org.stathissideris.ascii2image.graphics.Diagram Maven / Gradle / Ivy
Go to download
Show more of this group Show more artifacts with this name
Show all versions of plantuml Show documentation
Show all versions of plantuml Show documentation
PlantUML is a component that allows to quickly write :
* sequence diagram,
* use case diagram,
* class diagram,
* activity diagram,
* component diagram,
* state diagram
* object diagram
/*
* DiTAA - Diagrams Through Ascii Art
*
* Copyright (C) 2004 Efstathios Sideris
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version 2
* of the License, or (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
*
*/
package org.stathissideris.ascii2image.graphics;
import java.awt.Color;
import java.awt.Font;
import java.util.ArrayList;
import java.util.Iterator;
import org.stathissideris.ascii2image.core.ConversionOptions;
import org.stathissideris.ascii2image.core.Pair;
import org.stathissideris.ascii2image.core.ProcessingOptions;
import org.stathissideris.ascii2image.text.AbstractionGrid;
import org.stathissideris.ascii2image.text.CellSet;
import org.stathissideris.ascii2image.text.TextGrid;
/**
*
* @author Efstathios Sideris
*/
public class Diagram {
// ::remove folder when __HAXE__
private static final boolean DEBUG = false;
private static final boolean VERBOSE_DEBUG = false;
private ArrayList shapes = new ArrayList();
private ArrayList compositeShapes = new ArrayList();
private ArrayList textObjects = new ArrayList();
private int width, height;
private int cellWidth, cellHeight;
/**
*
* An outline of the inner workings of this very important (and monstrous)
* constructor is presented here. Boundary processing is the first step
* of the process:
*
*
* - Copy the grid into a work grid and remove all type-on-line
* and point markers from the work grid
* - Split grid into distinct shapes by plotting the grid
* onto an AbstractionGrid and its getDistinctShapes() method.
* - Find all the possible boundary sets of each of the
* distinct shapes. This can produce duplicate shapes (if the boundaries
* are the same when filling from the inside and the outside).
* - Remove duplicate boundaries.
* - Remove obsolete boundaries. Obsolete boundaries are the ones that are
* the sum of their parts when plotted as filled shapes. (see method
* removeObsoleteShapes())
* - Seperate the found boundary sets to open, closed or mixed
* (See CellSet class on how its done).
* - Are there any closed boundaries?
*
* - YES. Subtract all the closed boundaries from each of the
* open ones. That should convert the mixed shapes into open.
* - NO. In this (harder) case, we use the method
* breakTrulyMixedBoundaries() of CellSet to break boundaries
* into open and closed shapes (would work in any case, but it's
* probably slower than the other method). This method is based
* on tracing from the lines' ends and splitting when we get to
* an intersection.
*
*
* - If we had to eliminate any mixed shapes, we seperate the found
* boundary sets again to open, closed or mixed.
*
*
* At this stage, the boundary processing is all complete and we
* proceed with using those boundaries to create the shapes:
*
*
* - Create closed shapes.
* - Create open shapes. That's when the line end corrections are
* also applied, concerning the positioning of the ends of lines
* see methods connectEndsToAnchors() and moveEndsToCellEdges() of
* DiagramShape.
* - Assign color codes to closed shapes.
* - Assing extended markup tags to closed shapes.
*
- Create arrowheads.
*
- Create point markers.
