107

Why is i++ not atomic in Java?

To get a bit deeper in Java I tried to count how often the loop in threads are executed.

So I used a

private static int total = 0;

in the main class.

I have two threads.

  • Thread 1: Prints System.out.println("Hello from Thread 1!");
  • Thread 2: Prints System.out.println("Hello from Thread 2!");

And I count the lines printed by thread 1 and thread 2. But the lines of thread 1 + lines of thread 2 don't match the total number of lines printed out.

Here is my code:

import java.util.concurrent.ExecutorService;
import java.util.concurrent.Executors;
import java.util.logging.Level;
import java.util.logging.Logger;

public class Test {

    private static int total = 0;
    private static int countT1 = 0;
    private static int countT2 = 0;
    private boolean run = true;

    public Test() {
        ExecutorService newCachedThreadPool = Executors.newCachedThreadPool();
        newCachedThreadPool.execute(t1);
        newCachedThreadPool.execute(t2);
        try {
            Thread.sleep(1000);
        }
        catch (InterruptedException ex) {
            Logger.getLogger(Test.class.getName()).log(Level.SEVERE, null, ex);
        }
        run = false;
        try {
            Thread.sleep(1000);
        }
        catch (InterruptedException ex) {
            Logger.getLogger(Test.class.getName()).log(Level.SEVERE, null, ex);
        }
        System.out.println((countT1 + countT2 + " == " + total));
    }

    private Runnable t1 = new Runnable() {
        @Override
        public void run() {
            while (run) {
                total++;
                countT1++;
                System.out.println("Hello #" + countT1 + " from Thread 2! Total hello: " + total);
            }
        }
    };

    private Runnable t2 = new Runnable() {
        @Override
        public void run() {
            while (run) {
                total++;
                countT2++;
                System.out.println("Hello #" + countT2 + " from Thread 2! Total hello: " + total);
            }
        }
    };

    public static void main(String[] args) {
        new Test();
    }
}
8
  • 15
    Why don't you try with AtomicInteger?
    – Braj
    Aug 6, 2014 at 18:56
  • 7
  • 3
    the JVM has an iinc operation for incrementing integers, but that only works for local variables, where concurrency is not a concern. For fields, the compiler generates read-modify-write commands separately. Aug 6, 2014 at 21:24
  • 15
    Why would you even expect it to be atomic?
    – Hot Licks
    Aug 6, 2014 at 21:55
  • 2
    @Silly Freak: even if there was an iinc instruction for fields, having a single instruction does not guarantee atomicity, e.g. non-volatile long and double field access in not guaranteed to be atomic regardless of the fact that it is performed by a single bytecode instruction.
    – Holger
    Aug 7, 2014 at 10:41

10 Answers 10

134

i++ is probably not atomic in Java because atomicity is a special requirement which is not present in the majority of the uses of i++. That requirement has a significant overhead: there is a large cost in making an increment operation atomic; it involves synchronization at both the software and hardware levels that need not be present in an ordinary increment.

You could make the argument that i++ should have been designed and documented as specifically performing an atomic increment, so that a non-atomic increment is performed using i = i + 1. However, this would break the "cultural compatibility" between Java, and C and C++. As well, it would take away a convenient notation which programmers familiar with C-like languages take for granted, giving it a special meaning that applies only in limited circumstances.

Basic C or C++ code like for (i = 0; i < LIMIT; i++) would translate into Java as for (i = 0; i < LIMIT; i = i + 1); because it would be inappropriate to use the atomic i++. What's worse, programmers coming from C or other C-like languages to Java would use i++ anyway, resulting in unnecessary use of atomic instructions.

Even at the machine instruction set level, an increment type operation is usually not atomic for performance reasons. In x86, a special instruction "lock prefix" must be used to make the inc instruction atomic: for the same reasons as above. If inc were always atomic, it would never be used when a non-atomic inc is required; programmers and compilers would generate code that loads, adds 1 and stores, because it would be way faster.

In some instruction set architectures, there is no atomic inc or perhaps no inc at all; to do an atomic inc on MIPS, you have to write a software loop which uses the ll and sc: load-linked, and store-conditional. Load-linked reads the word, and store-conditional stores the new value if the word has not changed, or else it fails (which is detected and causes a re-try).

4
  • 2
    as java has no pointers, incrementing local variables is inherently thread save, so with loops the problem mostly wouldn't be so bad. your point about least surprise stands, of course. also, as it is, i = i + 1 would be a translation for ++i, not i++ Aug 6, 2014 at 22:19
  • 23
    The first word of the question is "why". As of now, this is the only answer to address the issue of "why". The other answers really just re-state the question. So +1. Aug 7, 2014 at 1:44
  • 3
    It might be worth noting that an atomicity guaranty would not solve the visibility issue for updates of non-volatile fields. So unless you will treat every field as implicitly volatile once one thread has used the ++ operator on it, such an atomicity guaranty would not solve concurrent update issues. So why potentially wasting performance for something if it doesn’t solve the problem.
    – Holger
    Aug 7, 2014 at 10:49
  • 1
    @DavidWallace don't you mean ++? ;) Aug 14, 2014 at 23:33
40

i++ involves two operations :

  1. read the current value of i
  2. increment the value and assign it to i

When two threads perform i++ on the same variable at the same time, they may both get the same current value of i, and then increment and set it to i+1, so you'll get a single incrementation instead of two.

