# Print two-dimensional array in spiral order

How do I print a 5×5 two-dimensional array in spiral order?

Is there any formula so that I can print an array of any size in spiral order?

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In what context? HTML? WPF? Command Line? Matlab? Skywriting? –  Tom Ritter Apr 7 '09 at 17:25
Maybe he's working on this Project Euler question: projecteuler.net/index.php?section=problems&id=28 –  Chris Upchurch Apr 7 '09 at 17:46

The idea is to treat the matrix as a series of layers, top-right layers and bottom-left layers. To print the matrix spirally we can peel layers from these matrix, print the peeled part and recursively call the print on the left over part. The recursion terminates when we don't have any more layers to print.

Input matrix:

1 2 3 4
5 6 7 8
9 0 1 2
3 4 5 6
7 8 9 1

After peeling top-right layer:

1 2 3 4
8
5 6 7  2
9 0 1  6
3 4 5  1
7 8 9

After peeling bottom-left layer from sub-matrix:

6 7
5  0 1
9  4 5
3
7 8 9

After peeling top-right layer from sub-matrix:

6 7
1
0  5
4

After peeling bottom-left layer from sub-matrix:

0
4

Recursion terminates.

C functions:

// function to print the top-right peel of the matrix and
// recursively call the print bottom-left on the submatrix.
void printTopRight(int a[][COL], int x1, int y1, int x2, int y2) {
int i = 0, j = 0;

// print values in the row.
for(i = x1; i<=x2; i++) {
printf("%d ", a[y1][i]);
}

// print values in the column.
for(j = y1 + 1; j <= y2; j++)         {
printf("%d ", a[j][x2]);
}

// see if more layers need to be printed.
if(x2-x1 > 0) {
// if yes recursively call the function to
// print the bottom left of the sub matrix.
printBottomLeft(a, x1, y1 + 1, x2-1, y2);
}
}

// function to print the bottom-left peel of the matrix and
// recursively call the print top-right on the submatrix.
void printBottomLeft(int a[][COL], int x1, int y1, int x2, int y2) {
int i = 0, j = 0;

// print the values in the row in reverse order.
for(i = x2; i>=x1; i--) {
printf("%d ", a[y2][i]);
}

// print the values in the col in reverse order.
for(j = y2 - 1; j >= y1; j--) {
printf("%d ", a[j][x1]);
}

// see if more layers need to be printed.
if(x2-x1 > 0) {
// if yes recursively call the function to
// print the top right of the sub matrix.
printTopRight(a, x1+1, y1, x2, y2-1);
}
}

void printSpiral(int arr[][COL]) {
printTopRight(arr,0,0,COL-1,ROW-1);
printf("\n");
}

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super explaination... –  GuruKulki Feb 18 '11 at 19:07
excuse me but may i know what is the logic behind the x2 - x1? –  Sikret Miseon Oct 21 '11 at 9:05
If x2 represents the rightmost column index and x1 represents the leftmost column index the check against x2-x1 > 0 determines whether there are any columns remaining to print out. If x2-x1=0 as in the last step in the example: [0 4] then there was only 1 column remaining which you just printed and the function should terminate. –  Bauhaus Apr 12 '13 at 5:01
for M * N we need to check for the maximum between row and column. then it will work for ant matrix. thanks. –  Trying Jul 20 '13 at 22:50
@codaddict shouldn't it be y2-y1 as the stopping condition in the printBottomLeft function –  ordinary Sep 22 '13 at 7:24

I see that no one has use only one for loop and without recursion in the code, and so I want to contribute.

The idea is like this:

Imagine there is a turtle standing at point (0,0)

It will keep going forward until it see a sign, then it will turn right

So if we put the turtle at point (0,0) facing right-ward, and if we place the signs at appropriate places, the turtle will traverse the array in spiral way.

Now the problem is: "Where to put the signs?"

