# How do you rotate a two dimensional array?

Inspired by Raymond Chen's post, say you have a 4x4 two dimensional array, write a function that rotates it 90 degrees. Raymond links to a solution in pseudo code, but I'd like to see some real world stuff.

``````[1][2][3][4]
[5][6][7][8]
[9][0][1][2]
[3][4][5][6]
``````

Becomes:

``````[3][9][5][1]
[4][0][6][2]
[5][1][7][3]
[6][2][8][4]
``````

Update: Nick's answer is the most straightforward, but is there a way to do it better than n^2? What if the matrix was 10000x10000?

-
How could you possibly get away with less than n^2? All elements must be read and set, and there are n^2 elements –  erikkallen Mar 14 '09 at 19:06
My solution below has O(1) memory and O(1) time performance: stackoverflow.com/questions/42519/… –  Drew Noakes May 11 '09 at 16:19
–  Marco van de Voort May 15 '09 at 6:32
The point of asking this question (in Raymond's story) was just to make sure the candidate had a certain set of baseline abilities. The n^2 solution is just fine. –  jeffamaphone Nov 3 '09 at 14:52
What is your n? You don't say if the 2D array is square (it's not in the general case! e.g a vector is a matrix with one dimension of 1), yet you seem to imply that n is the width and height, and have therefore n² elements. It would make more sense to have n be the number of elements, with n=w×h. –  niXar Jan 6 '10 at 22:34
show 5 more comments

Here it is in C#

``````int[,] array = new int[4,4] {
{ 1,2,3,4 },
{ 5,6,7,8 },
{ 9,0,1,2 },
{ 3,4,5,6 }
};

int[,] rotated = RotateMatrix(array, 4);

static int[,] RotateMatrix(int[,] matrix, int n) {
int[,] ret = new int[n, n];

for (int i = 0; i < n; ++i) {
for (int j = 0; j < n; ++j) {
ret[i, j] = matrix[n - j - 1, i];
}
}

return ret;
}
``````
-
Sure, but what about a solution using O(1) memory? –  AlexeyMK Sep 7 '08 at 17:51
My solution below has O(1) memory and O(1) time performance: stackoverflow.com/questions/42519/… –  Drew Noakes May 8 '09 at 18:09
Your solution has O(n^2) space complexity. Need to do better –  Kshitij Jain Oct 6 at 3:54

Python:

``````rotated = zip(*original[::-1])
``````

Cheap, I know.

And counterclockwise:

``````rotated_ccw = zip(*original)[::-1]
``````
-
I believe this code originates from Peter Norvig: norvig.com/python-iaq.html –  Josip Jul 7 '09 at 14:43
Shiiiiii* gotta learn Python. –  Camilo Martin Dec 28 '09 at 2:43
Is there an easy way to rotate counterclockwise using this, other than running it three times? –  Amyunimus Feb 23 '12 at 16:11
@Amyunimus: Yes, I've included the code for that as well. –  recursive Feb 23 '12 at 16:27
The same as Ruby, but 26 more votes, hmmm... UPD: ah, didn't look at answer timestamp. –  Nakilon Sep 9 '12 at 19:02

O(n^2) time and O(1) space algorithm ( without any workarounds and hanky-panky stuff! )

Rotate by +90:

1. Transpose
2. Reverse each row

Rotate by -90:

1. Transpose
2. Reverse each column

Rotate by +180:

Method 1: Rotate by +90 twice

Method 2: Reverse each row and then reverse each column

Rotate by -180:

Method 1: Rotate by -90 twice

Method 2: Reverse each column and then reverse each row

Method 3: Reverse by +180 as they are same

-
This was very helpful for me; I was able to write an algorithm once I knew the "[pseudo-]code version" of this operation. Thanks! –  duma Nov 16 '12 at 15:49
One of my favorite SO answers of all time. Very instructive! –  g33kz0r Apr 4 at 2:49
The Best answer ever.. –  Spandan Jun 2 at 15:53
I like this. Thanks. :) –  khalafnt Dec 3 at 15:36

