# Algorithm for iterating over an outward spiral on a discrete 2D grid from the origin

For example, here is the shape of intended spiral (and each step of the iteration)

``````          y
|
|
16 15 14 13 12
17  4  3  2 11
-- 18  5  0  1 10 --- x
19  6  7  8  9
20 21 22 23 24
|
|
``````

Where the lines are the x and y axes.

Here would be the actual values the algorithm would "return" with each iteration (the coordinates of the points):

``````[0,0],
[1,0], [1,1], [0,1], [-1,1], [-1,0], [-1,-1], [0,-1], [1,-1],
[2,-1], [2,0], [2,1], [2,2], [1,2], [0,2], [-1,2], [-2,2], [-2,1], [-2,0]..
``````

etc.

I've tried searching, but I'm not exactly sure what to search for exactly, and what searches I've tried have come up with dead ends.

I'm not even sure where to start, other than something messy and inelegant and ad-hoc, like creating/coding a new spiral for each layer.

Can anyone help me get started?

Also, is there a way that can easily switch between clockwise and counter-clockwise (the orientation), and which direction to "start" the spiral from? (the rotation)

Also, is there a way to do this recursively?

My application

I have a sparse grid filled with data points, and I want to add a new data point to the grid, and have it be "as close as possible" to a given other point.

To do that, I'll call `grid.find_closest_available_point_to(point)`, which will iterate over the spiral given above and return the first position that is empty and available.

So first, it'll check `point+[0,0]` (just for completeness's sake). Then it'll check `point+[1,0]`. Then it'll check `point+[1,1]`. Then `point+[0,1]`, etc. And return the first one for which the position in the grid is empty (or not occupied already by a data point).

There is no upper bound to grid size.

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I have done this, but can't understand the example of output you gave –  alcuadrado Sep 14 '10 at 5:10
Sounds like a code golf question... –  Jeff Meatball Yang Sep 14 '10 at 5:11
@alcuadrado First, it returns the origin. Then it returns the point [1,0]. Then it "spirals around" counter-clockwise and returns the point [1,1]. I'll try to make it more clear –  Justin L. Sep 14 '10 at 5:11
Is this question related to a ProjectEuler problem? –  AraK Sep 14 '10 at 5:13
@Arak it's not; I'll clarify my purpose in the post. –  Justin L. Sep 14 '10 at 5:14

There's nothing wrong with direct, "ad-hoc" solution. It can be clean enough too.
Just notice that spiral is built from segments. And you can get next segment from current one rotating it by 90 degrees. And each two rotations, length of segment grows by 1.

edit Illustration, those segments numbered

``````   ... 11 10
7 7 7 7 6 10
8 3 3 2 6 10
8 4 . 1 6 10
8 4 5 5 5 10
8 9 9 9 9  9
``````

.

``````    // (di, dj) is a vector - direction in which we move right now
int di = 1;
int dj = 0;
// length of current segment
int segment_length = 1;

// current position (i, j) and how much of current segment we passed
int i = 0;
int j = 0;
int segment_passed = 0;
for (int k = 0; k < NUMBER_OF_POINTS; ++k) {
// make a step, add 'direction' vector (di, dj) to current position (i, j)
i += di;
j += dj;
++segment_passed;
System.out.println(i + " " + j);

if (segment_passed == segment_length) {
// done with current segment
segment_passed = 0;

// 'rotate' directions
int buffer = di;
di = -dj;
dj = buffer;

// increase segment length if necessary
if (dj == 0) {
++segment_length;
}
}
}
``````

To change original direction, look at original values of `di` and `dj`. To switch rotation to clockwise, see how those values are modified.

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Just because I don't like i,j,k for personal reasons :) ... i=x, j=y, k=n, where n is number of coordinates. –  Jeff Meatball Yang Sep 14 '10 at 5:21
I like this method =) It's easy to implement and it's the one I'm using for now. I'll wait and see if other ones come up though, just out of curiosity, before I select this as best answer. –  Justin L. Sep 14 '10 at 6:22

This is the javascript solution based on the answer at Looping in a spiral

``````var x = 0,
y = 0,
delta = [0, -1],
// spiral width
width = 6,
// spiral height
height = 6;

for (i = Math.pow(Math.max(width, height), 2); i>0; i--) {
if ((-width/2 < x <= width/2)
&& (-height/2 < y <= height/2)) {
console.debug('POINT', x, y);
}

if (x === y
|| (x < 0 && x === -y)
|| (x > 0 && x === 1-y)){
// change direction
delta = [-delta[1], delta[0]]
}

x += delta[0];
y += delta[1];
}
``````

fiddle: http://jsfiddle.net/N9gEC/

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Here's a stab at it in C++, a stateful iterator.

``````class SpiralOut{
protected:
unsigned layer;
unsigned leg;
public:
int x, y; //read these as output from next, do not modify.
SpiralOut():layer(1),leg(0),x(0),y(0){}
void goNext(){
switch(leg){
case 0: ++x; if(x  == layer)  ++leg;                break;
case 1: ++y; if(y  == layer)  ++leg;                break;
case 2: --x; if(-x == layer)  ++leg;                break;
case 3: --y; if(-y == layer){ leg = 0; ++layer; }   break;
}
}
};
``````

Should be about as efficient as it gets. If you still want a clockwise/counterclockwise switch, tell me and I'll add one asap.