Let's see where we should put the signs (marked by #, and numbers by O):

For a grid that looks like this:
O O O O
O O O O
O O O O
O O O O

We put the signs like this:
O O O #
# O # O
O # # O
# O O #

For a grid that looks like this:
O O O
O O O
O O O
O O O

We put the signs like this:
O O #
# # O
O # O
# O #

And for a grid that looks like this:
O O O O O O O
O O O O O O O
O O O O O O O
O O O O O O O
O O O O O O O

We put the signs like this:
O O O O O O #
# O O O O # O
O # O O # O O
O # O O O # O
# O O O O O #

We can see that, unless the point is at the top-left part, the signs are places at points where the distances to the closest horizontal border and the closest vertical border are the same, while for the top-left part, the distance to the top border is one more than the distance to the left border, with priority given to top-right in case the point is horizontally centered, and to top-left in case the point is vertically centered.

This can be realized in a simple function quite easily, by taking the minimum of (curRow and height-1-curRow), then the minimum of (curCol and width-1-curCol) and compare if they are the same. But we need to account for the upper-left case, that is, when the minimum is curRow and curCol themselves. In that case we reduce the vertical distance accordingly.

Here is the C code:

#include <stdio.h>

int shouldTurn(int row, int col, int height, int width){
int same = 1;
if(row > height-1-row) row = height-1-row, same = 0; // Give precedence to top-left over bottom-left
if(col >= width-1-col) col = width-1-col, same = 0; // Give precedence to top-right over top-left
row -= same; // When the row and col doesn't change, this will reduce row by 1
if(row==col) return 1;
return 0;
}

int vecs[4][2] = {{0,1},{1,0},{0,-1},{-1,0}};
void printSpiral(int arr[4][4], int height, int width){
int vecIdx=0, i=0;
int curRow=0, curCol=0;
for(i=0; i<height*width; i++){
printf("%d ",arr[curRow][curCol]);
if(shouldTurn(curRow, curCol, height, width)){
vecIdx = (vecIdx+1)%4;
}
curRow += vecs[vecIdx][0];
curCol += vecs[vecIdx][1];
}
printf("\n");
}

int main(){
int arr[4][4]= {{1,2,3,4},{5,6,7,8},{9,10,11,12},{13,14,15,16}};
printSpiral(arr, 4, 4);
printSpiral(arr, 3, 4);
}

Which outputs:

1 2 3 4 8 12 16 15 14 13 9 5 6 7 11 10
1 2 3 4 8 12 11 10 9 5 6 7
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Nice idea. In this case this array is sorted from left to right and top to bottom. If that's the case can this solution be optimized further? –  yalkris Sep 3 at 1:14
What does sorted array have to do with this? We will still need to print in spiral way, right? –  justhalf Sep 3 at 1:24
You should change this line row -= same; to if (same && (col != width -1 -col)) { row -= same;} –  yalkris Sep 3 at 5:09
Why should I make a line longer? It's currently correct (as you can see from the output), since the value of same would have been updated to 0 when it's not in the upper-left section. –  justhalf Sep 3 at 5:15
To give top right more priority than top left. Try {{1,2,3},{4,5,6},{7,8,9},{10,11,12}}. You should turn at 5 but with your logic above shouldTurn returns 0 for row = 1 and column = 1. –  yalkris Sep 3 at 5:21

This program works for any n*n matrix..

public class circ {
public void get_circ_arr (int n,int [][] a)
{
int z=n;
{
for (int i=0;i<n;i++)
{
for (int l=z-1-i;l>=i;l--)
{
int k=i;
System.out.printf("%d",a[k][l]);
}

for (int j=i+1;j<=z-1-i;j++)
{
int k=i;
{
System.out.printf("%d",a[j][k]);
}
}

for (int j=i+1;j<=z-i-1;j++)
{
int k=z-1-i;
{
System.out.printf("%d",a[k][j]);
}
}

for (int j=z-2-i;j>=i+1;j--)
{
int k=z-i-1;
{
System.out.printf("%d",a[j][k]);
}
}
}
}
}
}

Hope it helps

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Given a matrix of chars, implement a method that prints all characters in the following order: first the outer circle, then the next one and so on.

public static void printMatrixInSpiral(int[][] mat){

if(mat.length == 0|| mat[0].length == 0){
/* empty matrix */
return;
}

StringBuffer str = new StringBuffer();
int counter = mat.length * mat[0].length;
int startRow = 0;
int endRow = mat.length-1;
int startCol = 0;
int endCol = mat[0].length-1;
boolean moveCol = true;
boolean leftToRight = true;
boolean upDown = true;

while(counter>0){

if(moveCol){

if(leftToRight){

/* printing entire row left to right */
for(int i = startCol; i <= endCol ; i++){
str.append(mat[startRow][i]);
counter--;
}
leftToRight = false;
moveCol = false;
startRow++;
}
else{

