Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I am working on an application and one design approach involves extremely heavy use of the instanceof operator. While I know that OO design generally tries to avoid using instanceof, that is a different story and this question is purely related to performance. I was wondering if there is any performance impact? Is is just as fast as ==?

For example, I have a base class with 10 subclasses. In a single function that takes the base class, I do checks for if the class is an instance of the subclass and carry out some routine.

One of the other ways I thought of solving it was to use to use a "type id" integer primitive instead, and use a bitmask to represent categories of the subclasses, and then just do a bit mask comparison of the subclasses "type id" to a constant mask representing the category.

Is instanceof somehow optimized by the JVM to be faster than that? I want to stick to Java but the performance of the app is critical. It would be cool if someone that has been down this road before could offer some advice. Am I nitpicking too much or focusing on the wrong thing to optimize?

share|improve this question
7  
The problem with overusing instanceof isn't in speed, it's in that you're voilating the spirit of object orientation. The answer you accepted from @Steve answer the speed question, but ignores the fact that doing that way is bad practice. –  Paul Tomblin Sep 19 '08 at 16:50
50  
I think the point of the question, however, was to set aside the question of best OO practice, and examine the performance. –  Dave L. Sep 19 '08 at 16:50
1  
@Dave L. Normally I would agree, but the OP does mention that he's looking for some general optimization techniques and he's not sure if his problem is related to 'instanceof'. I think it's worth at least mentioning the 'correct' design so he can profile both choices. –  Outlaw Programmer Sep 19 '08 at 16:54
28  
Ugh... Why do all the answers miss the point of the question and supply the same old Knuth rhetoric about optimisation? Your question is about whether instanceof is significantly/surprisingly slower than checking the class object with ==, and I've found that it is not. –  jgubby May 12 '10 at 10:18

22 Answers 22

up vote 128 down vote accepted

Modern JVM/JIC compilers have removed the performance hit of most of the traditionally "slow" operations, including instanceof, exception handling, reflection, etc.

As Donald Knuth wrote, "We should forget about small efficiencies, say about 97% of the time: premature optimization is the root of all evil." The performance of instanceof probably won't be an issue, so don't waste your time coming up with exotic workarounds until you're sure that's the problem.

share|improve this answer
4  
Modern JVM/JIC ..COuld you please mention from which java version these optimiszation have been covered? –  Ravisha Dec 3 '10 at 9:50
    
I don't have specific java versions, but any JVMs released by the major players (Sun/Oracle, IBM, Apple, etc) from the last 10 years or so could probably be considered "modern" in this regard. –  Steve Apr 8 '11 at 19:17
41  
Always there's someone, who cites Knuth when performance is the topic... Forgetting, that Knuth also stated (in the same article) "In established engineering disciplines a 12 % improvement, easily obtained, is never considered marginal and I believe the same viewpoint should prevail in software engineering", nearly all his work was about efficiency of algorithms and he wrote algorithms in assembly to (inter alia) achieve better performance. Meh... –  kgadek Sep 1 '11 at 8:43
2  
An aside here but would try { ObjT o = (ObjT)object } catch (e) { no not one of these } would be any faster slower ?? –  peterk Feb 13 '12 at 15:51
11  
If "object" is an instance of ObjT, casting it is a little faster than doing an instanceof, but the difference my quick test found was 10-20ms over 10,000,000 iterations. If "object" isn't an ObjT, though, catching the exception was over 3000x slower - over 31,000ms vs ~10ms for the instanceof. –  Steve Feb 18 '12 at 0:27

I just made a simple test to see how instanceOf performance is comparing to a simple s.equals() call to a string object with only one letter.

in a 10.000.000 loop the instanceOf gave me 63-96ms, and the string equals gave me 106-230ms

I used java jvm 6.

