I have a chess-like grid system and I would like to build an algorithm to get the squares in a given range around a given tile, assuming that the distance should be calculated in a *cross-like* fashion (diagonals count 2).

So, given that the circle is the central point, here is an example image:

I have found this solution (I am using javascript):

```
function findRange(tile, range){
var tiles = [];
for(row = 0; row < rows; row++){
for(col = 0; col < cols; col++){
if( (Math.abs(row - tile.y) + Math.abs(col - tile.x)) <= range )
tiles.push([col,row]);
}
}
return tiles;
}
```

Basically, I loop through all the tiles and then compare the sum of the absolute value difference of the coordinates to my range. I mean, it works (to my surprise); but, for some reason **it doesn't feel right**, it feels a bit **gimmicky** and also is probably less than optimal to loop every single tile: though I am working with small grids and I don't think that looping those is an expensive operation.

On the plus side, the code is really small.

I asked a friend of mine who is into game developing to come out with a solution to this problem and he suggested this (in C++):

```
Node *GetNodeAt(float x, float y)
{
float width = m_nodeSize * m_columns;
float height = m_nodeSize * m_rows;
if( x < 0.0f || y < 0.0f ||
x >= width || y >= height)
return nullptr;
int r = y/m_nodeSize;
int c = x/m_nodeSize;
int target = (m_columns*r + c);
return &m_nodesArray[target];
}
std::list<Node*> GetCrossArea(Node *origin, int range, bool addOriginNode)
{
std::list<Node*> area;
Node *n;
for(int k = range; k >= -range; k--)
{
n = GetNodeAt(origin->GetPosition().x + m_nodeSize * k, origin->GetPosition().y);
if(k == range || k == -range)
area.push_back(n);
else
{
if(n != origin)
area.push_back(n);
else if(addOriginNode)
area.push_back(n);
Node *nVert;
int verticalSteps = (range - abs(k));
for(int q = verticalSteps; q > 0; q--)
{
nVert = GetNodeAt(n->GetPosition().x, n->GetPosition().y + m_nodeSize * verticalSteps);
area.push_back(nVert);
nVert = GetNodeAt(n->GetPosition().x, n->GetPosition().y + (1 - m_nodeSize) * verticalSteps);
area.push_back(nVert);
verticalSteps--;
}
}
}
return area;
}
```

## Questions

Is there a better-known algorithm to solve this problem? If not, which of the proposed solutions is better? Am I missing something completely obvious in my approach?

`nodeList[x][y]`

for convenience. Looping through this would require again a nested loop. Do you suggest to store the node list into a simple one-dimensional array? Do you think it is a big of a drawback can be maintaining the node list into the memory all time (let's say for a 100x100 grid, it is indeed 10000 objects)? – Sunyatasattva Jul 23 '13 at 18:35