Apache Fury (incubating) is a blazingly-fast multi-language serialization framework powered by JIT (just-in-time compilation) and zero-copy, providing up to 170x performance and ultimate ease of use.
Important
Apache Fury (incubating) is an effort undergoing incubation at the Apache Software Foundation (ASF), sponsored by the Apache Incubator PMC.
Please read the DISCLAIMER and a full explanation of "incubating".
- Multiple languages: Java/Python/C++/Golang/JavaScript/Rust/Scala/TypeScript.
- Zero-copy: Cross-language out-of-band serialization inspired by pickle5 and off-heap read/write.
- High performance: A highly-extensible JIT framework to generate serializer code at runtime in an async multi-thread way to speed serialization, providing 20-170x speed up by:
- reduce memory access by inlining variables in generated code.
- reduce virtual method invocation by inline call in generated code.
- reduce conditional branching.
- reduce hash lookup.
- Multiple binary protocols: Object graph, row format, and so on.
In addition to cross-language serialization, Fury also features at:
- Drop-in replace Java serialization frameworks such as JDK/Kryo/Hessian, but 100x faster at most, which can greatly improve the efficiency of high-performance RPC calls, data transfer, and object persistence.
- 100% compatible with JDK serialization API with much faster implementation: supporting JDK
writeObject/readObject/writeReplace/readResolve/readObjectNoData/ExternalizableAPI. - Supports Java 8~21, Java 17+
recordis supported too. - Supports AOT compilation serialization for GraalVM native image, and no reflection/serialization json config are needed.
- Supports shared and circular reference object serialization for golang.
- Supports scala serialization
- Supports automatic object serialization for golang.
Fury designed and implemented multiple binary protocols for different scenarios:
- xlang serialization format:
- Cross-language serialize any object automatically, no need for IDL definition, schema compilation and object to/from protocol conversion.
- Support optional shared reference and circular reference, no duplicate data or recursion error.
- Support object polymorphism.
- Java serialization format: Highly-optimized and drop-in replacement for Java serialization.
- Row format format: A cache-friendly binary random access format, supports skipping serialization and partial serialization, and can convert to column-format automatically.
New protocols can be easily added based on Fury existing buffer, encoding, meta, codegen and other capabilities. All of those share the same codebase, and the optimization for one protocol can be reused by another protocol.
Different serialization frameworks are suitable for different scenarios, and benchmark results here are for reference only.
If you need to benchmark for your specific scenario, make sure all serialization frameworks are appropriately configured for that scenario.
Dynamic serialization frameworks support polymorphism and references, but they often come with a higher cost compared to static serialization frameworks, unless they utilize JIT techniques like Fury does. To ensure accurate benchmark statistics, it is advisable to warm up the system before collecting data due to Fury's runtime code generation.
In these charts below, titles containing "compatible" represent schema compatible mode: type forward/backward compatibility is enabled; while titles without "compatible" represent schema consistent mode: class schema must be the same between serialization and deserialization.
Where Struct is a class with 100 primitive fields, MediaContent is a class from jvm-serializers, and Sample is a class from kryo benchmark.
See benchmarks for more benchmarks about type forward/backward compatibility, off-heap support, zero-copy serialization.
Nightly snapshot:
<repositories>
<repository>
<id>apache</id>
<url>https://repository.apache.org/snapshots/</url>
<releases>
<enabled>false</enabled>
</releases>
<snapshots>
<enabled>true</enabled>
</snapshots>
</repository>
</repositories>
<dependency>
<groupId>org.apache.fury</groupId>
<artifactId>fury-core</artifactId>
<version>0.7.0-SNAPSHOT</version>
</dependency>
<!-- row/arrow format support -->
<!-- <dependency>
<groupId>org.apache.fury</groupId>
<artifactId>fury-format</artifactId>
<version>0.7.0-SNAPSHOT</version>
</dependency> -->Release version:
<dependency>
<groupId>org.apache.fury</groupId>
<artifactId>fury-core</artifactId>
<version>0.6.0</version>
</dependency>
<!-- row/arrow format support -->
<!-- <dependency>
<groupId>org.apache.fury</groupId>
<artifactId>fury-format</artifactId>
<version>0.6.0</version>
</dependency> -->libraryDependencies += "org.apache.fury" % "fury-core" % "0.6.0"pip install pyfurynpm install @furyjs/furygo get github.com/apache/fury/go/furyHere we give a quick start about how to use Fury, see user guide for more details about java, cross language, and row format.
