using System;
using System.Collections.Generic;
using System.Linq;
namespace Contours {
public enum IntersectionType {
None,
Cross,
Identical,
Inverted,
Touch_a0,
Touch_a1,
Touch_b0,
Touch_b1,
Touch_a0_b0,
Touch_a0_b1,
Touch_a1_b0,
Touch_a1_b1,
Along_a0_b0_a1_b1,
Along_a0_b0_b1_a1,
Along_a0_b1_a1_b0,
Along_a0_b1_b0_a1,
Along_b0_a0_a1_b1,
Along_b0_a0_b1_a1,
Along_b1_a0_a1_b0,
Along_b1_a0_b0_a1
}
public class Circuit<Parent, Child> where Parent: class where Child: class {
public class Entry {
readonly Child owner;
Circuit<Parent, Child> circuit;
Entry previous;
Entry next;
public Entry(Child owner) { this.owner = owner; }
public Child getOwner() { return owner; }
public Circuit<Parent, Child> getCircuit() { return circuit; }
public Parent getParent() {
Circuit<Parent, Child> circuit = getCircuit();
return circuit == null ? null : circuit.getOwner();
}
public Entry getPreviousEntry() { return previous; }
public Entry getNextEntry() { return next; }
public Entry getPreviousEntryLinear() {
Entry e = getPreviousEntry();
return e == null || e == circuit.last ? null : e;
}
public Entry getNextEntryLinear() {
Entry e = getNextEntry();
return e == null || e == circuit.first ? null : e;
}
public Child getPrevious() {
Entry e = getPreviousEntry();
return e == null ? null : e.getOwner();
}
public Child getNext() {
Entry e = getNextEntry();
return e == null ? null : e.getOwner();
}
public Child getPreviousLinear() {
Entry e = getPreviousEntryLinear();
return e == null ? null : e.getOwner();
}
public Child getNextLinear() {
Entry e = getNextEntryLinear();
return e == null ? null : e.getOwner();
}
public void unlink() {
if (previous != null) previous.next = next;
if (next != null) next.previous = previous;
if (circuit != null) {
if (circuit.first == this) {
circuit.first = next != this ? next : null;
circuit.last = previous != this ? previous : null;
}
--circuit.count;
circuit = null;
}
previous = null;
next = null;
}
public void insertBack(Circuit<Parent, Child> circuit) {
unlink();
if (circuit != null) {
if (circuit.empty()) {
this.circuit = circuit;
previous = next = this;
circuit.first = circuit.last = this;
++circuit.count;
} else {
insertAfterOf(circuit.getLastEntry());
}
}
}
public void insertFront(Circuit<Parent, Child> circuit) {
unlink();
if (circuit != null) {
if (circuit.empty()) {
this.circuit = circuit;
previous = next = this;
circuit.first = circuit.last = this;
++circuit.count;
} else {
insertBeforeOf(circuit.getFirstEntry());
}
}
}
public void insertAfterOf(Entry entry) {
if (entry == this) return;
unlink();
if (entry == null || entry.getCircuit() == null) return;
previous = entry;
next = entry.next;
previous.next = this;
if (next != null) next.previous = this;
circuit = entry.getCircuit();
if (circuit != null) {
if (circuit.getLastEntry() == entry)
circuit.last = this;
++circuit.count;
}
}
public void insertBeforeOf(Entry entry) {
if (entry == this) return;
unlink();
if (entry == null || entry.getCircuit() == null) return;
previous = entry.previous;
next = entry;
if (previous != null) previous.next = this;
next.previous = this;
circuit = entry.getCircuit();
if (circuit != null) {
if (circuit.getFirstEntry() == entry)
circuit.first = this;
++circuit.count;
}
}
public void swapWith(Entry other) {
if (other == this || other == null) return;
Circuit<Parent, Child> otherCircuit = other.circuit;
Entry otherPrevious = other.previous;
