HBASE-13867: Add endpoint coprocessor guide to HBase book.
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HBase coprocessors are modeled after the coprocessors which are part of Google's BigTable (http://www.scribd.com/doc/21631448/Dean-Keynote-Ladis2009, pages 66-67.). Coprocessors function in a similar way to Linux kernel modules.
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They provide a way to run server-level code against locally-stored data.
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The functionality they provide is very powerful, but also carries great risk and can have adverse effects on the system, at the level of the operating system.
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The information in this chapter is primarily sourced and heavily reused from Mingjie Lai's blog post at https://blogs.apache.org/hbase/entry/coprocessor_introduction.
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HBase Coprocessors are modeled after the Coprocessors which are part of Google's BigTable
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(http://research.google.com/people/jeff/SOCC2010-keynote-slides.pdf pages 41-42.). +
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Coprocessor is a framework that provides an easy way to run your custom code directly on
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Region Server.
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The information in this chapter is primarily sourced and heavily reused from:
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. Mingjie Lai's blog post
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link:https://blogs.apache.org/hbase/entry/coprocessor_introduction[Coprocessor Introduction].
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. Gaurav Bhardwaj's blog post
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link:http://www.3pillarglobal.com/insights/hbase-coprocessors[The How To Of HBase Coprocessors].
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Coprocessors are not designed to be used by end users of HBase, but by HBase developers who need to add specialized functionality to HBase.
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One example of the use of coprocessors is pluggable compaction and scan policies, which are provided as coprocessors in link:https://issues.apache.org/jira/browse/HBASE-6427[HBASE-6427].
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== Coprocessor Framework
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The implementation of HBase coprocessors diverges from the BigTable implementation.
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The HBase framework provides a library and runtime environment for executing user code within the HBase region server and master processes.
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When working with any data store (like RDBMS or HBase) you fetch the data (in case of RDBMS you
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might use SQL query and in case of HBase you use either Get or Scan). To fetch only relevant data
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you filter it (for RDBMS you put conditions in 'WHERE' predicate and in HBase you use
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link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/filter/Filter.html[Filter]).
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After fetching the desired data, you perform your business computation on the data.
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This scenario is close to ideal for "small data", where few thousand rows and a bunch of columns
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are returned from the data store. Now imagine a scenario where there are billions of rows and
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millions of columns and you want to perform some computation which requires all the data, like
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calculating average or sum. Even if you are interested in just few columns, you still have to
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fetch all the rows. There are a few drawbacks in this approach as described below:
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The framework API is provided in the link:https://hbase.apache.org/apidocs/org/apache/hadoop/hbase/coprocessor/package-summary.html[coprocessor] package.
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. In this approach the data transfer (from data store to client side) will become the bottleneck,
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and the time required to complete the operation is limited by the rate at which data transfer
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takes place.
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. It's not always possible to hold so much data in memory and perform computation.
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. Bandwidth is one of the most precious resources in any data center. Operations like this may
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saturate your data center’s bandwidth and will severely impact the performance of your cluster.
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. Your client code is becoming thick as you are maintaining the code for calculating average or
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summation on client side. Not a major drawback when talking of severe issues like
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performance/bandwidth but still worth giving consideration.
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Two different types of coprocessors are provided by the framework, based on their scope.
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In a scenario like this it's better to move the computation (i.e. user's custom code) to the data
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itself (Region Server). Coprocessor helps you achieve this but you can do more than that.
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There is another advantage that your code runs in parallel (i.e. on all Regions).
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To give an idea of Coprocessor's capabilities, different people give different analogies.
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The three most famous analogies for Coprocessor are:
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[[cp_analogies]]
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Triggers and Stored Procedure:: This is the most common analogy for Coprocessor. Observer
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Coprocessor is compared to triggers because like triggers they execute your custom code when
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certain event occurs (like Get or Put etc.). Similarly Endpoints Coprocessor is compared to the
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stored procedures and you can perform custom computation on data directly inside the region server.
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.Types of Coprocessors
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MapReduce:: As in MapReduce you move the computation to the data in the same way. Coprocessor
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executes your custom computation directly on Region Servers, i.e. where data resides. That's why
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some people compare Coprocessor to a small MapReduce jobs.
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System Coprocessors::
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System coprocessors are loaded globally on all tables and regions hosted by a region server.
