public static <T> List<T> toList(Enumeration<? extends T> things) {
   AbstractList<T> list = new ArrayList<T>();
   while (things.hasMoreElements()) {
     list.add(things.nextElement());
   }
   return list;
 }
Esempio n. 2
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 /**
  * Compile this mosaic into an optimal arrangement.
  *
  * @return true if this mosaic is used for images, false if it's empty
  */
 public boolean compile(Component progressComponent) {
   this.progressComponent = progressComponent;
   parts = partsList.toArray(new MosaicPart[partsList.size()]);
   Arrangement arrangement = new Arrangement(maxHeight, parts);
   int lastWidth = -1;
   double widthFactor = Math.log(((double) maxWidth) / minWidth);
   for (int i = 0; i < numWidths; i++) {
     int width;
     if (numWidths > 1) {
       // Increase width geometrically from minWidth to maxWidth
       double f = widthFactor * ((double) i) / (numWidths - 1);
       f = Math.exp(f) * minWidth;
       width = (int) (f + 0.5);
     } else {
       width = maxWidth;
     }
     if (width == lastWidth) {
       continue; // Don't try same width twice
     }
     lastWidth = width;
     arrangement.arrangeWithin(width);
     int pixels = arrangement.getPixelsUsed();
     if (pixels < currPixels) {
       setBestArrangement(arrangement);
     }
   }
   return currPixels > 0;
 }
Esempio n. 3
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  public static void main(String[] args) throws IOException {
    String s = args[0];
    char[] alphabet = new char[26];
    AbstractList<Integer> characters = new ArrayList<>();
    int count = 0;

    for (int i = 0; i < alphabet.length; i++) {
      alphabet[i] = (char) ('a' + i);
    }

    FileInputStream fileInputStream = new FileInputStream(s);
    while (fileInputStream.available() > 0) {
      characters.add(fileInputStream.read());
    }
    fileInputStream.close();

    for (int a : characters) {
      for (int i = 0; i < alphabet.length; i++) {
        if (a == alphabet[i]) {
          count++;
        }
      }
    }
    System.out.println(count);
  }
Esempio n. 4
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  @Override
  public void onEvent(ConsoleState state, Event.Key kev) {
    // System.out.println("WindowChildren OnEvent.Key " + kev.key);
    super.onEvent(state, kev);
    if (active_ != null) active_.onEvent(state, kev);

    if (kev.state == Event.State.RELEASED) {
      switch (kev.key) {
        case TAB:
          if (children_.isEmpty()) {
            setActive(state, null);
          } else {
            Window current = active_;
            boolean found = false;
            int i = active_ != null ? children_.indexOf(active_) + 1 : 0;
            while (!found) {
              if (i >= children_.size()) {
                if (current == null) break;
                else i = 0;
              }
              Window active = children_.get(i);
              found = setActive(state, active);
              if (active == current) break;
              ++i;
            }
          }
          break;
      }
    }
  }
Esempio n. 5
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 @Override
 public void handleMessage(Message msg) {
   @SuppressWarnings("unchecked")
   AbstractList<String> requestedUploads = (AbstractList<String>) msg.obj;
   if (msg.obj != null) {
     Iterator<String> it = requestedUploads.iterator();
     while (it.hasNext()) {
       mService.uploadFile(it.next());
     }
   }
   mService.stopSelf(msg.arg1);
 }
  private long testingAbstractListRoleList() {
    AbstractList<Object> array = new RoleList();
    long start = System.currentTimeMillis();
    for (int i = 0; i < getMax(); i++) {
      array.add(i);
    }
    long end = System.currentTimeMillis();
    long time = (end - start);
    refreshTotalTime(time);