As I said in my previous post, here's some code in C# that implements an O(1) matrix rotation for any size matrix. For brevity and readability there's no error checking or range checking. The code:

``````static void Main (string [] args)
{
int [,]
//  create an arbitrary matrix
m = {{0, 1}, {2, 3}, {4, 5}};

Matrix
//  create wrappers for the data
m1 = new Matrix (m),
m2 = new Matrix (m),
m3 = new Matrix (m);

//  rotate the matricies in various ways - all are O(1)
m1.RotateClockwise90 ();
m2.Rotate180 ();
m3.RotateAnitclockwise90 ();

//  output the result of transforms
System.Diagnostics.Trace.WriteLine (m1.ToString ());
System.Diagnostics.Trace.WriteLine (m2.ToString ());
System.Diagnostics.Trace.WriteLine (m3.ToString ());
}

class Matrix
{
enum Rotation
{
None,
Clockwise90,
Clockwise180,
Clockwise270
}

public Matrix (int [,] matrix)
{
m_matrix = matrix;
m_rotation = Rotation.None;
}

//  the transformation routines
public void RotateClockwise90 ()
{
m_rotation = (Rotation) (((int) m_rotation + 1) & 3);
}

public void Rotate180 ()
{
m_rotation = (Rotation) (((int) m_rotation + 2) & 3);
}

public void RotateAnitclockwise90 ()
{
m_rotation = (Rotation) (((int) m_rotation + 3) & 3);
}

//  accessor property to make class look like a two dimensional array
public int this [int row, int column]
{
get
{
int
value = 0;

switch (m_rotation)
{
case Rotation.None:
value = m_matrix [row, column];
break;

case Rotation.Clockwise90:
value = m_matrix [m_matrix.GetUpperBound (0) - column, row];
break;

case Rotation.Clockwise180:
value = m_matrix [m_matrix.GetUpperBound (0) - row, m_matrix.GetUpperBound (1) - column];
break;

case Rotation.Clockwise270:
value = m_matrix [column, m_matrix.GetUpperBound (1) - row];
break;
}

return value;
}

set
{
switch (m_rotation)
{
case Rotation.None:
m_matrix [row, column] = value;
break;

case Rotation.Clockwise90:
m_matrix [m_matrix.GetUpperBound (0) - column, row] = value;
break;

case Rotation.Clockwise180:
m_matrix [m_matrix.GetUpperBound (0) - row, m_matrix.GetUpperBound (1) - column] = value;
break;

case Rotation.Clockwise270:
m_matrix [column, m_matrix.GetUpperBound (1) - row] = value;
break;
}
}
}

//  creates a string with the matrix values
public override string ToString ()
{
int
num_rows = 0,
num_columns = 0;

switch (m_rotation)
{
case Rotation.None:
case Rotation.Clockwise180:
num_rows = m_matrix.GetUpperBound (0);
num_columns = m_matrix.GetUpperBound (1);
break;

case Rotation.Clockwise90:
case Rotation.Clockwise270:
num_rows = m_matrix.GetUpperBound (1);
num_columns = m_matrix.GetUpperBound (0);
break;
}

StringBuilder
output = new StringBuilder ();

output.Append ("{");

for (int row = 0 ; row <= num_rows ; ++row)
{
if (row != 0)
{
output.Append (", ");
}

output.Append ("{");

for (int column = 0 ; column <= num_columns ; ++column)
{
if (column != 0)
{
output.Append (", ");
}

output.Append (this [row, column].ToString ());
}

output.Append ("}");
}

output.Append ("}");

return output.ToString ();
}

int [,]
//  the original matrix
m_matrix;

Rotation
//  the current view of the matrix
m_rotation;
}
``````

OK, I'll put my hand up, it doesn't actually do any modifications to the original array when rotating. But, in an OO system that doesn't matter as long as the object looks like it's been rotated to the clients of the class. At the moment, the Matrix class uses references to the original array data so changing any value of m1 will also change m2 and m3. A small change to the constructor to create a new array and copy the values to it will sort that out.

