# Quicksort Algorithm causing stack overflow

SOLVED: posted in the end of THIS comment.

I keep getting this error and I can't find any explanation to why it occurs.

at java.util.Random.nextDouble(Random.java:444)
at java.lang.Math.random(Math.java:716)
at assignment6quickSort.M6.qsAlgorithm(M6.java:50)
at assignment6quickSort.M6.qsAlgorithm(M6.java:60)
at assignment6quickSort.M6.qsAlgorithm(M6.java:60)
at assignment6quickSort.M6.qsAlgorithm(M6.java:60)

I've been googling like crazy and it seems no one have had the same problem OR I'm to stupid to search for the right thing (utterly possible).

Anyway, I'm creating random numbers to find a pivot number for a generic quickSort and a couple of hours ago it worked some times but now I get this error every single time.

Please, I'm so frustrated... Hehe! What the h*ck am I doing wrong? How can this cause an overflow?

Here comes my code...

package assignment6quickSort;

import java.util.ArrayList;
import java.util.List;
import java.util.Comparator;

public class M6 {

static M6Comparator<Integer> comp = new M6Comparator<Integer>();
static Integer[] array = new Integer[20];
static ArrayList qsSorted = new ArrayList();

public static void main (String[] args) {

for (int i = 0; i < array.length; i++) {
array[i] = (int)(50 * Math.random());
}

for (int i: array) {
System.out.print(i + ", ");
}

quickSort(array, comp);
System.out.println("\n");

for (Object i: qsSorted) {
System.out.print(i + ", ");
}

}

static <T> void quickSort(T[] a, Comparator<? super T> comp) {

ArrayList<T> temp = new ArrayList<T>();
for (int i = 0; i < a.length; i++) {
}

qsSorted = qsAlgorithm(temp, comp);
}

static <T> ArrayList<T> qsAlgorithm(ArrayList<T> a, Comparator<? super T> comp) {

ArrayList<T> L = new ArrayList<T>();
ArrayList<T> G = new ArrayList<T>();

if (a.size() <= 1)
return a;
int pivot = (int)Math.random() * a.size();
T pivotValue = a.get(pivot);
for (int i = 0; i < a.size(); i++) {
if (comp.compare(a.get(i), pivotValue) == -1 || comp.compare(a.get(i), pivotValue) == 0) {
} else {
}
}

L = qsAlgorithm(L, comp);
G = qsAlgorithm(G, comp);

return L;

}

}

package assignment6quickSort;

import java.util.Comparator;

public class M6Comparator<E> implements Comparator<E> {

public int compare(E original, E other) {

return((Comparable<E>)original).compareTo(other);
}

}

### SOLUTION ###

Apparently a classic recursive overflow error. Thanks a bunch to @pst and @Marcin for the help! Here is the revision of qsAlgorithm() method:

static <T> ArrayList<T> qsAlgorithm(ArrayList<T> a, Comparator<? super T> comp) {

ArrayList<T> L = new ArrayList<T>();
ArrayList<T> P = new ArrayList<T>();
ArrayList<T> G = new ArrayList<T>();

if (a.size() <= 1)
return a;
int pivot = (int)Math.random() * a.size();
T pivotValue = a.get(pivot);
for (int i = 0; i < a.size(); i++) {
int v = comp.compare(a.get(i), pivotValue);
if (v == -1) {
} else if (v == 0) {
} else {
}
}

return concatenate(qsAlgorithm(L, comp), P, qsAlgorithm(G, comp));

}

static <T> ArrayList<T> concatenate(ArrayList<T> a, ArrayList<T> p, ArrayList<T> b) {

return a;

}
-
Are you sure that ((Comparable<E>)original).compareTo(other); is not calling itself? –  dasblinkenlight Mar 5 '13 at 18:27
Nope... I'm not sure at all. Can't say that I fully understand the comparator and generics. So... Is it calling it self? –  Patrik Bäckström Mar 5 '13 at 18:29
On a second look, no, it does not look like a call to itself. Never mind :) –  dasblinkenlight Mar 5 '13 at 18:30

You are entering recursive call too many times, until your stack overflows. The problem is that you reach a point in your main compare loop where you always add all elements to the temp array 'L', and none to 'G', so your recursive call:

L = qsAlgorithm(L, comp);

is always made with the same number of elements as the param:

ArrayList<T> a

so you never exit the recursion in line 49:

if (a.size() <= 1)
return a;

The solution would be to make an additional exit when your temp array has last 2 equal elements.