Entry otherNext = other.next;
other.circuit = circuit;
other.previous = previous;
other.next = next;
if (otherCircuit != null) {
if (otherCircuit.first == other)
otherCircuit.first = this;
if (otherCircuit.last == other)
otherCircuit.last = this;
}
if (circuit != null) {
if (circuit.first == this)
circuit.first = other;
if (circuit.last == this)
circuit.last = other;
}
circuit = otherCircuit;
previous = otherPrevious;
next = otherNext;
}
}
readonly Parent owner;
Entry first;
Entry last;
int count = 0;
public Circuit(Parent owner) { this.owner = owner; }
public Parent getOwner() { return owner; }
public int getCount() { return count; }
public Entry getFirstEntry() { return first; }
public Entry getLastEntry() { return last; }
public Child getFirst() {
Entry e = getFirstEntry();
return e == null ? null : e.getOwner();
}
public Child getLast() {
Entry e = getLastEntry();
return e == null ? null : e.getOwner();
}
public bool empty() { return getFirstEntry() == null; }
public void clear() {
while(!empty()) getFirstEntry().unlink();
}
}
public class Shape {
public class Position {
public int x = 0;
public int y = 0;
public readonly Circuit<Shape, Position>.Entry shape;
public readonly Circuit<Position, Link> links;
public Position() {
shape = new Circuit<Shape, Position>.Entry(this);
links = new Circuit<Position, Link>(this);
}
public Position(int x, int y): this() { this.x = x; this.y = y; }
public VectorInt toVectorInt() { return new VectorInt(x, y); }
}
public class Contour {
public bool inverted = false;
public Contour parent;
public List<Contour> childs;
public readonly Circuit<Shape, Contour>.Entry shape;
public readonly Circuit<Contour, Link> forward;
public readonly Circuit<Contour, Link> backward;
public Contour() {
shape = new Circuit<Shape, Contour>.Entry(this);
forward = new Circuit<Contour, Link>(this);
backward = new Circuit<Contour, Link>(this);
}
}
public class Link {
public readonly Circuit<Shape, Link>.Entry shape;
public readonly Circuit<Position, Link>.Entry position;
public readonly Circuit<Contour, Link>.Entry contour;
public bool forward = false;
public Position target = null;
public Link() {
shape = new Circuit<Shape, Link>.Entry(this);
position = new Circuit<Position, Link>.Entry(this);
contour = new Circuit<Contour, Link>.Entry(this);
}
public void unlink() {
contour.unlink();
position.unlink();
shape.unlink();
target = null;
}
public static Link create(Position position, Circuit<Contour, Link> contourCircuit) {
Link link = new Link();
link.shape.insertBack(contourCircuit.getOwner().shape.getParent().links);
link.position.insertBack(position.links);
link.contour.insertBack(contourCircuit);
link.forward = contourCircuit == contourCircuit.getOwner().forward;
return link;
}
public Link createSplitAfter(Position position) {
Link link = new Link();
link.forward = forward;
link.shape.insertBack(shape.getParent().links);
link.position.insertBack(position.links);
link.contour.insertAfterOf(contour);
return link;
}
public Link createSplitAfter(Circuit<Position, Link>.Entry position) {
Link link = new Link();
link.forward = forward;
link.shape.insertBack(shape.getParent().links);
link.position.insertAfterOf(position);
link.contour.insertAfterOf(contour);
return link;
}
}
public Circuit<Shape, Position> positions;
public Circuit<Shape, Link> links;
public Circuit<Shape, Contour> contours;
public List<Contour> rootContours;