*
*
* Finally, the text processing occurs: [pending]
*
* @param grid
* @param options
* @param processingOptions
*/
public Diagram(TextGrid grid, ConversionOptions options, ProcessingOptions processingOptions) {
this.cellWidth = options.renderingOptions.getCellWidth();
this.cellHeight = options.renderingOptions.getCellHeight();
FontMeasurer fontMeasurer = new FontMeasurer(
options.renderingOptions.getFont(), options.renderingOptions.getForceFontSize());
width = grid.getWidth() * cellWidth;
height = grid.getHeight() * cellHeight;
TextGrid workGrid = new TextGrid(grid);
workGrid.replaceTypeOnLine();
workGrid.replacePointMarkersOnLine();
if(DEBUG) workGrid.printDebug();
int width = grid.getWidth();
int height = grid.getHeight();
//split distinct shapes using AbstractionGrid
AbstractionGrid temp = new AbstractionGrid(workGrid, workGrid.getAllBoundaries());
ArrayList boundarySetsStep1 = temp.getDistinctShapes();
if(DEBUG){
System.out.println("******* Distinct shapes found using AbstractionGrid *******");
Iterator dit = boundarySetsStep1.iterator();
while (dit.hasNext()) {
CellSet set = (CellSet) dit.next();
set.printAsGrid();
}
System.out.println("******* Same set of shapes after processing them by filling *******");
}
//Find all the boundaries by using the special version of the filling method
//(fills in a different buffer than the buffer it reads from)
ArrayList boundarySetsStep2 = new ArrayList();
Iterator boundarySetIt = boundarySetsStep1.iterator();
while (boundarySetIt.hasNext()) {
CellSet set = (CellSet) boundarySetIt.next();
//the fill buffer keeps track of which cells have been
//filled already
TextGrid fillBuffer = new TextGrid(width * 3, height * 3);
for(int yi = 0; yi < height * 3; yi++){
for(int xi = 0; xi < width * 3; xi++){
if(fillBuffer.isBlank(xi, yi)){
TextGrid copyGrid = new AbstractionGrid(workGrid, set).getCopyOfInternalBuffer();
CellSet boundaries =
copyGrid
.findBoundariesExpandingFrom(copyGrid.new Cell(xi, yi));
if(boundaries.size() == 0) continue; //i'm not sure why these occur
boundarySetsStep2.add(boundaries.makeScaledOneThirdEquivalent());
copyGrid = new AbstractionGrid(workGrid, set).getCopyOfInternalBuffer();
CellSet filled =
copyGrid
.fillContinuousArea(copyGrid.new Cell(xi, yi), '*');
fillBuffer.fillCellsWith(filled, '*');
fillBuffer.fillCellsWith(boundaries, '-');
if(DEBUG){
//System.out.println("Fill buffer:");
//fillBuffer.printDebug();
boundaries.makeScaledOneThirdEquivalent().printAsGrid();
System.out.println("-----------------------------------");
}
}
}
}
}
if (DEBUG)
System.out.println("******* Removed duplicates *******");
boundarySetsStep2 = CellSet.removeDuplicateSets(boundarySetsStep2);
if(DEBUG){
Iterator dit = boundarySetsStep2.iterator();
while (dit.hasNext()) {
CellSet set = (CellSet) dit.next();
set.printAsGrid();
}
}
int originalSize = boundarySetsStep2.size();
boundarySetsStep2 = CellSet.removeDuplicateSets(boundarySetsStep2);
if(DEBUG) {
System.out.println(
"******* Removed duplicates: there were "
+originalSize
+" shapes and now there are "
+boundarySetsStep2.size());
}
//split boundaries to open, closed and mixed
if (DEBUG)
System.out.println("******* First evaluation of openess *******");
ArrayList open = new ArrayList();
ArrayList closed = new ArrayList();