/* printing entire row right to left */
for(int i = endCol ; i >= startCol ; i--){
str.append(mat[endRow][i]);
counter--;
}
leftToRight = true;
moveCol = false;
endRow--;
}
}
else
{
if(upDown){

/* printing column up down */
for(int i = startRow ; i <= endRow ; i++){
str.append(mat[i][endCol]);
counter--;
}
upDown = false;
moveCol = true;
endCol--;
}
else
{

/* printing entire col down up */
for(int i = endRow ; i >= startRow ; i--){
str.append(mat[i][startCol]);
counter--;
}
upDown = true;
moveCol = true;
startCol++;
}
}
}
System.out.println(str.toString());
}
-

I was obsessed with this problem when I was learning Ruby. This was the best I could do:

def spiral(matrix)
matrix.empty? ? [] : matrix.shift + spiral(matrix.transpose.reverse)
end

You can check out some of my other solutions by stepping back through the revisions in this gist. Also, if you follow the link back to whom I forked the gist from, you'll find some other clever solutions. Really interesting problem that can be solved in multiple elegant ways — especially in Ruby.

-
1. Pop top row
2. Transpose and flip upside-down (same as rotate 90 degrees counter-clockwise)
3. Go to 1

Python code:

import itertools

arr = [[1,2,3,4],
[12,13,14,5],
[11,16,15,6],
[10,9,8,7]]

def transpose_and_yield_top(arr):
while arr:
yield arr[0]
arr = list(reversed(zip(*arr[1:])))

print list(itertools.chain(*transpose_and_yield_top(arr)))
-

Here are the three interesting ways

1. Reading in spiral way can be treated like a snake moving towards boundary and turning on hitting the boundary or itself (I find it elegant and most efficient being a single loop of N iterations)

ar = [ [ 0, 1, 2, 3, 4], [15, 16, 17, 18, 5], [14, 23, 24, 19, 6], [13, 22, 21, 20, 7], [12, 11, 10, 9, 8]]

def print_spiral(ar): """ assuming a rect array """ rows, cols = len(ar), len(ar[0]) r, c = 0, -1 # start here nextturn = stepsx = cols # move so many steps stepsy = rows-1 inc_c, inc_r = 1, 0 # at each step move this much turns = 0 # how many times our snake had turned for i in range(rows*cols): c += inc_c r += inc_r

print ar[r][c],

if i == nextturn-1:
turns += 1
# at each turn reduce how many steps we go next
if turns%2==0:
nextturn += stepsx
stepsy -= 1
else:
nextturn += stepsy
stepsx -= 1
# change directions
inc_c, inc_r = -inc_r, inc_c

print_spiral(ar)

output:

0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24
1. A recursive approach would be to print outer layer and call same function for inner rectangle e.g.

def print_spiral(ar, sr=0, sc=0, er=None, ec=None): er = er or len(ar)-1 ec = ec or len(ar[0])-1

if sr > er or sc > ec:
print
return

# print the outer layer
top, bottom, left, right = [], [], [], []
for c in range(sc,ec+1):
top.append(ar[sr][c])
if sr != er:
bottom.append(ar[er][ec-(c-sc)])

for r in range(sr+1,er):
right.append(ar[r][ec])
if ec != sc:
left.append(ar[er-(r-sr)][sc])

print " ".join([str(a) for a in top + right + bottom + left]),

# peel next layer of onion
print_spiral(ar, sr+1, sc+1, er-1, ec-1)

2. Finally here is a small snippet to do it, not efficient but fun :), basically it prints top row, and rotates whole rectangle anti-clockwise and repeats

def print_spiral(ar): if not ar: return print " ".join(str(a) for a in ar[0]), ar = zip(*[ reversed(row) for row in ar[1:]]) print_spiral(ar)

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I just realize that this is similar to what I'm trying to achieve, but I used different method to find out when to turn. Counting the number of steps is a good idea, too! –  justhalf Sep 3 at 1:33

One solution involves directions right, left, up, down, and their corresponding limits (indices). Once the first row is printed, and direction changes (from right) to down, the row is discarded by incrementing the upper limit. Once the last column is printed, and direction changes to left, the column is discarded by decrementing the right hand limit... Details can be seen in the self-explanatory C code.