-
Bravo! This is a very nice solution and I don't know why it isn't the accepted answer. –  martinatime Sep 14 '08 at 16:11
@martinatime: perhaps because it is 5 times as big –  Toad Oct 4 '10 at 17:59
@Toad: Well, writing code is always a trade off between competing requirements: speed, size, cost, etc. –  Skizz Oct 4 '10 at 20:34
true... another problem is the fact that the matrix is in fact not rotated, but is rotated 'just in time'. Which is great for accessing a few elements, but would be horrible if this matrix was used in calculations or image manipulations. So saying O(1) is not really fair. –  Toad Oct 5 '10 at 11:17

Here is one that does the rotation in place instead of using a completely new array to hold the result. I've left off initialization of the array and printing it out. This only works for square arrays but they can be of any size. Memory overhead is equal to the size of one element of the array so you can do the rotation of as large an array as you want. (code is C++)

``````int a[4][4];
int n=4;
int tmp;
for (int i=0; i<n/2; i++){
for (int j=i; j<n-i-1; j++){
tmp=a[i][j];
a[i][j]=a[j][n-i-1];
a[j][n-i-1]=a[n-i-1][n-j-1];
a[n-i-1][n-j-1]=a[n-j-1][i];
a[n-j-1][i]=tmp;
}
}
``````
-
I can see at least one bug. If you're going to post code, test it or at least say you haven't done so. –  Hugh Allen Oct 1 '08 at 7:12
Where? Point it out and I'll fix it. I did test it and it worked fine on both odd and even sized arrays. –  dagorym Oct 4 '08 at 1:29
Just from looking: The second loop starts tests j < -i-1. It looks like j is always >= 0 and -i-1 is always negative, so the test never passes. –  Eyal May 7 '09 at 21:32
You're right. That's strange. I believe there is supposed to be an n in there that I left out when I posted it. Fixed it in the listing. –  dagorym May 8 '09 at 14:57
It's not O(1); it's still O(n^2) –  duma Nov 16 '12 at 15:39
show 3 more comments

Whilst rotating the data in place might be necessary (perhaps to update the physically stored representation), it becomes simpler and possibly more performant to add a layer of indirection onto the array access, perhaps an interface:

``````interface IReadableMatrix
{
int GetValue(int x, int y);
}
``````

If your `Matrix` already implements this interface, then it can be rotated via a decorator class like this:

``````class RotatedMatrix : IReadableMatrix
{

{
_baseMatrix = baseMatrix;
}

int GetValue(int x, int y)
{
// transpose x and y dimensions
return _baseMatrix(y, x);
}
}
``````

Rotating +90/-90/180 degrees, flipping horizontally/vertically and scaling can all be achieved in this fashion as well.

Performance would need to be measured in your specific scenario. However the O(n^2) operation has now been replaced with an O(1) call. It's a virtual method call which is slower than direct array access, so it depends upon how frequently the rotated array is used after rotation. If it's used once, then this approach would definitely win. If it's rotated then used in a long-running system for days, then in-place rotation might perform better. It also depends whether you can accept the up-front cost.

As with all performance issues, measure, measure, measure!

-
+1... I was going to add this O(1) solution. –  Mark Pattison May 8 '09 at 15:07
It seems a little unfair to call this an O(1) time solution. To solve the problem posed by the OP this will still take O(n^2) time. Not only that, it wouldn't solve the problem because it returns the transpose. The example given doesn't have the transpose as the solution. –  Vlad the Impala Apr 20 '10 at 4:32
Now, if all you wanted was the first 3 elements of the matrix, this is a fine solution, but the problem is to retrieve a completely transformed matrix (i.e. assuming you need all the matrix elements). Calling this O(1) is the Credit Default Swap method of Algorithm Analysis - you haven't solved the problem, you've just pushed it to someone else :) –  Paul Betts Jun 29 '10 at 23:31
@Paul Betts: I get your point, but like I wrote above in the comments, even if you actually have the matrix transposed you still have to write the loop if you want to read the values out. So reading all values from a matrix is always O(N^2) regardless. The difference here is that if you transpose, rotate, scale, scale again, etc, then you still only take the O(N^2) hit once. Like I said, this isn't always the best solution, but in many cases it's appropriate and worthwhile. The OP seemed to be looking for a magic solution, and this is as close as you'll get. –  Drew Noakes Jun 30 '10 at 4:29
I like this answer, but I want to point something out. Printing out the decorated matrix (and doing other sequential reads in general) may be much slower than doing the same to a matrix that's been rotated in memory, and it's not just because of virtual method calls. For a big matrix, you're going to vastly increase the number of cache misses you get by reading "down" rather than "across". –  Mike Daniels Oct 4 '10 at 18:23
show 15 more comments

A couple of people have already put up examples which involve making a new array.