public void addContours(ContourInt contours) {
foreach(List<VectorInt> contour in contours.contours)
addContour(contour);
}
public void addContour(ICollection<VectorInt> points) {
if (points.Count < 3)
return;
Contour contour = new Contour();
contour.shape.insertBack(contours);
foreach(VectorInt point in points) {
Position position = new Position(point.x, point.y);
position.shape.insertBack(positions);
Link.create(position, contour.forward);
Link.create(position, contour.backward);
}
}
public static int compare(VectorInt a0, VectorInt a1, VectorInt base0, VectorInt base1) {
if (base0.x < base1.x && a0.x < a1.x) return -1;
if (base0.x < base1.x && a1.x < a0.x) return 1;
if (base1.x < base0.x && a0.x < a1.x) return 1;
if (base1.x < base0.x && a1.x < a0.x) return -1;
if (base0.y < base1.x && a0.y < a1.x) return -1;
if (base0.y < base1.x && a1.y < a0.x) return 1;
if (base1.y < base0.x && a0.y < a1.x) return 1;
if (base1.y < base0.x && a1.y < a0.x) return -1;
return 0;
}
public static IntersectionType findIntersection(VectorInt a0, VectorInt a1, VectorInt b0, VectorInt b1, out VectorInt c) {
c = new VectorInt();
VectorInt da = new VectorInt(a1.x - a0.x, a1.y - a0.y);
VectorInt db = new VectorInt(b1.x - b0.x, b1.y - b0.y);
if (a0.x == b0.x && a0.y == b0.y && a1.x == b1.x && a1.y == b1.y)
return IntersectionType.Identical;
if (a0.x == b1.x && a0.y == b1.y && a1.x == b0.x && a1.y == b0.y)
return IntersectionType.Inverted;
long divider = (long)da.x*(long)db.y - (long)db.x*(long)da.y;
if (divider == 0) {
if ((long)da.x*(long)(b0.y - a0.y) != (long)da.y*(long)(b0.x - a0.x))
return IntersectionType.None;
int a0b0 = compare(a0, b0, a0, a1);
int a0b1 = compare(a0, b1, a0, a1);
int a1b0 = compare(a1, b0, a0, a1);
int a1b1 = compare(a1, b1, a0, a1);
int b0b1 = compare(b0, b1, a0, a1);
int b0a0 = -a0b0;
int b0a1 = -a1b0;
int b1a0 = -a0b1;
int b1a1 = -a1b1;
int b1b0 = -b0b1;
// a0a1b0b1
if (a1b0 == 0 && b0b1 < 0)
return IntersectionType.Touch_a1_b0;
// a0a1b1b0
if (a1b1 == 0 && b1b0 < 0)
return IntersectionType.Touch_a1_b1;
// b0b1a0a1
if (b0b1 < 0 && b1a0 == 0)
return IntersectionType.Touch_a0_b1;
// b1b0a0a1
if (b1b0 < 0 && b0a0 == 0)
return IntersectionType.Touch_a0_b0;
if (a0b0 <= 0 && b0a1 <= 0 && a1b1 <= 0)
return IntersectionType.Along_a0_b0_a1_b1;
if (a0b0 <= 0 && b0b1 <= 0 && b1a1 <= 0)
return IntersectionType.Along_a0_b0_b1_a1;
if (a0b1 <= 0 && b1a1 <= 0 && a1b0 <= 0)
return IntersectionType.Along_a0_b1_a1_b0;
if (a0b1 <= 0 && b1b0 <= 0 && b0a1 <= 0)
return IntersectionType.Along_a0_b1_b0_a1;
if (b0a0 <= 0 && /* a0a1 */ a1b1 <= 0)
return IntersectionType.Along_b0_a0_a1_b1;
if (b0a0 <= 0 && a0b1 <= 0 && b1a1 <= 0)
return IntersectionType.Along_b0_a0_b1_a1;
if (b1a0 <= 0 && /* a0a1 */ a1b0 <= 0)
return IntersectionType.Along_b1_a0_a1_b0;
if (b1a0 <= 0 && a0b0 <= 0 && b0a1 <= 0)
return IntersectionType.Along_b1_a0_b0_a1;
return IntersectionType.None;
}
if (a0.x == b0.x && a0.y == b0.y)
return IntersectionType.Touch_a0_b0;
if (a0.x == b1.x && a0.y == b1.y)
return IntersectionType.Touch_a0_b1;
if (a1.x == b0.x && a1.y == b0.y)
return IntersectionType.Touch_a1_b0;
if (a1.x == b1.x && a1.y == b1.y)
return IntersectionType.Touch_a1_b1;
long numeratorX = (long)da.x*((long)b1.y*(long)b0.x - (long)b0.y*(long)b1.x)
- (long)db.x*((long)a1.y*(long)a0.x - (long)a0.y*(long)a1.x);
long numeratorY = (long)db.y*((long)a1.x*(long)a0.y - (long)a0.x*(long)a1.y)