#include <stdio.h>
#define N_ROWS 5
#define N_COLS 3

void print_spiral(int a[N_ROWS][N_COLS])
{
enum {up, down, left, right} direction = right;
int up_limit = 0,
down_limit = N_ROWS - 1,
left_limit = 0,
right_limit = N_COLS - 1,
downcount = N_ROWS * N_COLS,
row = 0,
col = 0;

while(printf("%d ", a[row][col]) && --downcount)
if(direction == right)
{
if(++col > right_limit)
{
--col;
direction = down;
++up_limit;
++row;
}
}
else if(direction == down)
{
if(++row > down_limit)
{
--row;
direction = left;
--right_limit;
--col;
}
}
else if(direction == left)
{
if(--col < left_limit)
{
++col;
direction = up;
--down_limit;
--row;
}
}
else /* direction == up */
if(--row < up_limit)
{
++row;
direction = right;
++left_limit;
++col;
}
}

void main()
{
int a[N_ROWS][N_COLS] = {1,2,3,4,5,6,7,8,9,10,11,12,13,14,15};
print_spiral(a);
}

.

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This is my implementation:

public static void printMatrix(int matrix[][], int M, int N){
int level = 0;
int min = (M < N) ? M:N;
System.out.println();
while(level <= min/2){
for(int j = level; j < N - level - 1; j++){
System.out.print(matrix[level][j] + "\t");
}
for(int i = level; i < M - level - 1; i++) {
System.out.print(matrix[i][N - level - 1] + "\t");
}
for(int j = N - level - 1; j > level; j--){
System.out.print(matrix[M - level - 1][j] + "\t");
}
for(int i = M - level - 1; i > level; i-- ){
System.out.print(matrix[i][level] + "\t");
}
level++;
}
}
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I think your solution will fail at input matrix={{1}}, M=1, N=1. In that case, nothing will be print out. –  wenqiang Oct 28 '13 at 19:50
@wenqiang Yeah, you are right, my code will fail... I should consider corner case... –  WonderLi Nov 6 '13 at 6:49

int N = Integer.parseInt(args[0]);

// create N-by-N array of integers 1 through N
int[][] a = new int[N][N];
for (int i = 0; i < N; i++)
for (int j = 0; j < N; j++)
a[i][j] = 1 + N*i + j;

// spiral
for (int i = N-1, j = 0; i > 0; i--, j++) {
for (int k = j; k < i; k++) System.out.println(a[j][k]);
for (int k = j; k < i; k++) System.out.println(a[k][i]);
for (int k = i; k > j; k--) System.out.println(a[i][k]);
for (int k = i; k > j; k--) System.out.println(a[k][j]);
}

// special case for middle element if N is odd
if (N % 2 == 1) System.out.println(a[(N-1)/2][(N-1)/2]);
}

}

-
public class SpiralPrint{

//print the elements of matrix in the spiral order.
//my idea is to use recursive, for each outer loop

public static void printSpiral(int[][] mat, int layer){
int up = layer;
int buttom = mat.length - layer - 1;
int left = layer;
int right = mat[0].length - layer - 1;
if(up > buttom+1 || left > right + 1)
return; // termination condition

//traverse the other frame,
//print up
for(int i = left; i <= right; i ++){
System.out.print( mat[up][i]+ " " );
}
//print right
for(int i = up + 1; i <=buttom; i ++){
System.out.print(mat[i][right] + " ");
}

//print buttom
for(int i = right - 1; i >= left; i --){
System.out.print(mat[buttom][i] + " ");
}

//print left
for(int i = buttom - 1; i > up; i --){
System.out.print(mat[i][left] + " ");
}

//recursive call for the next level
printSpiral(mat, layer + 1);
}

public static void main(String[] args){

int[][] mat = {{1,2,3,4}, {5,6,7,8}, {9,10,11,12}, {13,14,15,16}};
int[][] mat2 = {{1,2,3}, {4,5,6}, {7,8,9}, {10,11,12}};
SpiralPrint.printSpiral(mat2,0);
return;
}
}
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For printing a 2-D matrix consider matrix as a composition of rectangles and/or line where smaller rectangle is fitted into larger one, take boundary of matrix which forms a rectangle to be printed, starting with up-left element each time in each layer; once done with this go inside for next layer of smaller rectangle, in case i don't have a rectangle then it should be line to be printed, a horizontal or vertical. I have pasted the code with an example matrix, HTH.

