Mercurial > dive4elements > river
view flys-artifacts/src/main/java/de/intevation/flys/artifacts/model/QRangeTree.java @ 4241:49cb65d5932d
Improved the historical discharge calculation.
The calculation now creates new HistoricalWQKms (new subclass of WQKms). Those WQKms are used
to create new facets from (new) type 'HistoricalDischargeCurveFacet'. The chart generator is
improved to support those facets.
| author | Ingo Weinzierl <ingo.weinzierl@intevation.de> |
|---|---|
| date | Wed, 24 Oct 2012 14:34:35 +0200 |
| parents | 51f76225823b |
| children | 729a5edb0313 |
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package de.intevation.flys.artifacts.model; import java.io.Serializable; import java.util.List; import java.util.ArrayList; import org.apache.log4j.Logger; public class QRangeTree implements Serializable { private static Logger log = Logger.getLogger(QRangeTree.class); public static final double EPSILON = 1e-4; public static class Node implements Serializable { Node left; Node right; Node prev; Node next; double a; double b; double q; public Node() { } public Node(double a, double b, double q) { this.a = a; this.b = b; this.q = q; } protected final double interpolatePrev(double pos) { /* f(prev.b) = prev.q f(a) = q prev.q = m*prev.b + n q = m*a + n <=> n = q - m*a q - prev.q = m*(a - prev.b) m = (q - prev.q)/(a - prev.b) # a != prev.b */ if (a == prev.b) { return 0.5*(q + prev.q); } double m = (q - prev.q)/(a - prev.b); double n = q - m*a; return m*pos + n; } protected final double interpolateNext(double pos) { /* f(next.a) = next.q f(b) = q next.q = m*next.a + n q = m*b + n <=> n = q - m*b q - next.q = m*(b - next.a) m = (q - next.q)/(b - next.a) # b != next.a */ if (b == next.a) { return 0.5*(q + next.q); } double m = (q - next.q)/(b - next.a); double n = q - m*b; return m*pos + n; } public double findQ(double pos) { Node current = this; for (;;) { if (pos < current.a) { if (current.left != null) { current = current.left; continue; } return current.prev != null ? current.interpolatePrev(pos) : Double.NaN; } if (pos > current.b) { if (current.right != null) { current = current.right; continue; } return current.next != null ? current.interpolateNext(pos) : Double.NaN; } return current.q; } } } // class Node protected Node root; public QRangeTree() { } public static final class AccessQAB { private int startIndex; public AccessQAB(int startIndex) { this.startIndex = startIndex; } public Double getQ(Object [] row) { return (Double)row[startIndex]; } public Double getA(Object [] row) { return (Double)row[startIndex+1]; } public Double getB(Object [] row) { return (Double)row[startIndex+2]; } } public static final AccessQAB WITH_COLUMN = new AccessQAB(1); public static final AccessQAB WITHOUT_COLUMN = new AccessQAB(0); /** wstQRanges need to be sorted by range.a */ public QRangeTree(List<Object []> qRanges, int start, int stop) { this(qRanges, WITH_COLUMN, start, stop); } public QRangeTree( List<Object []> qRanges, AccessQAB accessQAB, int start, int stop ) { if (stop <= start) { return; } int N = stop-start; List<Node> nodes = new ArrayList<Node>(N); Node last = null; for (int i = 0; i < N; ++i) { Object [] qRange = qRanges.get(start + i); Double q = accessQAB.getQ(qRange); Double a = accessQAB.getA(qRange); Double b = accessQAB.getB(qRange); double av = a != null ? a.doubleValue() : -Double.MAX_VALUE; double bv = b != null ? b.doubleValue() : Double.MAX_VALUE; double qv = q.doubleValue(); // If nodes are directly neighbored and Qs are the same // join them. if (last != null && Math.abs(last.b - av) < EPSILON && Math.abs(last.q - qv) < EPSILON) { last.b = bv; } else { nodes.add(last = new Node(av, bv, qv)); } } if (log.isDebugEnabled()) { log.debug("Before/after nodes join: " + N + "/" + nodes.size()); } root = wireTree(nodes); } protected static Node wireTree(List<Node> nodes) { int N = nodes.size(); for (int i = 0; i < N; ++i) { Node node = nodes.get(i); if (i > 0 ) node.prev = nodes.get(i-1); if (i < N-1) node.next = nodes.get(i+1); } return buildTree(nodes, 0, N-1); } protected static Node buildTree(List<Node> nodes, int lo, int hi) { if (lo > hi) { return null; } int mid = (lo + hi) >> 1; Node parent = nodes.get(mid); parent.left = buildTree(nodes, lo, mid-1); parent.right = buildTree(nodes, mid+1, hi); return parent; } public double findQ(double pos) { return root != null ? root.findQ(pos) : Double.NaN; } protected Node head() { Node head = root; while (head.left != null) { head = head.left; } return head; } public List<Range> findSegments(double a, double b) { if (a > b) { double t = a; a = b; b = t; } return findSegments(new Range(a, b)); } public List<Range> findSegments(Range range) { List<Range> segments = new ArrayList<Range>(); // Linear scan should be good enough here. for (Node curr = head(); curr != null; curr = curr.next) { if (!range.disjoint(curr.a, curr.b)) { Range r = new Range(curr.a, curr.b); if (r.clip(range)) { segments.add(r); } } } return segments; } @Override public String toString() { StringBuilder sb = new StringBuilder(); inorder(root, sb); return sb.toString(); } protected static void inorder(Node node, StringBuilder sb) { if (node != null) { inorder(node.left, sb); sb.append('[') .append(node.a) .append(", ") .append(node.b) .append(": ") .append(node.q) .append(']'); inorder(node.right, sb); } } private static final String name(Object o) { return String.valueOf(System.identityHashCode(o) & 0xffffffffL); } public String toGraph() { StringBuilder sb = new StringBuilder(); sb.append("subgraph c"); sb.append(name(this)); sb.append(" {\n"); if (root != null) { java.util.Deque<Node> stack = new java.util.ArrayDeque<Node>(); stack.push(root); while (!stack.isEmpty()) { Node current = stack.pop(); String name = "n" + name(current); sb.append(name); sb.append(" [label=\""); sb.append(current.a).append(", ").append(current.b); sb.append(": ").append(current.q).append("\"]\n"); if (current.left != null) { String leftName = name(current.left); sb.append(name).append(" -- n").append(leftName).append("\n"); stack.push(current.left); } if (current.right != null) { String rightName = name(current.right); sb.append(name).append(" -- n").append(rightName).append("\n"); stack.push(current.right); } } } sb.append("}\n"); return sb.toString(); } } // vim:set ts=4 sw=4 si et sta sts=4 fenc=utf8 :