I'm developing a simple 2D board game using hexagonal tile maps, I've read several articles (including the gamedev one's, which are linked every time there's a question on hexagonal tiles) on how to draw hexes on the screen and how to manage the movement (though much of it I had already done before). My main problem is finding the adjacent tiles based on a given radius.

This is how my map system works:

(0,0) (0,1) (0,2) (0,3) (0,4)
   (1,0) (1,1) (1,2) (1,3) (1,4)
(2,0) (2,1) (2,2) (2,3) (2,4)
   (3,0) (3,1) (3,2) (3,3) (3,4)


What I'm struggling with is the fact that I cant just 'select' the adjacent tiles by using for(x-range;x+range;x++); for(y-range;y+range;y++); because it selects unwanted tiles (in the example I gave, selecting the (1,1) tile and giving a range of 1 would also give me the (3,0) tile (the ones I actually need being (0,1)(0,2)(1,0)(1,2)(2,1)(2,2) ), which is kinda adjacent to the tile (because of the way the array is structured) but it's not really what I want to select. I could just brute force it, but that wouldn't be beautiful and would probably not cover every aspect of 'selecting radius thing'.

Can someone point me in the right direction here?

  • 3
    somebody posted a duplicate (copy paste) question of this. Since this is the original question, I am posting my answer here as well. See below.
    – Ed Barbu
    Commented Mar 20, 2013 at 13:09

2 Answers 2


hexagonal and orthogonal grids

What is a hexagonal grid?

What you can see above are the two grids. It's all in the way you number your tiles and the way you understand what a hexagonal grid is. The way I see it, a hexagonal grid is nothing more than a deformed orthogonal one.

The two hex tiles I've circled in purple are theoretically still adjacent to 0,0. However, due to the deformation we've gone through to obtain the hex-tile grid from the orthogonal one, the two are no longer visually adjacent.


What we need to understand is the deformation happened in a certain direction, along a [(-1,1) (1,-1)] imaginary line in my example. To be more precise, it is as if the grid has been elongated along that line, and squashed along a line perpendicular to that. So naturally, the two tiles on that line got spread out and are no longer visually adjacent. Conversely, the tiles (1, 1) and (-1, -1) which were diagonal to (0, 0) are now unusually close to (0, 0), so close in fact that they are now visually adjacent to (0, 0). Mathematically however, they are still diagonals and it helps to treat them that way in your code.


The image I show illustrates a radius of 1. For a radius of two, you'll notice (2, -2) and (-2, 2) are the tiles that should not be included in the selection. And so on. So, for any selection of radius r, the points (r, -r) and (-r, r) should not be selected. Other than that, your selection algorithm should be the same as a square-tiled grid.

Just make sure you have your axis set up properly on the hexagonal grid, and that you are numbering your tiles accordingly.


Let's expand on this for a bit. We now know that movement along any direction in the grid costs us 1. And movement along the stretched direction costs us 2. See (0, 0) to (-1, 1) for example.

Knowing this, we can compute the shortest distance between any two tiles on such a grid, by decomposing the distance into two components: a diagonal movement and a straight movement along one of the axis. For example, for the distance between (1, 1) and (-2, 5) on a normal grid we have:

Normal distance = (1, 1) - (-2, 5) = (3, -4)

That would be the distance vector between the two tiles were they on a square grid. However we need to compensate for the grid deformation so we decompose like this:

(3, -4) = (3, -3) + (0, -1)

As you can see, we've decomposed the vector into one diagonal one (3, -3) and one straight along an axis (0, -1).

We now check to see if the diagonal one is along the deformation axis which is any point (n, -n) where n is an integer that can be either positive or negative. (3, -3) does indeed satisfy that condition, so this diagonal vector is along the deformation. This means that the length (or cost) of this vector instead of being 3, it will be double, that is 6.

So to recap. The distance between (1, 1) and (-2, 5) is the length of (3, -3) plus the length of (0, -1). That is distance = 3 * 2 + 1 = 7.