So in my simple test is faster to do a instanceOf instead of a one character string comparison.

using Integer's .equals() instead of string's gave me the same result, only when I used the == i was faster than instanceOf by 20ms (in a 10.000.000 loop)

share|improve this answer
2  
Would it be possible for you to post the code here? That would be awesome! –  The Alchemist Dec 23 '10 at 14:52
3  
How did instanceOf compare to polymorphic function dispatch? –  Chris Jun 17 '11 at 21:11
9  
Why do you compare instanceof with a String.equals()? If you want to check the type you have to to object.getClass().equals(SomeType.class) –  marsbear Nov 18 '11 at 23:16
    
@marsbear equals() won't cut it, because subclassing; you need isAssignableFrom(). –  David Moles Feb 24 at 15:56
    
@DavidMoles I was refering to Dans experiment on String.equals(). As String is final subclassing won't be a problem. –  marsbear Feb 25 at 14:39

Answering your very last question: Unless a profiler tells you, that you spend ridiculous amounts of time in an instanceof: Yes, you're nitpicking.

Before wondering about optimizing something that never needed to be optimized: Write your algorithm in the most readable way and run it. Run it, until the jit-compiler gets a chance to optimize it itself. If you then have problems with this piece of code, use a profiler to tell you, where to gain the most and optimize this.

In times of highly optimizing compilers, your guesses about bottlenecks will be likely to be completely wrong.

And in true spirit of this answer (which I wholeheartly believe): I absolutely don't know how instanceof and == relate once the jit-compiler got a chance to optimize it.

I forgot: Never measure the first run.

share|improve this answer
8  
do profilers profile built-in operators? –  Seun Osewa Aug 8 '10 at 0:43

The items which will determine the performance impact are:

  1. The number of possible classes for which the instanceof operator could return true
  2. The distribution of your data - are most of the instanceof operations resolved in the first or second attempt? You'll want to put your most likely to return true operations first.
  3. The deployment environment. Running on a Sun Solaris VM is significantly different than Sun's Windows JVM. Solaris will run in 'server' mode by default, while Windows will run in client mode. The JIT optimizations on Solaris, will make all method access able the same.

I created a microbenchmark for four different methods of dispatch. The results from Solaris are as follows, with the smaller number being faster:

InstanceOf 3156
class== 2925 
OO 3083 
Id 3067
share|improve this answer

I have got same question, but because i did not find 'performance metrics' for use case similar to mine, i've done some more sample code. On my hardware and Java 6 & 7, the difference between instanceof and switch on 10mln iterations is

for 10 child classes - instanceof: 1200ms vs switch: 470ms
for 5 child classes  - instanceof:  375ms vs switch: 204ms

So, instanceof is really slower, especially on huge number of if-else-if statements, however difference will be negligible within real application.

import java.util.Date;

public class InstanceOfVsEnum {

    public static int c1, c2, c3, c4, c5, c6, c7, c8, c9, cA;

    public static class Handler {
        public enum Type { Type1, Type2, Type3, Type4, Type5, Type6, Type7, Type8, Type9, TypeA }
        protected Handler(Type type) { this.type = type; }
        public final Type type;

        public static void addHandlerInstanceOf(Handler h) {
            if( h instanceof H1) { c1++; }
            else if( h instanceof H2) { c2++; }
            else if( h instanceof H3) { c3++; }
            else if( h instanceof H4) { c4++; }
            else if( h instanceof H5) { c5++; }
            else if( h instanceof H6) { c6++; }
            else if( h instanceof H7) { c7++; }
            else if( h instanceof H8) { c8++; }
            else if( h instanceof H9) { c9++; }
            else if( h instanceof HA) { cA++; }
        }

        public static void addHandlerSwitch(Handler h) {
            switch( h.type ) {
                case Type1: c1++; break;
                case Type2: c2++; break;
                case Type3: c3++; break;
                case Type4: c4++; break;
                case Type5: c5++; break;
                case Type6: c6++; break;
                case Type7: c7++; break;
                case Type8: c8++; break;
                case Type9: c9++; break;
                case TypeA: cA++; break;
            }
        }
    }