Example :

int i = 5;
Thread 1 : i++;
           // reads value 5
Thread 2 : i++;
           // reads value 5
Thread 1 : // increments i to 6
Thread 2 : // increments i to 6
           // i == 6 instead of 7
8
  • (Even if i++ was atomic, it would not be well-defined/thread-safe behavior.) Aug 6, 2014 at 19:00
  • 16
    +1, but "1. A, 2. B and C" sounds like three operations, not two. :)
    – yshavit
    Aug 6, 2014 at 19:10
  • 3
    Note that even if the operation were implemented with a single machine instruction that incremented a storage location in place, there is no guarantee it would be thread-safe. The machine still needs to fetch the value, increment it, and store it back, plus there may be multiple cache copies of that storage location.
    – Hot Licks
    Aug 7, 2014 at 1:54
  • 3
    @Aquarelle - If two processors execute the same operation against the same storage location simultaneously, and there is no "reserve" broadcast on the location, then they will almost certainly interfere and produce bogus results. Yes, it is possible for this operation to be "safe", but it takes special effort, even at the hardware level.
    – Hot Licks
    Aug 7, 2014 at 12:02
  • 7
    But I think the question was "Why" and not "What happens". Aug 8, 2014 at 7:17
14

Java specification

The important thing is the JLS (Java Language Specification) rather than how various implementations of the JVM may or may not have implemented a certain feature of the language.

The JLS defines the ++ postfix operator in clause 15.14.2 which says i.a. "the value 1 is added to the value of the variable and the sum is stored back into the variable". Nowhere does it mention or hint at multithreading or atomicity.

For multithreading or atomicity, the JLS provides volatile and synchronized. Additionally, there are the Atomic… classes.

6

Why is i++ not atomic in Java?

Let's break the increment operation into multiple statements:

Thread 1 & 2 :

  1. Fetch value of total from memory
  2. Add 1 to the value
  3. Write back to the memory

If there is no synchronization then let's say Thread one has read the value 3 and incremented it to 4, but has not written it back. At this point, the context switch happens. Thread two reads the value 3, increments it and the context switch happens. Though both threads have incremented the total value, it will still be 4 - race condition.

5
  • 3
    I don't get how this should be an answer to the question. A language can define any feature as atomic, be it increments or unicorns. You just exemplify a consequence of not being atomic. Aug 7, 2014 at 14:54
  • Yes a language can define any feature as atomic but as far as java is considered increment operator(which is the question posted by OP) is not atomic and my answer states the reasons. Aug 7, 2014 at 16:29
  • 2
    (sorry for my harsh tone in first comment) But then, the reason seems to be "because if it would be atomic, then there would be no race conditions". I.e., it sounds as if a race condition is desirable. Aug 7, 2014 at 16:40
  • @phresnel the overhead introduced to keep an increment atomic is huge and rarely desired, keeping the operation cheap and as a result non atomic is desirable most of the time.
    – josefx
    Aug 8, 2014 at 6:00
  • 5
    @josefx: Note that I am not questioning the facts, but the reasoning in this answer. It basically says "i++ is not atomic in Java because of the race conditions it has", which is like saying "a car has no airbag because of the crashes that can happen" or "you get no knife with your currywurst-order because the wurst may need to be cut". Thus, I don't think this is an answer. The question was not "What does i++ do?" or "What is the consequence of i++ not being synced?". Aug 8, 2014 at 7:09
5

i++ is a statement which simply involves 3 operations:

  1. Read current value
  2. Write new value
  3. Store new value

These three operations are not meant to be executed in a single step or in other words i++ is not a compound operation. As a result all sorts of things can go wrong when more than one threads are involved in a single but non-compound operation.

Consider the following scenario:

Time 1:

Thread A fetches i
Thread B fetches i

Time 2:

Thread A overwrites i with a new value say -foo-
Thread B overwrites i with a new value say -bar-
Thread B stores -bar- in i

// At this time thread B seems to be more 'active'. Not only does it overwrite 
// its local copy of i but also makes it in time to store -bar- back to 
// 'main' memory (i)

Time 3:

Thread A attempts to store -foo- in memory effectively overwriting the -bar- 
value (in i) which was just stored by thread B in Time 2.

Thread B has nothing to do here. Its work was done by Time 2. However it was 
all for nothing as -bar- was eventually overwritten by another thread.

And there you have it. A race condition.


