com.sun.javafx.geom.DirtyRegionContainer Maven / Gradle / Ivy
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*
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package com.sun.javafx.geom;
import java.util.Arrays;
/**
* Container for array of dirty regions. This container internally holds
* pointer to the first empty dirty region in the array and index of last
* modified dirty region. It also introduces convenient methods to modify
* the array of dirty regions.
*/
public final class DirtyRegionContainer {
public static final int DTR_OK = 1;
public static final int DTR_CONTAINS_CLIP = 0;
private RectBounds[] dirtyRegions;
private int emptyIndex;
public DirtyRegionContainer(int count) {
initDirtyRegions(count);
}
@Override
public boolean equals(Object obj) {
if (obj instanceof DirtyRegionContainer) {
DirtyRegionContainer drc = (DirtyRegionContainer)obj;
if (size() != drc.size()) return false;
for(int i = 0; i < emptyIndex; i++) {
if (!getDirtyRegion(i).equals(drc.getDirtyRegion(i))) return false;
}
return true;
}
return false;
}
@Override
public int hashCode() {
int hash = 5;
hash = 97 * hash + Arrays.deepHashCode(this.dirtyRegions);
hash = 97 * hash + this.emptyIndex;
return hash;
}
public DirtyRegionContainer deriveWithNewRegion(RectBounds region) {
if (region == null) {
return this;
}
dirtyRegions[0].deriveWithNewBounds(region);
emptyIndex = 1;
return this;
}
public DirtyRegionContainer deriveWithNewRegions(RectBounds[] regions) {
if (regions == null ||
regions.length == 0) {
return this;
}
if (regions.length > maxSpace()) {
initDirtyRegions(regions.length);
}
regioncopy(regions, 0, dirtyRegions, 0, regions.length);
emptyIndex = regions.length;
return this;
}
public DirtyRegionContainer deriveWithNewContainer(DirtyRegionContainer other) {
if (other == null ||
other.maxSpace() == 0) {
return this;
}
if (other.maxSpace() > maxSpace()) {
initDirtyRegions(other.maxSpace());
}
regioncopy(other.dirtyRegions, 0, dirtyRegions, 0, other.emptyIndex);
emptyIndex = other.emptyIndex;
return this;
}
private void initDirtyRegions(int count) {
dirtyRegions = new RectBounds[count];
for (int i = 0; i < count; i++) {
dirtyRegions[i] = new RectBounds();
}
emptyIndex = 0;
}
public DirtyRegionContainer copy() {
DirtyRegionContainer drc = new DirtyRegionContainer(maxSpace());
regioncopy(dirtyRegions, 0, drc.dirtyRegions, 0, emptyIndex);
drc.emptyIndex = emptyIndex;
return drc;
}
public int maxSpace() {
return dirtyRegions.length;
}
/**
* Gets the dirty region at given index.
* @param index the index of requested dirty region
* @return dirty region at given index
*/
public RectBounds getDirtyRegion(int index) {
return dirtyRegions[index];
}
public void setDirtyRegion(int index, RectBounds region) {
dirtyRegions[index] = region;
}
/**
* Adds new dirty region to the array.
* @param region the dirty region.
*/
public void addDirtyRegion(final RectBounds region) {
if (region.isEmpty())
return;
RectBounds dr, tmp;
int tempIndex = 0;
int regionCount = emptyIndex;
for(int i = 0; i < regionCount; i++) {
//can't have overlapping regions
dr = dirtyRegions[tempIndex];
if (region.intersects(dr)) {
region.unionWith(dr);
tmp = dirtyRegions[tempIndex];
dirtyRegions[tempIndex] = dirtyRegions[emptyIndex - 1];
dirtyRegions[emptyIndex - 1] = tmp;
emptyIndex--;
} else {
tempIndex++;
}
}//for
if (hasSpace()) {
dr = dirtyRegions[emptyIndex];
dr.deriveWithNewBounds(region);
emptyIndex++;
return;
}
//match region into existing dirty regions
if (dirtyRegions.length == 1)
dirtyRegions[0].deriveWithUnion(region);
else
compress(region);
}
public void merge(DirtyRegionContainer other) {
int otherSize = other.size();
for(int i = 0; i < otherSize; i++) {
addDirtyRegion(other.getDirtyRegion(i));
}
}
public int size() {
return emptyIndex;
}
public void reset() {
emptyIndex = 0;
}
private RectBounds compress(final RectBounds region) {
compress_heap();
addDirtyRegion(region);
return region;
}
/**
* If there are empty regions in the dirty regions array.