    return time;
  }
Esempio n. 7
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 private void renderFullBoardRecursive(
     Graphics g, AbstractList<Space> finished, Space origin, int x, int y, Board b) {
   renderSpace(g, origin, x, y);
   Board.Coordinates coord = b.new Coordinates(x, y);
   Developer dev = b.getDeveloper(coord);
   if (dev != null) {
     renderDeveloper(dev, x, y);
   }
   if (origin.getTop() != null && !finished.contains(origin.getTop())) {
     finished.add(origin.getTop());
     renderFullBoardRecursive(g, finished, origin.getTop(), x, y - 1, b);
   }
   if (origin.getLeft() != null && !finished.contains(origin.getLeft())) {
     finished.add(origin.getLeft());
     renderFullBoardRecursive(g, finished, origin.getLeft(), x - 1, y, b);
   }
   if (origin.getRight() != null && !finished.contains(origin.getRight())) {
     finished.add(origin.getRight());
     renderFullBoardRecursive(g, finished, origin.getRight(), x + 1, y, b);
   }
   if (origin.getBottom() != null && !finished.contains(origin.getBottom())) {
     finished.add(origin.getBottom());
     renderFullBoardRecursive(g, finished, origin.getBottom(), x, y + 1, b);
   }
   int givenHeight = origin.getHeight();
   if (origin.getHeight() > 0 && origin.getTile().getType() == TileType.PALACE) {
     givenHeight = ((PalaceTile) origin.getTile()).getLevel();
   }
   spaceHeights[x][y] = givenHeight;
   renderText(
       g, "" + givenHeight, (x + 1) * TILE_WIDTH, (y + 1) * TILE_HEIGHT + g.getFont().getSize());
 }
Esempio n. 8
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  public Iterator<Host> iterator() {
    AbstractList<Host> ab =
        new AbstractList<Host>() {
          public int size() {
            return getLength();
          }

          public Host get(int index) {
            return (Host) item(index);
          }
        };

    return ab.iterator();
  }
Esempio n. 9
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  public Iterator<VirtualMachine> iterator() {
    AbstractList<VirtualMachine> ab =
        new AbstractList<VirtualMachine>() {
          public int size() {
            return getLength();
          }

          public VirtualMachine get(int index) {
            return (VirtualMachine) item(index);
          }
        };

    return ab.iterator();
  }
Esempio n. 10
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  public Iterator<Image> iterator() {
    AbstractList<Image> ab =
        new AbstractList<Image>() {
          public int size() {
            return getLength();
          }

          public Image get(int index) {
            return (Image) item(index);
          }
        };

    return ab.iterator();
  }
Esempio n. 11
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 protected void removeRange(int fromIndex, int toIndex) {
   checkForComodification();
   l.removeRange(fromIndex + offset, toIndex + offset);
   expectedModCount = l.modCount;
   size -= (toIndex - fromIndex);
   modCount++;
 }
Esempio n. 12
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 public void add(int index, E element) {
   if (index < 0 || index > size) throw new IndexOutOfBoundsException();
   checkForComodification();
   l.add(index + offset, element);
   expectedModCount = l.modCount;
   size++;
   modCount++;
 }
Esempio n. 13
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 public E remove(int index) {
   rangeCheck(index);
   checkForComodification();
   E result = l.remove(index + offset);
   expectedModCount = l.modCount;
   size--;
   modCount++;
   return result;
 }
Esempio n. 14
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  @Override
  public void onEvent(ConsoleState state, Event.MouseButton mbev) {
    super.onEvent(state, mbev);
    // System.err.println("WindowChildren::OnEvent " + mbev);