A few other things to consider:

(a) Instead of actually moving the data, simply traverse the "rotated" array differently.

(b) Doing the rotation in-place can be a little trickier. You'll need a bit of scratch place (probably roughly equal to one row or column in size). There's an ancient ACM paper about doing in-place transposes (http://doi.acm.org/10.1145/355719.355729), but their example code is nasty goto-laden FORTRAN.

http://doi.acm.org/10.1145/355611.355612 is another, supposedly superior, in-place transpose algorithm.

-
I agree with this. Have a method that determine the translation between the source data and the "rotated" data. –  martinatime Sep 14 '08 at 16:07

Ruby-way: `.transpose.map &:reverse`

-

This a better version of it in Java: I've made it for a matrix with a different width and height

• h is here the height of the matrix after rotating
• w is here the width of the matrix after rotating

``````public int[][] rotateMatrixRight(int[][] matrix)
{
/* W and H are already swapped */
int w = matrix.length;
int h = matrix[0].length;
int[][] ret = new int[h][w];
for (int i = 0; i < h; ++i) {
for (int j = 0; j < w; ++j) {
ret[i][j] = matrix[w - j - 1][i];
}
}
return ret;
}

public int[][] rotateMatrixLeft(int[][] matrix)
{
/* W and H are already swapped */
int w = matrix.length;
int h = matrix[0].length;
int[][] ret = new int[h][w];
for (int i = 0; i < h; ++i) {
for (int j = 0; j < w; ++j) {
ret[i][j] = matrix[j][h - i - 1];
}
}
return ret;
}
``````

This code is based on Nick Berardi's post.

-

Here's my Ruby version (note the values aren't displayed the same, but it still rotates as described).

``````def rotate(matrix)
result = []
4.times { |x|
result[x] = []
4.times { |y|
result[x][y] = matrix[y][3 - x]
}
}

result
end

matrix = []
matrix[0] = [1,2,3,4]
matrix[1] = [5,6,7,8]
matrix[2] = [9,0,1,2]
matrix[3] = [3,4,5,6]

def print_matrix(matrix)
4.times { |y|
4.times { |x|
print "#{matrix[x][y]} "
}
puts ""
}
end

print_matrix(matrix)
puts ""
print_matrix(rotate(matrix))
``````

The output:

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

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

Nick's answer would work for an NxM array too with only a small modification (as opposed to an NxN).

``````string[,] orig = new string[n, m];
string[,] rot = new string[m, n];

...

for ( int i=0; i < n; i++ )
for ( int j=0; j < m; j++ )
rot[j, n - i - 1] = orig[i, j];
``````

One way to think about this is that you have moved the center of the axis (0,0) from the top left corner to the top right corner. You're simply transposing from one to the other.

-

PHP:

``````<?php
\$a = array(array(1,2,3,4),array(5,6,7,8),array(9,0,1,2),array(3,4,5,6));
\$b = array(); //result

while(count(\$a)>0)
{
\$b[count(\$a[0])-1][] = array_shift(\$a[0]);
if (count(\$a[0])==0)
{
array_shift(\$a);
}
}
?>
``````
-

here's a in-space rotate method, by java, only for square. for non-square 2d array, you will have to create new array anyway.

``````private void rotateInSpace(int[][] arr) {
int z = arr.length;
for (int i = 0; i < z / 2; i++) {
for (int j = 0; j < (z / 2 + z % 2); j++) {
int x = i, y = j;
int temp = arr[x][y];
for (int k = 0; k < 4; k++) {
int temptemp = arr[y][z - x - 1];
arr[y][z - x - 1] = temp;
temp = temptemp;

int tempX = y;
y = z - x - 1;
x = tempX;
}
}
}
}
``````

code to rotate any size 2d array by creating new array:

``````private int[][] rotate(int[][] arr) {
int width = arr[0].length;
int depth = arr.length;
int[][] re = new int[width][depth];
for (int i = 0; i < depth; i++) {
for (int j = 0; j < width; j++) {
re[j][depth - i - 1] = arr[i][j];
}
}
return re;
}
``````
-

```For i:= 0 to X do For j := 0 to X do graphic[j][i] := graphic2[X-i][j]```

X is the size of the array the graphic is in.

-

#transpose is a standard method of Ruby's Array class, thus:

``````% irb
irb(main):001:0> m = [[1, 2, 3, 4], [5, 6, 7, 8], [9, 0, 1, 2], [3, 4, 5, 6]]
=> [[1, 2, 3, 4], [5, 6, 7, 8], [9, 0, 1, 2], [3, 4, 5, 6]]
irb(main):002:0> m.reverse.transpose
=> [[3, 9, 5, 1], [4, 0, 6, 2], [5, 1, 7, 3], [6, 2, 8, 4]]
``````

The implementation is an n^2 transposition function written in C. You can see it here: http://www.ruby-doc.org/core-1.9.3/Array.html#method-i-transpose by choosing "click to toggle source" beside "transpose".

I recall better than O(n^2) solutions, but only for specially constructed matrices (such as sparse matrices)

-

This is my implementation, in C, O(1) memory complexity, in place rotation, 90 degrees clockwise:

``````#include <stdio.h>

#define M_SIZE 5

static void initMatrix();
static void printMatrix();
static void rotateMatrix();

static int m[M_SIZE][M_SIZE];

int main(void){
initMatrix();
printMatrix();
rotateMatrix();
printMatrix();

return 0;
}

static void initMatrix(){
int i, j;

for(i = 0; i < M_SIZE; i++){
for(j = 0; j < M_SIZE; j++){
m[i][j] = M_SIZE*i + j + 1;
}
}
}

static void printMatrix(){
int i, j;

printf("Matrix\n");
for(i = 0; i < M_SIZE; i++){
for(j = 0; j < M_SIZE; j++){
printf("%02d ", m[i][j]);
}
printf("\n");
}
printf("\n");
}

static void rotateMatrix(){
int r, c;

for(r = 0; r < M_SIZE/2; r++){
for(c = r; c < M_SIZE - r - 1; c++){
int tmp = m[r][c];

m[r][c] = m[M_SIZE - c - 1][r];
m[M_SIZE - c - 1][r] = m[M_SIZE - r - 1][M_SIZE - c - 1];
m[M_SIZE - r - 1][M_SIZE - c - 1] = m[c][M_SIZE - r - 1];
m[c][M_SIZE - r - 1] = tmp;
}
}
}
``````
-

C code for matrix rotation 90 degree clockwise IN PLACE for any M*N matrix

``````void rotateInPlace(int * arr[size][size], int row, int column){
int i, j;
int temp = row>column?row:column;
int flipTill = row < column ? row : column;
for(i=0;i<flipTill;i++){
for(j=0;j<i;j++){
swapArrayElements(arr, i, j);
}
}

temp = j+1;

for(i = row>column?i:0; i<row; i++){
for(j=row<column?temp:0; j<column; j++){
swapArrayElements(arr, i, j);
}
}

for(i=0;i<column;i++){
for(j=0;j<row/2;j++){
temp = arr[i][j];
arr[i][j] = arr[i][row-j-1];
arr[i][row-j-1] = temp;
}
}
}
``````
-

here is my In Place implementation in C

``````void rotateRight(int matrix[][SIZE], int length) {

int layer = 0;

for (int layer = 0; layer < length / 2; ++layer) {

int first = layer;
int last = length - 1 - layer;

for (int i = first; i < last; ++i) {

int topline = matrix[first][i];
int rightcol = matrix[i][last];
int bottomline = matrix[last][length - layer - 1 - i];
int leftcol = matrix[length - layer - 1 - i][first];

matrix[first][i] = leftcol;
matrix[i][last] = topline;
matrix[last][length - layer - 1 - i] = rightcol;
matrix[length - layer - 1 - i][first] = bottomline;
}
}
}
``````
-

Here is the Java version:

