58 lines
4.3 KiB
Plaintext
58 lines
4.3 KiB
Plaintext
= Differences From ActiveMQ "Classic"
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== Architectural differences
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Although they are designed to do the same job, things are done differently internally.
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Here are some of the most notable architectural differences you need to be aware of when you're planning the migration.
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In ActiveMQ, we have a few different implementations of the IO connectivity layer, like tcp (synchronous one) and nio (non-blocking one).
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In Artemis, the IO layer is implemented using Netty, which is a nio framework.
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This means that there's no more need to choose between different implementations as the non-blocking one is used by default.
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The other important part of every broker is a message store.
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Most of the ActiveMQ users are familiar with KahaDB.
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It consists of a message journal for fast sequential storing of messages (and other command packets) and an index for retrieving messages when needed.
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Artemis has its own message store.
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It consists only of the append-only message journal.
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Because of the differences in how paging is done, there's no need for the message index.
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We'll talk more about that in a minute.
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It's important to say at this point that these two stores are not interchangeable, and data migration if needed must be carefully planed.
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What do we mean by paging differences?
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Paging is the process that happens when broker can't hold all incoming messages in its memory.
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The strategy of how to deal with this situation differs between two brokers.
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ActiveMQ have _cursors_, which are basically a cache of messages ready to be dispatched to the consumer.
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It will try to keep all incoming messages in there.
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When we run out of the available memory, messages are added to the store, but the caching stops.
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When the space become available again, the broker will fill the cache again by pulling messages from the store in batches.
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Because of this, we need to read the journal from time to time during a broker runtime.
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In order to do that, we need to maintain a journal index, so that messages' position can be tracked inside the journal.
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In Artemis, things work differently in this regard.
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The whole message journal is kept in memory and messages are dispatched directly from it.
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When we run out of memory, messages are paged _on the producer side_ (before they hit the broker).
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Theay are stored in sequential page files in the same order as they arrived.
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Once the memory is freed, messages are moved from these page files into the journal.
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With paging working like this, messages are read from the file journal only when the broker starts up, in order to recreate this in-memory version of the journal.
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In this case, the journal is only read sequentially, meaning that there's no need to keep an index of messages in the journal.
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This is one of the main differences between ActiveMQ "Classic" and Artemis.
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It's important to understand it early on as it affects a lot of destination policy settings and how we configure brokers in order to support these scenarios properly.
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== Addressing differences
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Another big difference that's good to cover early on is the difference of how message addressing and routing is done.
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ActiveMQ started as an open source JMS implementation, so at its core all JMS concepts like queues, topics and durable subscriptions are implemented as the first-class citizens.
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It's all based on OpenWire protocol developed within the project and even KahaDB message store is OpenWire centric.
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This means that all other supported protocols, like MQTT and AMQP are translated internally into OpenWire.
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Artemis took a different approach.
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It implements only queues internally and all other messaging concepts are achieved by routing messages to appropriate queue(s) using addresses.
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Messaging concepts like publish-subscribe (topics) and point-to-point (queues) are implemented using different type of routing mechanisms on addresses.
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_Multicast_ routing is used to implement _publish-subscribe_ semantics, where all subscribers to a certain address will get their own internal queue and messages will be routed to all of them.
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_Anycast_ routing is used implement _point-to-point_ semantics, where there'll be only one queue for the address and all consumers will subscribe to it.
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The addressing and routing scheme is used across all protocols.
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So for example, you can view the JMS topic just as a multicast address.
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We'll cover this topic in more details in the later articles.
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