- (long)da.y*((long)b1.x*(long)b0.y - (long)b0.x*(long)b1.y);
VectorInt p = new VectorInt((int)(numeratorX/divider), (int)(numeratorY/divider));
if (compare(p, a0, a0, a1) < 0 || compare(p, a1, a0, a1) > 0)
return IntersectionType.None;
if (p.x == a0.x && p.y == a0.y)
return IntersectionType.Touch_a0;
if (p.x == a1.x && p.y == a1.y)
return IntersectionType.Touch_a1;
if (p.x == b0.x && p.y == b0.y)
return IntersectionType.Touch_b0;
if (p.x == b1.x && p.y == b1.y)
return IntersectionType.Touch_b1;
c = p;
return IntersectionType.Cross;
}
public bool removeEmptyContours() {
bool removed = false;
bool retry = true;
while(retry) {
retry = false;
for(Contour contour = contours.getFirst(); !retry && contour != null; contour = contour.shape.getNextLinear()) {
if (contour.forward.getCount() < 3 || contour.backward.getCount() < 3) {
while(contour.forward.getFirst() != null)
contour.forward.getFirst().unlink();
while(contour.backward.getFirst() != null)
contour.backward.getFirst().unlink();
contour.shape.unlink();
retry = true;
removed = true;
break;
}
}
if (retry) continue;
}
}
public void findIntersections() {
bool retry = true;
while(retry) {
retry = false;
retry = removeEmptyContours();
if (retry) continue;
// remove empty positions
for(Position position = positions.getFirst(); !retry && position != null; position = position.shape.getNextLinear()) {
if (position.links.empty()) {
position.shape.unlink();
retry = true;
break;
}
}
if (retry) continue;
// merge positions
for(Position positionA = positions.getFirst(); !retry && positionA != null; positionA = positionA.shape.getNextLinear()) {
for(Position positionB = positionA.shape.getNextLinear(); !retry && positionB != null; positionB = positionB.shape.getNextLinear()) {
if (positionA.x == positionB.x && positionA.y == positionB.y) {
while(positionB.links.getFirst() != null)
positionB.links.getFirst().position.insertBack(positionA.links);
positionB.shape.unlink();
retry = true;
break;
}
}
}
if (retry) continue;
// remove zero-length links
for(Link linkA0 = links.getFirst(); !retry && linkA0 != null; linkA0 = linkA0.shape.getNextLinear()) {
Link linkA1 = linkA0.contour.getNext();
if (linkA0.position.getParent() == linkA1.position.getParent()) {
linkA1.unlink();
retry = true;
break;
}
}
if (retry) continue;
// check intersections
for(Link linkA0 = links.getFirst(); !retry && linkA0 != null; linkA0 = linkA0.shape.getNextLinear()) {
Link linkA1 = linkA0.contour.getNext();
for(Link linkB0 = links.getFirst(); !retry && linkB0 != null; linkB0 = linkB0.shape.getNextLinear()) {
Link linkB1 = linkB0.contour.getNext();
VectorInt cross = new VectorInt(0, 0);
Position position;
retry = true;
switch( findIntersection( linkA0.position.getParent().toVectorInt(),
linkA1.position.getParent().toVectorInt(),
linkB0.position.getParent().toVectorInt(),
linkB1.position.getParent().toVectorInt(),
out cross ))
{
case IntersectionType.Cross:
position = new Position(cross.x, cross.y);
position.shape.insertBack(positions);
linkA0.createSplitAfter(position);
linkB0.createSplitAfter(position);
break;
case IntersectionType.Touch_a0:
linkB0.createSplitAfter(linkA0.position);
break;
case IntersectionType.Touch_a1:
linkB0.createSplitAfter(linkA1.position);
break;
case IntersectionType.Touch_b0:
linkA0.createSplitAfter(linkB0.position);
break;
case IntersectionType.Touch_b1:
linkA0.createSplitAfter(linkB1.position);
break;