ArrayList mixed = new ArrayList();
Iterator sets = boundarySetsStep2.iterator();
while(sets.hasNext()){
CellSet set = (CellSet) sets.next();
int type = set.getType(workGrid);
if(type == CellSet.TYPE_CLOSED) closed.add(set);
else if(type == CellSet.TYPE_OPEN) open.add(set);
else if(type == CellSet.TYPE_MIXED) mixed.add(set);
if(DEBUG){
if(type == CellSet.TYPE_CLOSED) System.out.println("Closed boundaries:");
else if(type == CellSet.TYPE_OPEN) System.out.println("Open boundaries:");
else if(type == CellSet.TYPE_MIXED) System.out.println("Mixed boundaries:");
set.printAsGrid();
}
}
boolean hadToEliminateMixed = false;
if(mixed.size() > 0 && closed.size() > 0) {
// mixed shapes can be eliminated by
// subtracting all the closed shapes from them
if (DEBUG)
System.out.println("******* Eliminating mixed shapes (basic algorithm) *******");
hadToEliminateMixed = true;
//subtract from each of the mixed sets all the closed sets
sets = mixed.iterator();
while(sets.hasNext()){
CellSet set = (CellSet) sets.next();
Iterator closedSets = closed.iterator();
while(closedSets.hasNext()){
CellSet closedSet = (CellSet) closedSets.next();
set.subtractSet(closedSet);
}
// this is necessary because some mixed sets produce
// several distinct open sets after you subtract the
// closed sets from them
if(set.getType(workGrid) == CellSet.TYPE_OPEN) {
boundarySetsStep2.remove(set);
boundarySetsStep2.addAll(set.breakIntoDistinctBoundaries(workGrid));
}
}
} else if(mixed.size() > 0 && closed.size() == 0) {
// no closed shape exists, will have to
// handle mixed shape on its own
// an example of this case is the following:
// +-----+
// | A |C B
// + ---+-------------------
// | |
// +-----+
hadToEliminateMixed = true;
if (DEBUG)
System.out.println("******* Eliminating mixed shapes (advanced algorithm for truly mixed shapes) *******");
sets = mixed.iterator();
while(sets.hasNext()){
CellSet set = (CellSet) sets.next();
boundarySetsStep2.remove(set);
boundarySetsStep2.addAll(set.breakTrulyMixedBoundaries(workGrid));
}
} else {
if (DEBUG)
System.out.println("No mixed shapes found. Skipped mixed shape elimination step");
}
if(hadToEliminateMixed){
if (DEBUG)
System.out.println("******* Second evaluation of openess *******");
//split boundaries again to open, closed and mixed
open = new ArrayList();
closed = new ArrayList();
mixed = new ArrayList();
sets = boundarySetsStep2.iterator();
while(sets.hasNext()){
CellSet set = (CellSet) sets.next();
int type = set.getType(workGrid);
if(type == CellSet.TYPE_CLOSED) closed.add(set);
else if(type == CellSet.TYPE_OPEN) open.add(set);
else if(type == CellSet.TYPE_MIXED) mixed.add(set);
if(DEBUG){
if(type == CellSet.TYPE_CLOSED) System.out.println("Closed boundaries:");
else if(type == CellSet.TYPE_OPEN) System.out.println("Open boundaries:");
else if(type == CellSet.TYPE_MIXED) System.out.println("Mixed boundaries:");
set.printAsGrid();
}
}
}
boolean removedAnyObsolete = removeObsoleteShapes(workGrid, closed);
boolean allCornersRound = false;
if(processingOptions.areAllCornersRound()) allCornersRound = true;
//make shapes from the boundary sets
//make closed shapes
ArrayList closedShapes = new ArrayList();
sets = closed.iterator();
while(sets.hasNext()){
CellSet set = (CellSet) sets.next();
