Replacing a JSON Message Converter With MessagePack
You may be using JSON to transfer data (we were using it in our message queue). While this is good, it has the only benefit of being human-readable. If you don’t care about readability, you’d probably want to use a more efficient serialization mechanism. Multiple options exist: protobuf, MessagePack, protostuff, java serialization. The easiest of them to use is java serialization, but it is less efficient (with both memory and time) than the other solutions. There are some benchmarks that will help you choose the most efficient solution, but if you want it to be easy and almost drop-in replacement to your JSON solution, MessagePack might be the best option.
I made a simple test to compare the JSON output to the MessagePack output in terms of size: 2300 vs 150 bytes for a simple message. Pretty good reduction, and if the messages are a lot, it’s a must to optimize.
However, you need to register all classes in the message pack. There are two options:
- use @Message on all the objects in the serialized graph. This is a bit tedious, especially if you already have a lot of classes that are transferred. You have to go through the whole graph
- you can manually register all classes with the mesagpack. Again tedious, because you also have to register all classes that the message class contains as a field (recursively)
That’s why I wrote the following code to loop all our message classes, and register them with the message pack on startup. It partly relies on spring classes, but if you are not using Spring, you can replace them:
private MessagePack serializer = new MessagePack(); private ClassMapper classMapper = new DefaultClassMapper(); @PostConstruct public void init() { // we need to find all messages, and register their classes, and also all their fields' recursively ClassPathScanningCandidateComponentProvider provider = new ClassPathScanningCandidateComponentProvider(false); Set<BeanDefinition> classes = provider.findCandidateComponents("com.foo.bar.messages"); // hacking MessagePack to allow Set handling Field fld = ReflectionUtils.findField(MessagePack.class, "registry"); ReflectionUtils.makeAccessible(fld); TemplateRegistry registry = (TemplateRegistry) ReflectionUtils.getField(fld, serializer); registry.register(Set.class, new SetTemplate(new AnyTemplate(registry))); registry.registerGeneric(Set.class, new GenericCollectionTemplate(registry, SetTemplate.class)); try { for (BeanDefinition def : classes) { Class<?> clazz = Class.forName(def.getBeanClassName()); registerHierarcy(clazz, serializer, Sets.<Class<?>>newHashSet()); } } catch (ClassNotFoundException e) { throw new IllegalStateException(e); } } private void registerHierarcy(Class<?> clazz, MessagePack serializer, Set<Class<?>> handledClasses) { if (!isEligibleForRegistration(clazz)) { return; } Class<?> currentClass = clazz; while (currentClass != null && !currentClass.isEnum() && currentClass != Object.class) { for (Field field : currentClass.getDeclaredFields()) { registerHierarcy(field.getType(), serializer, handledClasses); // type parameters Type type = field.getGenericType(); if (type instanceof ParameterizedType) { for (Type typeParam : ((ParameterizedType) type).getActualTypeArguments()) { // avoid circular generics references, resulting in stackoverflow Class<?> typeParamClass = (Class<?>) typeParam; if (!handledClasses.contains(typeParamClass)) { handledClasses.add(typeParamClass); registerHierarcy(typeParamClass, serializer, handledClasses); } } } } currentClass = currentClass.getSuperclass(); } try { serializer.register(clazz); } catch (Exception ex) { logger.warn("Problem registering class " + clazz, ex.getMessage()); } } private boolean isEligibleForRegistration(Class<?> clazz) { return !(clazz.isAnnotationPresent(Entity.class) || clazz == Class.class || Type.class.isAssignableFrom(clazz) || clazz.isInterface() || clazz.isArray() || ClassUtils.isPrimitiveOrWrapper(clazz) || clazz == String.class || clazz == Date.class || clazz == Object.class); }