   = getWs();
            qs   = getQsForWs(ws);
            if (qs == null) {
                return error(new WQKms[0], "conversion ws to qs failed.");
            }
        }

        WstValueTable wst = WstValueTableFactory.getTable(river);
        if (wst == null) {
            return error(new WQKms[0], "No Wst found for selected river.");
        }


        double [] range = FLYSUtils.getKmRange(this);
        if (range == null) {
            return error(new WQKms[0], "No range found");
        }

        double refKm;

        if (isFreeQ()) {
            refKm = range[0];
            logger.debug("'free' calculation (km " + refKm + ")");
        }
        else {
            Gauge gauge = river.determineGaugeByPosition(range[0]);
            if (gauge == null) {
                return error(
                    new WQKms[0], "No gauge found for km " + range[0]);
            }

            refKm = gauge.getStation().doubleValue();

            logger.debug(
                "reference gauge: " + gauge.getName() + " (km " + refKm + ")");
        }

        return computeWaterlevelData(kms, qs, ws, wst, refKm);
    }


    /**
     * Computes the data of a waterlevel computation based on the interpolation
     * in WstValueTable.
     *
     * @param kms The kilometer values.
     * @param qa The discharge values.
     * @param wst The WstValueTable used for the interpolation.
     *
     * @return an array of data triples that consist of W, Q and Kms.
     */
    public static CalculationResult computeWaterlevelData(
        double []     kms,
        double []     qs,
        double []     ws,
        WstValueTable wst,
        double        refKm
    ) {
        logger.info("WINFOArtifact.computeWaterlevelData");

        Calculation1 calc1 = new Calculation1(kms, qs, ws, refKm);

        return calc1.calculate(wst);
    }


    /**
     * Returns the data that is computed by a duration curve computation.
     *
     * @return the data computed by a duration curve computation.
     */
    public CalculationResult getDurationCurveData() {
        logger.debug("WINFOArtifact.getDurationCurveData");

        River r = FLYSUtils.getRiver(this);

        if (r == null) {
            return error(null, "Cannot determine river.");
        }

        Gauge g = getGauge();

        if (g == null) {
           return error(null, "Cannot determine gauge.");
        }

        double[] locations = FLYSUtils.getLocations(this);

        if (locations == null) {
            return error(null, "Cannot determine location.");
        }

        WstValueTable wst = WstValueTableFactory.getTable(r);
        if (wst == null) {
            return error(null, "No Wst found for selected river.");
        }

        return computeDurationCurveData(g, wst, locations[0]);
    }


    /**
     * Computes the data used to create duration curves.
     *
     * @param gauge The selected gauge.
     * @param location The selected location.
     *
     * @return the computed data.
     */
    public static CalculationResult computeDurationCurveData(
        Gauge           gauge,
        WstValueTable   wst,
        double          location)
    {
        logger.info("WINFOArtifact.computeDurationCurveData");

        Object[] obj = MainValuesFactory.getDurationCurveData(gauge);

        int[]    days = (int[]) obj[0];
        double[] qs   = (double[]) obj[1];

        Calculation3 calculation = new Calculation3(location, days, qs);

        return calculation.calculate(wst);
    }


    /**
     * Returns the data that is used to create discharge curves.
     *
     */
    public CalculationResult getDischargeCurveData() {

        River river = FLYSUtils.getRiver(this);
        if (river == null) {
            return error(new WQKms[0], "no river found");
        }

        double [] distance = FLYSUtils.getKmRange(this);

        if (distance == null) {
            return error(new WQKms[0], "no range found");
        }

        List<Gauge> gauges = river.determineGauges(distance[0], distance[1]);

        if (gauges.isEmpty()) {
            return error(new WQKms[0], "no gauges found");
        }

        String [] names = new String[gauges.size()];

        for (int i = 0; i < names.length; ++i) {
            names[i] = gauges.get(i).getName();
        }

        DischargeTables dt = new DischargeTables(river.getName(), names);

        Map<String, double [][]> map = dt.getValues(100d);