    public static class H1 extends Handler { public H1() { super(Type.Type1); } }
    public static class H2 extends Handler { public H2() { super(Type.Type2); } }
    public static class H3 extends Handler { public H3() { super(Type.Type3); } }
    public static class H4 extends Handler { public H4() { super(Type.Type4); } }
    public static class H5 extends Handler { public H5() { super(Type.Type5); } }
    public static class H6 extends Handler { public H6() { super(Type.Type6); } }
    public static class H7 extends Handler { public H7() { super(Type.Type7); } }
    public static class H8 extends Handler { public H8() { super(Type.Type8); } }
    public static class H9 extends Handler { public H9() { super(Type.Type9); } }
    public static class HA extends Handler { public HA() { super(Type.TypeA); } }

    final static int cCycles = 10000000;

    public static void main(String[] args) {
        H1 h1 = new H1();
        H2 h2 = new H2();
        H3 h3 = new H3();
        H4 h4 = new H4();
        H5 h5 = new H5();
        H6 h6 = new H6();
        H7 h7 = new H7();
        H8 h8 = new H8();
        H9 h9 = new H9();
        HA hA = new HA();

        Date dtStart = new Date();
        for( int i = 0; i < cCycles; i++ ) {
            Handler.addHandlerInstanceOf(h1);
            Handler.addHandlerInstanceOf(h2);
            Handler.addHandlerInstanceOf(h3);
            Handler.addHandlerInstanceOf(h4);
            Handler.addHandlerInstanceOf(h5);
            Handler.addHandlerInstanceOf(h6);
            Handler.addHandlerInstanceOf(h7);
            Handler.addHandlerInstanceOf(h8);
            Handler.addHandlerInstanceOf(h9);
            Handler.addHandlerInstanceOf(hA);
        }
        System.out.println("Instance of - " + (new Date().getTime() - dtStart.getTime()));

        dtStart = new Date();
        for( int i = 0; i < cCycles; i++ ) {
            Handler.addHandlerSwitch(h1);
            Handler.addHandlerSwitch(h2);
            Handler.addHandlerSwitch(h3);
            Handler.addHandlerSwitch(h4);
            Handler.addHandlerSwitch(h5);
            Handler.addHandlerSwitch(h6);
            Handler.addHandlerSwitch(h7);
            Handler.addHandlerSwitch(h8);
            Handler.addHandlerSwitch(h9);
            Handler.addHandlerSwitch(hA);
        }
        System.out.println("Switch of - " + (new Date().getTime() - dtStart.getTime()));
    }
}
share|improve this answer

instanceof is probably going to be more costly than a simple equals in most real world implementations (that is, the ones where instanceof is really needed, and you can't just solve it by overriding a common method, like every beginner textbook as well as Demian above suggest).

Why is that? Because what is probably going to happen is that you have several interfaces, that provide some functionality (let's say, interfaces x, y and z), and some objects to manipulate that may (or not) implement one of those interfaces... but not directly. Say, for instance, I have:

w extends x

A implements w

B extends A

C extends B, implements y

D extends C, implements z

Suppose I am processing an instance of D, the object d. Computing (d instanceof x) requires to take d.getClass(), loop through the interfaces it implements to know whether one is == to x, and if not do so again recursively for all of their ancestors... In our case, if you do a breadth first exploration of that tree, yields at least 8 comparisons, supposing y and z don't extend anything...

The complexity of a real-world derivation tree is likely to be higher. In some cases, the JIT can optimize most of it away, if it is able to resolve in advance d as being, in all possible cases, an instance of something that extends x. Realistically, however, you are going to go through that tree traversal most of the time.

If that becomes an issue, I would suggest using a handler map instead, linking the concrete class of the object to a closure that does the handling. It removes the tree traversal phase in favor of a direct mapping. However, beware that if you have set a handler for C.class, my object d above will not be recognized.

here are my 2 cents, I hope they help...

share|improve this answer

instanceof is really fast, taking only a few CPU instructions.

Apparently, if a class X has no subclasses loaded (JVM knows), instanceof can be optimized as:

     x instanceof X    
==>  x.getClass()==X.class  
==>  x.classID == constant_X_ID

The main cost is just a read!

If X does have subclasses loaded, a few more reads are needed; they are likely co-located so the extra cost is very low too.

