To better understand the following sections, some basic knowledge about the concepts of the application node and cluster are required.

One or more ElasticSearch nodes can be set up on a physical or a virtual server depending on the available resources such as RAM, CPU, and disk space.

A default node allows you to store data in it to process requests and responses. (In Chapter 2, Downloading and Setting Up, we'll see details about how to set up different nodes and cluster topologies).

When a node is started, several actions take place during its startup, such as:

After the node startup, the node searches for other cluster members and checks its index and shard status.

To join two or more nodes in a cluster, the following rules must be observed:

A common approach in cluster management is to have a master node, which is the main reference for all cluster-level actions, and the other nodes, called secondary nodes, that replicate the master data and its actions.

To be consistent in the write operations, all the update actions are first committed in the master node and then replicated in the secondary nodes.

In a cluster with multiple nodes, if a master node dies, a master-eligible node is elected to be the new master node. This approach allows automatic failover to be set up in an ElasticSearch cluster.

There are two important behaviors in an ElasticSearch node: the non-data node (or arbiter) and the data container behavior.

Non-data nodes are able to process REST responses and all other operations of search. During every action execution, ElasticSearch generally executes actions using a map/reduce approach: the non-data node is responsible for distributing the actions to the underlying shards (map) and collecting/aggregating the shard results (redux) to be able to send a final response. They may use a huge amount of RAM due to operations such as facets, aggregations, collecting hits and caching (such as scan/scroll queries).

Data nodes are able to store data in them. They contain the indices shards that store the indexed documents as Lucene (internal ElasticSearch engine) indices.

Using the standard configuration, a node is both an arbiter and a data container.

In big cluster architectures, having some nodes as simple arbiters with a lot of RAM, with no data, reduces the resources required by data nodes and improves performance in searches using the local memory cache of arbiters.

Every ElasticSearch server that is running provides services.

ElasticSearch natively provides a large set of functionalities that can be extended with additional plugins.

During a node startup, a lot of required services are automatically started. The most important are:

To work with ElasticSearch data, a user must have basic concepts of data management and JSON data format, which is the lingua franca to work with ElasticSearch data and services.

Our main data container is called index (plural indices) and it can be considered as a database in the traditional SQL world. In an index, the data is grouped into data types called mappings in ElasticSearch. A mapping describes how the records are composed (fields).

Every record that must be stored in ElasticSearch must be a JSON object.

Natively, ElasticSearch is a schema-less data store; when you enter records in it during the insert process it processes the records, splits it into fields, and updates the schema to manage the inserted data.

To manage huge volumes of records, ElasticSearch uses the common approach to split an index into multiple shards so that they can be spread on several nodes. Shard management is transparent to the users; all common record operations are managed automatically in the ElasticSearch application layer.

Every record is stored in only a shard; the sharding algorithm is based on a record ID, so many operations that require loading and changing of records/objects, can be achieved without hitting all the shards, but only the shard (and its replica) that contains your object.

The following schema compares ElasticSearch structure with SQL and MongoDB ones:

To ensure safe operations on index/mapping/objects, ElasticSearch internally has rigid rules about how to execute operations.

In ElasticSearch, the operations are divided into:

When a record is saved in ElasticSearch, the destination shard is chosen based on:

Splitting an index in shard allows you to store your data in different nodes, because ElasticSearch tries to balance the shard distribution on all the available nodes.

Every shard can contain up to 2^32 records (about 4.9 billion), so the real limit to a shard size is its storage size.

Shards contain your data and during search process all the shards are used to calculate and retrieve results. So ElasticSearch performance in big data scales horizontally with the number of shards.

All native records operations (such as index, search, update, and delete) are managed in shards.

Shard management is completely transparent to the user. Only an advanced user tends to change the default shard routing and management to cover their custom scenarios. A common custom scenario is the requirement to put customer data in the same shard to speed up his operations (search/index/analytics).

You need one or more nodes running to have a cluster. To test an effective cluster, you need at least two nodes (that can be on the same machine).

An index can have one or more replicas; the shards are called primary if they are part of the primary replica, and secondary ones if they are part of replicas.