``````public static void rightRotate(int[][] matrix, int n) {
for (int layer = 0; layer < n / 2; layer++) {
int first = layer;
int last = n - 1 - first;
for (int i = first; i < last; i++) {
int offset = i - first;
int temp = matrix[first][i];
matrix[first][i] = matrix[last-offset][first];
matrix[last-offset][first] = matrix[last][last-offset];
matrix[last][last-offset] = matrix[i][last];
matrix[i][last] = temp;
}
}
}
``````

the method first rotate the mostouter layer, then move to the inner layer squentially.

-

There are tons of good code here but I just want to show what's going on geometrically so you can understand the code logic a little better. Here is how I would approach this.

first of all, do not confuse this with transposition which is very easy..

the basica idea is to treat it as layers and we rotate one layer at a time..

say we have a 4x4

``````1   2   3   4
5   6   7   8
9   10  11  12
13  14  15  16
``````

after we rotate it clockwise by 90 we get

``````13  9   5   1
14  10  6   2
15  11  7   3
16  12  8   4
``````

so let's decompose this, first we rotate the 4 corners essentially

``````1           4

13          16
``````

then we rotate the following diamond which is sort of askew

``````    2
8
9
15
``````

and then the 2nd skewed diamond

``````        3
5
12
14
``````

so that takes care of the outer edge so essentially we do that one shell at a time until

finally the middle square (or if it's odd just the final element which does not move)

``````6   7
10  11
``````

so now let's figure out the indices of each layer, assume we always work with the outermost layer, we are doing

``````[0,0] -> [0,n-1], [0,n-1] -> [n-1,n-1], [n-1,n-1] -> [n-1,0], and [n-1,0] -> [0,0]
[0,1] -> [1,n-1], [1,n-2] -> [n-1,n-2], [n-1,n-2] -> [n-2,0], and [n-2,0] -> [0,1]
[0,2] -> [2,n-2], [2,n-2] -> [n-1,n-3], [n-1,n-3] -> [n-3,0], and [n-3,0] -> [0,2]
``````

so on and so on until we are halfway through the edge

so in general the pattern is

``````[0,i] -> [i,n-i], [i,n-i] -> [n-1,n-(i+1)], [n-1,n-(i+1)] -> [n-(i+1),0], and [n-(i+1),0] to [0,i]
``````
-

The O(1) memory algorithm:

1. rotate the outer-most data, then you can get below result:

``````[3][9][5][1]
[4][6][7][2]
[5][0][1][3]
[6][2][8][4]
``````

To do this rotation, we know

``````    dest[j][n-1-i] = src[i][j]
``````

Observe below: a(0,0) -> a(0,3) a(0,3) -> a(3,3) a(3,3) -> a(3,0) a(3,0) -> a(0,0)

Therefore it's a circle, you can rotate N elements in one loop. Do this N-1 loop then you can rotate the outer-most elements.

1. Now you can the inner is a same question for 2X2.

Therefore we can conclude it like below:

``````function rotate(array, N)
{
Rotate outer-most data
rotate a new array with N-2 or you can do the similar action following step1
}
``````
-

Here is my attempt for matrix 90 deg rotation which is a 2 step solution in C. First transpose the matrix in place and then swap the cols.

``````#define ROWS        5
#define COLS        5

void print_matrix_b(int B[][COLS], int rows, int cols)
{
for (int i = 0; i <= rows; i++) {
for (int j = 0; j <=cols; j++) {
printf("%d ", B[i][j]);
}
printf("\n");
}
}

void swap_columns(int B[][COLS], int l, int r, int rows)
{
int tmp;
for (int i = 0; i <= rows; i++) {
tmp = B[i][l];
B[i][l] = B[i][r];
B[i][r] = tmp;
}
}

void matrix_2d_rotation(int B[][COLS], int rows, int cols)
{
int tmp;
// Transpose the matrix first
for (int i = 0; i <= rows; i++) {
for (int j = i; j <=cols; j++) {
tmp = B[i][j];
B[i][j] = B[j][i];
B[j][i] = tmp;
}
}
// Swap the first and last col and continue until
// the middle.
for (int i = 0; i < (cols / 2); i++)
swap_columns(B, i, cols - i, rows);
}

int _tmain(int argc, _TCHAR* argv[])
{
int B[ROWS][COLS] = {
{1, 2, 3, 4, 5},
{6, 7, 8, 9, 10},
{11, 12, 13, 14, 15},
{16, 17, 18, 19, 20},
{21, 22, 23, 24, 25}
};