Good news everyone!

share|improve this answer

Instanceof is very fast. It boils down to a bytecode that is used for class reference comparison. Try a few million instanceofs in a loop and see for yourself.

share|improve this answer

It's hard to say how a certain JVM implements instance of, but in most cases, Objects are comparable to structs and classes are as well and every object struct has a pointer to the the class struct it is an instance of. So actually instanceof for

if (o instanceof java.lang.String)

might be as fast as the following C code

if (objectStruct->iAmInstanceOf == &java_lang_String_class)

assuming a JIT compiler is in place and does a decent job.

Considering that this is only accessing a pointer, getting a pointer at a certain offset the pointer points to and comparing this to another pointer (which is basically the same as testing to 32 bit numbers being equal), I'd say the operation can actually be very fast.

It doesn't have to, though, it depends a lot on the JVM. However, if this would turn out to be the bottleneck operation in your code, I'd consider the JVM implementation rather poor. Even one that has no JIT compiler and only interprets code should be able to make an instanceof test in virtually no time.

share|improve this answer
1  
Doesn't it have to figure out if o inherits from java.lang.String? –  WW. Feb 2 '09 at 8:08
1  
That's why I said it "might" be as fast. In reality it performs a loop, first checking iAmInstanceOf against the class in question, then it goes upwards the inheritance tree of o and repeating this check for every super-class of o (so it it might have to run this loop a couple of times for a match) –  Mecki Feb 2 '09 at 17:41

Demian and Paul mention a good point; however, the placement of the code to execute really depends on how you want to use the data...

I'm a big fan of small data objects that can be used in many ways. If you follow the override (polymorphic) approach, your objects can only be used "one way".

This is where patterns come in...

You can use double-dispatch (as in the visitor pattern) to ask each object to "call you" passing itself -- this will resolve the type of the object. However (again) you'll need a class that can "do stuff" with all of the possible subtypes.

I prefer to use a strategy pattern, where you can register strategies for each subtype you want to handle. Something like the following. Note that this only helps for exact type matches, but has the advantage that it's extensible - third-party contributors can add their own types and handlers. (This is good for dynamic frameworks like OSGi, where new bundles can be added)

Hopefully this will inspire some other ideas...

package com.javadude.sample;

import java.util.HashMap;
import java.util.Map;

public class StrategyExample {
    static class SomeCommonSuperType {}
    static class SubType1 extends SomeCommonSuperType {}
    static class SubType2 extends SomeCommonSuperType {}
    static class SubType3 extends SomeCommonSuperType {}

    static interface Handler<T extends SomeCommonSuperType> {
        Object handle(T object);
    }

    static class HandlerMap {
        private Map<Class<? extends SomeCommonSuperType>, Handler<? extends SomeCommonSuperType>> handlers_ =
            new HashMap<Class<? extends SomeCommonSuperType>, Handler<? extends SomeCommonSuperType>>();
        public <T extends SomeCommonSuperType> void add(Class<T> c, Handler<T> handler) {
            handlers_.put(c, handler);
        }
        @SuppressWarnings("unchecked")
        public <T extends SomeCommonSuperType> Object handle(T o) {
            return ((Handler<T>) handlers_.get(o.getClass())).handle(o);
        }
    }

    public static void main(String[] args) {
        HandlerMap handlerMap = new HandlerMap();

        handlerMap.add(SubType1.class, new Handler<SubType1>() {
            @Override public Object handle(SubType1 object) {
                System.out.println("Handling SubType1");
                return null;
            } });
        handlerMap.add(SubType2.class, new Handler<SubType2>() {
            @Override public Object handle(SubType2 object) {
                System.out.println("Handling SubType2");
                return null;
            } });
        handlerMap.add(SubType3.class, new Handler<SubType3>() {
            @Override public Object handle(SubType3 object) {
                System.out.println("Handling SubType3");
                return null;
            } });

        SubType1 subType1 = new SubType1();
        handlerMap.handle(subType1);
        SubType2 subType2 = new SubType2();
        handlerMap.handle(subType2);
        SubType3 subType3 = new SubType3();
        handlerMap.handle(subType3);
    }
}
share|improve this answer
    
A little dirty, but the handler logic can be easily extracted to a separate type. –  The Alchemist Dec 23 '10 at 15:01

instanceof is very efficient, so your performance is unlikely to suffer. However, using lots of instanceof suggests a design issue.