        ArrayList<WQKms> res = new ArrayList<WQKms>();

        for (Gauge gauge: gauges) {
            String name = gauge.getName();
            double [][] values = map.get(name);
            if (values == null) {
                continue;
            }
            double [] kms = new double[values[0].length];
            Arrays.fill(kms, gauge.getStation().doubleValue());
            res.add(new WQKms(kms, values[0], values[1], name));
        }

        return new CalculationResult(
            res.toArray(new WQKms[res.size()]),
            new Calculation());
    }


    /**
     * Returns the data that is computed by a discharge curve computation.
     *
     * @return the data computed by a discharge curve computation.
     */
    public CalculationResult getComputedDischargeCurveData()
    throws NullPointerException
    {
        logger.debug("WINFOArtifact.getComputedDischargeCurveData");

        River r = FLYSUtils.getRiver(this);

        if (r == null) {
            return error(new WQKms[0], "Cannot determine river.");
        }

        double[] locations = FLYSUtils.getLocations(this);

        if (locations == null) {
            return error(new WQKms[0], "Cannot determine location.");
        }

        WstValueTable wst = WstValueTableFactory.getTable(r);
        if (wst == null) {
            return error(new WQKms[0], "No Wst found for selected river.");
        }

        return computeDischargeCurveData(wst, locations[0]);
    }


    /**
     * Computes the data used to create computed discharge curves.
     *
     * @param wst The WstValueTable that is used for the interpolation.
     * @param location The location where the computation should be based on.
     *
     * @return an object that contains tuples of W/Q values at the specified
     * location.
     */
    public static CalculationResult computeDischargeCurveData(
        WstValueTable wst,
        double location)
    {
        logger.info("WINFOArtifact.computeDischargeCurveData");

        Calculation2 calculation = new Calculation2(location);

        return calculation.calculate(wst);
    }

    protected static final CalculationResult error(Object data, String msg) {
        return new CalculationResult(data, new Calculation(msg));
    }


    /**
     * Returns the data computed by the discharge longitudinal section
     * computation.
     *
     * @return an array of WQKms object - one object for each given Q value.
     */
    public CalculationResult getDischargeLongitudinalSectionData() {

        logger.debug("WINFOArtifact.getDischargeLongitudinalSectionData");

        River river = FLYSUtils.getRiver(this);
        if (river == null) {
            logger.debug("No river selected.");
            return error(new WQKms[0], "No river selected.");
        }

        WstValueTable table = WstValueTableFactory.getTable(river);
        if (table == null) {
            logger.debug("No wst found for selected river.");
            return error(new WQKms[0], "No wst found for selected river.");
        }

        List<Segment> segments = getSegments();

        if (segments == null) {
            logger.debug("Cannot create segments.");
            return error(new WQKms[0], "Cannot create segments.");
        }

        double [] range = getFromToStep();

        if (range == null) {
            logger.debug("Cannot figure out range.");
            return error(new WQKms[0], "Cannot figure out range.");
        }

        Calculation4 calc4 = new Calculation4(segments, river, isQ());

        return calc4.calculate(table, range[0], range[1], range[2]);
    }


    public List<Segment> getSegments() {
        StateData wqValues = getData("wq_values");
        if (wqValues == null) {
            logger.warn("no wq_values given");
            return Collections.emptyList();
        }
        String input = (String)wqValues.getValue();
        if (input == null || (input = input.trim()).length() == 0) {
            logger.warn("wq_values are empty");
            return Collections.emptyList();
        }
        return Segment.parseSegments(input);
    }


    /**
     * Get List of all cross-sections for current river.
     *
     * @return List of CrossSections for current river, null in case of error.
     */
    protected List<CrossSection> getCrossSections() {
        River river = FLYSUtils.getRiver(this);
        if (river == null) {
            logger.warn("No river in WINFO found");
            return null;
        }
        return CrossSectionFactory.getCrossSections(river);
    }