* @return true if there is empty region in the array; false otherwise
*/
private boolean hasSpace() {
return emptyIndex < dirtyRegions.length;
}
private void regioncopy(RectBounds[] src, int from, RectBounds[] dest, int to, int length) {
RectBounds rb;
for (int i = 0; i < length; i++) {
rb = src[from++];
if (rb == null) {
dest[to++].makeEmpty();
} else {
dest[to++].deriveWithNewBounds(rb);
}
}
}
public boolean checkAndClearRegion(int index) {
boolean removed = false;
if (dirtyRegions[index].isEmpty()) {
System.arraycopy(dirtyRegions, index + 1, dirtyRegions, index, emptyIndex - index - 1);
--emptyIndex;
removed = true;
}
return removed;
}
public void grow(int horizontal, int vertical) {
if (horizontal != 0 || vertical != 0) {
for (int i = 0; i < emptyIndex; i++) {
getDirtyRegion(i).grow(horizontal, vertical);
}
}
}
public void roundOut() {
for (int i = 0; i < emptyIndex; ++i) {
dirtyRegions[i].roundOut();
}
}
@Override
public String toString() {
StringBuilder sb = new StringBuilder();
for (int i = 0; i < emptyIndex; i++) {
sb.append(dirtyRegions[i]);
sb.append('\n');
}
return sb.toString();
}
/***************************************************************************
* Shared for all compressing algorithms
***************************************************************************/
private int[][] heap; // heap used for compressing dirty regions
private int heapSize;
private long invalidMask;
private void heapCompress() {
invalidMask = 0;
int[] map = new int[dirtyRegions.length];
for (int i = 0; i < map.length; ++i) {
map[i] = i;
}
int[] min;
for (int i = 0; i < dirtyRegions.length / 2; ++i) { //compress to 1/2
min = takeMinWithMap(map);
int idx0 = resolveMap(map, min[1]);
int idx1 = resolveMap(map, min[2]);
if (idx0 != idx1) {
dirtyRegions[idx0].deriveWithUnion(dirtyRegions[idx1]);
map[idx1] = idx0;
invalidMask |= 1 << idx0;
invalidMask |= 1 << idx1;
}
}
// move the unused regions to the end
RectBounds tmp;
for (int i = 0; i < emptyIndex; ++i) {
if (map[i] != i) {
while(map[emptyIndex - 1] != emptyIndex - 1 ) --emptyIndex;
if (i < emptyIndex - 1) {
tmp = dirtyRegions[emptyIndex - 1];
dirtyRegions[emptyIndex - 1] = dirtyRegions[i];
dirtyRegions[i] = tmp;
map[i] = i; // indicate that this element is OK
--emptyIndex;
}
}
}
}
private void heapify() {
for (int i = heapSize / 2; i >= 0; --i) {
siftDown(i);
}
}
private void siftDown(int i) {
int end = heapSize >> 1;
int[] temp;
while (i < end) {
int child = (i << 1) + 1;
int[] left = heap[child];
if (child + 1 < heapSize && heap[child + 1][0] < left[0]) {
child = child + 1;
}
if (heap[child][0] >= heap[i][0]) {
break;
}
temp = heap[child];
heap[child] = heap[i];
heap[i] = temp;
i = child;
}
}
private int[] takeMinWithMap(int[] map) {
int[] temp = heap[0];
// Check if the minimum element wasn't computed with some already merged region
// If so, we can recompute it and push it down (as the new merged region can be
// only greater than the original region)
while (((1 << temp[1] | 1 << temp[2]) & invalidMask) > 0) {
temp[0] = unifiedRegionArea(resolveMap(map, temp[1]), resolveMap(map, temp[2]));
siftDown(0);
if (heap[0] == temp) {
break;
}
temp = heap[0];
}
heap[heapSize - 1] = temp;
siftDown(0);
heapSize--;
return temp;
}
private int[] takeMin() {
int[] temp = heap[0];
heap[0] = heap[heapSize - 1];
heap[heapSize - 1] = temp;
siftDown(0);
heapSize--;
return temp;
}
private int resolveMap(int[] map, int idx) {
while(map[idx] != idx) idx = map[idx];
return idx;
}
private int unifiedRegionArea(int i0, int i1) {
RectBounds r0 = dirtyRegions[i0];
RectBounds r1 = dirtyRegions[i1];
float minX, minY, maxX, maxY;
minX = r0.getMinX() < r1.getMinX() ? r0.getMinX() : r1.getMinX();
minY = r0.getMinY() < r1.getMinY() ? r0.getMinY() : r1.getMinY();
maxX = r0.getMaxX() > r1.getMaxX() ? r0.getMaxX() : r1.getMaxX();
maxY = r0.getMaxY() > r1.getMaxY() ? r0.getMaxY() : r1.getMaxY();
return (int) ((maxX - minX) * (maxY - minY));
}
/***************************************************************************
* Heap-based compressing algorithm
***************************************************************************/
private void compress_heap() {
assert dirtyRegions.length == emptyIndex; // call only when there is no space left
if (heap == null) {
int n = dirtyRegions.length;
heap = new int[n * (n-1) / 2][3];
}
heapSize = heap.length;
int k = 0;
for (int i = 0; i < dirtyRegions.length - 1; ++i) {
for (int j = i + 1; j < dirtyRegions.length; ++j) {
heap[k][0] = unifiedRegionArea(i, j);
heap[k][1] = i;
heap[k++][2] = j;
}
}
heapify();
heapCompress();
}
/***************************************************************************
* Simple Monte-Carlo variant of compressing algorithm
***************************************************************************/
// private void compress_mc() {
// assert dirtyRegions.length == emptyIndex; // call only when there is no space left
// heapSize = dirtyRegions.length;
// if (heap == null) {
// heap = new int[heapSize][3];
// }
// for (int i = 0; i < heapSize; ++i) { //number of tries
// int i0 = random(dirtyRegions.length);
// int i1 = random(dirtyRegions.length);
// if (i1 == i0) i1 = (i0 + random(dirtyRegions.length / 2) + 1) % dirtyRegions.length;
// heap[i][0] = unifiedRegionArea(i0, i1);
// heap[i][1] = i0;
// heap[i][2] = i1;
// }
// heapify();
// heapCompress();
// }
//
// private static long rnd = System.currentTimeMillis();
// // XOR Random generator by George Marsaglia http://www.jstatsoft.org/v08/i14/
// // The LCG algorithm of Random() has an upleasant trait that the numbers generated in
// // pairs always have some (tight) mathematical relationship
// private int random(int n) {
// rnd ^= (rnd << 21);
// rnd ^= (rnd >>> 35);
// rnd ^= (rnd << 4);
// return (int) ((rnd) % n + n) % n; // the problem with this algorithm is that 0 is never produced.
// // Given it's independed probability for every bit, we can safely do % n here
// }
}
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