That's why i++ is not atomic. If it was, none of this would have happened and each fetch-update-store would happen atomically. That's exactly what AtomicInteger is for and in your case it would probably fit right in.

P.S.

An excellent book covering all of those issues and then some is this: Java Concurrency in Practice

4
  • 2
    Hmm. A language can define any feature as atomic, be it increments or unicorns. You just exemplify a consequence of not being atomic. Aug 7, 2014 at 14:55
  • @phresnel Exactly. But I also point out that it's not a single operation which by extension implies that the computational cost for turning multiple such operations into atomic ones is much more expensive which in turn -partially- justifies why i++ is not atomic.
    – stratis
    Aug 7, 2014 at 15:20
  • 2
    While I get your point, your answer is a bit confusing to the learning. I see an example, and a conclusion that says "because of the situation in the example"; imho this is an incomplete reasoning :( Aug 7, 2014 at 15:23
  • 1
    @phresnel Maybe not the most pedagogical answer but it's the best I can currently offer. Hopefully it will help people and not confuse them. Thanks for critisism however. I 'll try to be more precise in my future posts.
    – stratis
    Aug 7, 2014 at 15:30
2

In the JVM, an increment involves a read and a write, so it's not atomic.

1

If the operation i++ would be atomic you wouldn't have the chance to read the value from it. This is exactly what you want to do using i++ (instead of using ++i).

For example look at the following code:

public static void main(final String[] args) {
    int i = 0;
    System.out.println(i++);
}

In this case we expect the output to be: 0 (because we post increment, e.g. first read, then update)

This is one of the reasons the operation can't be atomic, because you need to read the value (and do something with it) and then update the value.

The other important reason is that doing something atomically usually takes more time because of locking. It would be silly to have all the operations on primitives take a little bit longer for the rare cases when people want to have atomic operations. That is why they've added AtomicInteger and other atomic classes to the language.

4
  • 3
    This is misleading. You have to separate execution and getting the result, otherwise you couldn't get values from any atomic operation. Aug 7, 2014 at 14:56
  • No it isn't, that is why Java's AtomicInteger has a get(), getAndIncrement(), getAndDecrement(), incrementAndGet(), decrementAndGet() etc. Aug 7, 2014 at 18:56
  • 2
    And the Java-language could have defined i++ to be expanded to i.getAndIncrement(). Such expanding isn't new. E.g., lambdas in C++ are expanded to anonymous class definitions in C++. Aug 7, 2014 at 20:19
  • 1
    Given an atomic i++ one can trivially create an atomic ++i or vice-versa. One is equivalent to the other plus one. Nov 24, 2015 at 10:21
1

There are two steps:

  1. fetch i from memory
  2. set i+1 to i

so it's not atomic operation. When thread1 executes i++, and thread2 executes i++, the final value of i may be i+1.

-1

In JVM or any VM, the i++ is equivalent to the following:

int temp = i;     // 1. read
i = temp + 1;    // 2. increment the value then 3. write it back

that is why i++ is non-atomic.

1
  • That is how it is non-atomic, not why, as so many of the other answers and comments have covered. Feb 4, 2022 at 23:28
-2

Concurrency (the Thread class and such) is an added feature in v1.0 of Java. i++ was added in the beta before that, and as such is it still more than likely in its (more or less) original implementation.

It is up to the programmer to synchronize variables. Check out Oracle's tutorial on this.

Edit: To clarify, i++ is a well defined procedure that predates Java, and as such the designers of Java decided to keep the original functionality of that procedure.

The ++ operator was defined in B (1969) which predates java and threading by just a tad.

7
  • -1 "public class Thread ... Since: JDK1.0" Source: docs.oracle.com/javase/7/docs/api/index.html?java/lang/… Aug 6, 2014 at 21:33
  • The version doesn't matter so much as the fact that it was still implemented before the Thread class and was not changed because of it, but I've edited my answer to please you.
    – TheBat
    Aug 6, 2014 at 21:37
  • 6
    What matters is that your claim "it was still implemented before the Thread class" is not backed by sources. i++ not being atomic is a design decision, not an oversight in a growing system. Aug 6, 2014 at 21:40
  • 1
    Just because a language feature is borrowed from or inspired by a corresponding feature in other languages doesn't mean it necessarily keeps the exact same underlying characteristics. Consider, for instance, the variety of lambda functions in different languages (e.g. the weakness of Python's lambda compared to true Lisp lambdas symbo1ics.com/blog/?p=1292). Even in C++, certain features taken from C aren't quite identical to their C counterparts, despite the fact that C++ is often thought to be backwards-compatible with C (cprogramming.com/tutorial/c-vs-c++.html). Aug 7, 2014 at 17:09
  • 1
    @TheBat: But many borrowed keywords and operators are not implemented like in the language/s they were borrowed from. E.g., class and operator. in C++ are totally orthogonal to their Java "equivalents". Aug 8, 2014 at 7:17

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