If you don't have cross-language requirements, using this mode will result in better performance.
import org.apache.fury.*;
import org.apache.fury.config.*;
import java.util.*;
public class Example {
public static void main(String[] args) {
SomeClass object = new SomeClass();
// Note that Fury instances should be reused between
// multiple serializations of different objects.
{
Fury fury = Fury.builder().withLanguage(Language.JAVA)
.requireClassRegistration(true)
.build();
// Registering types can reduce class name serialization overhead, but not mandatory.
// If class registration enabled, all custom types must be registered.
fury.register(SomeClass.class);
byte[] bytes = fury.serialize(object);
System.out.println(fury.deserialize(bytes));
}
{
ThreadSafeFury fury = Fury.builder().withLanguage(Language.JAVA)
.requireClassRegistration(true)
.buildThreadSafeFury();
// Registering types can reduce class name serialization overhead, but not mandatory.
// If class registration enabled, all custom types must be registered.
fury.register(SomeClass.class);
byte[] bytes = fury.serialize(object);
System.out.println(fury.deserialize(bytes));
}
{
ThreadSafeFury fury = new ThreadLocalFury(classLoader -> {
Fury f = Fury.builder().withLanguage(Language.JAVA)
.withClassLoader(classLoader).build();
f.register(SomeClass.class);
return f;
});
byte[] bytes = fury.serialize(object);
System.out.println(fury.deserialize(bytes));
}
}
}Java
import org.apache.fury.*;
import org.apache.fury.config.*;
import java.util.*;
public class ReferenceExample {
public static class SomeClass {
SomeClass f1;
Map<String, String> f2;
Map<String, String> f3;
}
public static Object createObject() {
SomeClass obj = new SomeClass();
obj.f1 = obj;
obj.f2 = ofHashMap("k1", "v1", "k2", "v2");
obj.f3 = obj.f2;
return obj;
}
// mvn exec:java -Dexec.mainClass="org.apache.fury.examples.ReferenceExample"
public static void main(String[] args) {
Fury fury = Fury.builder().withLanguage(Language.XLANG)
.withRefTracking(true).build();
fury.register(SomeClass.class, "example.SomeClass");
byte[] bytes = fury.serialize(createObject());
// bytes can be data serialized by other languages.
System.out.println(fury.deserialize(bytes));
}
}Python
from typing import Dict
import pyfury
class SomeClass:
f1: "SomeClass"
f2: Dict[str, str]
f3: Dict[str, str]
fury = pyfury.Fury(ref_tracking=True)
fury.register_class(SomeClass, type_tag="example.SomeClass")
obj = SomeClass()
obj.f2 = {"k1": "v1", "k2": "v2"}
obj.f1, obj.f3 = obj, obj.f2
data = fury.serialize(obj)
# bytes can be data serialized by other languages.
print(fury.deserialize(data))Golang
package main
import furygo "github.com/apache/fury/go/fury"
import "fmt"
func main() {
type SomeClass struct {
F1 *SomeClass
F2 map[string]string
F3 map[string]string
}
fury := furygo.NewFury(true)
if err := fury.RegisterTagType("example.SomeClass", SomeClass{}); err != nil {
panic(err)
}
value := &SomeClass{F2: map[string]string{"k1": "v1", "k2": "v2"}}
value.F3 = value.F2
value.F1 = value
bytes, err := fury.Marshal(value)
if err != nil {
}
var newValue interface{}
// bytes can be data serialized by other languages.