DiagramComponent shape = DiagramComponent.createClosedFromBoundaryCells(workGrid, set, cellWidth, cellHeight, allCornersRound);
if(shape != null){
if(shape instanceof DiagramShape){
addToShapes((DiagramShape) shape);
closedShapes.add(shape);
} else if(shape instanceof CompositeDiagramShape)
addToCompositeShapes((CompositeDiagramShape) shape);
}
}
if(processingOptions.performSeparationOfCommonEdges())
separateCommonEdges(closedShapes);
//make open shapes
sets = open.iterator();
while(sets.hasNext()){
CellSet set = (CellSet) sets.next();
if(set.size() == 1){ //single cell "shape"
TextGrid.Cell cell = (TextGrid.Cell) set.getFirst();
if(!grid.cellContainsDashedLineChar(cell)) {
DiagramShape shape = DiagramShape.createSmallLine(workGrid, cell, cellWidth, cellHeight);
if(shape != null) {
addToShapes(shape);
shape.connectEndsToAnchors(workGrid, this);
}
}
} else { //normal shape
DiagramComponent shape =
CompositeDiagramShape
.createOpenFromBoundaryCells(
workGrid, set, cellWidth, cellHeight, allCornersRound);
if(shape != null){
if(shape instanceof CompositeDiagramShape){
addToCompositeShapes((CompositeDiagramShape) shape);
((CompositeDiagramShape) shape).connectEndsToAnchors(workGrid, this);
} else if(shape instanceof DiagramShape) {
addToShapes((DiagramShape) shape);
((DiagramShape) shape).connectEndsToAnchors(workGrid, this);
((DiagramShape) shape).moveEndsToCellEdges(grid, this);
}
}
}
}
//assign color codes to shapes
//TODO: text on line should not change its color
//TODO: each color tag should be assigned to the smallest containing shape (like shape tags)
Iterator cellColorPairs = grid.findColorCodes().iterator();
while(cellColorPairs.hasNext()){
TextGrid.CellColorPair pair =
(TextGrid.CellColorPair) cellColorPairs.next();
ShapePoint point =
new ShapePoint(getCellMidX(pair.cell), getCellMidY(pair.cell));
Iterator shapes = getShapes().iterator();
while(shapes.hasNext()){
DiagramShape shape = (DiagramShape) shapes.next();
if(shape.contains(point)) shape.setFillColor(pair.color);
}
}
//assign markup to shapes
Iterator cellTagPairs = grid.findMarkupTags().iterator();
while(cellTagPairs.hasNext()){
TextGrid.CellTagPair pair =
(TextGrid.CellTagPair) cellTagPairs.next();
ShapePoint point =
new ShapePoint(getCellMidX(pair.cell), getCellMidY(pair.cell));
//find the smallest shape that contains the tag
DiagramShape containingShape = null;
Iterator shapes = getShapes().iterator();
while(shapes.hasNext()){
DiagramShape shape = (DiagramShape) shapes.next();
if(shape.contains(point)){
if(containingShape == null){
containingShape = shape;
} else {
if(shape.isSmallerThan(containingShape)){
containingShape = shape;
}
}
}
}
//this tag is not within a shape, skip
if(containingShape == null) continue;
//TODO: the code below could be a lot more concise
if(pair.tag.equals("d")){
CustomShapeDefinition def =
processingOptions.getFromCustomShapes("d");
if(def == null)
containingShape.setType(DiagramShape.TYPE_DOCUMENT);
else {
containingShape.setType(DiagramShape.TYPE_CUSTOM);
containingShape.setDefinition(def);
}
} else if(pair.tag.equals("s")){
CustomShapeDefinition def =
processingOptions.getFromCustomShapes("s");
if(def == null)
containingShape.setType(DiagramShape.TYPE_STORAGE);
else {
containingShape.setType(DiagramShape.TYPE_CUSTOM);
containingShape.setDefinition(def);