#include <stdio.h>

int a[2][4] = { 1, 2 ,3, 44,
8, 9 ,4, 55 };

void print(int, int, int, int);

int main() {

int row1, col1, row2, col2;

row1=0;
col1=0;
row2=1;
col2=3;

while(row2>=row1 && col2>=col1)
{
print(row1, col1, row2, col2);

row1++;
col1++;
row2--;
col2--;
}

return 0;
}

void print(int row1, int col1, int row2, int col2) {

int i=row1;
int j=col1;

/* This is when single horizontal line needs to be printed */
if( row1==row2 && col1!=col2) {
for(j=col1; j<=col2; j++)
printf("%d ", a[i][j]);
return;
}

/* This is when single vertical line needs to be printed */
if( col1==col2 && row1!=row2) {
for(i=row1; j<=row2; i++)
printf("%d ", a[i][j]);
return;
}

/* This is reached when there is a rectangle to be printed */

for(j=col1; j<=col2; j++)
printf("%d ", a[i][j]);

for(j=col2,i=row1+1; i<=row2; i++)
printf("%d ", a[i][j]);

for(i=row2,j=col2-1; j>=col1; j--)
printf("%d ", a[i][j]);

for(j=col1,i=row2-1; i>row1; i--)
printf("%d ", a[i][j]);

}
-

Here is my implementation in Java:

public class SpiralPrint {
static void spiral(int a[][],int x,int y){

//If the x and y co-ordinate collide, break off from the function

if(x==y)
return;
int i;

//Top-left to top-right

for(i=x;i<y;i++)
System.out.println(a[x][i]);

//Top-right to bottom-right

for(i=x+1;i<y;i++)
System.out.println(a[i][y-1]);

//Bottom-right to bottom-left

for(i=y-2;i>=x;i--)
System.out.println(a[y-1][i]);

//Bottom left to top-left

for(i=y-2;i>x;i--)
System.out.println(a[i][x]);

//Recursively call spiral

spiral(a,x+1,y-1);

}

public static void main(String[] args) {

int a[][]={{1,2,3,4},{5,6,7,8},{9,10,11,12},{13,14,15,16}};
spiral(a,0,4);
/*Might be implemented without the 0 on an afterthought, all arrays will start at 0 anyways. The second parameter will be the dimension of the array*/

}

}
-
#define R 3
#define C 6
using namespace std;

void  PrintSpiral(int er,int ec,int arr[R][C])
{
int sr=0,sc=0,i=0;

while(sr<=er && sc<=ec)
{
for(int i=sc;i<=ec;++i)
cout<<arr[sr][i]<<" ";
++sr;

for(int i=sr;i<=er;++i)
cout<<arr[i][ec]<<" ";
ec--;

if(sr<=er)
{
for(int i=ec;i>=sc;--i)
cout<<arr[er][i]<<" ";
er--;
}

if(sc<=ec)
{
for(int i=er;i>=sr;--i)
cout<<arr[i][sc]<<" ";
++sc;
}

}

}

int main()
{
int a[R][C] = { {1,  2,  3,  4,  5,  6},
{7,  8,  9,  10, 11, 12},
{13, 14, 15, 16, 17, 18}
};

