Elusive race condition in Java

I am creating a graphing calculator.

In an attempt to squeeze some more performance out of it, I added some multithreaded to the line calculator. Essentially what my current implementation does is construct a thread-safe `Queue` of X values, then start however many threads it needs, each one calculating a point on the line using the queue to get its values, and then ordering the points using a `HashMap` when the calculations are done. This implementation works great, and that's not where my race condition is (merely some background info).

In examining the performance results from this, I found that the `HashMap` is a performance bottleneck, since I do that synchronously on one thread. So I figured that ordering each point as its calculated would work best. I tried a `PriorityQueue`, but that was slower than the `HashMap`.

I ended up creating an algorithm that essentially works like this:

I construct a list of X values to calculate, like in my current algorithm.

I then copy that list of values into another class, unimaginatively and temporarily named `BlockingList`, which is responsible for ordering the points as they are calculated.

`BlockingList` contains a `put()` method, which takes in two `BigDecimal`s as parameters, the first the X value, the second the calculated Y value. `put()` will only accept a value if the X value is the next one on the list to be accepted in the list of X values, and will block until another thread gives it the next excepted value.

For example, since that can be confusing, say I have two threads, `Thread-1` and `Thread-2`. `Thread-2` gets the X value `10.0` from the values queue, and `Thread-1` gets `9.0`. However, `Thread-1` completes its calculations first, and calls `put()` before `Thread-2` does. Because `BlockingList` is expecting to get `10.0` first, and not `9.0`, it will block on `Thread-1` until `Thread-2` finishes and calls `put()`. Once `Thread-2` gives `BlockingList` `10.0`, it `notify()`s all waiting threads, and expects `9.0` next. This continues until `BlockingList` gets all of its expected values.

(I apologise if that was hard to follow, if you need more clarification, just ask.)

As expected by the question title, there is a race condition in here. If I run it without any `System.out.println`s, it will sometimes lock because of conflicting `wait()` and `notifyAll()`s, but if I put a `println` in, it will run great.

A small implementation of this is included below, and exhibits the same behavior:

``````import java.math.BigDecimal;
import java.util.concurrent.ConcurrentLinkedQueue;

public class Example {
public static void main(String[] args) throws InterruptedException {
// Various scaling values, determined based on the graph size
// in the real implementation
BigDecimal xMax = new BigDecimal(10);
BigDecimal xStep = new BigDecimal(0.05);

// Construct the values list, from -10 to 10
final ConcurrentLinkedQueue<BigDecimal> values = new ConcurrentLinkedQueue<BigDecimal>();

for (BigDecimal i = new BigDecimal(-10); i.compareTo(xMax) <= 0; i = i.add(xStep)) {
values.add(i);
}

// Contains the calculated values
final BlockingList list = new BlockingList(values);

for (int i = 0; i < 4; i++) {
new Thread() {
public void run() {
BigDecimal x;

// Keep looping until there are no more values
while ((x = values.poll()) != null) {
PointPair pair = new PointPair();
pair.realX = x;

try {
list.put(pair);
} catch (Exception ex) {
ex.printStackTrace();
}
}
}
}.start();
}
}

private static class PointPair {
public BigDecimal realX;
}

private static class BlockingList {
private final ConcurrentLinkedQueue<BigDecimal> _values;
private final ConcurrentLinkedQueue<PointPair> _list = new ConcurrentLinkedQueue<PointPair>();

public BlockingList(ConcurrentLinkedQueue<BigDecimal> expectedValues) throws InterruptedException {
// Copy the values into a new queue
BigDecimal[] arr = expectedValues.toArray(new BigDecimal[0]);

_values = new ConcurrentLinkedQueue<BigDecimal>();
for (BigDecimal dec : arr) {
_values.add(dec);
}
}

public void put(PointPair item) throws InterruptedException {
while (item.realX.compareTo(_values.peek()) != 0) {
synchronized (this) {
// Block until someone enters the next desired value
wait();
}
}

_list.add(item);
_values.poll();

synchronized (this) {
notifyAll();
}
}
}
}
``````

My question is can anybody help me find the threading error?