}
} else if(pair.tag.equals("io")){
CustomShapeDefinition def =
processingOptions.getFromCustomShapes("io");
if(def == null)
containingShape.setType(DiagramShape.TYPE_IO);
else {
containingShape.setType(DiagramShape.TYPE_CUSTOM);
containingShape.setDefinition(def);
}
} else if(pair.tag.equals("c")){
CustomShapeDefinition def =
processingOptions.getFromCustomShapes("c");
if(def == null)
containingShape.setType(DiagramShape.TYPE_DECISION);
else {
containingShape.setType(DiagramShape.TYPE_CUSTOM);
containingShape.setDefinition(def);
}
} else if(pair.tag.equals("mo")){
CustomShapeDefinition def =
processingOptions.getFromCustomShapes("mo");
if(def == null)
containingShape.setType(DiagramShape.TYPE_MANUAL_OPERATION);
else {
containingShape.setType(DiagramShape.TYPE_CUSTOM);
containingShape.setDefinition(def);
}
} else if(pair.tag.equals("tr")){
CustomShapeDefinition def =
processingOptions.getFromCustomShapes("tr");
if(def == null)
containingShape.setType(DiagramShape.TYPE_TRAPEZOID);
else {
containingShape.setType(DiagramShape.TYPE_CUSTOM);
containingShape.setDefinition(def);
}
} else if(pair.tag.equals("o")){
CustomShapeDefinition def =
processingOptions.getFromCustomShapes("o");
if(def == null)
containingShape.setType(DiagramShape.TYPE_ELLIPSE);
else {
containingShape.setType(DiagramShape.TYPE_CUSTOM);
containingShape.setDefinition(def);
}
} else {
CustomShapeDefinition def =
processingOptions.getFromCustomShapes(pair.tag);
containingShape.setType(DiagramShape.TYPE_CUSTOM);
containingShape.setDefinition(def);
}
}
//make arrowheads
Iterator arrowheadCells = workGrid.findArrowheads().iterator();
while(arrowheadCells.hasNext()){
TextGrid.Cell cell = (TextGrid.Cell) arrowheadCells.next();
DiagramShape arrowhead = DiagramShape.createArrowhead(workGrid, cell, cellWidth, cellHeight);
if(arrowhead != null) addToShapes(arrowhead);
else System.err.println("Could not create arrowhead shape. Unexpected error.");
}
//make point markers
Iterator markersIt = grid.getPointMarkersOnLine().iterator();
while (markersIt.hasNext()) {
TextGrid.Cell cell = (TextGrid.Cell) markersIt.next();
DiagramShape mark = new DiagramShape();
mark.addToPoints(new ShapePoint(
getCellMidX(cell),
getCellMidY(cell)
));
mark.setType(DiagramShape.TYPE_POINT_MARKER);
mark.setFillColor(Color.white);
shapes.add(mark);
}
removeDuplicateShapes();
if(DEBUG) System.out.println("Shape count: "+shapes.size());
if(DEBUG) System.out.println("Composite shape count: "+compositeShapes.size());
//copy again
workGrid = new TextGrid(grid);
workGrid.removeNonText();
// ****** handle text *******
//break up text into groups
TextGrid textGroupGrid = new TextGrid(workGrid);
CellSet gaps = textGroupGrid.getAllBlanksBetweenCharacters();
//kludge
textGroupGrid.fillCellsWith(gaps, '|');
CellSet nonBlank = textGroupGrid.getAllNonBlank();
ArrayList textGroups = nonBlank.breakIntoDistinctBoundaries();
if(DEBUG) System.out.println(textGroups.size()+" text groups found");
Font font = fontMeasurer.getFontFor(cellHeight);
Iterator textGroupIt = textGroups.iterator();
while(textGroupIt.hasNext()){
CellSet textGroupCellSet = (CellSet) textGroupIt.next();
TextGrid isolationGrid = new TextGrid(width, height);
workGrid.copyCellsTo(textGroupCellSet, isolationGrid);
ArrayList strings = isolationGrid.findStrings();