If you can use xClass == String.class, this is faster. Note: you don't need instanceof for final classes.

share|improve this answer
    
Btw what do you mean by "don't need instanceof for final classes" ? –  Pacerier Mar 6 '12 at 15:57
    
A final class cannot have sub classes. In this case x.getClass() == Class.class is the same as x instanceof Class –  Peter Lawrey Mar 6 '12 at 16:32
    
Cool, assuming that x is not null, which would you prefer? –  Pacerier Mar 6 '12 at 16:41
    
Good point. It would depend on whether I expect x to be null I suppose. (Or whichever is clearer) –  Peter Lawrey Mar 6 '12 at 16:42
    
Ic, thanks for the help =D –  Pacerier Mar 6 '12 at 17:13

Unless you're doing it in an inner loop, I wouldn't worry about it.

share|improve this answer

Generally the reason why the "instanceof" operator is frowned upon in a case like that (where the instanceof is checking for subclasses of this base class) is because what you should be doing is moving the operations into a method and overridding it for the appropriate subclasses. For instance, if you have:

if (o instanceof Class1)
   doThis();
else if (o instanceof Class2)
   doThat();
//...

You can replace that with

o.doEverything();

and then have the implementation of "doEverything()" in Class1 call "doThis()", and in Class2 call "doThat()", and so on.

share|improve this answer
8  
But sometimes you can't. If you're implementing an interface that has you taking in an Object, and you need to tell which type it is, then instanceof is really the only option. You could try casting, but instanceof is generally cleaner. –  Herms Sep 19 '08 at 17:29

'instanceof' is actually an operator, like + or -, and I believe that it has its own JVM bytecode instruction. It should be plenty fast.

I should not that if you have a switch where you are testing if an object is an instance of some subsclass, then your design might need to be reworked. Consider pushing the subclass-specific behavior down into the subclasses themselves.

share|improve this answer

InstanceOf is a warning of poor Object Oriented design.

Current JVMs do mean the instanceOf is not much of a performance worry in itself. If you are finding yourself using it a lot, especially for core functionality, it is probably time to look at the design. The performance (and simplicity/maintainability) gains of refactoring to a better design will greatly outweigh any actual processor cycles spent on the actual instanceOf call.

To give a very small simplistic programming example.

if (SomeObject instanceOf Integer) {
  [do something]
}
if (SomeObject instanceOf Double) {
  [do something different]
}

Is a poor architecture a better choice would have been to have SomeObject be the parent class of two child classes where each child class overrides a method (doSomething) so the code would look as such:

Someobject.doSomething();
share|improve this answer
50  
I'm aware of that. That was not what I asked. –  Josh Oct 6 '08 at 14:35
    
Unsure of whether to vote this up or not as it is a good point, but doesn't answer the question asked ... –  jklp Nov 12 '08 at 0:09
5  
I think the code example is actually a very bad one: You cannot extend the class Double, and also you cannot derive Double from some other class. If you had used other classes for the example, it would have been ok. –  Lena Schimmel Jan 7 '09 at 16:16
5  
Also if the child classes of SomeObject are value objects, then you don't want to put the logic in them. E.g. Pie and Roast might not be the correct place for putInOven() and putInMouth() logic. –  sk. Jan 27 '09 at 18:34

In modern Java version the instanceof operator is faster as a simple method call. This means:

if(a instanceof AnyObject){
}

is faster as:

if(a.getType() == XYZ){
}

Another thing is if you need to cascade many instanceof. Then a switch that only call once getType() is faster.

share|improve this answer

If speed is your sole aim then using int constants to identify sub classes seems to shave a milliseconds of the time

static final int ID_A = 0;
static final int ID_B = 1;
abstract class Base {
  final int id;
  Base(int i) { id = i; }
}
class A extends Base {
 A() { super(ID_A); }
}
class B extends Base {
 B() { super(ID_B); }
}
...
Base obj = ...
switch(obj.id) {
case  ID_A: .... break;
case  ID_B: .... break;
}

terrible OO design, but if your performance analysis indicates this is where you bottleneck is then maybe. In my code the dispatch code takes 10% of total execution time and this maybe contributed to a 1% total speed improvement.

share|improve this answer

You should measure/profile if it's really a performance issue in your project. If it is I'd recommend a redesign - if possible. I'm pretty sure you can't beat the platform's native implementation (written in C). You should also consider the multiple inheritance in this case.