Thanks!

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If you know exactly how many values there are going to be, and in what order, why not just allocate an array of the appropriate size, and have each thread write the values in the correct spots? No blocking, no race-conditions... –  tzaman May 1 '10 at 0:28
Ah... Well, yes, that would be a significantly better solution. Ugh, there's a reason you don't code when you're dead tired. Thanks for the suggestion, I'll implement it and see how it performs. –  mgbowen May 1 '10 at 0:34
Your solution did great, and it performs much faster! Thank you very much! –  mgbowen May 1 '10 at 0:41
You're most welcome. Go have a cup of coffee :) Or better yet, get some rest! –  tzaman May 1 '10 at 0:42

4 Answers

You're adding the threading to improve performance, but in doing so have introduced a performance bottleneck.

You write:

I figured that ordering each point as its calculated would work best

Let's evaluate the performance cost of doing this.

Adding a single point to an already sorted list can be done very quickly.

With a BubbleSort algorithm, this will take O(N) time - linear time proportional to the size of the list already present. Repeating this for every point you're adding means that you repeat this O(N) operation N times, giving O(N^2) performance. Running this over many cores might reduce the wall clock time, but the killer is the N^2 performance.

Unfortunately, Java doesn't use the BubbleSort algorithm internally - it uses the QuickSort, which is generally better behaved. For adding a single number to an already sorted list, QuickSort takes O(N lg N) time; repeating this N times gives O(N^2 lg N) performance. Double ouch.

Resorting a list many times is inefficient - if you instead just gathered all the items together and sorted them once at the end, sorting will cost you just O(N lg N) time, giving you a much better end result.

Note that having multiple cores will just scale the results by a constant factor, it doesn't change the overall analysis. Going multithreaded can improve performance markedly, so you're going the right way, but always measure the results.

In examining the performance results from this, I found that the HashMap is a performance bottleneck, since I do that synchronously on one thread

Instead of using a Hashmap, try using a simple list to gather the points together - adding a point to a list is near-constant, near-zero time, as long as you set the list capacity high enough in advance.

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Indeed, using an array worked much better, since I already know how many points I will have, and what order they're in. I'll mark this as the answer unless tzaman wants to put his into an answer. Thanks! –  mgbowen May 1 '10 at 0:48

You have to realise why Java requires wait() and notify() to be synchronized.

Imagine you are a thread, and have just completed this.

``````while (item.realX.compareTo(_values.peek()) != 0) {
synchronized (this) {
// Block until someone enters the next desired value
wait();
}
}
``````

You had the lock, released it for the wait, then get it back when the wait finished. Then - you gave it up again!

``````        _list.add(item);
_values.poll();
``````

During this time, your other threads have access to the lock. Then you go on and re-obtain a lock in order to poll the list and perform the actual 'put'.

``````        synchronized (this) {
notifyAll();
}
``````

The point of the 'synchronized' is for you to keep the lock while you make the changes - you should put the 'wait', 'add' and 'poll' statements within the same 'synchronized' statement.

-

Does it work if you put synchronized in front of the entire `BlockingList.put` method?

What if thread A executes

``````while (item.realX.compareTo(_values.peek()) != 0) {
``````

Thread B goes on and does

``````_list.add(item);
_values.poll();

synchronized (this) {
notifyAll();
}
``````

Thread A does

``````synchronized (this) {
// Block until someone enters the next desired value
wait();
}
``````
-
No, unfortunately, but see the comments on the question, I used tzaman's solution for this problem, which is much better than my convoluted one. –  mgbowen May 1 '10 at 0:42
updated the answer. What do you think? (Even if you updated to another solution, the race-condition issue is still a relevant question) –  aioobe May 1 '10 at 0:43
Yeah, it does seem that would be where the race condition is, Thread B calls `notifyAll()` before thread A can call `wait()`. I suppose making it `wait(10)` or some other arbitrary number would work better, so that it checks after a bit. –  mgbowen May 1 '10 at 0:47

The best way to understand race conditions in threads and how to resolve them, you should read this book:

Java Concurrency in Practice (2006)

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