Iterator it = strings.iterator();
while(it.hasNext()){
TextGrid.CellStringPair pair = (TextGrid.CellStringPair) it.next();
TextGrid.Cell cell = pair.cell;
String string = pair.string;
if (DEBUG)
System.out.println("Found string "+string);
TextGrid.Cell lastCell = isolationGrid.new Cell(cell.x + string.length() - 1, cell.y);
int minX = getCellMinX(cell);
int y = getCellMaxY(cell);
int maxX = getCellMaxX(lastCell);
DiagramText textObject;
if(fontMeasurer.getWidthFor(string, font) > maxX - minX){ //does not fit horizontally
Font lessWideFont = fontMeasurer.getFontFor(maxX - minX, string);
textObject = new DiagramText(minX, y, string, lessWideFont, fontMeasurer);
} else textObject = new DiagramText(minX, y, string, font, fontMeasurer);
textObject.centerVerticallyBetween(getCellMinY(cell), getCellMaxY(cell));
//TODO: if the strings start with bullets they should be aligned to the left
//position text correctly
int otherStart = isolationGrid.otherStringsStartInTheSameColumn(cell);
int otherEnd = isolationGrid.otherStringsEndInTheSameColumn(lastCell);
if(0 == otherStart && 0 == otherEnd) {
textObject.centerHorizontallyBetween(minX, maxX);
} else if(otherEnd > 0 && otherStart == 0) {
textObject.alignRightEdgeTo(maxX);
} else if(otherEnd > 0 && otherStart > 0){
if(otherEnd > otherStart){
textObject.alignRightEdgeTo(maxX);
} else if(otherEnd == otherStart){
textObject.centerHorizontallyBetween(minX, maxX);
}
}
addToTextObjects(textObject);
}
}
if (DEBUG)
System.out.println("Positioned text");
//correct the color of the text objects according
//to the underlying color
Iterator shapes = this.getAllDiagramShapes().iterator();
while(shapes.hasNext()){
DiagramShape shape = (DiagramShape) shapes.next();
Color fillColor = shape.getFillColor();
if(shape.isClosed()
&& shape.getType() != DiagramShape.TYPE_ARROWHEAD
&& fillColor != null
&& BitmapRenderer.isColorDark(fillColor)){
Iterator textObjects = getTextObjects().iterator();
while(textObjects.hasNext()){
DiagramText textObject = (DiagramText) textObjects.next();
if(shape.intersects(textObject.getBounds())){
textObject.setColor(Color.white);
}
}
}
}
//set outline to true for test within custom shapes
shapes = this.getAllDiagramShapes().iterator();
while(shapes.hasNext()){
DiagramShape shape = (DiagramShape) shapes.next();
if(shape.getType() == DiagramShape.TYPE_CUSTOM){
Iterator textObjects = getTextObjects().iterator();
while(textObjects.hasNext()){
DiagramText textObject = (DiagramText) textObjects.next();
textObject.setHasOutline(true);
textObject.setColor(DiagramText.DEFAULT_COLOR);
}
}
}
if (DEBUG)
System.out.println("Corrected color of text according to underlying color");
}
/**
* Returns a list of all DiagramShapes in the Diagram, including
* the ones within CompositeDiagramShapes
*
* @return
*/
public ArrayList getAllDiagramShapes(){
ArrayList shapes = new ArrayList();
shapes.addAll(this.getShapes());
Iterator shapesIt = this.getCompositeShapes().iterator();
while(shapesIt.hasNext()){
CompositeDiagramShape compShape = (CompositeDiagramShape) shapesIt.next();
shapes.addAll(compShape.getShapes());
}
return shapes;
}
/**
* Removes the sets from sets
that are the sum of their parts
* when plotted as filled shapes.
*
* @return true if it removed any obsolete.