    // TODO only send if in box, unless captured
    if (capture_ != null) capture_.onEvent(state, mbev);
    else {
      // for (Window d : children_) // Should be in reverse order
      java.util.ListIterator<Window> itr = children_.listIterator(children_.size());
      while (itr.hasPrevious()) {
        Window d = itr.previous();
        if (d.inside(mbev.mx, mbev.my)) {
          d.onEvent(state, mbev);
          break;
        }
      }
    }
  }
Esempio n. 15
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 SubList(AbstractList<E> list, int fromIndex, int toIndex) {
   if (fromIndex < 0) throw new IndexOutOfBoundsException("fromIndex = " + fromIndex);
   if (toIndex > list.size()) throw new IndexOutOfBoundsException("toIndex = " + toIndex);
   if (fromIndex > toIndex)
     throw new IllegalArgumentException("fromIndex(" + fromIndex + ") > toIndex(" + toIndex + ")");
   l = list;
   offset = fromIndex;
   size = toIndex - fromIndex;
   expectedModCount = l.modCount;
 }
Esempio n. 16
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 /**
  * Helper method that prints out a list.
  *
  * @param list the list to print.
  * @param depth the depth of the object within other objects, used for indenting.
  */
 @SuppressWarnings("unchecked")
 public static void printList(AbstractList list, int depth) {
   final Iterator i = list.iterator();
   Object o = null;
   for (int k = 0; k < depth; k++) System.out.print("  ");
   System.out.println("List: ");
   while (i.hasNext() && (o = i.next()) != null) {
     for (int k = 0; k < depth; k++) System.out.print("  ");
     System.out.print(" +");
     print(o, depth);
   }
 }
Esempio n. 17
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  public boolean addAll(int index, Collection<? extends E> c) {
    if (index < 0 || index > size)
      throw new IndexOutOfBoundsException("Index: " + index + ", Size: " + size);
    int cSize = c.size();
    if (cSize == 0) return false;

    checkForComodification();
    l.addAll(offset + index, c);
    expectedModCount = l.modCount;
    size += cSize;
    modCount++;
    return true;
  }
Esempio n. 18
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  public static <VertexType extends BaseVertex, EdgeType extends BaseEdge<VertexType>>
      BaseGraph<VertexType, EdgeType> getVertexInducedSubgraph(
          BaseGraph<VertexType, EdgeType> graph, AbstractList<VertexType> inducedVertices) {
    BaseGraph<VertexType, EdgeType> newGraph = graph.createEmptyGraph();
    newGraph.registerSubgraph(graph);
    newGraph.setSubGraphIndex(graph.getNewSubgraphIndex());

    for (VertexType v : inducedVertices) {
      graph.checkVertex(v);
      newGraph.insertVertex(v);
    }

    for (int i = 0; i < inducedVertices.size(); ++i) {
      for (int j = i + 1; j < inducedVertices.size(); ++j) {
        AbstractList<EdgeType> edges =
            graph.getEdges(inducedVertices.get(i), inducedVertices.get(j));

        for (EdgeType edge : edges) newGraph.insertEdge(edge);
      }
    }

    return newGraph;
  }
 @Override
 protected void finalize() {
   // System.out.println("finalize TempMultiFileStringList: " + this.hashCode());
   for (String name : list) {
     File f = new File(dir, name);
     if (f.exists() && f.delete() == false) {
       System.err.println("cannot delete a temp File:" + f.getAbsolutePath());
     }
   }
   try {
     super.finalize();
   } catch (Throwable e) {
     e.printStackTrace();
   }
 }
Esempio n. 20
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 /**
  * a slow function in java, but the only other way is for the users of this list to do it, and
  * since its used as a normal java.util.List, they probably wont know to do that.
  */
 protected void finalize() throws Throwable {
   acyc.oneLessRefFromOutside(pointer);
   super.finalize();
 }
Esempio n. 21
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 /** Removes sufficiently replicated blocks from the block list of a datanode. */
 private void pruneSufficientlyReplicated(
     final DatanodeDescriptor datanode, AbstractList<BlockInfo> blocks) {
   processBlocksForDecomInternal(datanode, blocks.iterator(), null, true);
 }
Esempio n. 22
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    private void check() {
      final Iterator<Map.Entry<DatanodeDescriptor, AbstractList<BlockInfo>>> it =
          new CyclicIteration<>(decomNodeBlocks, iterkey).iterator();
      final LinkedList<DatanodeDescriptor> toRemove = new LinkedList<>();

