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I've been thinking about this and I just can't think of a way to fill in a matrix with an outward spiral, so that I can do the following:

Turn this: 1 2 3 4 5 ... n


21 22 23 24 25 26
20 07 08 09 10 27
19 06 01 02 11 28
18 05 04 03 12 29
17 16 15 14 13 30

My problem is the algorithm itself, but if instead of pseudocode you can help with C++, that'd be better.

This is some code I wrote to test things out, but I really don't know how I can go about to do this.

#include <stdio.h>
#include <string>

using namespace std;

int main() {
  //int n = 5;
  int spiral[5][6];

  for (int i = 0; i < 5; i++)
    for (int u = 0; u < 6; u++)
      spiral[i][u] = 0;

  spiral[2][2] = 1;
  string direction = "right";
  for (int i = 2; i < 5; i++) {
    for (int u = 2; u < 6; u++) {
      if (direction == "right") {
        spiral[i][u + 1] = spiral[i][u] + 1;
        direction = "down";

  for (int i = 0; i < 5; i++) {
    for (int u = 0; u < 6; u++) {
      printf("%02d ", spiral[i][u]);

  return 0;

Thank you!

share|improve this question
Do you only want a solution for this case of 30 for int spiral[5][6]; or the general case for any int spiral[X][Y]? – gbulmer Mar 29 '12 at 21:52
I need a general solution. – David Gomes Mar 30 '12 at 8:38
It looks symmetric across the diagonal, i.e. the 30 could be top left, at spiral[0][0]. Does that matter? – gbulmer Mar 30 '12 at 9:24
up vote 4 down vote accepted

You can make the observation that there are similar squares with the lowest value in the bottom-left position then going upwards, right, down and left.

You can use this to create such a function:

template <typename Array>
void spiral_square(Array& a, int x, int y, int side, int& value)
  int mx = x+side-1, my=y+side-1;
  for (int i = 1; i <= side-1; ++i) a[my-i][x] = value++;
  for (int i = 1; i <= side-1; ++i) a[y][x+i] = value++;
  for (int i = 1; i <= side-1; ++i) a[y+i][mx] = value++;
  for (int i = 1; i <= side-1; ++i) a[my][mx-i] = value++;

See it in action:

share|improve this answer

Start at the last number, and go inwards from a corner. Move in one direction, and when you hit a wall, turn left 90-degrees.

share|improve this answer
Starting at the last number seems like a good idea, but how can I know what the size of the array would be? For example, if I were to have a n=30, I would start at the bottom right corner and go up, but it would be different for every number, because some numbers aren't even in corners. – David Gomes Mar 30 '12 at 8:42
you can then make a reverse on the array so it loops outward, as its what the op wanted. You don't hit a wall, you test if the cell you would add to array, already exists or is out of bounds. That is when you turn 90. If you do it twice consecutively, then the snake eats its own tail and you stop. The total nr of cells will be N * M of the matrix of course :). N * N if its a square. – Discipol Aug 13 '13 at 14:31

I think ipc's solution is based on the assumption you always want to fill out an entire matrix. What if you want to do n = 28 (ie having some incomplete row or column)?

For a generic n solution, I found it easiest to start from the starting point and increment outwards knowing the pattern of travel. Notice that you go:

1 right, 1 down, 2 left, 2 up, 3 right, 3 down, 4 left, 4 up, etc

So basically the pattern is you travel right, down, left, up for a number of steps that increments every two direction changes.

