Android flood-fill algorithm

Does anyone know a iterative and efficient algorithm for flood-fill?

Or is there any way to implement recursive `floodfill` algorithm without stack overflow error?

Tried the one @ Flood fill using a stack but i cant find a way to work on white and black image.

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Try this question: stackoverflow.com/questions/1257117/… –  Mark Ransom Nov 9 '11 at 19:42

Somebody ported J. Dunlap's Queue-Linear Flood Fill Algorithm to android here. I've tried it and it's pretty fast.

I've modified the `copyImage()` method which originally makes use of a class called Utilities which the author hasn't provided.

``````public class QueueLinearFloodFiller {

protected Bitmap image = null;
protected int[] tolerance = new int[] { 0, 0, 0 };
protected int width = 0;
protected int height = 0;
protected int[] pixels = null;
protected int fillColor = 0;
protected int[] startColor = new int[] { 0, 0, 0 };
protected boolean[] pixelsChecked;
protected Queue<FloodFillRange> ranges;

// Construct using an image and a copy will be made to fill into,
// Construct with BufferedImage and flood fill will write directly to
// provided BufferedImage
public QueueLinearFloodFiller(Bitmap img) {
copyImage(img);
}

public QueueLinearFloodFiller(Bitmap img, int targetColor, int newColor) {
useImage(img);

setFillColor(newColor);
setTargetColor(targetColor);
}

public void setTargetColor(int targetColor) {
startColor[0] = Color.red(targetColor);
startColor[1] = Color.green(targetColor);
startColor[2] = Color.blue(targetColor);
}

public int getFillColor() {
return fillColor;
}

public void setFillColor(int value) {
fillColor = value;
}

public int[] getTolerance() {
}

public void setTolerance(int[] value) {
tolerance = value;
}

public void setTolerance(int value) {
tolerance = new int[] { value, value, value };
}

public Bitmap getImage() {
return image;
}

public void copyImage(Bitmap img) {
// Copy data from provided Image to a BufferedImage to write flood fill
// to, use getImage to retrieve
// cache data in member variables to decrease overhead of property calls
width = img.getWidth();
height = img.getHeight();

image = Bitmap.createBitmap(width, height, Bitmap.Config.RGB_565);
Canvas canvas = new Canvas(image);
canvas.drawBitmap(img, 0, 0, null);

pixels = new int[width * height];

image.getPixels(pixels, 0, width, 1, 1, width - 1, height - 1);
}

public void useImage(Bitmap img) {
// Use a pre-existing provided BufferedImage and write directly to it
// cache data in member variables to decrease overhead of property calls
width = img.getWidth();
height = img.getHeight();
image = img;

pixels = new int[width * height];

image.getPixels(pixels, 0, width, 1, 1, width - 1, height - 1);
}

protected void prepare() {
// Called before starting flood-fill
pixelsChecked = new boolean[pixels.length];
}

// Fills the specified point on the bitmap with the currently selected fill
// color.
// int x, int y: The starting coords for the fill
public void floodFill(int x, int y) {
// Setup
prepare();

if (startColor[0] == 0) {
// ***Get starting color.
int startPixel = pixels[(width * y) + x];
startColor[0] = (startPixel >> 16) & 0xff;
startColor[1] = (startPixel >> 8) & 0xff;
startColor[2] = startPixel & 0xff;
}

// ***Do first call to floodfill.
LinearFill(x, y);

// ***Call floodfill routine while floodfill ranges still exist on the
// queue
FloodFillRange range;

while (ranges.size() > 0) {
// **Get Next Range Off the Queue
range = ranges.remove();

// **Check Above and Below Each Pixel in the Floodfill Range
int downPxIdx = (width * (range.Y + 1)) + range.startX;
int upPxIdx = (width * (range.Y - 1)) + range.startX;
int upY = range.Y - 1;// so we can pass the y coord by ref
int downY = range.Y + 1;

for (int i = range.startX; i <= range.endX; i++) {
// *Start Fill Upwards
// if we're not above the top of the bitmap and the pixel above
// this one is within the color tolerance
if (range.Y > 0 && (!pixelsChecked[upPxIdx])
&& CheckPixel(upPxIdx))
LinearFill(i, upY);

// *Start Fill Downwards
// if we're not below the bottom of the bitmap and the pixel
// below this one is within the color tolerance
if (range.Y < (height - 1) && (!pixelsChecked[downPxIdx])
&& CheckPixel(downPxIdx))
LinearFill(i, downY);

downPxIdx++;
upPxIdx++;
}
}

image.setPixels(pixels, 0, width, 1, 1, width - 1, height - 1);
}

// Finds the furthermost left and right boundaries of the fill area
// on a given y coordinate, starting from a given x coordinate, filling as
// it goes.
// Adds the resulting horizontal range to the queue of floodfill ranges,
// to be processed in the main loop.

// int x, int y: The starting coords
protected void LinearFill(int x, int y) {
// ***Find Left Edge of Color Area
int lFillLoc = x; // the location to check/fill on the left
int pxIdx = (width * y) + x;

while (true) {
// **fill with the color
pixels[pxIdx] = fillColor;

// **indicate that this pixel has already been checked and filled
pixelsChecked[pxIdx] = true;

// **de-increment
lFillLoc--; // de-increment counter
pxIdx--; // de-increment pixel index

// **exit loop if we're at edge of bitmap or color area
if (lFillLoc < 0 || (pixelsChecked[pxIdx]) || !CheckPixel(pxIdx)) {
break;
}
}

lFillLoc++;

// ***Find Right Edge of Color Area
int rFillLoc = x; // the location to check/fill on the left

pxIdx = (width * y) + x;

while (true) {
// **fill with the color
pixels[pxIdx] = fillColor;

// **indicate that this pixel has already been checked and filled
pixelsChecked[pxIdx] = true;

// **increment
rFillLoc++; // increment counter
pxIdx++; // increment pixel index

// **exit loop if we're at edge of bitmap or color area
if (rFillLoc >= width || pixelsChecked[pxIdx] || !CheckPixel(pxIdx)) {
break;
}
}

rFillLoc--;

FloodFillRange r = new FloodFillRange(lFillLoc, rFillLoc, y);

ranges.offer(r);
}

// Sees if a pixel is within the color tolerance range.
protected boolean CheckPixel(int px) {
int red = (pixels[px] >>> 16) & 0xff;
int green = (pixels[px] >>> 8) & 0xff;
int blue = pixels[px] & 0xff;

return (red >= (startColor[0] - tolerance[0])
&& red <= (startColor[0] + tolerance[0])
&& green >= (startColor[1] - tolerance[1])
&& green <= (startColor[1] + tolerance[1])
&& blue >= (startColor[2] - tolerance[2]) && blue <= (startColor[2] + tolerance[2]));
}

// Represents a linear range to be filled and branched from.
protected class FloodFillRange {
public int startX;
public int endX;
public int Y;

public FloodFillRange(int startX, int endX, int y) {
this.startX = startX;
this.endX = endX;
this.Y = y;
}
}
}
``````

