Java Reflection, but Faster
What is the fastest way to read a getter from a Java class without knowing the class at compilation time? Java frameworks often do this — a lot. And, it can directly influence their performance. So, let’s benchmark different approaches, such as reflection, method handles, and code generation.
Use Cases
Presume we have a simple Person
class with a name and an address:
public class Person {
...
public String getName() {...}
public Address getAddress() {...}
}
And, we want to use one of the frameworks, such as:
- XStream, JAXB, or Jackson to serialize instances to XML or JSON
- JPA/Hibernate to store persons in a database
- OptaPlanner to assign addresses (in case they’re tourists or homeless)
None of these frameworks know the Person
class. So, they can’t simply call person.getName()
:
// Framework code
public Object executeGetter(Object object) {
// Compilation error: class Person is unknown to the framework
return ((Person) object).getName();
}
Instead, the code uses reflection, method handles, or code generation.
But, such code is called an awful lot:
- If you insert 1000 different persons in a database, JPA/Hibernate probably calls such code 2000 times:
- 1000 calls to
Person.getName()
- another 1000 calls to
Person.getAddress()
- 1000 calls to
- Similarly, if you write 1000 different persons to XML or JSON, there are likely 2000 calls by XStream, JAXB or Jackson.
Obviously, when such code is called x times per second, its performance matters.
Benchmarks
Using JMH, I ran a set of micro-benchmarks using OpenJDK 1.8.0_111 on Linux on a 64-bit 8-core Intel i7-4790 desktop with 32GB RAM. The JMH benchmark ran with three forks, five warmup iterations of 1 second, and 20 measurement iterations of 1 second. All warmup costs are gone; increasing the length of an iteration to five seconds has little to no impact on the numbers reported here.
The source code of that benchmark is available on this GitHub repository.
TL;DR Results
- Java Reflection is slow.
- Java
MethodHandles
are slow too. - Generated code with
javax.tools.JavaCompiler
is fast. - LambdaMetafactory is pretty fast.
NOTE: These observations are based on the use cases I benchmarked with the workload I used. Your mileage may vary!
So, the devil is in the details. Let’s go through the implementations to confirm that I applied typical magical tricks, such as setAccessible(true)
.
Implementations
Direct Access: Baseline
I’ve used a normal person.getName()
call as the baseline:
public final class MyAccessor {
public Object executeGetter(Object object) {
return ((Person) object).getName();
}
}
This takes about 2.6 nanoseconds per operation:
Benchmark Mode Cnt Score Error Units
===================================================
DirectAccess avgt 60 2.590 ± 0.014 ns/op
Direct access is naturally the fastest approach at runtime, with no bootstrap cost. But, it imports Person
at compilation time, so it’s unusable by every framework.
Reflection
The obvious way for a framework read that getter at runtime, without knowing it in advance, is through Java Reflection:
public final class MyAccessor {
private final Method getterMethod;
public MyAccessor() {
getterMethod = Person.class.getMethod("getName");
// Skip Java language access checking during executeGetter()
getterMethod.setAccessible(true);
}
public Object executeGetter(Object bean) {
return getterMethod.invoke(bean);
}
}
Adding the setAccessible(true)
call makes these reflection calls faster, but even then, it takes 5.5 nanoseconds per call.
Benchmark Mode Cnt Score Error Units
===================================================
DirectAccess avgt 60 2.590 ± 0.014 ns/op
Reflection avgt 60 5.275 ± 0.053 ns/op
Reflection is 104 percent slower than direct access, meaning it is about twice as slow. It also takes longer to warm up.
This wasn’t a big surprise to me, because when I profile using sampling and a simple Traveling Salesman Problem with 980 cities in OptaPlanner, the reflection cost sticks out like a sore thumb:
MethodHandles
MethodHandle
was introduced in Java 7 to support invokedynamic instructions. According to the Javadoc, it’s a typed, directly executable reference to an underlying method. Sounds fast, right?
public final class MyAccessor {
private final MethodHandle getterMethodHandle;
public MyAccessor() {
MethodHandles.Lookup lookup = MethodHandles.lookup();
// findVirtual() matches signature of Person.getName()
getterMethodHandle = lookup.findVirtual(Person.class, "getName", MethodType.methodType(String.class))
// asType() matches signature of MyAccessor.executeGetter()
.asType(MethodType.methodType(Object.class, Object.class));
}
public Object executeGetter(Object bean) {
return getterMethodHandle.invokeExact(bean);
}
}
Well, unfortunately, MethodHandle
is even slower than reflection in OpenJDK 8. It takes 6.1 nanoseconds per operation, so it's 136 percent slower than direct access.
