# Finding colors in images: can Nearest do it?

I'm trying to find a way to look for colors in images. Here's a simplified example:

``````tree = ExampleData[{"TestImage", "Tree"}]
``````

I can see there's blue in there, so I want an xy location somewhere in that sea of pixels. Say I'm looking for a particular shade of blue, which I can supply some approximate RGB values for:

``````Manipulate[Graphics[{RGBColor[r, g, b], Disk[]}], {r, 0, 1}, {g, 0, 1}, {b, 0, 1}]
``````

and now I want to find the coordinates of some pixels which have that value, or near enough. `Nearest` might be able to do it:

``````Nearest[ImageData[tree], {0.32, 0.65, .8}]
``````

but doesn't - it 'generates a very large output'...

It's the reverse of doing this:

``````ImageValue[tree, {90, 90}]
``````

which is OK if I've got the numbers already, or can click on the image. Once the location of the colors I want is known, I can then supply this to functions that require 'markers' - such as `RegionBinarize`.

I feel there must be a Mathematica function for this, but can't find it yet...

-

Does this

``````Position[#, First@Nearest[Flatten[#, 1], {0.32, 0.65, .8}]] &@
ImageData[tree]
(*
{{162, 74}}
*)
``````

do what you want?

OK, try this:

``````tree = ExampleData[{"TestImage", "Tree"}];

dat = Reverse[ImageData[tree]\[Transpose], {2}];

dim = Dimensions[dat][[{1, 2}]];

nearfunc = Nearest[Join @@ dat -> Tuples @ Range @ dim];

Manipulate[
rgb = Extract[dat, Ceiling[p]];
posns = nearfunc[rgb, num];
Graphics[{
Raster[dat\[Transpose]], Red, Point[posns]
}],
{{p, {10, 10}}, Locator},
{{num, 20}, 1, 100, 1}
]
``````

this lets you click somewhere on the image, determines a number of points that are closest (according to the default norm) to the colour of that point, and displays them. `num` is the number of points to be shown.

It looks like this:

-
@corm You can do `ImageData[tree]//Shallow` to see the structure of the data `ImageData` produces. You see it is a list of lists of lists(basically, a matrix, each element of which is a vector). This is why `Position` returns both the `x` and `y` coordinates, and this is why you need to flatten the list. – acl Dec 18 '11 at 21:04
@acl I think all the red points are somehow rotated 90 degrees counterclockwise relative to the points they're referring to - at least, that's something I noticed on a simpler image – cormullion Dec 19 '11 at 11:24
The rotation is due to the fact that the pixel at position `{a, b}` in `Show[tree]` corresponds to `ImageData[tree][[H-b,a]]` where `H` is the height of the image, i.e. `H=ImageDimensions[tree][[1]]`. The easiest way around this is to redefine `dat = Transpose[Reverse[ImageData[tree]]];` which basically rotates the image data matrix 90 degrees. – Heike Dec 19 '11 at 13:16
BTW, if you define `nearfunc` as something like `nearfunc = Nearest[Flatten[dat, 1] -> Flatten[Table[{i, j}, {i, dim[[1]]}, {j, dim[[2]]}], 1]];`, it will return a list of coordinates instead of rgb values so you don't need to use `Position` to extract the coordinates making the code a bit faster. – Heike Dec 19 '11 at 13:43
@Mr.W but there's no way I'd have written this code! But ok, if you want to slog away for my benefit, have at it :) [the tuples bit is clever] – acl Dec 19 '11 at 16:07

There are a few problems with what you are trying to do.

1. You want a position coordinate, not the nearest value itself

2. `Nearest` may return a lot of values rather than just one (use the third argument to specify)

3. `Nearest` wants a list of values to search, not a table

You probably want something like this:

``````Nearest[Join @@ ImageData@tree, {0.32, 0.65, .8}, 1]
Position[ImageData@tree, #] & /@ %
``````
`{{0.321569, 0.65098, 0.8}}`
`{{{162, 74}}}`

Don't miss the chance to build a NearestFunction for efficiency, if you are going to be using this dynamically. Here is a more complete example:

``````tree = ExampleData[{"TestImage", "Tree"}]

findcolor[img_Image] :=
DynamicModule[
{dat, nearfunc},
dat = ImageData@img;
nearfunc = Nearest[Join @@ dat];
Manipulate[
Column[{
Graphics[{RGBColor[r, g, b], Disk[]}],
Position[dat, nearfunc[{r, g, b}, 1][[1]]]
}],
{{r, 0.5}, 0, 1}, {{g, 0.5}, 0, 1}, {{b, 0.5}, 0, 1}
]
]

findcolor[tree]
``````

-
so, are you planning to make this interactive, so that you select the colour and see the 100 points nearest to that colour superposed on the image? – acl Dec 18 '11 at 19:16
@Mr.Wizard Yes, you see my problems well, and particularly number 3. - how to use ImageData correctly in functions. As you say, I probably don't know the difference between lists and tables. (I thought they were the same thing... :) Your solution is great! Thanks. – cormullion Dec 18 '11 at 20:26

Not exactly an answer to the question, but you might find ideas in this one too:

``````image = ExampleData[{"TestImage", "Tree"}];
red = Image@ConstantArray[List @@ Red, ImageDimensions[image]];

threshold = 0.15;
p = ImageDimensions[image]/2;
Row[
{VerticalSlider[Dynamic[threshold]],
LocatorPane[
Dynamic[p],
Dynamic[
colour =
Extract[ImageData[image],
Ceiling[p] /. {x_, y_} :> {ImageDimensions[image][[2]] - y, x} /.
0 -> 1];
Binarize[ImageApply[Abs[# - colour] &, image], threshold];
Image[
ImageCompose[image, {SetAlphaChannel[red, mask], 0.5}],
Magnification -> 1
]
]
],
Dynamic@
Graphics[{}, Background -> RGBColor @@ colour,
ImageSize -> ImageDimensions[image]]
}
]
``````

-
That's really good! And the big colour swatch is a bonus. Thanks. – cormullion Dec 20 '11 at 15:24
@cormullion With a bit of extra work, you can make the swatch into a `ColorSetter[]`, but I didn't want to complicate things (we'd have to make sure that the locator thing doesn't immediately overwrite the colour value when it's set from the `ColorSetter`, and we need to handle `{r,g,b}`, and `RGBColor[r,g,b]` formats separate, without slowing the whole thing down too much. It's already pretty slow as is, it could be made faster) – Szabolcs Dec 20 '11 at 15:37
very cool! amazing what you can do with a little code – acl Dec 20 '11 at 18:18
@szabolcs It's quick and smooth on my iMac - at least on the 'tree' image! – cormullion Dec 20 '11 at 20:40