# Traverse Matrix in Diagonal strips

I thought this problem had a trivial solution, couple of for loops and some fancy counters, but apparently it is rather more complicated.

So my question is, how would you write (in C) a function traversal of a square matrix in diagonal strips.

Example:

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

Would have to be traversed in the following order:

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

Each strip above is enclosed by square brackets. One of the requirements is being able to distinguish between strips. Meaning that you know when you're starting a new strip. This because there is another function that I must call for each item in a strip and then before the beginning of a new strip. Thus a solution without code duplication is ideal.

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Is this homework? –  abyx Nov 22 '09 at 16:37
No, but it is part of a problem I am trying to solve for a personal project. –  alyx Nov 22 '09 at 16:40
How is the matrix stored? –  Stephen Canon Nov 22 '09 at 16:47
As a C style single dimensional int array. –  alyx Nov 22 '09 at 16:57

Here's something you can use. Just replace the printfs with what you actually want to do.

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

int main()
{
int x[3][3] = {1, 2, 3,
4, 5, 6,
7, 8, 9};
int n = 3;
for (int slice = 0; slice < 2 * n - 1; ++slice) {
printf("Slice %d: ", slice);
int z = slice < n ? 0 : slice - n + 1;
for (int j = z; j <= slice - z; ++j) {
printf("%d ", x[j][slice - j]);
}
printf("\n");
}
return 0;
}
``````

Output:

``````Slice 0: 1
Slice 1: 2 4
Slice 2: 3 5 7
Slice 3: 6 8
Slice 4: 9
``````
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Exactly what I was looking for! Thanks. –  alyx Nov 22 '09 at 17:00
This is DRY, but not easy to follow at all –  abyx Nov 22 '09 at 17:02
Beautiful, precise logic even though it takes a while to grasp. –  Joy Dutta Nov 23 '09 at 20:49
Beautiful logic!!.. if you want to traverse the reverse side i.e, from top-right corner of the matrix, just change slice-j to (n-1)-slice-j. –  vprajan May 1 '11 at 17:12
@coder, i don't know what case didn't work for you.. did you miss the brackets ? its (n-1)-(slice-j), slice always >0.. check here: analgorithmaday.blogspot.com/2011/04/… –  vprajan May 2 '11 at 14:12
show 1 more comment

The key is to iterate every item in the first row, and from it go down the diagonal. Then iterate every item in the last column (without the first, which we stepped through in the previous step) and then go down its diagonal.

Here is source code that assumes the matrix is a square matrix (untested, translated from working python code):

``````#define N 10
void diag_step(int[][] matrix) {
for (int i = 0; i < N; i++) {
int j = 0;
int k = i;
printf("starting a strip\n");
while (j < N && i >= 0) {
printf("%d ", matrix[j][k]);
k--;
j++;
}
printf("\n");
}

for (int i = 1; i < N; i++) {
int j = N-1;
int k = i;
printf("starting a strip\n");
while (j >= 0 && k < N) {
printf("%d ", matrix[k][j]);
k++;
j--;
}
printf("\n");
}
}
``````
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I know, still trying to figure out a better way that is also readable –  abyx Nov 22 '09 at 16:56

Pseudo code:

``````N = 2 // or whatever the size of the [square] matrix
for x = 0 to N
strip = []
y = 0
repeat
x -= 1
y -= 1
until x < 0
// here to print the strip or do some' with it

// And yes, Oops, I had missed it...
// the 2nd half of the matrix...
for y = 1 to N    // Yes, start at 1 not 0, since main diagonal is done.
strip = []
x = N
repeat
x -= 1
y += 1
until x < 0
// here to print the strip or do some' with it
``````

(Assumes x indexes rows, y indexes columns, reverse these two if matrix is indexed the other way around)

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This doesn't seem to cover the second half of the matrix. –  Mark Byers Nov 22 '09 at 16:57
@Mark B Thanks for noting that! Proves that nothing is fully trivial, sloppy me! –  mjv Nov 22 '09 at 17:09

I thought this problem had a trivial solution, couple of for loops and some fancy counters

Precisely.

The important thing to notice is that if you give each item an index (i, j) then items on the same diagonal have the same value j+ni, where n is the width of your matrix. So if you iterate over the matrix in the usual way (i.e. nested loops over i and j) then you can keep track of the diagonals in an array that is addressed in the above mentioned way.

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you have to break the matrix in to upper and lower parts, and iterate each of them separately, one half row first, another column first. let us assume the matrix is n*n, stored in a vector, row first, zero base, loops are exclusive to last element.