Implementation in C++

Below is the implementation in C++ of the algorithm I have explained above:

int ComputeDistanceHexGrid(const Point & A, const Point & B)
  // compute distance as we would on a normal grid
  Point distance;
  distance.x = A.x - B.x;
  distance.y = A.y - B.y;

  // compensate for grid deformation
  // grid is stretched along (-n, n) line so points along that line have
  // a distance of 2 between them instead of 1

  // to calculate the shortest path, we decompose it into one diagonal movement(shortcut)
  // and one straight movement along an axis
  Point diagonalMovement;
  int lesserCoord = abs(distance.x) < abs(distance.y) ? abs(distance.x) : abs(distance.y);
  diagonalMovement.x = (distance.x < 0) ? -lesserCoord : lesserCoord; // keep the sign 
  diagonalMovement.y = (distance.y < 0) ? -lesserCoord : lesserCoord; // keep the sign

  Point straightMovement;

  // one of x or y should always be 0 because we are calculating a straight
  // line along one of the axis
  straightMovement.x = distance.x - diagonalMovement.x;
  straightMovement.y = distance.y - diagonalMovement.y;

  // calculate distance
  size_t straightDistance = abs(straightMovement.x) + abs(straightMovement.y);
  size_t diagonalDistance = abs(diagonalMovement.x);

  // if we are traveling diagonally along the stretch deformation we double
  // the diagonal distance
  if ( (diagonalMovement.x < 0 && diagonalMovement.y > 0) || 
       (diagonalMovement.x > 0 && diagonalMovement.y < 0) )
    diagonalDistance *= 2;

  return straightDistance + diagonalDistance;

Now, given the above implemented ComputeDistanceHexGrid function, you can now have a naive, unoptimized implementation of a selection algorithm that will ignore any tiles further than the specified selection range:

int _tmain(int argc, _TCHAR* argv[])
  // your radius selection now becomes your usual orthogonal algorithm
  // except you eliminate hex tiles too far away from your selection center
  // for(x-range;x+range;x++); for(y-range;y+range;y++);
  Point selectionCenter = {1, 1};
  int range = 1;

  for ( int x = selectionCenter.x - range;
            x <= selectionCenter.x + range;
            ++x )
    for ( int y = selectionCenter.y - range;
              y <= selectionCenter.y + range;
              ++y )
      Point p = {x, y};
      if ( ComputeDistanceHexGrid(selectionCenter, p) <= range )
        cout << "(" << x << ", " << y << ")" << endl;
        // do nothing, skip this tile since it is out of selection range

    return 0;

For a selection point (1, 1) and a range of 1, the above code will display the expected result:

(0, 0)
(0, 1)
(1, 0)
(1, 1)
(1, 2)
(2, 1)
(2, 2)

Possible optimization

For optimizing this, you can include the logic of knowing how far a tile is from the selection point (logic found in ComputeDistanceHexGrid) directly into your selection loop, so you can iterate the grid in a way that avoids out of range tiles altogether.

  • Very nice drawing and a very long and thorough answer. Probably comes from having solved the problem yourself before. Commented Jun 17, 2014 at 12:46
  • Indeed, I had to deal with it myself before. Thanks.
    – Ed Barbu
    Commented Jun 17, 2014 at 12:47

Simplest method i can think of...

minX = x-range; maxX = x+range
select (minX,y) to (maxX, y), excluding (x,y) if that's what you want to do
for each i from 1 to range:
    if y+i is odd then maxX -= 1, otherwise minX += 1
    select (minX, y+i) to (maxX, y+i)
    select (minX, y-i) to (maxX, y-i)

It may be a little off; i just worked it through in my head. But at the very least, it's an idea of what you need to do.

In C'ish:

void select(int x, int y) {
    /* todo: implement this */
    /* should ignore coordinates that are out of bounds */

void selectRange(int x, int y, int range) {
    int minX = x - range, maxX = x + range;
    for (int i = minX; i <= maxX; ++i) {
        if (i != x) select(i, y);
    for (int yOff = 1; yOff <= range; ++yOff) {
        if ((y+yOff) % 2 == 1) --maxX; else ++minX;
        for (int i=minX; i<=maxX; ++i) {
            select(i, y+yOff);
            select(i, y-yOff);
  • It's working exactly as I needed, I really appreciate your help and thanks for you time :)
    – Luke B.
    Commented Jan 3, 2011 at 16:17
  • Excellent method, thank you! For anyone else who finds this, I had to turn y+yOff % 2 into (y+yOff) % 2 for it to properly work in C#, but otherwise it's great!
    – Nerrolken
    Commented Aug 6, 2021 at 6:21
  • 1
    @Nerrolken: Oops...yeah, that was supposed to be (y+yOff) % 2. Thanks for letting me know!
    – cHao
    Commented Aug 6, 2021 at 19:19
  • @cHao Happy to help! :) And one more refinement: if you make it Mathf.Abs(y+yOff) % 2, it'll work for negative grid spaces as well. That might just be a C# thing, though, since I've heard different languages implement modulo a little differently.
    – Nerrolken
    Commented Aug 11, 2021 at 8:01

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