Unfortunately, I have not programmed in c++ in a while, so I did it in Ruby.

def output_spiral(n)
  #For formatting, determine the length of the largest number
  max_number_length = n.to_s.length

  #Determine matrix size
  max_x = Math.sqrt(n).floor
  max_y = Math.sqrt(n).floor
  if max_x * max_y < n
    max_x += 1
    if max_x * max_y < n
      max_y += 1

  #The a matrix of the required size.
  #Note that for simplicity in printing spiral is an array of row arrays.
  spiral =
  row ={ |i| '  ' }
  max_y.times{ spiral << row.clone }

  #Determine the starting point index (ie where to insert 1)
  x = ((max_x-1)/2).floor
  y = ((max_y-1)/2).floor

  #Input the start point value, formatted to the right size
  spiral[y][x] = "%0#{max_number_length}d" % 1

  #Setup counters required to iterate through the spiral
  steps_in_direction = 1        #This defines how many steps to take in a direction
  steps_count = 0               #This defines how many steps have been taken in the direction
  direction = 'right'           #This defines the direction currently travelling
  steps_in_direction_count = 0  #This define how many times we have used the same steps_in_direction value

  #Iterate through all the numbers up to n
  2.upto(n) do |i|
    #Change index based on the direction we are travelling
    case direction
      when 'right' then x += 1
      when 'down' then y += 1
      when 'left' then x -= 1
      when 'up' then y -= 1

    #Input the value, formatted to the right size
    spiral[y][x] = "%0#{max_number_length}d" % i

    #Increment counters
    steps_count += 1
    if steps_count == steps_in_direction
      steps_count = 0
      steps_in_direction_count += 1

      if steps_in_direction_count == 2
        steps_in_direction += 1
        steps_in_direction_count = 0

      case direction
        when 'right' then direction = 'down'
        when 'down' then direction = 'left'
        when 'left' then direction = 'up'
        when 'up' then direction = 'right'


  #Output spiral
  spiral.each do |x|
    puts x.join(' ')


See, which does a spiral of n=95.

share|improve this answer

I'm going to assume this is for project euler #28 (I just did this problem the other day). The secret isn't in creating the matrix, but in realizing the pattern. Realize the pattern and you can just count the two diagonals out without creating the matrix.

1, 3, 5, 7, 9, 13, 17, 21, 25, ... , n

Skipping anything?

As far as recreating the spiral matrix, I think the best way would be to work backwards after figuring out the pattern. Start from n and work your way down to 1. It would be a lot easier to place 'n' than 1 in the matrix.


It isn't too difficult to create the matrix after determining the diagonals (problem 28). I placed those values into the matrix and then "walked" the matrix filling in all of the other values based on the main diagonal values that I had previously filled into the matrix. However, I waste a small amount of time determining the two main diagonals. I like IPC's solution better. However, just as another method, here is the code to compute the matrix after I have determined the two main diagonals. Let n refer to the size of the grid, for example, 5.

int[,] t = new int[n, n];
int sizeOf = n - 1;

//Note that nums is the array of the two diagonals, which are already in sorted order based on my solution to problem 28.

//fill in diagonals
for (int diagNum = numsCount, i = sizeOf, j = 0; ; i--, j++)
    if (diagNum < 3)
        t[i, j] = 1;

    t[i, i] = nums[diagNum--];
    t[i, j] = nums[diagNum--];

    t[j, j] = nums[diagNum--];
    t[j, i] = nums[diagNum--];

//finish filling in matrix
for (int i = sizeOf, c = 0; i > 1; i--, c++)
    for (int j = i - 1; j > sizeOf - i; j--)
        t[i, j] = t[i, i] - i + j;

    for (int j = c + 1; j < sizeOf - c; j++)
        t[c, j] = t[c, c] - j + c;

    for (int j = c + 1; j < i; j++)
        t[j, i] = t[c, i] - j + c;

    for (int j = i - 1; j > c; j--)
        t[j, c] = t[i, c] - i + j;
share|improve this answer
Well, this isn't for problem #28, but on my particular case, I really need to create the matrix. – David Gomes Mar 30 '12 at 8:40


long int i,j,k,a,b,c,d,sum1=0,sum2=0,sum3=0,sum4=0;


share|improve this answer
please add show text in answer which explain who this answer help in solving problem to OP and others.Thanks – ρяσѕρєя K Dec 7 '15 at 16:11

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