matrix_2d_rotation(B, ROWS - 1, COLS - 1);

print_matrix_b(B, ROWS - 1, COLS -1);
return 0;
}
``````
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``````#include <iostream>
#include <iomanip>

using namespace std;
const int SIZE=3;
void print(int a[][SIZE],int);
void rotate(int a[][SIZE],int);

void main()
{
int a[SIZE][SIZE]={{11,22,33},{44,55,66},{77,88,99}};
cout<<"the array befor rotate\n";

print(a,SIZE);
rotate( a,SIZE);
cout<<"the array after rotate\n";
print(a,SIZE);
cout<<endl;

}

void print(int a[][SIZE],int SIZE)
{
int i,j;
for(i=0;i<SIZE;i++)
for(j=0;j<SIZE;j++)
cout<<a[i][j]<<setw(4);
}

void rotate(int a[][SIZE],int SIZE)
{
int temp[3][3],i,j;
for(i=0;i<SIZE;i++)
for(j=0;j<SIZE/2.5;j++)
{
temp[i][j]= a[i][j];
a[i][j]= a[j][SIZE-i-1] ;
a[j][SIZE-i-1] =temp[i][j];

}
}
``````
-

@dagorym: Aw, man. I had been hanging onto this as a good "I'm bored, what can I ponder" puzzle. I came up with my in-place transposition code, but got here to find yours pretty much identical to mine...ah, well. Here it is in Ruby.

``````require 'pp'
n = 10
a = []
n.times { a << (1..n).to_a }

pp a

0.upto(n/2-1) do |i|
i.upto(n-i-2) do |j|
tmp             = a[i][j]
a[i][j]         = a[n-j-1][i]
a[n-j-1][i]     = a[n-i-1][n-j-1]
a[n-i-1][n-j-1] = a[j][n-i-1]
a[j][n-i-1]     = tmp
end
end

pp a
``````
-
``````short normal[4][4] = {{8,4,7,5},{3,4,5,7},{9,5,5,6},{3,3,3,3}};

short rotated[4][4];

for (int r = 0; r < 4; ++r)
{
for (int c = 0; c < 4; ++c)
{
rotated[r][c] = normal[c][3-r];
}
}
``````

Simple C++ method, tho there would be a big memory overhead in a big array.

-

All the current solutions have O(n^2) overhead as scratch space (this excludes those filthy OOP cheaters!). Here's a solution with O(1) memory usage, rotating the matrix in-place 90 degress right. Screw extensibility, this sucker runs fast!

``````#include <algorithm>
#include <cstddef>

// Rotates an NxN matrix of type T 90 degrees to the right.
template <typename T, size_t N>
void rotate_matrix(T (&matrix)[N][N])
{
for(size_t i = 0; i < N; ++i)
for(size_t j = 0; j <= (N-i); ++j)
std::swap(matrix[i][j], matrix[j][i]);
}
``````

DISCLAIMER: I didn't actually test this. Let's play whack-a-bug!

-
Doesn't this just transpose the matrix, not rotate it? –  recursive Oct 5 '11 at 13:39

Implementation of dimple's +90 pseudocode (e.g. transpose then reverse each row) in JavaScript:

``````function rotate90(a){
// transpose from http://www.codesuck.com/2012/02/transpose-javascript-array-in-one-line.html
a = Object.keys(a[0]).map(function (c) { return a.map(function (r) { return r[c]; }); });
// row reverse
for (i in a){
a[i] = a[i].reverse();
}
return a;
}
``````
-
``````private static int[][] rotate(int[][] matrix, int n) {
int[][] rotated = new int[n][n];
for (int i = 0; i < n; i++) {
for (int j = 0; j < n; j++) {
rotated[i][j] = matrix[n-j-1][i];
}
}
return rotated;
}
``````
-
Which language is this in? –  Don Cruickshank Aug 2 at 9:44

It is not possible to do it quicker than O(n^2) for in place rotation, for the reason that if we want to rotate the matrix, we have to touch all the n^2 element at least once, no matter what algorithm you are implementing.

-