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I would solve it using some math. Here is Ruby code (with input and output):

``````(0..(\$*.pop.to_i)).each do |i|
j = Math.sqrt(i).round
k = (j ** 2 - i).abs - j
p = [k, -k].map {|l| (l + j ** 2 - i - (j % 2)) * 0.5 * (-1) ** j}.map(&:to_i)
puts "p => #{p[0]}, #{p[1]}"
end
``````

E.g.

``````\$ ruby spiral.rb 10
p => 0, 0
p => 1, 0
p => 1, 1
p => 0, 1
p => -1, 1
p => -1, 0
p => -1, -1
p => 0, -1
p => 1, -1
p => 2, -1
p => 2, 0
``````

And golfed version:

``````p (0..\$*.pop.to_i).map{|i|j=Math.sqrt(i).round;k=(j**2-i).abs-j;[k,-k].map{|l|(l+j**2-i-j%2)*0.5*(-1)**j}.map(&:to_i)}
``````

Edit

First try to approach the problem functionally. What do you need to know, at each step, to get to the next step?

Focus on plane's first diagonal `x = y`. `k` tells you how many steps you must take before touching it: negative values mean you have to move `abs(k)` steps vertically, while positive mean you have to move `k` steps horizontally.

Now focus on the length of the segment you're currently in (spiral's vertices - when the inclination of segments change - are considered as part of the "next" segment). It's `0` the first time, then `1` for the next two segments (= 2 points), then `2` for the next two segments (= 4 points), etc. It changes every two segments and each time the number of points part of that segments increase. That's what `j` is used for.

Accidentally, this can be used for getting another bit of information: `(-1)**j` is just a shorthand to "`1` if you're decreasing some coordinate to get to this step; `-1` if you're increasing" (Note that only one coordinate is changed at each step). Same holds for `j%2`, just replace `1` with `0` and `-1` with `1` in this case. This mean they swap between two values: one for segments "heading" up or right and one for those going down or left.

This is a familiar reasoning, if you're used to functional programming: the rest is just a little bit of simple math.

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This looks pretty nice. Can you explain how it works? –  Justin L. Sep 16 '10 at 3:24
Very nice answer, the only one without using loop. Good job! But why "golfed version"?? This should be "forbidden" (unless on IOCCC :). Code like this is nice example of code which needs 2x more lines of comments and doc than actual code. –  NightElfik Jul 19 '13 at 6:31
Great job dude I have just done spiral pattern design but your code is much more smaller than mine...appreciate..1+ –  Gagan Gami Sep 19 at 11:40

This problem is best understood by analyzing how changes coordinates of spiral corners. Consider this table of first 8 spiral corners (excluding origin):

``` x,y   |  dx,dy  | k-th corner | N | Sign |
___________________________________________
1,0    |  1,0    | 1           | 1 |  +
1,1    |  0,1    | 2           | 1 |  +
-1,1   |  -2,0   | 3           | 2 |  -
-1,-1  |  0,-2   | 4           | 2 |  -
2,-1   |  3,0    | 5           | 3 |  +
2,2    |  0,3    | 6           | 3 |  +
-2,2   |  -4,0   | 7           | 4 |  -
-2,-2  |  0,-4   | 8           | 4 |  -
```

By looking at this table we can calculate X,Y of k-th corner given X,Y of (k-1) corner:

```N = INT((1+k)/2)
Sign = | +1 when N is Odd
| -1 when N is Even
[dx,dy] = | [N*Sign,0]  when k is Odd
| [0,N*Sign]  when k is Even
[X(k),Y(k)] = [X(k-1)+dx,Y(k-1)+dy]
```

Now when you know coordinates of k and k+1 spiral corner you can get all data points in between k and k+1 by simply adding 1 or -1 to x or y of last point. Thats it.

good luck.

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Try searching for either parametric or polar equations. Both are suitable to plotting spirally things. Here's a page that has plenty of examples, with pictures (and equations). It should give you some more ideas of what to look for.

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I've done pretty much the same thin as a training exercise, with some differences in the output and the spiral orientation, and with an extra requirement, that the functions spatial complexity has to be O(1).

After think for a while I came to the idea that by knowing where does the spiral start and the position I was calculating the value for, I could simplify the problem by subtracting all the complete "circles" of the spiral, and then just calculate a simpler value.

