# How does the fill operation work in paint applications?

All paint programs, independent of how simple or complex they are, come with a fill tool. This basically replaces the color of a closed region with another color. I know that there are different APIs to do this, but I am interested in the algorithm. What would be an efficient algorithm to implement this tool?

A couple of things I can think of quickly are:

1. Convert image into a binary map, where pixels in the color to be replaced are `1` and all other colors are `0`.
2. Find a closed region around the point you want to change such that all the pixels inside are 1 and all the neighbouring pixels are 0.

Sample Image

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@dbr: "neighbouring"? You Brits speak our language funny. :-) Much better title, though! –  Adam Liss Nov 8 '08 at 4:12

Many implementations are done as a recursive conquer and divide algorithm. If you do a quick google for "flood fill algorithm" you will find plenty of resources including the excellent wikipedia page on the topic.

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Gosh, the animations are awesome! I recall when I could watch the algorithm in Deluxe Paint on my Amiga 500. –  akuhn Nov 10 '08 at 10:16

The Flood Fill algorithm is what's most commonly used. The following is a naive version of it straight out of my old university textbook, "Computer Graphics with OpenGL" by Hearn Baker, 3rd ed:

``````void floodFill4 (int x, int y, int fillColor, int interiorColor)
{
int color;

/* Set current color to fillColor, then perform the following operations */
getPixel(x, y, color);
if (color == interiorColor)
{
setPixel(x,y);  // Set color of pixel to fillColor.
floodFill4(x + 1, y, fillColor, interiorColor);
floodFill4(x - 1, y, fillColor, interiorColor);
floodFill4(x, y + 1, fillColor, interiorColor);
floodFill4(x, y - 1, fillColor, interiorColor);
}
}
``````

For large images, however, the above will probably give you a stack-overflow error due to recursing for every pixel. Often, this algorithm is modified so that it uses iteration when filling a row of pixels, then recursively fills the rows above and below. As @kasperjj stated, wikipedia has a good article about this.

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Upmodded for mention of stack overflow in context...! –  Justin Bozonier Nov 8 '08 at 4:23

These kinds of algorithms are discussed in detail in Computer Graphics: Principles and Practice. I highly recommend this book if you're interested in understanding how to rasterize lines, fill polygons, writing 3d code without the benefit of using DirectX or OpenGL APIs. Of course, for real world applications, you'll probably want to use existing libraries, but if you're curious about how these libraries work, this is an awesome read.

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The book I quoted, "Computer Graphics with OpenGL" is also an excellent one for delving deeply into the theory behind 2d and 3d rendering and is very well written. It only uses OpenGL to show how some of the algorithms and equations are applied. It's quite intensive on the mathematics though. –  Cybis Nov 8 '08 at 6:26
Good to know, thanks! –  Mitch Haile Nov 9 '08 at 14:40

If you want a time efficient algorithm that doesn't care very about memory efficiency, you can do it by:

1) keeping a boolean memory of which cells you have already visited: `Vis[]`

2) keeping a list of points you have already visited but have not yet marked the neighbours for: `Busy[]`

3) start both of those as empty

4) add your start point to `Busy`

5)

``````while you have a point P in Busy:
{
for each neighbour N of the point P for which Vis[N] is still false
{
if appropriate (not crossing the boundary of the fill region)
{
set Vis[N] to true
update the colour of N in the bitmap
add N to the end of Busy[]
}
remove P from Busy[]
}
}
``````
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Also read about connected component labelling. This is an efficent way to find connected pixels whilst only visiting every pixel twice.

Wikipedia article.

The advantage to this is that the pixel values don't have to necessarily be the same or the function that describes pixels as connected could be something other than raw value - gradient perhaps.

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