PrintSpiral(R-1, C-1, a);
}
-

Java code if anybody is interested.
Input:
4
1 2 3 4
5 6 7 8
9 1 2 3
4 5 6 7

Output: 1 2 3 4 8 3 7 6 5 4 9 5 6 7 2 1

public class ArraySpiralPrinter {

public static void main(String[] args) {
Scanner sc = new Scanner(System.in);
int n = sc.nextInt(); //marrix size
int[][] ar = new int[n][n];
for (int i = 0; i < n; i++) {
for (int j = 0; j < n; j++) {
ar[i][j] = sc.nextInt();
}
}
printTopRight(0, 0, n - 1, n - 1, ar);
}
//prints top and right layers.
//(x1,y1) to (x1, y2) - top layer & (x1,y2) to (x2, y2)
private static void printTopRight(int x1, int y1, int x2, int y2, int[][] ar) {
//print row values - top
for (int y = y1; y <= y2; y++) {
System.out.printf("%d ", ar[x1][y]);
}
//print column value - right
for (int x = x1 + 1; x <= x2; x++) {
System.out.printf("%d ", ar[x][y2]);
}

//are there any remaining layers
if (x2 - x1 > 0) {
//call printBottemLeft
printBottomLeft(x1 + 1, y1, x2, y2 - 1, ar);
}
}

//prints bottom and left layers in reverse order
//(x2,y2) to (x2, y1) - bottom layer & (x2,y1) to (x1, y1)
private static void printBottomLeft(int x1, int y1, int x2, int y2, int[][] ar) {
//print row values in reverse order - bottom
for (int y = y2; y >= y1; y--) {
System.out.printf("%d ", ar[x2][y]);
}

//print column value in reverse order - left
for (int x = x2-1; x >= x1; x--) {
System.out.printf("%d ", ar[x][y1]);
}

//are there any remaining layers
if (x2 - x1 > 0) {
printTopRight(x1, y1 + 1, x2 - 1, y2, ar);
}
}
}
-

This is a recursive version in C that I could think of:-

void printspiral  (int[][100],int, int, int, int);

int main()
{
int r,c, i, j;
printf ("Enter the dimensions of the matrix");
scanf("%d %d", &r, &c);
int arr[r][100];
int min = (r<c?r:c);
if (min%2 != 0) min = min/2 +1;
for (i = 0;i<r; i++)
for (j = 0; j<c; j++)
scanf ("%d",&arr[i][j]);

printspiral(arr,0,r,c,min );

}

void printspiral (int arr[][100], int i, int j, int k, int min)
{
int a;

for (a = i; a<k;a++)
printf("%d\n", arr[i][a]);
for (a=i+1;a<j;a++)
printf ("%d\n", arr[a][k-1]);
for (a=k-2; a>i-1;a--)
printf("%d\n", arr[j-1][a]);
for (a=j-2; a>i; a--)
printf("%d\n", arr[a][i]);
if (i < min)
printspiral(arr,i+1, j-1,k-1, min);

}
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http://www.technicalinterviewquestions.net/2009/03/print-2d-array-matrix-spiral-order.html

here is the best explanation for the above answer :) along with diagram :)

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public static void printSpiral1(int array[][],int row,int col){

int rowStart=0,colStart=0,rowEnd=row-1,colEnd=col-1;
int i;

while(rowStart<=rowEnd && colStart<= colEnd){

for(i=colStart;i<=colEnd;i++)
System.out.print(" "+array[rowStart][i]);

for(i=rowStart+1;i<=rowEnd;i++)
System.out.print(" "+array[i][colEnd]);

for(i=colEnd-1;i>=colStart;i--)
System.out.print(" "+array[rowEnd][i]);

for(i=rowEnd-1;i>=rowStart+1;i--)
System.out.print(" "+array[i][colStart]);

rowStart++;
colStart++;
rowEnd--;
colEnd--;
}

}
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I think this has a bug...try printSpiral1(new int[]{ 1, 2 }, 1, 2) –  user1389813 Mar 12 at 21:04
its not overloaded method so you can only pass 2-D array. –  Addy Mar 13 at 18:52
oops i mean printSpiral1(new int[][]{{1,2}}, 1 ,2 ) –  user1389813 Mar 13 at 21:31
and also new int[][] {{ 1, 2, 3 }, { 16, 17, 4 }, { 15, 18, 5 },{ 14, 19, 6 }, { 13, 20, 7 },{ 12, 21, 8 },{ 11, 10, 9 } }. try it and you will see –  user1389813 Mar 13 at 21:31
ideone.com/LdX63s –  user1389813 Mar 13 at 21:39