      while (it.hasNext() && !exceededNumBlocksPerCheck() && !exceededNumNodesPerCheck()) {
        numNodesChecked++;
        final Map.Entry<DatanodeDescriptor, AbstractList<BlockInfo>> entry = it.next();
        final DatanodeDescriptor dn = entry.getKey();
        AbstractList<BlockInfo> blocks = entry.getValue();
        boolean fullScan = false;
        if (blocks == null) {
          // This is a newly added datanode, run through its list to schedule
          // under-replicated blocks for replication and collect the blocks
          // that are insufficiently replicated for further tracking
          LOG.debug(
              "Newly-added node {}, doing full scan to find " + "insufficiently-replicated blocks.",
              dn);
          blocks = handleInsufficientlyReplicated(dn);
          decomNodeBlocks.put(dn, blocks);
          fullScan = true;
        } else {
          // This is a known datanode, check if its # of insufficiently
          // replicated blocks has dropped to zero and if it can be decommed
          LOG.debug("Processing decommission-in-progress node {}", dn);
          pruneSufficientlyReplicated(dn, blocks);
        }
        if (blocks.size() == 0) {
          if (!fullScan) {
            // If we didn't just do a full scan, need to re-check with the
            // full block map.
            //
            // We've replicated all the known insufficiently replicated
            // blocks. Re-check with the full block map before finally
            // marking the datanode as decommissioned
            LOG.debug(
                "Node {} has finished replicating current set of "
                    + "blocks, checking with the full block map.",
                dn);
            blocks = handleInsufficientlyReplicated(dn);
            decomNodeBlocks.put(dn, blocks);
          }
          // If the full scan is clean AND the node liveness is okay,
          // we can finally mark as decommissioned.
          final boolean isHealthy = blockManager.isNodeHealthyForDecommission(dn);
          if (blocks.size() == 0 && isHealthy) {
            setDecommissioned(dn);
            toRemove.add(dn);
            LOG.debug(
                "Node {} is sufficiently replicated and healthy, " + "marked as decommissioned.",
                dn);
          } else {
            if (LOG.isDebugEnabled()) {
              StringBuilder b = new StringBuilder("Node {} ");
              if (isHealthy) {
                b.append("is ");
              } else {
                b.append("isn't ");
              }
              b.append(
                  "healthy and still needs to replicate {} more blocks,"
                      + " decommissioning is still in progress.");
              LOG.debug(b.toString(), dn, blocks.size());
            }
          }
        } else {
          LOG.debug(
              "Node {} still has {} blocks to replicate "
                  + "before it is a candidate to finish decommissioning.",
              dn,
              blocks.size());
        }
        iterkey = dn;
      }
      // Remove the datanodes that are decommissioned
      for (DatanodeDescriptor dn : toRemove) {
        Preconditions.checkState(
            dn.isDecommissioned(), "Removing a node that is not yet decommissioned!");
        decomNodeBlocks.remove(dn);
      }
    }
Esempio n. 23
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 public T remove(int index) {
   return adapter.remove(index);
 }
Esempio n. 24
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  public static GraphModel createIPGraph(Vector<Triplet> tow) {
    // create the DAG
    dag = new GraphModel(true);
    HashMap<Object, VertexModel> V = new HashMap<Object, VertexModel>();
    for (Triplet t : tow) {
      VertexModel ik = getVertex(t.i, t.k, dag, V);
      VertexModel jk = getVertex(t.j, t.k, dag, V);
      VertexModel ij = getVertex(t.i, t.j, dag, V);
      EdgeModel e = new EdgeModel(ij, ik);
      e.getProp().obj = t;
      dag.insertEdge(e);
      e = new EdgeModel(ij, jk);
      e.getProp().obj = t;
      dag.insertEdge(e);
    }

