# Hexagonal Grids, how do you find which hexagon a point is in?

I have a map made up of rows and columns of hexagons

This isn't an actual image of the hex-map I am using, but uses the same size and shape hexagons

I need to be able to tell which one the mouse is over when the user clicks,

Each Hexagon is represented by an instance of a "Tile" class, however this doesn't hold any location specific data, or even a polygon, they are drawn using the following code

``````for (int i = 0; i < region.numX; i++)
for (int j = 0; j < region.numY; j++)
{
Tile t = region.tiles[i][j];

int centerX = 0;
int centerY = 0;

if (i % 2 == 0)
{
centerX = j * 40;
centerY = i * 30;
}
else
{
centerX = j * 40;
centerY = i * 30;
}

g.drawImage(images.tiles[t.info[COLOUR_ID]], centerX, centerY, renderer);
}
``````

So basically the only way to tell where a particular hexagon is, is to know it's position in the 2D array.

I have used a square grid before, and it was relatively easy to figure out which square was selected, because pixels are also square,

``````        // example where each square is 10 by 10 pixels:

private void getClickedSquare(MouseEvent me)
{
int mouseX = me.getX();// e.g. 25
int mouseY = me.getY();// e.g. 70

int tileX = (int) (mouseX / 10);// in this case 2
int tileY = (int) (mouseY / 10);// in this case 7

//then to access the tile I would do

map.squares[squareX][squareY].whatever();
}
``````

But I'm not even sure where to start with Hexagons, does anyone have any experience?

I cannot use polygons (Java), as when I get onto moving the map around on screen, and increasing it's size I'll run into problems with updating vast amounts of polygons each frame. Although then I could just check to see if a point is included in any of the map's tile's polygons!

At the moment the hexagons displayed are just BufferedImages.

-

(UPDATED: Refactored code to make more understandable and more efficient) (UPDATED: Reduced answer length, fixed bugs in code, improved quality of images)

This image shows the top left corner of a hexagonal grid and overlaid is a blue square grid. It is easy to find which of the squares a point is inside and this would give a rough approximation of which hexagon too. The white portions of the hexagons show where the square and hexagonal grid share the same coordinates and the grey portions of the hexagons show where they do not.

The solution is now as simple as finding which box a point is in, then checking to see if the point is in either of the triangles, and correcting the answer if necessary.

``````private final Hexagon getSelectedHexagon(int x, int y)
{
// Find the row and column of the box that the point falls in.
int row = (int) (y / gridHeight);
int column;

boolean rowIsOdd = row % 2 == 1;

// Is the row an odd number?
if (rowIsOdd)// Yes: Offset x to match the indent of the row
column = (int) ((x - halfWidth) / gridWidth);
else// No: Calculate normally
column = (int) (x / gridWidth);
``````

At this point we have the row and column of the box our point is in, next we need to test our point against the two top edges of the hexagon to see if our point lies in either of the hexagons above:

``````    // Work out the position of the point relative to the box it is in
double relY = y - (row * gridHeight);
double relX;

if (rowIsOdd)
relX = (x - (column * gridWidth)) - halfWidth;
else
relX = x - (column * gridWidth);
``````

Having relative coordinates makes the next step easier.

Like in the image above, if the y of our point is > mx + c we know our point lies above the line, and in our case, the hexagon above and to the left of the current row and column. Note that the coordinate system in java has y starting at 0 in the top left of the screen and not the bottom left as is usual in mathematics, hence the negative gradient used for the left edge and the positive gradient used for the right.

``````    // Work out if the point is above either of the hexagon's top edges
if (relY < (-m * relX) + c) // LEFT edge
{
row--;
if (!rowIsOdd)
column--;
}
else if (relY < (m * relX) - c) // RIGHT edge
{
row--;
if (rowIsOdd)
column++;
}

return hexagons[column][row];
}
``````

A quick explanation of the variables used in the above example:

m is the gradient, so m = c / halfWidth

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I can't even explain how much time this post just saved me in head scratching. I seriously can't thank you enough for this. –  Steve Gattuso Apr 12 '12 at 16:54
No problem :) if you need any help with anything else check out my blog, my email is there and some open source projects on my github, which are only going to increase in number :) troygamedev.blogspot.co.uk –  Sebastian Troy Apr 13 '12 at 10:29

EDIT: this question is more difficult than I thought at first, I will rewrite my answer with some working, however I'm not sure whether the solution path is any improvement on the other answers.

The question could be rephrased: given any x,y find the hexagon whose centre is closest to x,y

i.e. minimise dist_squared( Hex[n].center, (x,y) ) over n (squared means you don't need to worry about square roots which saves some CPU)

However, first we should narrow down the number of hexagons to check against -- we can narrow it down to a maximum of 5 by the following method:

So, first step is Express your point (x,y) in UV-space i.e. (x,y) = lambda*U + mu*V, so = (lambda, mu) in UV-space

That's just a 2D matrix transform (http://playtechs.blogspot.co.uk/2007/04/hex-grids.html might be helpful if you don't understand linear transforms).

Now given a point (lambda, mu), if we round both to the nearest integer then we have this:

Everywhere within the Green Square maps back to (2,1)

So most points within that Green Square will be correct, i.e. They are in hexagon (2,1).