Here is my solution in C#:

public static void PrintSpiral(int[][] matrix, int n)
{
if (matrix == null)
{
return;
}

for (int layer = 0; layer < Math.Ceiling(n / 2.0); layer++)
{
var start = layer;
var end = n - layer - 1;
var offset = end - 1;

Console.Write("Layer " + layer + ": ");

// Center case
if (start == end)
{
Console.Write(matrix[start][start]);
}

// Top
for (int i = start; i <= offset; i++)
{
Console.Write(matrix[start][i] + " ");
}

// Right
for (int i = start; i <= offset; i++)
{
Console.Write(matrix[i][end] + " ");
}

// Bottom
for (int i = end; i > start; i--)
{
Console.Write(matrix[end][i] + " ");
}

// Left
for (int i = end; i > start; i--)
{
Console.Write(matrix[i][start] + " ");
}

Console.WriteLine();
}
}
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Here's my approach using an Iterator . Note this solves almost the same problem.. Complete code here : https://github.com/rdsr/algorithms/blob/master/src/jvm/misc/FillMatrix.java

import java.util.Iterator;

class Pair {
final int i;
final int j;

Pair(int i, int j) {
this.i = i;
this.j = j;
}

@Override
public String toString() {
return "Pair [i=" + i + ", j=" + j + "]";
}
}

enum Direction {
N, E, S, W;
}

class SpiralIterator implements Iterator<Pair> {
private final int r, c;
int ri, ci;
int cnt;

Direction d; // current direction
int level; // spiral level;

public SpiralIterator(int r, int c) {
this.r = r;
this.c = c;

d = Direction.E;
level = 1;
}

@Override
public boolean hasNext() {
return cnt < r * c;
}

@Override
public Pair next() {
final Pair p = new Pair(ri, ci);
switch (d) {
case E:
if (ci == c - level) {
ri += 1;
d = changeDirection(d);
} else {
ci += 1;
}
break;

case S:
if (ri == r - level) {
ci -= 1;
d = changeDirection(d);
} else {
ri += 1;
}
break;

case W:
if (ci == level - 1) {
ri -= 1;
d = changeDirection(d);
} else {
ci -= 1;
}
break;

case N:
if (ri == level) {
ci += 1;
level += 1;
d = changeDirection(d);
} else {
ri -= 1;
}
break;
}

cnt += 1;
return p;
}

private static Direction changeDirection(Direction d) {
switch (d) {
case E:
return Direction.S;
case S:
return Direction.W;
case W:
return Direction.N;
case N:
return Direction.E;
default:
throw new IllegalStateException();
}
}

@Override
public void remove() {
throw new UnsupportedOperationException();
}

}

public class FillMatrix {
static int[][] fill(int r, int c) {
final int[][] m = new int[r][c];
int i = 1;
final Iterator<Pair> iter = new SpiralIterator(r, c);
while (iter.hasNext()) {
final Pair p = iter.next();
m[p.i][p.j] = i;
i += 1;
}
return m;
}

public static void main(String[] args) {
final int r = 19, c = 19;
final int[][] m = FillMatrix.fill(r, c);
for (int i = 0; i < r; i++) {
for (int j = 0; j < c; j++) {
System.out.print(m[i][j] + " ");
}
System.out.println();
}
}
}
-

Complete pure C program for any 2D array matrix with given row x column.

#include <stdio.h>
void  printspiral(int *p,int r, int c) {
int i=0,j=0,m=1,n=0;
static int firstrun=1,gCol;
if (!p||r<=0||c<=0)
return ;
if(firstrun) {
gCol=c;
firstrun=0;
}
for(i=0,j=0;(0<=i && i<c)&&(0<=j && j<r);i+=m,j+=n) {
printf(" %d",p[i+j*gCol]);
if (i==0 && j==1 && (i+1)!=c) break;
else if (i+1==c && !j) {m=0;n=1;}
else if (i+1==c && j+1==r && j) {n=0;m=-1;}
else if (i==0 && j+1==r && j) {m=0;n=-1;}
}
printspiral(&p[i+j*gCol+1],r-2,c-2);
firstrun=1;
printf("\n");
}
int main() {
int a[3][3]={{0,1,2},{3,4,5},{6,7,8}};
int b[3][4]={{0,1,2,3},{4,5,6,7},{8,9,10,11}};
int c[4][3]={{0,1,2},{3,4,5},{6,7,8},{9,10,11}};
int d[3][1]={{0},{1},{2}};
int e[1][3]={{0,1,2}};
int f[1][1]={{0}};
int g[5][5]={{0,1,2,3,4},{5,6,7,8,9},{10,11,12,13,14},{15,16,17,18,19},{20,21,22,23,24}};
printspiral(a,3,3);
printspiral(b,3,4);
printspiral(c,4,3);
printspiral(d,3,1);
printspiral(e,1,3);
printspiral(f,1,1);
printspiral(g,5,5);
return 0;
}
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This question is related to this one: Logical problem