You could also use a thread if you don't want the UI to wait for the image to be filled.

``````public class FloodFillThread extends Thread {
ProgressDialog mProgressDialog;
Bitmap mBitmap;
int mTargetColor;
int mNewColor;
Point mPoint;
Runnable mCallback;

public FloodFillThread(ProgressDialog pd, Runnable callback, Bitmap bitmap,
Point pt, int targetColor, int newColor) {
mBitmap = bitmap;
mPoint = pt;
mTargetColor = targetColor;
mNewColor = newColor;
mProgressDialog = pd;
mCallback = callback;
}

@Override
public void run() {
QueueLinearFloodFiller filler = new QueueLinearFloodFiller(mBitmap, mTargetColor, mNewColor);
filler.setTolerance(10);
filler.floodFill(mPoint.x, mPoint.y);

handler.sendEmptyMessage(0);
}

private Handler handler = new Handler() {
@Override
public void handleMessage(Message msg) {
mProgressDialog.dismiss();
mCallback.run();
}
};
}
``````
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thanks,how should i pass `Runnable callBack` to FloodFillThread constructor?I mean how should i use your code from my activity –  Arash Jan 26 at 16:23
it solved.it is so fast.i implemented Runnable in my Activity class and passed `this` to constructor –  Arash Jan 26 at 16:30
Seems QueueLinearFloodFiller has bug - if using it with bitmap already filled in only one color it does not fill entire bitmap. Problem in next lines: image.getPixels(pixels, 0, width, 1, 1, width - 1, height - 1); image.setPixels(pixels, 0, width, 1, 1, width - 1, height - 1); Should be: image.getPixels(pixels, 0, width, 0, 0, width, height); image.setPixels(pixels, 0, width, 0, 0, width, height); –  Steel FedeX Mar 7 at 12:03