But some points should be returning hexagon # (2,2), i.e:

Similarly some should be returning hexagon # (3,1). And then on the opposite corner of that green parallelogram, there will be 2 further regions.

So to summarise, if int(lambda,mu) = (p,q) then we are probably inside hexagon (p,q) but we could also be inside hexagons (p+1,q), (p,q+1), (p-1,q) or (p,q-1)

Several ways to determine which of these is the case. The easiest would be to convert the centres of all of these 5 hexagons back into the original coordinate system, and find which is closest to our point.

But it turns out you can narrow that down to ~50% of the time doing no distance checks, ~25% of the time doing one distance check, and the remaining ~25% of the time doing 2 distance checks (I'm guessing the numbers by looking at the areas each check works on):

``````p,q = int(lambda,mu)

if lambda * mu < 0.0:
// opposite signs, so we are guaranteed to be inside hexagon (p,q)
// look at the picture to understand why; we will be in the green regions
outPQ = p,q
``````

``````else:
// circle check
distSquared = dist2( Hex2Rect(p,q), Hex2Rect(lambda, mu) )

if distSquared < .5^2:
// inside circle, so guaranteed inside hexagon (p,q)
outPQ = p,q
``````

``````    else:
if lambda > 0.0:
candHex = (lambda>mu) ? (p+1,q): (p,q+1)
else:
candHex = (lambda<mu) ? (p-1,q) : (p,q-1)
``````

And that last test can be tidied up:

``````     else:
// same sign, but which end of the parallelogram are we?
sign = (lambda<0) ? -1 : +1
candHex = ( abs(lambda) > abs(mu) ) ? (p+sign,q) : (p,q+sign)
``````

Now we have narrowed it down to one other possible hexagon, we just need to find which is closer:

``````        dist2_cand = dist2( Hex2Rect(lambda, mu), Hex2Rect(candHex) )

outPQ = ( distSquared < dist2_cand ) ? (p,q) : candHex
``````

A Dist2_hexSpace(A,B) function would tidy things up further.

-
Aren't Cos and Sin calculations fairly hefty? –  Sebastian Troy Apr 30 at 14:00
You can precalculate them, as you know it is 60°. If I remember correctly (cos60,sin60) is (1/2, root(3)/2) –  P i Apr 30 at 21:43
Sounds like a perfectly valid solution, however I'm not sure it would be any faster than the method above, do you reckon you could provide some pseudo code? –  Sebastian Troy May 1 at 12:52
I changed my answer and put some pictures in. –  P i May 1 at 14:56
It will still work with 'flattened' hexagons. U and V will just be different. I still feel like there is some really simple clever way to do it that we're missing... somehow using the three-way symmetry of the isometric grid, maybe getting 3 solution sets and finding the intersection. But I can't quite see it. –  P i May 1 at 20:37

I've had another look at http://playtechs.blogspot.co.uk/2007/04/hex-grids.html and it is very tidy mathematically.

However Sebastian's approach does seem to cut to the chase, and accomplish the task in remarkably few lines of code.

If you read through the comments section you can find that someone has written a Python implementation at http://gist.github.com/583180

I will repaste that here for posterity:

``````# copyright 2010 Eric Gradman
# free to use for any purpose, with or without attribution
# from an algorithm by James McNeill at
# http://playtechs.blogspot.com/2007/04/hex-grids.html

# the center of hex (0,0) is located at cartesian coordinates (0,0)

import numpy as np

# R ~ center of hex to edge
# S ~ edge length, also center to vertex
# T ~ "height of triangle"

real_R = 75. # in my application, a hex is 2*75 pixels wide
R = 2.
S = 2.*R/np.sqrt(3.)
T = S/2.
SCALE = real_R/R

# XM*X = I
# XM = Xinv
X = np.array([
[ 0, R],
[-S, S/2.]
])
XM = np.array([
[1./(2.*R),  -1./S],
[1./R,        0.  ]
])
# YM*Y = I
# YM = Yinv
Y = np.array([
[R,    -R],
[S/2.,  S/2.]
])
YM = np.array([
[ 1./(2.*R), 1./S],
[-1./(2.*R), 1./S],
])

def cartesian2hex(cp):
"""convert cartesian point cp to hex coord hp"""
cp = np.multiply(cp, 1./SCALE)
Mi = np.floor(np.dot(XM, cp))
xi, yi = Mi
i = np.floor((xi+yi+2.)/3.)

Mj = np.floor(np.dot(YM, cp))
xj, yj = Mj
j = np.floor((xj+yj+2.)/3.)

hp = i,j
return hp

def hex2cartesian(hp):
"""convert hex center coordinate hp to cartesian centerpoint cp"""
i,j = hp
cp = np.array([
i*(2*R) + j*R,
j*(S+T)
])
cp = np.multiply(cp, SCALE)

return cp
``````
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you can take a look at https://code.google.com/p/jhexed/ it has methods to get cell for a point coordinates

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The code isn't amazingly commented but a cursory search suggests that it iterates through each individual hexagon and then does six checks to see if the point lies within that hexagon, hardly an efficient way to do it... –  Sebastian Troy Jul 22 at 18:37