The answers presented seem to work but are complicated to understand. A very simple way to solve this is divide and conquer i.e., after reading the edge, remove it and the next read will be much simpler. Check out a complete solution in PHP below:

#The source number matrix
\$source[0] = array(1, 2, 3, 4);
\$source[1] = array(5, 6, 7, 8);
\$source[2] = array(9, 10, 11, 12);
\$source[3] = array(13, 14, 15, 16);
\$source[4] = array(17, 18, 19, 20);

#Get the spiralled numbers
\$final_spiral_list = get_spiral_form(\$source);
print_r(\$final_spiral_list);

function get_spiral_form(\$matrix)
{
#Array to hold the final number list
\$spiralList = array();

\$result = \$matrix;
while(count(\$result) > 0)
{
}

return \$spiralList;
}

{

\$rowNumber = count(\$matrix);
\$colNumber = count(\$matrix[0]);

#Check if the array has one row or column
if(\$colNumber == 1) for(\$i=0; \$i<\$rowNumber; \$i++) array_push(\$read, \$matrix[\$i][0]);
#Check if array has 2 rows or columns
if(\$rowNumber == 2 || (\$rowNumber == 2 && \$colNumber == 2))
{
}

if(\$colNumber == 2 && \$rowNumber != 2)
{
#First read left to right for the first row
#Then read down on right column
#..and up on left column
}

#If more than 2 rows or columns, pick up all the edge values by spiraling around the matrix
if(\$rowNumber > 2 && \$colNumber > 2)
{
#Move left to right
#Move top to bottom
#Move right to left
#Move bottom to top
}

#Now remove these edge read values to create a new reduced matrix for the next read

}

function remove_top_row(\$matrix)
{
\$removedRow = array_shift(\$matrix);
return \$matrix;
}

function remove_right_column(\$matrix)
{
\$neededCols = count(\$matrix[0]) - 1;
\$finalMatrix = array();
for(\$i=0; \$i<count(\$matrix); \$i++) \$finalMatrix[\$i] = array_slice(\$matrix[\$i], 0, \$neededCols);
return \$finalMatrix;
}

function remove_bottom_row(\$matrix)
{
unset(\$matrix[count(\$matrix)-1]);
return \$matrix;
}

function remove_left_column(\$matrix)
{
\$neededCols = count(\$matrix[0]) - 1;
\$finalMatrix = array();
for(\$i=0; \$i<count(\$matrix); \$i++) \$finalMatrix[\$i] = array_slice(\$matrix[\$i], 1, \$neededCols);
return \$finalMatrix;
}
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Two dimensional N*N Matrix is Square matrix

Idea:

We have to traverse in four different directions to traverse like spiral. We have to traverse inside matrix once one layer of spiral is over. So total, we need 5 loops, 4 loops to traverse like spiral and 1 loop to traverse through the layers.

public void printSpiralForm(int[][] a, int length)
{

for( int i = 0 , j = length-1 ; i < j ; i++ , j-- )
{

for( int k = i ; k < j ; k++ )
{
System.out.print( a[i][k] + " " ) ;
}

for( int k = i ; k < j ; k++ )
{
System.out.print(a[k][j] + " ");
}

for( int k = j ; k > i ; k-- )
{
System.out.print(a[j][k] + " ") ;
}

for( int k = j ; k > i ; k-- )
{
System.out.print( a[k][i] + " " ) ;
}

}

if ( length % 2 == 1 )
{
System.out.println( a[ length/2 ][ length/2 ] ) ;
}

}
-