    /**
     * Get sorted, valid Points of a CrossSectionLine.
     *
     * @param line line of interest.
     *
     * @return list of points of CrossSectionLine, sorted.
     */
    protected List<Point2D> getCrossSectionLinesPoints(CrossSectionLine line) {
        List<Point2D> points = new ArrayList<Point2D>(); 
        List<CrossSectionPoint> linePoints = line.getPoints();
        if (linePoints.isEmpty()) {
            logger.info("No points in selected CrossSectionLine.");
            return points;
        }
        Collections.sort(linePoints, CrossSectionApp.COL_POS_CMP);
        for (CrossSectionPoint p: linePoints) {
            double x = p.getX().doubleValue();
            double y = p.getY().doubleValue();
            if (CrossSectionApp.isValid(x) && CrossSectionApp.isValid(y)) {
                points.add(new Point2D.Double(x,y));
            }
        }
        return points;
    }


    /**
     * Get CrossSectionLine spatially closest to what is specified in the data
     * "cross_section.km".
     *
     * @return CrossSectionLine closest to "cross_section.km".
     */
    protected CrossSectionLine searchCrossSectionKmLine() {
        double wishKM = 0.0f;
        try {
            wishKM = Double.parseDouble(getDataAsString("cross_section.km"));
        }
        catch (Exception e) {
            ;
        }

        // Get the cross section closest to requested km.
        // Naive, linear approach.
        List<CrossSectionLine> crossSectionLines =
            getCrossSections().get(0).getLines();
        CrossSectionLine oldLine = crossSectionLines.get(0);
        double oldDiff = Math.abs(wishKM - oldLine.getKm().doubleValue());
        for (CrossSectionLine line: crossSectionLines) {
            double diff = Math.abs(wishKM - line.getKm().doubleValue());
            if (diff > oldDiff) {
                break;
            }
            oldDiff = diff;
            oldLine = line;
        }
        return oldLine;
    }


    /**
     * Get km for which a CrossSection is actually available (this may vary
     * from the user picked "cross_section.km" data).
     *
     * @return km for which cross section is calculated.
     */
    public double getCrossSectionSnapKm() {
        // Note that this is this triggers a linear search.
        return searchCrossSectionKmLine().getKm().doubleValue();
    }


    /**
     * Get points of Profile of cross section.
     *
     * @return an array holding coordinates of points of profile (
     *         in the form {{x1, x2} {y1, y2}} ).
     */
    public double [][] getCrossSectionData() {
        logger.info("getCrossSectionData() for cross_section.km "
            + getDataAsString("cross_section.km"));
        CrossSectionLine line = searchCrossSectionKmLine();
        return getCrossSectionProfile(line);
    }


    /**
     * Get points of line describing the surface of water at cross section.
     *
     * @return an array holding coordinates of points of surface of water (
     *         in the form {{x1, x2} {y1, y2}} ).
     */
    public double [][] getWaterLines() {
        logger.debug("getWaterLines()");
        CrossSectionLine csl = searchCrossSectionKmLine();
        List<Point2D> points = getCrossSectionLinesPoints(csl);
        // Need W at km
        WQKms [] wqkms = (WQKms[]) getWaterlevelData().getData();
        if (wqkms.length == 0) {
            logger.error("No WQKms found.");
            return CrossSectionApp.createWaterLines(points, 0.0f);
        }
        else
        {
            if (wqkms.length > 1) {
                logger.warn("More than one wqkms found, taking first one.");
            }
            // Find W at km, linear naive approach.
            WQKms triple = wqkms[0];
            // Find index of km.
            double wishKM = 0.0f;
            int old_idx = 0;
            try {
                wishKM = Double.parseDouble(getDataAsString("cross_section.km"));
            }
            catch (Exception e) {
                ;
            }

            // Linear seach in WQKms for closest km.
            double old_dist_wish = Math.abs(wishKM - triple.getKm(0));

            for (int i = 0; i < triple.size(); i++) {
                double diff = Math.abs(wishKM - triple.getKm(i));
                if (diff > old_dist_wish) {
                    return CrossSectionApp.createWaterLines(points,
                        triple.getW(i));
                }
                old_dist_wish = diff;
            }
            return CrossSectionApp.createWaterLines(points,
                triple.getW(triple.size()-1));
        }
    }