    // convert it to a dag (from each cycle remove an edge)
    // convertToDag(dag);
    boolean first = true;
    while ((cycle = DAG.findACycle(dag)) != null) {
      if (first) {
        TripNet.println("Warning 0: Input triplets are inconsistent!");
        first = false;
      }
      ArrayList<Triplet> cycleTriplets = TripNet.getCycleTriplets(cycle);
      Triplet minT = cycleTriplets.get(0);
      for (Triplet t : cycleTriplets) {
        if (t.w < minT.w) minT = t;
      }
      TripNet.println(
          "removing: "
              + minT
              + " with weight: "
              + minT.w
              + " ::: Resolving the cycle: "
              + cycleTriplets);
      if (TripNet.REAMOVE_CYCLIC_TRIPLETS) {
        TripNet.println("removing Triplet of tow: " + cycleTriplets);
        tow.remove(minT);
      }
      VertexModel ik = getVertex(minT.i, minT.k, dag, V);
      VertexModel jk = getVertex(minT.j, minT.k, dag, V);
      VertexModel ij = getVertex(minT.i, minT.j, dag, V);
      dag.removeEdge(dag.getEdge(ij, jk));
      dag.removeEdge(dag.getEdge(ij, ik));
    }
    // topological sort
    AbstractList<VertexModel> topsort = DAG.doSort(dag);

    if (topsort == null) {
      // the inputs are inconsistent, they are not a dag
      // GraphData gd = new GraphData(Application.blackboard);
      // gd.core.showGraph(dag);
      cycle = DAG.findACycle(dag);
      VertexModel p = cycle.get(0);
      VertexModel c = cycle.get(1);
      EdgeModel e = dag.getEdge(p, c);
      dag.removeEdge(e);
      TripNet.println("Err 0: please contact us for this error! :(");
      return null;
    }
    // set Xij

    // find the length of the longest chain
    int max = -1;
    for (Pair<VertexModel, Integer> p : DAG.findLongestPath(dag)) {
      max = Math.max(max, p.second);
    }

    // set the Xij as large as u can
    for (int i = topsort.size() - 1; i >= 0; i--) {
      VertexModel v = topsort.get(i);
      int min = max + 1;
      for (VertexModel trg : dag.getNeighbors(v)) {
        min = Math.min(min, trg.getColor());
      }
      v.setColor(min - 1); // the color will be related edge's weight (or
      // formally Xij)
    }

    // create the network graph
    HashMap<Object, VertexModel> VR = new HashMap<Object, VertexModel>();
    GraphModel ret = new GraphModel(false);
    if (TripNet.verbose) TripNet.println("Integer Programming Results:");
    TripNet.ths.maxW = max;
    for (VertexModel v : topsort) {
      Pair<Integer, Integer> edge = (Pair<Integer, Integer>) getVId(v);
      VertexModel i = getVertex(edge.first, ret, VR);
      VertexModel j = getVertex(edge.second, ret, VR);
      EdgeModel e = new EdgeModel(i, j);
      int w = v.getColor();
      e.setWeight(w);
      ret.insertEdge(e);
      if (TripNet.verbose) System.out.println(edge.first + "," + edge.second + ": " + w);
      TripNet.ths.F0.put(edge.first + "," + edge.second, w);
      TripNet.ths.weights.put(new Pair<Integer, Integer>(edge.first, edge.second), w);
    }
    // check consistency of results
    for (Triplet t : tow) {
      if ((TripNet.getW(t.i, t.j).intValue() <= TripNet.getW(t.i, t.k).intValue())
          && (TripNet.getW(t.i, t.j).intValue() <= TripNet.getW(t.j, t.k).intValue())) continue;
      System.err.println("inconsistant weight");
    }
    return ret;
  }
Esempio n. 25
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 public <U> U[] toArray(U[] a) {
   return adapter.toArray(a);
 }
Esempio n. 26
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 public Object[] toArray() {
   return adapter.toArray();
 }
Esempio n. 27
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 public int size() {
   return adapter.size();
 }
Esempio n. 28
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 public boolean remove(Object o) {
   return adapter.remove(o);
 }
Esempio n. 29
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 public boolean retainAll(Collection<?> c) {
   return adapter.retainAll(c);
 }
Esempio n. 30
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 public T set(int index, T element) {
   return adapter.set(index, element);
 }