You should tell more about the problem, maybe you could use an associative store, e.g. a Map<Class, Object> if you are only interested in the concrete types.

share|improve this answer

With regard to Peter Lawrey's note that you don't need instanceof for final classes and can just use a reference equality, be careful! Even though the final classes cannot be extended, they are not guaranteed to be loaded by the same classloader. Only use x.getClass() == SomeFinal.class or its ilk if you are absolutely positive that there is only one classloader in play for that section of code.

share|improve this answer
2  
If a class is loaded by a different classloader, I don't think instanceof will match either. –  Peter Lawrey Feb 19 '09 at 22:34

I'll get back to you on instanceof performance. But a way to avoid problem (or lack thereof) altogether would be to create a parent interface to all the subclasses on which you need to do instanceof. The interface will be an super set of all the methods in sub-classes for which you need to do instanceof check. Where a method does not apply to a specific sub-class, simply provide a dummy implementation of this method. If I didn't misunderstand the issue, this is how I've gotten around the problem int he past.

share|improve this answer

I also prefer an enum approach, but I would use a abstract base class to force the subclasses to implement the getType() method.

public abstract class Base
{
  protected enum TYPE
  {
    DERIVED_A, DERIVED_B
  }

  public abstract TYPE getType();

  class DerivedA extends Base
  {
    @Override
    public TYPE getType()
    {
      return TYPE.DERIVED_A;
    }
  }

  class DerivedB extends Base
  {
    @Override
    public TYPE getType()
    {
      return TYPE.DERIVED_B;
    }
  }
}
share|improve this answer

You're focusing on the wrong thing. The difference between instanceof and any other method for checking the same thing would probably not even be measurable. If performance is critical then Java is probably the wrong language. The major reason being that you can't control when the VM decides it wants to go collect garbage, which can take the CPU to 100% for several seconds in a large program (MagicDraw 10 was great for that). Unless you are in control of every computer this program will run on you can't guarantee which version of JVM it will be on, and many of the older ones had major speed issues. If it's a small app you may be ok with Java, but if you are constantly reading and discarding data then you will notice when the GC kicks in.

share|improve this answer
4  
That is much less true of the more modern java garbage collection algorithms than it ever used to be. Even the simplest algorithms don't care any more how much memory you discard just after you useit - they only care how much is retained across young-generation collections. –  Bill Michell Sep 23 '08 at 14:34
3  
Great, except I'm on the most recent JVM and my computer still crawls when the GC runs. On a dual-core, 3GB ram server. Java is not a language to use if performance actually matters. –  tloach Oct 8 '08 at 0:20
    
Real-time is not the same thing as performant. –  David Moles Oct 27 '11 at 22:14
    
@David: You don't need require real-time to have issues when your app goes away for a period of time. A fun one I've encountered is a java app that connected to a TCP stream that died when the GC ran because it didn't close the stream first and couldn't handle the overload of network traffic when it came back - it would immediately go into a loop where GC runs, when app resumes it tries to churn through a bunch of data, which made it run out of memory, which triggered the GC, etc. Java is great for a lot of tasks, but not tasks where very strong performance is a requirement. –  tloach Oct 28 '11 at 13:04
2  
@tloach sounds to me like bad app design. you talk about "performance" as if it was one-dimensional. I've worked with (and on) plenty of java apps that were, for instance, performant in providing snappy interactive statistical analysis and visualization of very large data sets, or performant in processing very large transaction volumes very quickly. "performance" isn't just one thing, and the fact that someone can write an application that manages memory badly and lets GC get in its own way doesn't mean anything requiring "performance" should be written in something else. –  David Moles Nov 1 '11 at 22:25

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.