    /**
     * Get name of cross section.
     */
    public String getCrossSectionName() {
        return getCrossSections().get(0).getDescription();
    }


    /**
     * Get points of CrossSection Line.
     */
    protected double [][] getCrossSectionProfile(CrossSectionLine csl) {
        List<Point2D> points = getCrossSectionLinesPoints(csl);
        double [] xs = new double[points.size()];
        double [] ys = new double[points.size()];

        if (points.isEmpty()) {
            return new double [][] {xs, ys};
        }

        xs[0] = points.get(0).getX();
        ys[0] = points.get(0).getY();

        for (int i = 1; i < points.size(); i++) {
            Point2D p = points.get(i);
            xs[i] = p.getX();
            if (xs[i] < xs[i-1]) {
                xs[i] = xs[i-1] + CrossSectionApp.EPSILON;
            }
            ys[i] = p.getY(); 
        }
        return new double [][] { xs, ys };
    }


    /**
     * Returns the Qs for a number of Ws. This method makes use of
     * DischargeTables.getQForW().
     *
     * @param ws An array of W values.
     *
     * @return an array of Q values.
     */
    public double[] getQsForWs(double[] ws) {

        boolean debug = logger.isDebugEnabled();

        if (debug) {
            logger.debug("FLYSArtifact.getQsForWs");
        }

        River r = FLYSUtils.getRiver(this);
        if (r == null) {
            logger.warn("no river found");
            return null;
        }

        double [] range = FLYSUtils.getKmRange(this);
        if (range == null) {
            logger.warn("no ranges found");
            return null;
        }

        if (debug) {
            logger.debug("range: " + Arrays.toString(range));
        }

        Gauge g = r.determineGaugeByPosition(range[0]);
        if (g == null) {
            logger.warn("no gauge found for km: " + range[0]);
            return null;
        }

        if (debug) {
            logger.debug("convert w->q with gauge '" + g.getName() + "'");
        }

        DischargeTables dt = new DischargeTables(r.getName(), g.getName());
        Map<String, double [][]>  tmp = dt.getValues();

        double[][] values = tmp.get(g.getName());
        double[]   qs     = new double[ws.length];

        for (int i = 0; i < ws.length; i++) {
            qs[i] = dt.getQForW(values, ws[i]);
            if (debug) {
                logger.debug("w: " + ws[i] + " -> q: " + qs[i]);
            }
        }

        return qs;
    }


    /**
     * Determines the selected mode of distance/range input.
     *
     * @return true, if the range mode is selected otherwise false.
     */
    public boolean isRange() {
        StateData mode = getData("ld_mode");

        if (mode == null) {
            logger.warn("No mode location/range chosen. Defaults to range.");
            return true;
        }

        String value = (String) mode.getValue();

        return value.equals("distance");
    }


    /**
     * Returns the selected distance based on a given range (from, to).
     *
     * @param dFrom The StateData that contains the lower value.
     * @param dTo The StateData that contains the upper value.
     *
     * @return the selected distance.
     */
    protected double[] getDistanceByRange(StateData dFrom, StateData dTo) {
        double from = Double.parseDouble((String) dFrom.getValue());
        double to   = Double.parseDouble((String) dTo.getValue());

        return new double[] { from, to };
    }


    /**
     * Returns the selected Kms.
     *
     * @param distance An 2dim array with [lower, upper] values.
     *
     * @return the selected Kms.
     */
    public double[] getKms(double[] distance) {
        StateData dStep = getData("ld_step");

        if (dStep == null) {
            logger.warn("No step width given. Cannot compute Kms.");
            return null;
        }

        double step = Double.parseDouble((String) dStep.getValue());

        // transform step from 'm' into 'km'
        step = step / 1000;

        if (step == 0d) {
            step = DEFAULT_KM_STEPS;
        }

        return DoubleUtil.explode(distance[0], distance[1], step);
    }


    /**
     * Returns the selected Kms.
     *
     * @return the selected kms.
     */
    public double[] getKms() {
        if (isRange()) {
            double[] distance = FLYSUtils.getKmRange(this);
            return getKms(distance);

