# Slow implementation of famous compression algorithm (LZ78)

I'm writing a method which approximates the Kolmogorov complexity of a String by following the LZ78 algorithm, except instead of adding to a table I just keep a counter i.e i'm only interested in the size of the compression.

The problem is that for large inputs it is taking hours. Is it the way I have implemented it?

``````/**
* Uses the LZ78 compression algorithm to approximate the Kolmogorov
* complexity of a String
*
* @param s
* @return the approximate Kolmogorov complexity
*/
public double kComplexity(String s) {

ArrayList<String> dictionary = new ArrayList<String>();
StringBuilder w = new StringBuilder();
double comp = 0;
for (int i = 0; i < s.length(); i++) {
char c = s.charAt(i);
if (dictionary.contains(w.toString() + c)) {
w.append(c);
} else {
comp++;
w = new StringBuilder();
}
}
if (w.length() != 0) {
comp++;
}

return comp;
}
``````

UPDATE: Using

``````HashSet<String> dictionary = new HashSet<String>();
``````

``````ArrayList<String> dictionary = new ArrayList<String>();
``````

makes it much faster

-
Number one problem is the ArrayList<String> - you compare the string in question against every string in the list. That's horribly slow. You could instead store a pair <string, hash of that string> and first search by that hash and only if match by hash is found compare the string for equality. –  sharptooth Jul 15 '09 at 10:22

I think I can do better (sorry a bit long):

``````import java.io.File;
import java.io.FileInputStream;
import java.util.HashMap;
import java.util.HashSet;
import java.util.Map;
import java.util.Set;
import java.util.concurrent.ExecutorService;
import java.util.concurrent.Executors;

public class LZ78 {
/**
* Uses the LZ78 compression algorithm to approximate the Kolmogorov
* complexity of a String
*
* @param s
* @return the approximate Kolmogorov complexity
*/
public static double kComplexity(String s) {
Set<String> dictionary = new HashSet<String>();
StringBuilder w = new StringBuilder();
double comp = 0;
for (int i = 0; i < s.length(); i++) {
char c = s.charAt(i);
if (dictionary.contains(w.toString() + c)) {
w.append(c);
} else {
comp++;
w = new StringBuilder();
}
}
if (w.length() != 0) {
comp++;
}
return comp;
}

private static boolean equal(Object o1, Object o2) {
return o1 == o2 || (o1 != null && o1.equals(o2));
}

public static final class FList<T> {
public final T tail;
private final int hashCodeValue;

public FList(FList<T> head, T tail) {
this.tail = tail;
hashCodeValue = v * 31 + (tail != null ? tail.hashCode() : 0);
}

@Override
public boolean equals(Object obj) {
if (obj instanceof FList<?>) {
FList<?> that = (FList<?>) obj;
&& equal(this.tail, that.tail);
}
return false;
}

@Override
public int hashCode() {
return hashCodeValue;
}

@Override
public String toString() {
return head + ", " + tail;
}
}

public static final class FListChar {
public final char tail;
private final int hashCodeValue;

public FListChar(FListChar head, char tail) {
this.tail = tail;
hashCodeValue = v * 31 + tail;
}

@Override
public boolean equals(Object obj) {
if (obj instanceof FListChar) {
FListChar that = (FListChar) obj;
}
return false;
}

@Override
public int hashCode() {
return hashCodeValue;
}

@Override
public String toString() {
return head + ", " + tail;
}
}

public static double kComplexity2(String s) {
Map<FList<Character>, FList<Character>> dictionary =
new HashMap<FList<Character>, FList<Character>>();
FList<Character> w = null;
double comp = 0;
for (int i = 0; i < s.length(); i++) {
char c = s.charAt(i);
FList<Character> w1 = new FList<Character>(w, c);
FList<Character> ex = dictionary.get(w1);
if (ex != null) {
w = ex;
} else {
comp++;
dictionary.put(w1, w1);
w = null;
}
}
if (w != null) {
comp++;
}
return comp;
}

public static double kComplexity3(String s) {
Map<FListChar, FListChar> dictionary =
new HashMap<FListChar, FListChar>(1024);
FListChar w = null;
double comp = 0;
for (int i = 0; i < s.length(); i++) {
char c = s.charAt(i);
FListChar w1 = new FListChar(w, c);
FListChar ex = dictionary.get(w1);
if (ex != null) {
w = ex;
} else {
comp++;
dictionary.put(w1, w1);
w = null;
}
}
if (w != null) {
comp++;
}
return comp;
}

public static void main(String[] args) throws Exception {
File f = new File("methods.txt");
byte[] data = new byte[(int) f.length()];
FileInputStream fin = new FileInputStream(f);
fin.close();
final String test = new String(data, 0, len);

final int n = 100;
exec.submit(new Runnable() {
@Override
public void run() {
long t = System.nanoTime();
double value = 0;
for (int i = 0; i < n; i++) {
value += kComplexity(test);
}
System.out.printf("kComplexity: %.3f; Time: %d ms%n",
value / n, (System.nanoTime() - t) / 1000000);
}
});
exec.submit(new Runnable() {
@Override
public void run() {
long t = System.nanoTime();
double value = 0;
for (int i = 0; i < n; i++) {
value += kComplexity2(test);
}
System.out.printf("kComplexity2: %.3f; Time: %d ms%n", value
/ n, (System.nanoTime() - t) / 1000000);
}
});
exec.submit(new Runnable() {
@Override
public void run() {
long t = System.nanoTime();
double value = 0;
for (int i = 0; i < n; i++) {
value += kComplexity3(test);
}
System.out.printf("kComplexity3: %.3f; Time: %d ms%n", value
/ n, (System.nanoTime() - t) / 1000000);
}
});
exec.shutdown();
}
}
``````