this algorithm worked good for me.

``````private void FloodFill(Bitmap bmp, Point pt, int targetColor, int replacementColor)
{
while (q.size() > 0) {
Point n = q.poll();
if (bmp.getPixel(n.x, n.y) != targetColor)
continue;

Point w = n, e = new Point(n.x + 1, n.y);
while ((w.x > 0) && (bmp.getPixel(w.x, w.y) == targetColor)) {
bmp.setPixel(w.x, w.y, replacementColor);
if ((w.y > 0) && (bmp.getPixel(w.x, w.y - 1) == targetColor))
if ((w.y < bmp.getHeight() - 1)
&& (bmp.getPixel(w.x, w.y + 1) == targetColor))
w.x--;
}
while ((e.x < bmp.getWidth() - 1)
&& (bmp.getPixel(e.x, e.y) == targetColor)) {
bmp.setPixel(e.x, e.y, replacementColor);

if ((e.y > 0) && (bmp.getPixel(e.x, e.y - 1) == targetColor))
if ((e.y < bmp.getHeight() - 1)
&& (bmp.getPixel(e.x, e.y + 1) == targetColor))
e.x++;
}
}
}
``````
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but it is consuming lots of memory and make application slow. –  Satyajitsinh Raijada Aug 11 '12 at 7:12
May be, but you cannot run recursive algorithms if the algorithm will work so many times, because you don't have that much memory, so you got to try some iterative ways to solve problems. you should really calculate the time complexity real good to make sure your algorithm will not make your app slower than you guess. But in this case I believe its better to go with iterative rather than recursive, I've tried this algorithm in recursive and it stopped working after 10th step of the for loop. Its very easy to get StackOverflow Error with recursion. thanks for your feedback. –  aBottleOfPills Aug 12 '12 at 14:53

its better that you make `FloodFill()` a method return a `Bitmap` object. make it a method of the custom `View` class. you know the custom `View` class has. `the onDraw(Canvas canvas)` method. in the `onDraw(Canvas c)`, use `FloodFill()` like the following:

``````//resize the picture that you want to fill to fit the whole display.
bitmap=Bitmap.createScaledBitmap(bitmap, canvas.getWidth(),canvas.getHeight(), true);

/*get the same bitmap flood fill it. we reassign the bit map to iself to keep it for the next and another flood fill

currently_selected_point is a variable/object of type Point.
use the Point object to save your onTouchEvent(Event event) finger coordinates.

I used the Color.RED as a replacement color.

the target color is the color of the selected point currently_selected_point.
*/
bitmap=FloodFill(bitmap, currently_selected_point, bitmap.getPixel(currently_selected_point.x, currently_selected_point.y), Color.RED);
canvas.drawBitmap(bitmap,0,0, paint);
``````
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setPixel method called hundreds or thousands times isn't very efficient. It's better to move the algorithm to C++ via JNI. Here is my simple library You can use. It's incredibly much faster than pure java implementation.

https://github.com/mar3kk/threekkapps_library/

just call

``````JniBitmap.floodFill(bitmap,x,y,color);
``````
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I made the algorithm above faster.
Use `getPixels()` and `setPixels()` instead of calling `getPixel()` repeatedly.

