## 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.

## Deformation

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.

## Selection

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.

## Implementation

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;
else
{
// 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.