# Sorting of two-dimensional array based on two parameters

The following code performs 'hierarchical' sorting of a two-dimensional matrix. Firstly, it sorts elements based on the values of `ranks`. Secondly, it takes this sorted matrix, searches elements that have the same values of `ranks`, and sorts them based on `dist`. In descending order.

Question 1: Is it possible to achieve the same result in the easier way? I tried to create a `Comparator`, but it provided incorrect result for this particular case.

Question 2: How to get indexes of unsorted elements after sorting?

``````import java.util.ArrayList;

public class Test {

public static void main(String args[]) {

ArrayList<ArrayList<Double>> values = new ArrayList<ArrayList<Double>>();

ArrayList<Double> ranks = new ArrayList<Double>();
ArrayList<Double> dist = new ArrayList<Double>();

int len = ranks.size();

ArrayList<ArrayList<Double>> sortedranks = new ArrayList<ArrayList<Double>>();

sortedranks = order(values,0,ranks.size());

boolean swapped = true;
int j = 0;
double tmp1, tmp2;
while (swapped) {
swapped = false;
j++;
for (int i = 0; i < len - j; i++) {
double val1 = sortedranks.get(0).get(i);
double val2 = sortedranks.get(0).get(i+1);
if (val1==val2) {
if (sortedranks.get(1).get(i) < sortedranks.get(1).get(i+1)) {
tmp1 = sortedranks.get(1).get(i);
tmp2 = sortedranks.get(1).get(i+1);
sortedranks.get(1).remove(i);
sortedranks.get(1).remove(i);
swapped = true;
}
}
}
}

for (int i = 0; i < len; i++) {
System.out.println("Ranks " + i + " : " + sortedranks.get(0).get(i)
+ ", Distances : " + sortedranks.get(1).get(i));
}

}

public static ArrayList<ArrayList<Double>> order(ArrayList<ArrayList<Double>> values, int i_start, int i_fin) {
boolean swapped = true;
int j = 0;
int i_rank = 0;
int i_dist = 1;
double tmp1_rank, tmp2_rank, tmp1_dist, tmp2_dist;
while (swapped) {
swapped = false;
j++;
for (int i = i_start; i < i_fin - j; i++) {
if (values.get(i_rank).get(i) < values.get(i_rank).get(i+1)) {
tmp1_rank = values.get(i_rank).get(i);
tmp2_rank = values.get(i_rank).get(i+1);
tmp1_dist = values.get(i_dist).get(i);
tmp2_dist = values.get(i_dist).get(i+1);
values.get(i_rank).remove(i);
values.get(i_rank).remove(i);
values.get(i_dist).remove(i);
values.get(i_dist).remove(i);
swapped = true;
}
}
}
return values;
}
}
``````

The code that uses Comparator (does not work for my case):

``````public class MyEntry implements Comparable<MyEntry> {

private Double rank;
private Double dist;

public MyEntry(double rank, double dist) {

this.rank = rank;
this.dist = dist;

}

public static Comparator<MyEntry> ValueComparator = new Comparator<MyEntry>() {

public int compare(MyEntry value1, MyEntry value2) {

Double rfirst = value1.rank;
Double rsecond = value2.rank;

Double dfirst = value1.dist;
Double dsecond = value2.dist;

if (rsecond != rfirst) {
return (int) (rsecond - rfirst);
}
else {
return (int) (dsecond - dfirst);
}

}

};
}
``````
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Have you tried using sorted collection. –  eatSleepCode Apr 5 '13 at 12:36
Why did your Comparator not work? I have done two-level sorts using Comparator, and they work well. Perhaps you could post that code. –  jalynn2 Apr 5 '13 at 12:37
@jalynn2: Unfortunately, I have not saved the whole code that used Comparator. Please see an update of my post. –  Klausos Klausos Apr 5 '13 at 12:42
@eatSleepCode: No. Could you please provide an example? –  Klausos Klausos Apr 5 '13 at 12:46
This is your result: Ranks 0 : 8.0, Distances : 1.9 Ranks 1 : 8.0, Distances : 1.8 Ranks 2 : 3.0, Distances : 2.8 Ranks 3 : 1.0, Distances : 2.1 What should be the output? –  eatSleepCode Apr 5 '13 at 13:04

Your Comperator approach would work, but is has a few bugs. First of all I would replace the `Double`s in `MyEntry` by `double`.

Comparing `Double` is not the same as comparing `double` For example:

``````Double a = 1.0;
Double b = 1.0;
System.out.println(a == b);
System.out.println(a.equals(b));
System.out.println(a.doubleValue()== b.doubleValue());
``````

Will return

``````false
true
true
``````

Then in the comparison you cast to `int`, but this implies flooring that data. `(int) (2 - 1.9)` will give `0` Better is to compare using `<` and return -1 or 1.

``````  public static Comparator<MyEntry> ValueComparator = new Comparator<MyEntry>() {

public int compare(MyEntry value1, MyEntry value2) {

double rfirst = value1.rank;
double rsecond = value2.rank;

double dfirst = value1.dist;
double dsecond = value2.dist;

if (rsecond != rfirst) {
return rsecond < rfirst?-1:1;
}
else if(dsecond!=dfirst){
return dsecond < dfirst ?-1:1;
}
return 0;

}
}
``````

For your second question you require an index. This could be done in two ways. First option is to include the index in `MyEntry` like this:

`````` public class MyEntry implements Comparable<MyEntry> {

private double rank;
private double dist;
private int index;
private static int nextIndex = 0;

public MyEntry(double rank, double dist) {

this.rank = rank;
this.dist = dist;
this.index = nextIndex++;

}
``````

This way you will be able to retain the index but it is not so flexible.

A more flexible approach could be to have the index in a separate array, and sort that.

``````    class IndexedArrayComparator implements Comparator<Integer>{

MyEntry[] array;

public IndexedArrayComparator(MyEntry[] entries){
this.array=entries;
}

public Integer[] createIndexes(){
Integer[] index = new Integer[array.length];
for(int i =0;i<index.length;i++){
index[i]=i;
}
return index;
}

public int compare(Integer i0, Integer i1) {
double rfirst = array[i0].rank;
double rsecond = array[i1].rank;

double dfirst = array[i0].dist;
double dsecond = array[i1].dist;

if (rsecond != rfirst) {
return rsecond > rfirst?-1:1;
}
else if(dsecond!=dfirst){
return dsecond > dfirst ?-1:1;
}
return 0;
}

}
``````

You can then use it like this:

`````` MyEntry[] entries = new MyEntry[5];
entries[0]= new MyEntry(1.1,5);
entries[1]= new MyEntry(1.1,4);
entries[2]= new MyEntry(2.1,5);
entries[3]= new MyEntry(0.1,3);
entries[4]= new MyEntry(3.1,1);

IndexedArrayComparator comp = new IndexedArrayComparator(entries);
Integer[] index = comp.createIndexes();
Arrays.sort(index,comp);
for(int i =0;i<index.length;i++){
MyEntry e = entries[index[i]];
System.out.println(String.format("%2d:r= %3.1f, d= %3.1f" ,index[i],e.rank,e.dist));
}
``````

Which will give:

`````` 3:r= 0.1, d= 3.0
1:r= 1.1, d= 4.0
0:r= 1.1, d= 5.0
2:r= 2.1, d= 5.0
4:r= 3.1, d= 1.0
``````

The second way of sorting while maintaining the index is also described here. Credits to Jon Skeet

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