Here is my implementation of that algorithm in ruby:

``````def print_spiral(n)
(0...n).each do |y|
(0...n).each do |x|
printf("%02d ", get_value(x, y, n))
end
print "\n"
end
end

def distance_to_border(x, y, n)
[x, y, n - 1 - x, n - 1 - y].min
end

def get_value(x, y, n)
dist = distance_to_border(x, y, n)
initial = n * n - 1

(0...dist).each do |i|
initial -= 2 * (n - 2 * i) + 2 * (n - 2 * i - 2)
end

x -= dist
y -= dist
n -= dist * 2

if y == 0 then
initial - x # If we are in the upper row
elsif y == n - 1 then
initial - n - (n - 2) - ((n - 1) - x) # If we are in the lower row
elsif x == n - 1 then
initial - n - y + 1# If we are in the right column
else
initial - 2 * n - (n - 2) - ((n - 1) - y - 1) # If we are in the left column
end
end

print_spiral 5
``````

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I had a similar problem, but I didn't want to loop over the entire spiral each time to find the next new coordinate. The requirement is that you know your last coordinate.

Here is what I came up with with a lot of reading up on the other solutions:

``````function getNextCoord(coord) {

// required info
var x     = coord.x,
y     = coord.y,
level = Math.max(Math.abs(x), Math.abs(y));
delta = {x:0, y:0};

// calculate current direction (start up)
if (-x === level)
delta.y = 1;    // going up
else if (y === level)
delta.x = 1;    // going right
else if (x === level)
delta.y = -1;    // going down
else if (-y === level)
delta.x = -1;    // going left

// check if we need to turn down or left
if (x > 0 && (x === y || x === -y)) {
// change direction (clockwise)
delta = {x: delta.y,
y: -delta.x};
}

// move to next coordinate
x += delta.x;
y += delta.y;

return {x: x,
y: y};
}

coord = {x: 0, y: 0}
for (i = 0; i < 40; i++) {
console.log('['+ coord.x +', ' + coord.y + ']');
coord = getNextCoord(coord);

}
``````

Still not sure if it is the most elegant solution. Perhaps some elegant maths could remove some of the if statements. Some limitations would be needing some modification to change spiral direction, doesn't take into account non-square spirals and can't spiral around a fixed coordinate.

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Here's the algorithm. It rotates clockwise, but could easily rotate anticlockwise, with a few alterations. I made it in just under an hour.

```````// spiral_get_value(x,y);
sx = argument0;
sy = argument1;
a = max(sqrt(sqr(sx)),sqrt(sqr(sy)));
c = -b;
d = (b*2)+1;
us = (sy==c and sx !=c);
rs = (sx==b and sy !=c);
bs = (sy==b and sx !=b);
ls = (sx==c and sy !=b);
ra = rs*((b)*2);
ba = bs*((b)*4);
la = ls*((b)*6);
ax = (us*sx)+(bs*-sx);
ay = (rs*sy)+(ls*-sy);
return(value);`
``````

It will handle any x / y values (infinite).

It's written in GML (Game Maker Language), but the actual logic is sound in any programming language.

The single line algorithm only has 2 variables (sx and sy) for the x and y inputs. I basically expanded brackets, a lot. It makes it easier for you to paste it into notepad and change 'sx' for your x argument / variable name and 'sy' to your y argument / variable name.

`// spiral_get_value(x,y);

sx = argument0;

sy = argument1;

value = ((((sx==max(sqrt(sqr(sx)),sqrt(sqr(sy))) and sy !=(-1*max(sqrt(sqr(sx)),sqrt(sqr(sy))))))*((max(sqrt(sqr(sx)),sqrt(sqr(sy))))2))+(((sy==max(sqrt(sqr(sx)),sqrt(sqr(sy))) and sx !=max(sqrt(sqr(sx)),sqrt(sqr(sy)))))((max(sqrt(sqr(sx)),sqrt(sqr(sy))))*4))+(((sx==(-1*max(sqrt(sqr(sx)),sqrt(sqr(sy)))) and sy !=max(sqrt(sqr(sx)),sqrt(sqr(sy)))))*((max(sqrt(sqr(sx)),sqrt(sqr(sy))))*6))+((((sy==(-1*max(sqrt(sqr(sx)),sqrt(sqr(sy)))) and sx !=(-1*max(sqrt(sqr(sx)),sqrt(sqr(sy))))))sx)+(((sy==max(sqrt(sqr(sx)),sqrt(sqr(sy))) and sx !=max(sqrt(sqr(sx)),sqrt(sqr(sy)))))-sx))+(((sx==max(sqrt(sqr(sx)),sqrt(sqr(sy))) and sy !=(-1*max(sqrt(sqr(sx)),sqrt(sqr(sy))))))*sy)+(((sx==(-1*max(sqrt(sqr(sx)),sqrt(sqr(sy)))) and sy !=max(sqrt(sqr(sx)),sqrt(sqr(sy)))))*-sy))+sqr(((max(sqrt(sqr(sx)),sqrt(sqr(sy)))*2)+1)-2)+max(sqrt(sqr(sx)),sqrt(sqr(sy)));

return(value);`

I know the reply is awfully late :D but i hope it helps future visitors.

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