if err := fury.Unmarshal(bytes, &newValue); err != nil {
panic(err)
}
fmt.Println(newValue)
}public class Bar {
String f1;
List<Long> f2;
}
public class Foo {
int f1;
List<Integer> f2;
Map<String, Integer> f3;
List<Bar> f4;
}
RowEncoder<Foo> encoder = Encoders.bean(Foo.class);
Foo foo = new Foo();
foo.f1 = 10;
foo.f2 = IntStream.range(0, 1000000).boxed().collect(Collectors.toList());
foo.f3 = IntStream.range(0, 1000000).boxed().collect(Collectors.toMap(i -> "k"+i, i->i));
List<Bar> bars = new ArrayList<>(1000000);
for (int i = 0; i < 1000000; i++) {
Bar bar = new Bar();
bar.f1 = "s"+i;
bar.f2 = LongStream.range(0, 10).boxed().collect(Collectors.toList());
bars.add(bar);
}
foo.f4 = bars;
// Can be zero-copy read by python
BinaryRow binaryRow = encoder.toRow(foo);
// can be data from python
Foo newFoo = encoder.fromRow(binaryRow);
// zero-copy read List<Integer> f2
BinaryArray binaryArray2 = binaryRow.getArray(1);
// zero-copy read List<Bar> f4
BinaryArray binaryArray4 = binaryRow.getArray(3);
// zero-copy read 11th element of `readList<Bar> f4`
BinaryRow barStruct = binaryArray4.getStruct(10);
// zero-copy read 6th of f2 of 11th element of `readList<Bar> f4`
barStruct.getArray(1).getInt64(5);
RowEncoder<Bar> barEncoder = Encoders.bean(Bar.class);
// deserialize part of data.
Bar newBar = barEncoder.fromRow(barStruct);
Bar newBar2 = barEncoder.fromRow(binaryArray4.getStruct(20));@dataclass
class Bar:
f1: str
f2: List[pa.int64]
@dataclass
class Foo:
f1: pa.int32
f2: List[pa.int32]
f3: Dict[str, pa.int32]
f4: List[Bar]
encoder = pyfury.encoder(Foo)
foo = Foo(f1=10, f2=list(range(1000_000)),
f3={f"k{i}": i for i in range(1000_000)},
f4=[Bar(f1=f"s{i}", f2=list(range(10))) for i in range(1000_000)])
binary: bytes = encoder.to_row(foo).to_bytes()
foo_row = pyfury.RowData(encoder.schema, binary)
print(foo_row.f2[100000], foo_row.f4[100000].f1, foo_row.f4[200000].f2[5])Fury java object graph serialization supports class schema forward/backward compatibility. The serialization peer and deserialization peer can add/delete fields independently.
We plan to add the schema compatibility support of cross-language serialization after meta compression is finished.
We are still improving our protocols, thus binary compatibility is not guaranteed between Fury major releases for now.
However, it is guaranteed between minor versions. Please
versioning your data by Fury major version if you will upgrade Fury in the future, see how to upgrade fury for further details.
Binary compatibility will be guaranteed when Fury 1.0 is released.
Static serialization is relatively secure. But dynamic serialization such as Fury java/python native serialization supports deserializing unregistered types, which provides more dynamics and flexibility, but also introduce security risks.
For example, the deserialization may invoke init constructor or equals/hashCode method, if the method body contains malicious code, the system will be at risk.
Fury provides a class registration option that is enabled by default for such protocols, allowing only deserialization of trusted registered types or built-in types. Do not disable class registration unless you can ensure your environment is secure.
If this option is disabled, you are responsible for serialization security. You can configure org.apache.fury.resolver.ClassChecker by
ClassResolver#setClassChecker to control which classes are allowed for serialization.
To report security vulnerabilities found in Fury, please follow the ASF vulnerability reporting process.
Please read the BUILD guide for instructions on how to build.
Please read the CONTRIBUTING guide for instructions on how to contribute.
Licensed under the Apache License, Version 2.0