Benchmark Mode Cnt Score Error Units
===================================================
DirectAccess avgt 60 2.590 ± 0.014 ns/op
Reflection avgt 60 5.275 ± 0.053 ns/op
MethodHandle avgt 60 6.100 ± 0.079 ns/op
Using lookup.unreflectGetter(Field)
instead of lookup.findVirtual(…)
has no notable difference. I do hope that MethodHandle
will become as fast as direct access in future Java versions.
Static MethodHandles
I also ran a benchmark with MethodHandle
in a static field. The JVM can do more magic with static fields, as explained by Aleksey Shipilёv. Aleksey and John O’Hara correctly pointed out that the original benchmark didn’t use static fields correctly, so I fixed that. Here are the amended results:
Benchmark Mode Cnt Score Error Units
===================================================
DirectAccess avgt 60 2.590 ± 0.014 ns/op
MethodHandle avgt 60 6.100 ± 0.079 ns/op
StaticMethodHandle avgt 60 2.635 ± 0.027 ns/op
Yes, a static MethodHandle
is as fast as direct access, but it’s still useless, unless we want to write code like this:
public final class MyAccessors {
private static final MethodHandle handle1; // Person.getName()
private static final MethodHandle handle2; // Person.getAge()
private static final MethodHandle handle3; // Company.getName()
private static final MethodHandle handle4; // Company.getAddress()
private static final MethodHandle handle5; // ...
private static final MethodHandle handle6;
private static final MethodHandle handle7;
private static final MethodHandle handle8;
private static final MethodHandle handle9;
...
private static final MethodHandle handle1000;
}
If our framework deals with a domain class hierarchy with four getters, it would fill up the first four fields. However, if it deals with 100 domain classes with 20 getters each, totaling 2000 getters, it will crash due to a lack of static fields.
Besides, if I wrote code like this, even first-year students would come to tell me that I am doing it wrong. Static fields shouldn’t be used for instance variables.
Generated Code With javax.tools.JavaCompiler
In Java, it’s possible to compile and run generated Java code at runtime. So, with the javax.tools.JavaCompiler
API, we can generate the direct access code at runtime:
public abstract class MyAccessor {
// Just a gist of the code, the full source code is linked in a previous section
public static MyAccessor generate() {
final String String fullClassName = "x.y.generated.MyAccessorPerson$getName";
final String source = "package x.y.generated;\n"
+ "public final class MyAccessorPerson$getName extends MyAccessor {\n"
+ " public Object executeGetter(Object bean) {\n"
+ " return ((Person) object).getName();\n"
+ " }\n"
+ "}";
JavaFileObject fileObject = new ...(fullClassName, source);
JavaCompiler compiler = ToolProvider.getSystemJavaCompiler();
ClassLoader classLoader = ...;
JavaFileManager javaFileManager = new ...(..., classLoader)
CompilationTask task = compiler.getTask(..., javaFileManager, ..., singletonList(fileObject));
boolean success = task.call();
...
Class compiledClass = classLoader.loadClass(fullClassName);
return compiledClass.newInstance();
}
// Implemented by the generated subclass
public abstract Object executeGetter(Object object);
}
The full source code is much longer and available in this GitHub repository. For more information on how to use javax.tools.JavaCompiler
, take a look at page 2 of this article or this article. In Java 8, it requires the tools.jar
on the classpath, which is there automatically in a JDK installation. In Java 9, it requires the module java.compiler
in the modulepath. Also, proper care needs to be taken so that it doesn’t generate a classlist.mf
file in the working directory and uses the correct ClassLoader
.
Besides javax.tools.JavaCompiler
, similar approaches can use ASM or CGLIB, but those infer Maven dependencies and might have different performance results.
