## Euclidean distance

You can compute the euclidean distance by using the normal formula applied to the computed locations.

Suppose we start with locations a0,b0 and a1,b1.

The x position is given by b*w where w is a constant that depends on the size of the hexagons.

The y position is given by (a+b/2)*h. So the complete formula is:

```
x0 = b0*w
x1 = b1*w
y0 = (a0+b0/2)*h
y1 = (a1+b1/2)*h
dist = sqrt( (x1-x0)^2 + (y1-y0)^2 )
```

h is the height of a hexagon

w is the horizontal distance between columns of hexagons

w can also be computed as a function of h as:

```
w=sqrt(3)*h/2
```

## Hexagon distance

Suppose you can move from a hexagon to an adjoining hexagon.

You can compute a count of the number of moves to go from one hexagon to another by:

```
x0 = a0-floor(b0/2)
y0 = b0
x1 = a1-floor(b1/2)
y1 = b1
dx = x1 - x0
dy = y1 - y0
dist = max(abs(dx), abs(dy), abs(dx+dy))
```