``````for i in 0:n
for j in 0:i +1
A[i + j*(n-2)]

the other half can be done in a similar way, starting with:
for j in 1:n
for i in 0:n-j
... each step is i*(n-2) ...
``````
-

I would shift the rows like so:

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

And just iterate the columns. This can actually be done without physical shifting.

-

I would probably do something like this (apologies in advance for any index errors, haven't debugged this):

``````// Operation to be performed on each slice:
void doSomething(const int lengthOfSlice,
elementType *slice,
const int stride) {
for (int i=0; i<lengthOfSlice; ++i) {
elementType element = slice[i*stride];
// Operate on element ...
}
}

void operateOnSlices(const int n, elementType *A) {
// distance between consecutive elements of a slice in memory:
const int stride = n - 1;

// Operate on slices that begin with entries in the top row of the matrix
for (int column = 0; column < n; ++column)
doSomething(column + 1, &A[column], stride);

// Operate on slices that begin with entries in the right column of the matrix
for (int row = 1; row < n; ++row)
doSomething(n - row, &A[n*row + (n-1)], stride);
}
``````
-

// This algorithm works for matrices of all sizes. ;)

``````    int x = 0;
int y = 0;
int sub_x;
int sub_y;

while (true) {

sub_x = x;
sub_y = y;

while (sub_x >= 0 && sub_y < y_axis.size()) {

this.print(sub_x, sub_y);
sub_x--;
sub_y++;

}

if (x < x_axis.size() - 1) {

x++;

} else if (y < y_axis.size() - 1) {

y++;

} else {

break;

}

}
``````
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Thanks for not assuming that width and height would always be identical! –  sharoz Sep 29 '11 at 21:59

Let's take a look how matrix elements are indexed.

``````(0,0)   (0,1)   (0,2)   (0,3)   (0,4)
(1,0)   (1,1)   (1,2)   (1,3)   (1,4)
(2,0)   (2,1)   (2,2)   (2,3)   (2,4)
``````

Now, let's take a look at the stripes:

``````Stripe 1: (0,0)
Stripe 2: (0,1)    (1,0)
Stripe 3: (0,2)    (1,1)    (2,0)
Stripe 4: (0,3)    (1,2)    (2,1)
Stripe 5: (0,4)    (1,3)    (2,2)
Stripe 6: (1,4)    (2,3)
Stripe 7: (2,4)
``````

If you take a closer look, you'll notice one thing. The sum of indexes of each matrix element in each stripe is constant. So, here's the code that does this.

``````public static void printSecondaryDiagonalOrder(int[][] matrix) {
int rows = matrix.length;
int cols = matrix[0].length;
int maxSum = rows + cols - 2;

for (int sum = 0; sum <= maxSum; sum++) {
for (int i = 0; i < rows; i++) {
for (int j = 0; j < cols; j++) {
if (i + j - sum == 0) {
System.out.print(matrix[i][j] + "\t");
}
}
}
System.out.println();
}
}
``````

It's not the fastest algorithm out there (does(rows * cols * (rows+cols-2)) operations), but the logic behind it is quite simple.

-

Just in case somebody needs to do this in python, it is very easy using numpy:

``````#M is a square numpy array
for i in range(-M.shape[0]+1, M.shape[0]):
print M.diagonal(offset=i)
``````
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``````static int[][] arr = {{ 1, 2, 3, 4},
{ 5, 6, 7, 8},
{ 9,10,11,12},
{13,14,15,16} };

public static void main(String[] args) {
for (int i = 0; i < arr.length; i++) {
for (int j = 0; j < i+1; j++) {
System.out.print(arr[j][i-j]);
System.out.print(",");
}
System.out.println();
}

for (int i = 1; i < arr.length; i++) {
for (int j = 0; j < arr.length-i; j++) {
System.out.print(arr[i+j][arr.length-j-1]);
System.out.print(",");
}
System.out.println();
}
}
``````
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