case IntersectionType.Along_a0_b0_a1_b1:
linkA0.createSplitAfter(linkB0.position);
linkB0.createSplitAfter(linkA1.position);
break;
case IntersectionType.Along_a0_b0_b1_a1:
linkA0.createSplitAfter(linkB0.position)
.createSplitAfter(linkB1.position);
break;
case IntersectionType.Along_a0_b1_a1_b0:
linkA0.createSplitAfter(linkB1.position);
linkB0.createSplitAfter(linkA1.position);
break;
case IntersectionType.Along_a0_b1_b0_a1:
linkA0.createSplitAfter(linkB1.position)
.createSplitAfter(linkB0.position);
break;
case IntersectionType.Along_b0_a0_a1_b1:
linkB0.createSplitAfter(linkA0.position)
.createSplitAfter(linkA1.position);
break;
case IntersectionType.Along_b0_a0_b1_a1:
linkA0.createSplitAfter(linkB1.position);
linkB0.createSplitAfter(linkA0.position);
break;
case IntersectionType.Along_b1_a0_a1_b0:
linkB0.createSplitAfter(linkA1.position)
.createSplitAfter(linkA0.position);
break;
case IntersectionType.Along_b1_a0_b0_a1:
linkA0.createSplitAfter(linkB0.position);
linkB0.createSplitAfter(linkA0.position);
break;
default:
retry = false;
break;
}
}
}
if (retry) continue;
}
}
void unlinkContoursChains() {
while(!contours.empty()) {
Contour contour = contours.getFirst();
while(!contour.forward.empty()) {
Link link = contour.forward.getFirst();
link.target = link.contour.getNext().position.getParent();
link.contour.unlink();
}
while(!contour.backward.empty()) {
Link link = contour.backward.getFirst();
link.target = link.contour.getNext().position.getParent();
link.contour.unlink();
}
contour.shape.unlink();
contour.childs.Clear();
contour.parent = null;
}
rootContours.Clear();
}
static bool compareAngle(VectorInt a, VectorInt b, VectorInt c) {
int d = a.x*c.y - a.y*c.x;
// angle AC < 180 deg
if (d > 0)
return a.x*b.y >= a.y*b.x && c.x*b.y <= c.y*b.x;
// angle AC > 180 deg
if (d < 0)
return a.x*b.y >= a.y*b.x || c.x*b.y <= c.y*b.x;
// angle AC == 180 deg
if ((a.x >= 0) != (c.x >= 0) || (a.y >= 0) != (c.y >= 0))
return a.x*b.y >= a.y*b.x;
// angle AC == 0 deg
return true;
}
static bool compareAngle(VectorInt center, VectorInt a, VectorInt b, VectorInt c) {
return compareAngle( new VectorInt(a.x - center.x, a.y - center.y),
new VectorInt(b.x - center.x, b.y - center.y),
new VectorInt(c.x - center.x, c.y - center.y) );
}
void sortLinksAtPosition(Position position) {
if (position.links.getCount() < 3) return;
Link first = position.links.getFirst();
Link linkA = first;
while (true) {
Link linkB = linkA.position.getNext();
Link linkC = linkB.position.getNext();
if ( !compareAngle(
position.toVectorInt(),
linkA.target.toVectorInt(),
linkB.target.toVectorInt(),
linkC.target.toVectorInt() ))
{
linkB.position.swapWith(linkC.position);
first = linkA = linkC;
continue;
}
linkA = linkB;
if (linkA == first) break;
};
}
void sortLinksAtPositions() {
for(Position position = positions.getFirst(); position != null; position = position.shape.getNextLinear())
sortLinksAtPosition(position);
}
void removeLinkFromPosition(Link link) {
Position position = link.position.getParent();
Link nextToRemove = null;
// remove back link
if (link.target != null) {
Link backLink = link.target.links.getFirst();
while (backLink != null) {
Link l = backLink;
backLink = backLink.position.getNextLinear();
if ( l.forward != link.forward
&& l.contour.getNext() != null
&& l.contour.getNext().position.getParent() == position )
{
l.unlink();
break;
}
}
if (link.target.links.getCount() == 1)