Edit: A quick and dirty fix... this is by no means efficient code. I used another 'E' collection for 'even' values and add them to the resulting list at the end.

static <T> ArrayList<T> qsAlgorithm(ArrayList<T> a, Comparator<? super T> comp) {

ArrayList<T> L = new ArrayList<T>();
ArrayList<T> E = new ArrayList<T>();
ArrayList<T> G = new ArrayList<T>();

if (a.size() <= 1)
return a;
int pivot = (int)Math.random() * a.size();
T pivotValue = a.get(pivot);
for (int i = 0; i < a.size(); i++) {
int v = comp.compare(a.get(i), pivotValue);
if (v == -1) {
} else if (v == 0) {
} else {
}
}

L = qsAlgorithm(L, comp);
G = qsAlgorithm(G, comp);

return L;

}
-
I'm not really sure of how that second exit would look. Do you mean that if an array has to identical values it should exit? –  Patrik Bäckström Mar 5 '13 at 19:06
@PatrikBäckström See en.wikipedia.org/wiki/Quicksort - note the pseudo-code concatenate(quicksort('less'), 'pivot', quicksort('greater')). For sorting sequences where many elements are expected to be the same, pivot could itself be a sequence, but it will be sufficient if it is just a single element (not included in either sub-problem). Quicksort is mostly academic anyway. –  user166390 Mar 5 '13 at 19:10
Yeah. I found a pseudo that look like this. codefor i := 0 to length[A]-1 (excluding pivot) do ... return quickSort(L) + pivotValue + quickSort(G)code and got really confused on how to concatenate the three values. That's why I ended up using L = ... and G = ... Futher more I don't really get how a.size() - 1 (length[A]-1 in pseudo) would take away my specific pivot value –  Patrik Bäckström Mar 5 '13 at 19:18
Yeah. That solution got rid of the stack overflow. I somehow mixed it a little with what @pst said with the concatenate (made a separate method for it) but now it's only showing a few of the values –  Patrik Bäckström Mar 5 '13 at 19:46

Like me, if most of you were using the out-of-place algorithm of quicksort given on wikipedia.

function quicksort('array')
if length('array') <= 1
return 'array'  // an array of zero or one elements is already sorted
select and remove a pivot value 'pivot' from 'array'
create empty lists 'less' and 'greater'
for each 'x' in 'array'
if 'x' ≤ 'pivot' then append 'x' to 'less'
else append 'x' to 'greater'
return concatenate(quicksort('less'), 'pivot', quicksort('greater')) // two recursive calls

Please notice, the line 4 says :

select and remove a pivot value 'pivot' from 'array'

remove !!! not ArrayList.get(), but ArrayList.remove() !!!

-

Random is not causing the recursion that causes the stack overflow, but it is the straw that broke the camel's back.

The previous 2-ton hay bale1:

at assignment6quickSort.M6.qsAlgorithm(M6.java:50)
at assignment6quickSort.M6.qsAlgorithm(M6.java:60)
at assignment6quickSort.M6.qsAlgorithm(M6.java:60)
at assignment6quickSort.M6.qsAlgorithm(M6.java:60)
..

1 The problem in the posed code is that the pivot is included in the recursive sub-problem. Imagine the case of input [x,x] where both values are recursively selected in the L sequence as x <= x. R will always be terminal (0 elements), but L will never be terminal (2 elements).

See Quicksort on Wikipedia and note the pseudo-code concatenate(quicksort('less'), 'pivot', quicksort('greater')). That is, the pivot element is not included in the sub-problems.

-
But the array I'm sorting have only got 20 indexes. Even if I set the pivot to alway be a.size() / 2 it gives me the error. How can it possibly go so deep that it would cause an overflow? –  Patrik Bäckström Mar 5 '13 at 18:32
Yeah... Even if I try with an array of size 3 it gives me the same error... –  Patrik Bäckström Mar 5 '13 at 18:46
Damn... That sounded way to theoretical to grasp. Honestly I can't understand what you're pointing at... /; –  Patrik Bäckström Mar 5 '13 at 19:30
Aha... Yeah I saw that in the pseudo I used and I can't understand how to concatenate two array lists like that –  Patrik Bäckström Mar 5 '13 at 19:33
Thanks @pst . This was helpful after some more reading! –  Patrik Bäckström Mar 5 '13 at 20:22
show 1 more comment

It is probably not the nextDouble function that really overflows your stack, it just so happens that you are calling it in each recursion step and therefore it is likely to be the function that reaches the limit. The real problem is that you are recursing too deep (a wrongful base case where you stop recursing, perhaps).

It looks like a.size is your variant. Make sure that a does indeed decrease with every step of your recursion.

-
Since I'm always dividing a into two parts before I call the same method I suppose it would decrease. –  Patrik Bäckström Mar 5 '13 at 18:53