If the simplification to integer grid coordinates is ok (as your remark on "nearly equal distance" suggests), you can do go through the cells ring-wise with increasing distance with the code below. If you have a starting point different from (0,0) you just need to add that to each generated point. The key ideas are:

- starting from
`(d,0)`

we iteratively look for a neighbouring point with a "similar" distance (integer part = `d`

) in counter-clockwise direction around `(0,0)`

until we reach the starting point.
- each point will have (except for the neighbour we came from) at most one direct neighbouhr (via edge) with "similar" distance. If there is no direct neighbour then there is exactly one diagonal neigbour with "similar" distance (again except for the previous neighbour).
- the vector to the next neighbour is "almost" orthogonal to the vector to the origin.

Here is the code:

```
#include <cmath>
#include <vector>
template <typename T> int sgn(T val) {
return (T(0) < val) - (val < T(0));
}
int dist(double dx, double dy)
{
return (int)sqrt(dx*dx + dy*dy);
}
typedef std::pair<int,int> TPoint;
typedef std::vector<TPoint> TPoints;
void generateNeighbourRing(int d, TPoints& ring)
{
int dx = d;
int dy = 0;
do
{
ring.push_back(TPoint(dx,dy));
int nx = -sgn(dy);
int ny = sgn(dx);
if (nx != 0 && dist(dx+nx, dy) == d)
dx += nx;
else if (ny != 0 && dist(dx, dy+ny) == d)
dy += ny;
else
{
dx += nx;
dy += ny;
}
} while (dx != d || dy != 0);
}
int main()
{
TPoints points;
const int d_max = 4;
for (int d = 0; d <= d_max; ++d)
generateNeighbourRing(d, points);
printf("spiral for dmax=%d (%d points):\n", d_max, points.size());
for (unsigned int i=0; i<points.size(); ++i)
printf(" (%d,%d),", points[i].first, points[i].second);
printf("\n");
}
```

**Plausibility of correctness:**

Let us look at images first where cells with equal distances to the center cell have the same color (once the distance is truncated, once the distance is rounded):

-- -- -- -- -- --

With `(dx,dy)`

we iterate over the cells of a ring with equal distance; `(nx,ny)`

is a kind of normal vector, which is constant along each half-axis and within each quadrant:

The black arrows show `(nx,ny)`

for each region; the blue arrows show the directions into which a (direct) neighbour with equal distance is searched for first.

Next we need to consider which configurations of neighbours with equal distance are possible. Since the quadrants are rotationally symmetric it suffices to look at the first quadrant. The distance to the center cell between two direct neighbours can differ by at most 1; diagonally towards or away from the center the distance differs by 1 or 2:

. . .

(This follows from straight forward inequalities.) The important conclusion is that a 2x2 block of equal distances cannot happen; at most 4 neighbours can have the same distance forming a "zig-zag":

. . .

Another important conclusion is that each cell has at least 2 neighbours with equal distance, again only in certain configurations. From this it can be reasoned that if the neighbours along the blue arrows have a different distance then the neighbour along the black arrow has the same distance. Thus all points put into the variable `ring`

have distance `d`

. (Note that in the second `else`

-branch the distance is not checked.)

Next we go for the termination of the `do ... while`

-loop. Note that with each iteration the angle between the line (0,0)-(dx,dy) and the positive x-axis increases. Since the distance stays the same we will finally leave the current quadrant and go into the next one. And since along the half-axis each distance appears exactly once we will finally arrive at the starting point (d,0).

From this it also follows that no point is taken twice: Within one call of `generateNeighbourRing`

starting an iteration of the `do ... while`

loop with the same point again would lead to an infinite loop and hence contradict the termination. Across several calls of `generateNeighbourRing`

all points are different because of different distances to the center cell.

Looking at the possible configurations with neighbours with the same distance one can also show that all points with given distance `d`

will be collected.