nextToRemove = link.target.links.getFirst();
}
// remove
link.unlink();
// remove next
if (nextToRemove != null)
removeLinkFromPosition(nextToRemove);
}
void removeDuplicateLinksFromPosition(Position position) {
for(Link linkA = position.links.getFirst(); linkA != null; linkA = linkA.position.getNextLinear()) {
Position otherPosition = linkA.target;
// count forward and backward links
int count = 0;
Link forwardLink = null;
Link backwardLink = null;
Link linkB = linkA;
do {
if (linkB.target == otherPosition) {
if (linkB.forward) { forwardLink = linkB; ++count; }
else { backwardLink = linkB; --count; }
}
linkB.position.getNext();
} while(linkB != linkA);
// remove extra links
Link linkToSave = count > 0 ? forwardLink
: count < 0 ? backwardLink
: null;
linkB = position.links.getFirst();
while(linkB != null) {
if (linkB.target == otherPosition && linkB != linkToSave) {
removeLinkFromPosition(linkA);
// reset linkA
linkB = linkA = position.links.getFirst();
} else {
linkB = linkB.position.getNextLinear();
}
}
}
}
void removeInvisibleContoursFromPosition(Position position) {
if (position.links.getCount() < 3) return;
Link first = position.links.getFirst();
Link link = first.position.getNext();
while(link != first) {
bool previous = link.position.getPrevious().forward;
bool current = link.forward;
bool next = link.position.getNext().forward;
if ( ( previous && current && !next)
|| (!previous && !current && next) )
{
// remove link
removeLinkFromPosition(link);
first = position.links.getFirst();
link = first.position.getNext();
}
};
}
void removeEmptyPositions() {
for(Position position = positions.getFirst(); position != null;) {
if (position.links.empty()) {
Position p = position;
position = position.shape.getNextLinear();
p.shape.unlink();
} else {
position = position.shape.getNextLinear();
}
}
}
void optimizePositions() {
// remove extra links
for(Position position = positions.getFirst(); position != null; position = position.shape.getNextLinear()) {
removeDuplicateLinksFromPosition(position);
removeInvisibleContoursFromPosition(position);
}
}
void traceContours() {
for(Link linkA = links.getFirst(); linkA != null; linkA = linkA.shape.getNext()) {
if (linkA.forward && linkA.contour.getParent() == null) {
Contour contour = new Contour();
contour.shape.insertBack(contours);
Link forwardLink = linkA;
Link backwardLink = null;
do {
// find pair
for(Link l = linkA.target.links.getFirst(); l != null; l = l.position.getNext())
if (l.target == linkA.position.getParent())
{ backwardLink = l; break; }
if (backwardLink == null)
throw new Exception();
forwardLink.contour.insertBack(contour.forward);
backwardLink.contour.insertBack(contour.backwardLink);
forwardLink = backwardLink.position.getNext();
if ( !forwardLink.forward
|| forwardLink == backwardLink
|| forwardLink.contour.getParent() != null )
throw new Exception();
} while (forwardLink != linkA);
}
}
}
void removeFreeLinks() {
for(Link linkA = links.getFirst(); linkA != null; linkA = linkA.shape.getNext())
if (linkA.contour.getParent() == null)
throw Exception();
}
void makeContourRay(Contour contour, bool invert, out VectorInt p0, out VectorInt p1) {
Link first = contour.forward.getFirst();
VectorInt previousPosition = first.contour.getPrevious().position.getParent().toVectorInt();
VectorInt currentPosition = first.position.getParent().toVectorInt();
VectorInt nextPosition = first.contour.getNext().position.getParent().toVectorInt();