In any case, the generated code is as fast as direct access:
Benchmark Mode Cnt Score Error Units
===================================================
DirectAccess avgt 60 2.590 ± 0.014 ns/op
JavaCompiler avgt 60 2.726 ± 0.026 ns/op
So, when I ran that Traveling Salesman Problem again in the OptaPlanner, this time using code generation to access planning variables, the score calculation speed was 18 percent faster, overall. And, the profiling (using sampling) looks much better too:
Note that in normal use cases, that performance gain will hardly be detectable, due to massive CPU needs of a realistically complex score calculation.
One downside of code generation at runtime is that it infers a noticeable bootstrap cost (as discussed later), especially if the generated code isn’t compiled in bulk. So, I am still hoping that someday MethodHandles
will get as fast as direct access, just to avoid that bootstrap cost and the dependency pain.
LambdaMetafactory
On Reddit, I received an eloquent suggestion to use LambdaMetafactory
:
Getting LambdaMetafactory
to work on a non-static method turned out to be challenging, due to lack of documentation and StackOverflow questions, but it does work:
public final class MyAccessor {
private final Function getterFunction;
public MyAccessor() {
MethodHandles.Lookup lookup = MethodHandles.lookup();
CallSite site = LambdaMetafactory.metafactory(lookup,
"apply",
MethodType.methodType(Function.class),
MethodType.methodType(Object.class, Object.class),
lookup.findVirtual(Person.class, "getName", MethodType.methodType(String.class)),
MethodType.methodType(String.class, Person.class));
getterFunction = (Function) site.getTarget().invokeExact();
}
public Object executeGetter(Object bean) {
return getterFunction.apply(bean);
}
}
And, it looks good: LambdaMetafactory
is almost as fast as direct access. It’s only 33 percent slower than direct access, so much better than reflection.
Benchmark Mode Cnt Score Error Units
===================================================
DirectAccess avgt 60 2.590 ± 0.014 ns/op
Reflection avgt 60 5.275 ± 0.053 ns/op
LambdaMetafactory avgt 60 3.453 ± 0.034 ns/op
When I ran that Traveling Salesman Problem again in OptaPlanner, this time using LambdaMetafactory
to access planning variables, the score calculation speed was 9 percent faster overall. However, the profiling (using sampling) still shows a lot of executeGetter()
time that is still less than with reflection.
The metaspace cost seems to be about 2kb per lambda in a non-scientific measurement and it gets garbage collected normally.
Bootstrap Cost
The runtime cost matters most, as it’s not uncommon to retrieve a getter on thousands of instances per second. However, the bootstrap cost matters, too, because we need to create a MyAccessor
for every getter in the domain hierarchy that we want to reflect over, such as Person.getName()
, Person.getAddress()
, Address.getStreet()
, Address.getCity().
Reflection
and MethodHandle
have a neglectable bootstrap cost. For LambdaMetafactory
, it is still acceptable. My machine creates about 25k accessors per second. But for JavaCompiler
, it is not — my machine creates only about 200 accessors per second.
Benchmark Mode Cnt Score Error Units
=======================================================================
Reflection Bootstrap avgt 60 268.510 ± 25.271 ns/op // 0.3µs/op
MethodHandle Bootstrap avgt 60 1519.177 ± 46.644 ns/op // 1.5µs/op
JavaCompiler Bootstrap avgt 60 4814526.314 ± 503770.574 ns/op // 4814.5µs/op
LambdaMetafactory Bootstrap avgt 60 38904.287 ± 1330.080 ns/op // 39.9µs/op
This benchmark does not do caching or bulk complication.
Conclusion
In this investigation, reflection and (usable) MethodHandles
are twice as slow as the direct access in OpenJDK 8. Generated code is as fast as direct access, but it’s a pain. LambdaMetafactory
is almost as fast as direct access.
Benchmark Mode Cnt Score Error Units
===================================================
DirectAccess avgt 60 2.590 ± 0.014 ns/op
Reflection avgt 60 5.275 ± 0.053 ns/op // 104% slower
MethodHandle avgt 60 6.100 ± 0.079 ns/op // 136% slower
StaticMethodHandle avgt 60 2.635 ± 0.027 ns/op // 2% slower
JavaCompiler avgt 60 2.726 ± 0.026 ns/op // 5% slower
LambdaMetafactory avgt 60 3.453 ± 0.034 ns/op // 33% slower
Your mileage may vary.
Happy coding!