*
*/
private boolean removeObsoleteShapes(TextGrid grid, ArrayList sets){
if (DEBUG)
System.out.println("******* Removing obsolete shapes *******");
boolean removedAny = false;
ArrayList filledSets = new ArrayList();
Iterator it;
if(VERBOSE_DEBUG) {
System.out.println("******* Sets before *******");
it = sets.iterator();
while(it.hasNext()){
CellSet set = (CellSet) it.next();
set.printAsGrid();
}
}
//make filled versions of all the boundary sets
it = sets.iterator();
while(it.hasNext()){
CellSet set = (CellSet) it.next();
set = set.getFilledEquivalent(grid);
if(set == null){
return false;
} else filledSets.add(set);
}
ArrayList toBeRemovedIndices = new ArrayList();
it = filledSets.iterator();
while(it.hasNext()){
CellSet set = (CellSet) it.next();
if(VERBOSE_DEBUG){
System.out.println("*** Deciding if the following should be removed:");
set.printAsGrid();
}
//find the other sets that have common cells with set
ArrayList common = new ArrayList();
common.add(set);
Iterator it2 = filledSets.iterator();
while(it2.hasNext()){
CellSet set2 = (CellSet) it2.next();
if(set != set2 && set.hasCommonCells(set2)){
common.add(set2);
}
}
//it only makes sense for more than 2 sets
if(common.size() == 2) continue;
//find largest set
CellSet largest = set;
it2 = common.iterator();
while(it2.hasNext()){
CellSet set2 = (CellSet) it2.next();
if(set2.size() > largest.size()){
largest = set2;
}
}
if(VERBOSE_DEBUG){
System.out.println("Largest:");
largest.printAsGrid();
}
//see if largest is sum of others
common.remove(largest);
//make the sum set of the small sets on a grid
TextGrid gridOfSmalls = new TextGrid(largest.getMaxX() + 2, largest.getMaxY() + 2);
CellSet sumOfSmall = new CellSet();
it2 = common.iterator();
while(it2.hasNext()){
CellSet set2 = (CellSet) it2.next();
if(VERBOSE_DEBUG){
System.out.println("One of smalls:");
set2.printAsGrid();
}
gridOfSmalls.fillCellsWith(set2, '*');
}
if(VERBOSE_DEBUG){
System.out.println("Sum of smalls:");
gridOfSmalls.printDebug();
}
TextGrid gridLargest = new TextGrid(largest.getMaxX() + 2, largest.getMaxY() + 2);
gridLargest.fillCellsWith(largest, '*');
int index = filledSets.indexOf(largest);
if(gridLargest.equals(gridOfSmalls)
&& !toBeRemovedIndices.contains(index)) {
toBeRemovedIndices.add(index);
if (DEBUG){
System.out.println("Decided to remove set:");
largest.printAsGrid();
}
} else if (DEBUG){
System.out.println("This set WILL NOT be removed:");
largest.printAsGrid();
}
//if(gridLargest.equals(gridOfSmalls)) toBeRemovedIndices.add(new Integer(index));
}
ArrayList setsToBeRemoved = new ArrayList();
it = toBeRemovedIndices.iterator();
while(it.hasNext()){
int i = ((Integer) it.next()).intValue();
setsToBeRemoved.add(sets.get(i));
}
it = setsToBeRemoved.iterator();
while(it.hasNext()){
CellSet set = (CellSet) it.next();
removedAny = true;
sets.remove(set);
}
if(VERBOSE_DEBUG) {
System.out.println("******* Sets after *******");
it = sets.iterator();
while(it.hasNext()){
CellSet set = (CellSet) it.next();
set.printAsGrid();
}
}
return removedAny;
}
public float getMinimumOfCellDimension(){
return Math.min(getCellWidth(), getCellHeight());
}
private void separateCommonEdges(ArrayList shapes){
float offset = getMinimumOfCellDimension() / 5;
ArrayList edges = new ArrayList();
//get all adges
Iterator it = shapes.iterator();
while (it.hasNext()) {
DiagramShape shape = (DiagramShape) it.next();
edges.addAll(shape.getEdges());
}
//group edges into pairs of touching edges
ArrayList> listOfPairs = new ArrayList>();
it = edges.iterator();