To maintain consistency in write operations, the following workflow is executed:

During search operations, if there are some replicas, a valid set of shards is chosen randomly between primary and secondary to improve its performance. ElasticSearch has several allocation algorithms to better distribute shards on nodes. For reliability, replicas are allocated in a way that if a single node becomes unavailable, there is always at least one replica of each shard that is still available on the remaining nodes.

The following figure shows some examples of possible shards and replica configuration:

The replica has a cost in increasing the indexing time due to data node synchronization, which is the time spent to propagate the message to the slaves (mainly in an asynchronous way).

Related to the concept of replication, there is the cluster status indicator that will show you information on the health of your cluster. It can cover three different states:

Setting up different node types in the next chapter.

You will need a working instance of the ElasticSearch cluster.

ElasticSearch is designed to be used as a RESTful server, so the main protocol is the HTTP, usually on port number 9200 and above. Thus, it allows using different protocols such as native and thrift ones.

Many others are available as extension plugins, but they are seldom used, such as memcached, couchbase, and websocket. (If you need to find more on the transport layer, simply type in Elasticsearch transport on the GitHub website to search.)

Every protocol has advantages and disadvantages. It's important to choose the correct one depending on the kind of applications you are developing. If you are in doubt, choose the HTTP Protocol layer that is the standard protocol and is easy to use.

Choosing the right protocol depends on several factors, mainly architectural and performance related. This schema factorizes advantages and disadvantages related to them. If you are using any of the protocols to communicate with ElasticSearch official clients, switching from a protocol to another is generally a simple setting in the client initialization.

You need a working instance of the ElasticSearch cluster. Using default configuration, ElasticSearch enables port number 9200 on your server to communicate in HTTP.

The standard RESTful protocol is easy to integrate.

We will see how easy it is to fetch the ElasticSearch greeting API on a running server on port 9200 using different programming languages:

For every language sample, the response will be the same:

{
  "ok" : true,
  "status" : 200,
  "name" : "Payge, Reeva",
  "version" : {
    "number" : "1.4.0",
    "snapshot_build" : false
  },
  "tagline" : "You Know, for Search"
}

Every client creates a connection to the server index / and fetches the answer. The answer is a valid JSON object. You can invoke the ElasticSearch server from any language that you like.

The main advantages of this protocol are:

In this book, a lot of the examples are done by calling the HTTP API via the command-line cURL program. This approach is very fast and allows you to test functionalities very quickly.

Every language provides drivers for best integration with ElasticSearch or RESTful web services.

The ElasticSearch community provides official drivers that support the most used programming languages.

You need a working instance of the ElasticSearch cluster; the standard port number for native protocol is 9300.

The following are the steps required to use the native protocol in a Java environment (we'll discuss this in depth in Chapter 10, Java Integration):

To initialize a native client, a settings object is required, which contains some configuration parameters. The most important ones are:

With the settings object, it's possible to initialize a new client by giving an IP address and port a number (default 9300).

The native protocol is the internal one used in ElasticSearch. It's the fastest protocol that is available to communicate with ElasticSearch.

The native protocol is an optimized binary and works only for JVM languages; to use this protocol, you need to include the elasticsearch.jar in your JVM project. Because it depends on ElasticSearch implementation, it must be the same version of ElasticSearch cluster.

For this reason, every time you update ElasticSearch, you need to update the elasticsearch.jar file on which it depends and if there are internal API changes, you need to update your code.

To use this protocol, you need to study the internals of ElasticSearch, so it's not as easy to use as HTTP and Thrift protocol.

Native protocol is useful for massive data import. But as ElasticSearch is mainly thought as a REST HTTP server to communicate with, it lacks support for everything that is not standard in the ElasticSearch core, such as the plugin's entry points. So using this protocol, you are unable to call entry points made by external plugins.

You need a working instance of ElasticSearch cluster with the thrift plugin installed (https://github.com/elasticsearch/elasticsearch-transport-thrift/); the standard port for the Thrift protocol is 9500.

To use the Thrift protocol in a Java environment, perform the following steps:

Some drivers, to connect to ElasticSearch, provide an easy-to-use API to interact with Thrift without the boulder that this protocol needs.

For advanced usage, I suggest the use of the Thrift protocol to bypass some problems related to HTTP limits, such as:

A big advantage of this protocol is that on the server side it wraps the REST entry points so that it can also be used with calls provided by external REST plugins.