Results:

```kComplexity: 41546,000; Time: 17028 ms
kComplexity2: 41546,000; Time: 6555 ms
kComplexity3: 41546,000; Time: 5971 ms```

Edit Peer pressure: How does it work?

Franky, have no idea, it just seemed to be a good way to speed up things. I have to figure it out too, so here we go.

It was an observation that the original code made lot of string appends, however, replacing it with a `LinkedList<String>` wouldn't help as there is a constant pressure for looking up collections in the hash-table - every time, the hashCode() and equals() are used it needs to traverse the entire list.

But how can I make sure the code doesn't perform this unnecessary? The answer: Immutability - if your class is immutable, then at least the hashCode is constant, therefore, can be pre-computed. The equality check can be shortcutted too - but in worst case scenario it will still traverse the entire collection.

That's nice, but then how do you 'modify' an immutable class. No you don't, you create a new one every time a different content is needed. However, when you look close at the contents of the dictionary, you'll recognize it contains redundant information: `[]a`, `[abc]d`, `[abc]e`, `[abcd]f`. So why not just store the head as a pointer to a previously seen pattern and have a tail for the current character?

Exactly. Using immutability and back-references you can spare space and time, and even the garbage collector will love you too. One speciality of my solution is that in F# and Haskell, the list uses a head:[tail] signature - the head is the element type and the tail is a pointer to the next collection. In this question, the opposite was required as the lists grow at the tail side.

From here on its just some further optimization - for example, use a concrete `char` as the tail type to avoid constant char autoboxing of the generic version.

One drawback of my solution is that it utilizes recursion when calculating the aspects of the list. For relatively small list it's fine, but longer list could require you to increase the Thread stack size on which your computation runs. In theory, with Java 7's tail call optimization, my code can be rewritten in such a way that it allows the JIT to perform the optimization (or is it already so? Hard to tell).

-
this is significantly faster –  Robert Jul 15 '09 at 11:26
I would like to express my gratitude to the F#/Haskell community for this kind of linked list concept. –  kd304 Jul 15 '09 at 11:39
As I concurred with a comment below - it would be nice to see a theoretical explanation, as although I'm using java I'm not an expert and have not seen some of this before. –  Robert Jul 15 '09 at 12:21
Then start a new question about it and have a cross-reference between your new question to this question. –  kd304 Jul 15 '09 at 12:32
Or you could just edit your answer to add a short description of how it works. I think you would get more upvotes to your answer that way as well since I sincerely hope no one upvotes things they don't understand and it seems like there's a few of us who are curious about your solution. –  Hannes Ovrén Jul 15 '09 at 14:16

In my opinion an `ArrayList` isn't the best datastructure for keeping a dictionary with only contains and adds.

EDIT

Try using an HashSet, which stores its elements in a hash table, is the best-performing implementation of the Set interface; however it makes no guarantees concerning the order of iteration

-
what is the best in your opinion? –  Robert Jul 15 '09 at 10:22

An ArrayList will have O(N) search complexity. Use a data structure such as a hash table or dictionary.

-
This implies that string comparison is a primitive operation which is not true. Since strings get larger and larger as their indices of ArrayList increase comparison will also depend on those lengths. –  sharptooth Jul 15 '09 at 10:24
@sharptooth: the poster's update to the question seems to validate my answer. –  Mitch Wheat Jul 15 '09 at 11:30

Since you are always checking for prefix+c I think a good data structure could be a tree where each child has its parent as prefix:

``````           root
/       |
a        b
/  |     /  |
an  ap   ba bo
|
ape
``````

Another perhaps more simple approach is to use a sorted list and then use binary search to find the string you are looking at. I still think the tree approach will be faster though.

-
Wow, check my FList<T> and FListChar. Does it fit your description? –  kd304 Jul 15 '09 at 11:37
Maybe, but I did not look at it close enough. As it was only (a lot of) code and no theoretical description I did not spend enough time understanding it. I am not a Java programmer so it would have taken me quite a while to look up all the stuff you used that I had not seen before. –  Hannes Ovrén Jul 15 '09 at 11:59
yes, would be nice to see a theoretical explanation too. –  Robert Jul 15 '09 at 12:19