But here is a tarde off.
This algorithm uses more memory space for an array `int[bmp.width * bmp.height]`.

``````private void floodFill_array(Bitmap bmp, Point pt, int targetColor, int replacementColor)
{
if(targetColor == replacementColor)
return;

int width, height;
int[] arrPixels;

width = bmp.getWidth();
height = bmp.getHeight();

arrPixels = new int[width*height];
bmp.getPixels(arrPixels, 0, width, 0, 0, width, height);

while (q.size() > 0) {
Point n = q.poll();
if (arrPixels[width*n.y + n.x] != targetColor)
continue;

Point w = n, e = new Point(n.x + 1, n.y);
while ((w.x > 0) && (arrPixels[width*w.y + w.x] == targetColor)) {

arrPixels[width*w.y + w.x] = replacementColor;  // setPixel

if ((w.y > 0) && (arrPixels[width*(w.y-1) + w.x] == targetColor))
if ((w.y < height - 1)
&& (arrPixels[width*(w.y+1) + w.x] == targetColor))
w.x--;
}

while ((e.x < width - 1)
&& (arrPixels[width*e.y + e.x] == targetColor)) {

arrPixels[width*e.y + e.x] = replacementColor;  // setPixel

if ((e.y > 0) && (arrPixels[width*(e.y-1) + e.x] == targetColor))
if ((e.y < height - 1)
&& (arrPixels[width*(e.y+1) + e.x] == targetColor))
e.x++;
}
}

bmp.setPixels(arrPixels, 0, width, 0, 0, width, height);
}
``````

If you want to use the "Tolerance" option, use this code below.

``````int minR, maxR, minG, maxG, minB, maxB;  // instance values

private void floodFill_array(Bitmap bmp, Point pt, int targetColor, int replacementColor, int tolerance)
{
if(targetColor == replacementColor)
return;

/* tolerable values */
minR = ((targetColor & 0xFF0000) >> 16) - tolerance;
if(minR < 0) minR = 0;
else minR = minR << 16;
maxR = ((targetColor & 0xFF0000) >> 16) + tolerance;
if(maxR > 0xFF) maxR = 0xFF0000;
else maxR = maxR << 16;

minG = ((targetColor & 0x00FF00) >> 8) - tolerance;
if(minG < 0) minG = 0;
else minG = minG << 8;
maxG = ((targetColor & 0x00FF00) >> 8) + tolerance;
if(maxG > 0xFF) maxG = 0x00FF00;
else maxG = maxG << 8;

minB = (targetColor & 0x0000FF) - tolerance;
if(minB < 0) minB = 0;
maxB = (targetColor & 0x0000FF) + tolerance;
if(maxB > 0xFF) maxB = 0x0000FF;
/* tolerable values */

int width, height;
int[] arrPixels;

width = bmp.getWidth();
height = bmp.getHeight();

arrPixels = new int[width*height];
bmp.getPixels(arrPixels, 0, width, 0, 0, width, height);

while (q.size() > 0) {

Point n = q.poll();

if(!isTolerable(arrPixels[width*n.y + n.x]))
continue;

Point w = n, e = new Point(n.x + 1, n.y);
while ((w.x > 0) && isTolerable(arrPixels[width*w.y + w.x])) {
arrPixels[width*w.y + w.x] = replacementColor;  // setPixel

if ((w.y > 0) && isTolerable(arrPixels[width*(w.y-1) + w.x]))

if ((w.y < height - 1) && isTolerable(arrPixels[width*(w.y+1) + w.x]))

w.x--;
}

while ((e.x < width - 1) && isTolerable(arrPixels[width*e.y + e.x])) {
arrPixels[width*e.y + e.x] = replacementColor;  // setPixel

if ((e.y > 0) && isTolerable(arrPixels[width*(e.y-1) + e.x]))

if ((e.y < height - 1) && isTolerable(arrPixels[width*(e.y+1) + e.x]))

e.x++;
}
}

bmp.setPixels(arrPixels, 0, width, 0, 0, width, height);
}

/**
* If the passed color is tolerable, return true.
*/
private boolean isTolerable(int currentColor){
int r = currentColor & 0xFF0000;
int g = currentColor & 0x00FF00;
int b = currentColor & 0x0000FF;

if(r<minR || r>maxR || g<minG || g>maxG || b<minB || b>maxB)
return false;   // less than or grater than tolerable values
else
return true;
}
``````
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