This four year old project has had a new update. The original intention was to illuminate the serialization of a two-dimensional array into a one-dimensional array. This is often done through the JPEG (or MJPG) libraries. My project (or app-demo) now implements something further, (other than the 'ZigZag'-routine): 'RowMajor', 'ColumnMajor', 'Random', 'Circular', and 'DiagonalUp'.

## Introduction

The downloadable code displays a grid of changeable size, rows and columns. The grid represents a matrix of numbers ordering by zigzag. It shows zero-based number indexing from zero to rows times columns minus one. If the matrix has 8 rows and 8 columns, the number indexing is from 0 to 63. It also shows red line segments across the numbers. The problem and why I have made this program follows: "How to serialize a matrix? That is: how to cast a two-dimensional array into a one-dimentional array? The most simple solution is to do a row-major or a column-major ordering. The more difficult part is to do zigzag ordering.

## Background

The background of this problem is how e.g. image compression (JPEG) encodes and decodes blocks of frequency transformed images into a serialized stream (one-dimensional array). It is like a compromise between the row-major and column-major serialization.

## Using the Code

This code snippet takes two arguments, rows count and columns count. Then generate a tuple list of zero-based indexing. (The language is C#.) The tuple consists of `(0, 0), (0, 1), (1, 0), (2, 0), (1, 1)`

and so on...

private static Tuple<int, int>[] ZigZag(int rows, int cols)
{
Tuple<int, int>[] a = new Tuple<int, int>[rows * cols];
int p = 0;
int i = 0;
int j = 0;
a[p++] = Tuple.Create(i, j);
while (p < rows * cols)
{
if (j < cols - 1)
{
j++;
}
else
{
i++;
}
while (i < rows && j >= 0)
{
a[p++] = Tuple.Create(i, j);
i++;
j--;
}
i--;
j++;
if (i < rows - 1)
{
i++;
}
else
{
j++;
}
while (i >= 0 && j < cols)
{
a[p++] = Tuple.Create(i, j);
i--;
j++;
}
i++;
j--;
}
return a;
}

Here is the old version:

Drawing the 'ZigZag'-method:

Here is the new version:

Drawing the 'RowMajor'-method:

Drawing the 'ColumnMajor'-method:

Drawing the 'Random'-method:

Drawing the 'Circular'-method:

Drawing the 'DiagonalUp'-method:

## Points of Interest

The interesting part is to think strategic when designing the algorithm.

Test the program/problem for correctness. Find inconsistencies. Ask questions. Report errors.

## History

First designed the algorithm, tested, made sure the numbers are correct back and forth.

Then made a visual application with user interaction (buttons and checkboxes) and a grid to display the numbers and zigzag line segments.

I am sometimes very interested in software development.