//all-against-all touching test for the edges
int startIndex = 1; //skip some to avoid duplicate comparisons and self-to-self comparisons
while(it.hasNext()){
ShapeEdge edge1 = (ShapeEdge) it.next();
for(int k = startIndex; k < edges.size(); k++) {
ShapeEdge edge2 = edges.get(k);
if(edge1.touchesWith(edge2)) {
listOfPairs.add(new Pair(edge1, edge2));
}
}
startIndex++;
}
ArrayList movedEdges = new ArrayList();
//move equivalent edges inwards
it = listOfPairs.iterator();
while(it.hasNext()){
Pair pair = (Pair) it.next();
if(!movedEdges.contains(pair.first)) {
pair.first.moveInwardsBy(offset);
movedEdges.add(pair.first);
}
if(!movedEdges.contains(pair.second)) {
pair.second.moveInwardsBy(offset);
movedEdges.add(pair.second);
}
}
}
//TODO: removes more than it should
private void removeDuplicateShapes() {
ArrayList originalShapes = new ArrayList();
Iterator shapesIt = getShapesIterator();
while(shapesIt.hasNext()){
DiagramShape shape = (DiagramShape) shapesIt.next();
boolean isOriginal = true;
Iterator originals = originalShapes.iterator();
while(originals.hasNext()){
DiagramShape originalShape = (DiagramShape) originals.next();
if(shape.equals(originalShape)){
isOriginal = false;
}
}
if(isOriginal) originalShapes.add(shape);
}
shapes.clear();
shapes.addAll(originalShapes);
}
private void addToTextObjects(DiagramText shape){
textObjects.add(shape);
}
private void addToCompositeShapes(CompositeDiagramShape shape){
compositeShapes.add(shape);
}
private void addToShapes(DiagramShape shape){
shapes.add(shape);
}
public Iterator getShapesIterator(){
return shapes.iterator();
}
/**
* @return
*/
public int getHeight() {
return height;
}
/**
* @return
*/
public int getWidth() {
return width;
}
/**
* @return
*/
public int getCellWidth() {
return cellWidth;
}
/**
* @return
*/
public int getCellHeight() {
return cellHeight;
}
/**
* @return
*/
public ArrayList getCompositeShapes() {
return compositeShapes;
}
/**
* @return
*/
public ArrayList getShapes() {
return shapes;
}
public int getCellMinX(TextGrid.Cell cell){
return getCellMinX(cell, cellWidth);
}
public static int getCellMinX(TextGrid.Cell cell, int cellXSize){
return cell.x * cellXSize;
}
public int getCellMidX(TextGrid.Cell cell){
return getCellMidX(cell, cellWidth);
}
public static int getCellMidX(TextGrid.Cell cell, int cellXSize){
return cell.x * cellXSize + cellXSize / 2;
}
public int getCellMaxX(TextGrid.Cell cell){
return getCellMaxX(cell, cellWidth);
}
public static int getCellMaxX(TextGrid.Cell cell, int cellXSize){
return cell.x * cellXSize + cellXSize;
}
public int getCellMinY(TextGrid.Cell cell){
return getCellMinY(cell, cellHeight);
}
public static int getCellMinY(TextGrid.Cell cell, int cellYSize){
return cell.y * cellYSize;
}
public int getCellMidY(TextGrid.Cell cell){
return getCellMidY(cell, cellHeight);
}
public static int getCellMidY(TextGrid.Cell cell, int cellYSize){
return cell.y * cellYSize + cellYSize / 2;
}
public int getCellMaxY(TextGrid.Cell cell){
return getCellMaxY(cell, cellHeight);
}
public static int getCellMaxY(TextGrid.Cell cell, int cellYSize){
return cell.y * cellYSize + cellYSize;
}
public TextGrid.Cell getCellFor(ShapePoint point){
if(point == null) throw new IllegalArgumentException("ShapePoint cannot be null");
//TODO: the fake grid is a problem
TextGrid g = new TextGrid();
return g.new Cell((int) point.x / cellWidth,
(int) point.y / cellHeight);
}
/**
* @return
*/
public ArrayList getTextObjects() {
return textObjects;
}
}
© 2015 - 2024 Weber Informatics LLC | Privacy Policy