        }
        else {
            return LocationDistanceSelect.getLocations(this);
        }
    }


    public double [] getFromToStep() {
        if (!isRange()) {
            return null;
        }
        double [] fromTo = FLYSUtils.getKmRange(this);

        if (fromTo == null) {
            return null;
        }

        StateData dStep = getData("ld_step");
        if (dStep == null) {
            return null;
        }

        double [] result = new double[3];
        result[0] = fromTo[0];
        result[1] = fromTo[1];

        try {
            String step = (String)dStep.getValue();
            result[2] = DoubleUtil.round(Double.parseDouble(step) / 1000d);
        }
        catch (NumberFormatException nfe) {
            return null;
        }

        return result;
    }


    /**
     * Returns the gauge based on the current distance and river.
     *
     * @return the gauge.
     */
    public Gauge getGauge() {
        River river = FLYSUtils.getRiver(this);

        if (river == null) {
            logger.debug("no river found");
            return null;
        }

        double[] dist  = FLYSUtils.getKmRange(this);

        if (dist == null) {
            logger.debug("no range found");
            return null;
        }

        if (logger.isDebugEnabled()) {
            logger.debug("Determine gauge for:");
            logger.debug("... river: " + river.getName());
            logger.debug("... distance: " + dist[0] + " - " + dist[1]);
        }

        Gauge gauge = river.determineGauge(dist[0], dist[1]);

        String name = gauge != null ? gauge.getName() : "'n/a";
        logger.debug("Found gauge: " + name);

        return gauge;
    }


    /**
     * Returns the gauges that match the selected kilometer range.
     *
     * @return the gauges based on the selected kilometer range.
     */
    public List<Gauge> getGauges() {

        River river = FLYSUtils.getRiver(this);
        if (river == null) {
            return null;
        }

        double [] dist = FLYSUtils.getKmRange(this);
        if (dist == null) {
            return null;
        }

        return river.determineGauges(dist[0], dist[1]);
    }


    /**
     * This method returns the Q values.
     *
     * @return the selected Q values or null, if no Q values are selected.
     */
    public double[] getQs() {
        StateData dMode      = getData("wq_mode");
        StateData dSelection = getData("wq_selection");

        String mode = dMode != null ? (String) dMode.getValue() : "";
        String sel  = dSelection != null ? (String)dSelection.getValue() : null;

        if (mode.equals("Q")) {
            if (sel != null && sel.equals("single")) {
                return getSingleWQValues();
            }
            else {
                return getWQTriple();
            }
        }
        else {
            logger.warn("You try to get Qs, but W has been inserted.");
            return null;
        }
    }


    public boolean isQ() {
        StateData mode = getData("wq_mode");
        return mode != null && mode.getValue().equals("Q");
    }


    /**
     * Returns true, if the parameter is set to compute data on a free range.
     * Otherwise it returns false, which tells the calculation that it is bound
     * to a gauge.
     *
     * @return true, if the calculation should compute on a free range otherwise
     * false and the calculation is bound to a gauge.
     */
    public boolean isFreeQ() {
        StateData mode  = getData("wq_free");
        String    value = (mode != null) ? (String) mode.getValue() : null;

        logger.debug("isFreeQ: " + value);

        if (value == null) {
            return false;
        }

        return Boolean.valueOf(value);
    }


    /**
     * Returns the Q values based on a specified kilometer range.
     *
     * @param range A 2dim array with lower and upper kilometer range.
     *
     * @return an array of Q values.
     */
    public double[] getQs(double[] range) {
        StateData dMode   = getData("wq_mode");
        StateData dValues = getData("wq_values");

        String mode = (dMode != null) ? (String) dMode.getValue() : "";

        if (mode.equals("Q")) {
            return getWQForDist(range);
        }

        logger.warn("You try to get Qs, but Ws has been inserted.");
        return null;
    }