VectorInt direction = new VectorInt(
previousPosition.y - nextPosition.y,
nextPosition.x - previousPosition.x );
if (invert) { direction.x = -direction.x; direction.y = -direction.y; }
int amplifierX =
direction.x > 0 ? (ContourInt.MaxValue - currentPosition.x)/direction.x + 1
: direction.x < 0 ? (ContourInt.MaxValue + currentPosition.x)/(-direction.x) + 1
: int.MaxValue;
int amplifierY =
direction.y > 0 ? (ContourInt.MaxValue - currentPosition.y)/direction.y + 1
: direction.y < 0 ? (ContourInt.MaxValue + currentPosition.y)/(-direction.y) + 1
: int.MaxValue;
int amplifier = Math.Min(amplifierX, amplifierY);
VectorInt farPosition = new VectorInt(
currentPosition.x + direction.x*amplifier,
currentPosition.y + direction.y*amplifier );
p0 = currentPosition;
p1 = farPosition;
}
int countContourIntersections(Contour contour, VectorInt p0, VectorInt p1) {
int count = 0;
for(Link link = contour.forward.getFirst(); link != null; link = link.contour.getNextLinear()) {
VectorInt pp0 = link.position.getParent().toVectorInt();
VectorInt pp1 = link.contour.getNext().position.getParent().toVectorInt();
long d = (long)(p0.y - p1.y)*(long)(pp1.x - pp0.x)
+ (long)(p1.x - p0.x)*(long)(pp1.y - pp0.y);
d = Math.Sign(d);
VectorInt c;
switch(findIntersection(p0, p1, pp0, pp1, out c)) {
case IntersectionType.Cross:
count += 2*d;
break;
case IntersectionType.Touch_b0:
count += d;
break;
case IntersectionType.Touch_b1:
count -= d;
break;
default:
break;
}
}
return count;
}
bool isContourInverted(Contour contour) {
VectorInt p0, p1;
makeContourRay(contour, false, out p0, out p1);
return countContourIntersections(contour, p0, p1) == 0;
}
bool isContourInside(Contour inner, Contour outer) {
VectorInt p0, p1;
makeContourRay(inner, inner.inverted, out p0, out p1);
return countContourIntersections(outer, p0, p1) != 0;
}
Contour findParent(Contour contour, Dictionary<Contour, Dictionary<Contour, bool> > parents) {
if (!parents.ContainsKey(contour)) return null;
if (parents[contour].Count == 1) return parents[contour].Keys.First;
}
void sortChilds(Contour contour, Contour parent) {
// set parent
contour.parent = parent;
// remove sub-childs from parent list
if (parent != null)
foreach(Contour c in contour.childs)
parent.childs.Remove(c);
// sub-calls
foreach(Contour c in contour.childs)
sortChilds(c, contour);
}
void sortContours() {
// calculate directions of contours
for(Contour contourA = contours.getFirst(); contourA != null; contourA = contourA.shape.getNext()) {
contourA.inverted = isContourInverted(contourA);
rootContours.Add(contourA);
}
// find childs
for(Contour contourA = contours.getFirst(); contourA != null; contourA = contourA.shape.getNext()) {
bool isRoot = true;
for(Contour contourB = contourA.shape.getNextLinear(); contourB != null; contourB = contourB.shape.getNext())
if (isContourInside(contourA, contourB)) {
contourB.childs.Add(contourA);
rootContours.Remove(contourA);
} else
if (isContourInside(contourA, contourB)) {
contourA.childs.Add(contourB);
rootContours.Remove(contourB);
}
}
// sort childs
foreach(Contour c in rootContours)
sortChilds(c, null);
}
void removeInvisibleContours() {
// TODO:
}
void optimizeContours() {
findIntersections();
unlinkContoursChains();
sortLinksAtPositions();
optimizePositions();
traceContours();
removeEmptyContours();
removeInvisibleContours();
removeEmptyPositions();
}
}
}