    /**
     * Returns the W values based on a specified kilometer range.
     *
     * @param range A 2dim array with lower and upper kilometer range.
     *
     * @return an array of W values.
     */
    public double[] getWs(double[] range) {
        StateData dMode   = getData("wq_mode");
        StateData dValues = getData("wq_values");

        String mode = (dMode != null) ? (String) dMode.getValue() : "";

        if (mode.equals("W")) {
            return getWQForDist(range);
        }

        logger.warn("You try to get Ws, but Qs has been inserted.");
        return null;
    }


    /**
     * This method returns the W values.
     *
     * @return the selected W values or null, if no W values are selected.
     */
    public double[] getWs() {
        StateData dMode   = getData("wq_mode");
        StateData dSingle = getData("wq_single");

        String mode = (dMode != null) ? (String) dMode.getValue() : "";

        if (mode.equals("W")) {
            if (dSingle != null) {
                return getSingleWQValues();
            }
            else {
                return getWQTriple();
            }
        }
        else {
            logger.warn("You try to get Qs, but W has been inserted.");
            return null;
        }
    }

    /**
     * This method returns the given W or Q values for a specific range
     * (inserted in the WQ input panel for discharge longitudinal sections).
     *
     * @param dist A 2dim array with lower und upper kilometer values.
     *
     * @return an array of W or Q values.
     */
    protected double[] getWQForDist(double[] dist) {
        logger.debug("Search wq values for range: " + dist[0] + " - " + dist[1]);
        StateData data = getData("wq_values");

        if (data == null) {
            logger.warn("Missing wq values!");
            return null;
        }

        String dataString = (String) data.getValue();
        String[]   ranges = dataString.split(":");

        for (String range: ranges) {
            String[] parts = range.split(";");

            double lower = Double.parseDouble(parts[0]);
            double upper = Double.parseDouble(parts[1]);

            if (lower <= dist[0] && upper >= dist[1]) {
                String[] values = parts[2].split(",");

                int      num = values.length;
                double[] res = new double[num];

                for (int i = 0; i < num; i++) {
                    try {
                        res[i] = Double.parseDouble(values[i]);
                    }
                    catch (NumberFormatException nfe) {
                        logger.warn(nfe, nfe);
                    }
                }

                return res;
            }
        }

        logger.warn("Specified range for WQ not found!");

        return null;
    }


    /**
     * This method returns an array of inserted WQ triples that consist of from,
     * to and the step width.
     *
     * @return an array of from, to and step width.
     */
    protected double[] getWQTriple() {
        StateData dFrom = getData("wq_from");
        StateData dTo   = getData("wq_to");

        if (dFrom == null || dTo == null) {
            logger.warn("Missing start or end value for range.");
            return null;
        }

        double from = Double.parseDouble((String) dFrom.getValue());
        double to   = Double.parseDouble((String) dTo.getValue());

        StateData dStep = getData("wq_step");

        if (dStep == null) {
            logger.warn("No step width given. Cannot compute Qs.");
            return null;
        }

        double step  = Double.parseDouble((String) dStep.getValue());

        // if no width is given, the DEFAULT_Q_STEPS is used to compute the step
        // width. Maybe, we should round the value to a number of digits.
        if (step == 0d) {
            double diff = to - from;
            step = diff / DEFAULT_Q_STEPS;
        }

        return DoubleUtil.explode(from, to, step);
    }


    /**
     * Returns an array of inserted WQ double values stored as whitespace
     * separated list.
     *
     * @return an array of W or Q values.
     */
    protected double[] getSingleWQValues() {
        StateData dSingle = getData("wq_single");

        if (dSingle == null) {
            logger.warn("Cannot determine single WQ values. No data given.");
            return null;
        }

        String   tmp       = (String) dSingle.getValue();
        String[] strValues = tmp.split(" ");

        TDoubleArrayList values = new TDoubleArrayList();

        for (String strValue: strValues) {
            try {
                values.add(Double.parseDouble(strValue));
            }
            catch (NumberFormatException nfe) {
                logger.warn(nfe, nfe);
            }
        }

        values.sort();

        return values.toNativeArray();
    }
}
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