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AOP:: Some people compare it to _Aspect Oriented Programming_ (AOP). As in AOP, you apply advice
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(on occurrence of specific event) by intercepting the request and then running some custom code
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(probably cross-cutting concerns) and then forwarding the request on its path as if nothing
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happened (or even return it back). Similarly in Coprocessor you have this facility of intercepting
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the request and running custom code and then forwarding it on its path (or returning it).
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Table Coprocessors::
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You can specify which coprocessors should be loaded on all regions for a table on a per-table basis.
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The framework provides two different aspects of extensions as well: _observers_ and _endpoints_.
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Although Coprocessor derives its roots from Google's Bigtable but it deviates from it largely in
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its design. Currently there are efforts going on to bridge this gap. For more information see
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link:https://issues.apache.org/jira/browse/HBASE-4047[HBASE-4047].
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Observers::
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Observers are analogous to triggers in conventional databases.
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They allow you to insert user code by overriding upcall methods provided by the coprocessor framework.
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Callback functions are executed from core HBase code when events occur.
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Callbacks are handled by the framework, and the coprocessor itself only needs to insert the extended or alternate functionality.
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In HBase, to implement a Coprocessor certain steps must be followed as described below:
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Endpoints (HBase 0.96.x and later)::
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The implementation for endpoints changed significantly in HBase 0.96.x due to the introduction of protocol buffers (protobufs) (link:https://issues.apache.org/jira/browse/HBASE-5448[HBASE-5488]). If you created endpoints before 0.96.x, you will need to rewrite them.
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Endpoints are now defined and callable as protobuf services, rather than endpoint invocations passed through as Writable blobs
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. Either your class should extend one of the Coprocessor classes (like
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// Below URL is more than 100 characters long.
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link:https://hbase.apache.org/devapidocs/org/apache/hadoop/hbase/coprocessor/BaseRegionObserver.html[BaseRegionObserver]
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) or it should implement Coprocessor interfaces (like
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link:https://hbase.apache.org/devapidocs/org/apache/hadoop/hbase/Coprocessor.html[Coprocessor],
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// Below URL is more than 100 characters long.
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link:https://hbase.apache.org/devapidocs/org/apache/hadoop/hbase/coprocessor/CoprocessorService.html[CoprocessorService]).
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Endpoints (HBase 0.94.x and earlier)::
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Dynamic RPC endpoints resemble stored procedures.
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An endpoint can be invoked at any time from the client.
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When it is invoked, it is executed remotely at the target region or regions, and results of the executions are returned to the client.
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. Load the Coprocessor: Currently there are two ways to load the Coprocessor. +
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Static:: Loading from configuration
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Dynammic:: Loading via 'hbase shell' or via Java code using HTableDescriptor class). +
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For more details see <<cp_loading,Loading Coprocessors>>.
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== Examples
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. Finally your client-side code to call the Coprocessor. This is the easiest step, as HBase
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handles the Coprocessor transparently and you don't have to do much to call the Coprocessor.
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An example of an observer is included in _hbase-examples/src/test/java/org/apache/hadoop/hbase/coprocessor/example/TestZooKeeperScanPolicyObserver.java_.
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Several endpoint examples are included in the same directory.
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== Building A Coprocessor
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The framework API is provided in the
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// Below URL is more than 100 characters long.
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link:https://hbase.apache.org/apidocs/org/apache/hadoop/hbase/coprocessor/package-summary.html[coprocessor]
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package. +
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Coprocessors are not designed to be used by the end users but by developers. Coprocessors are
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executed directly on region server; therefore a faulty/malicious code can bring your region server
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down. Currently there is no mechanism to prevent this, but there are efforts going on for this.
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For more, see link:https://issues.apache.org/jira/browse/HBASE-4047[HBASE-4047]. +
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Two different types of Coprocessors are provided by the framework, based on their functionality.
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Before you can build a processor, it must be developed, compiled, and packaged in a JAR file.
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The next step is to configure the coprocessor framework to use your coprocessor.
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You can load the coprocessor from your HBase configuration, so that the coprocessor starts with HBase, or you can configure the coprocessor from the HBase shell, as a table attribute, so that it is loaded dynamically when the table is opened or reopened.
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=== Load from Configuration
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To configure a coprocessor to be loaded when HBase starts, modify the RegionServer's _hbase-site.xml_ and configure one of the following properties, based on the type of observer you are configuring:
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== Types of Coprocessors
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* `hbase.coprocessor.region.classes`for RegionObservers and Endpoints
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* `hbase.coprocessor.wal.classes`for WALObservers
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* `hbase.coprocessor.master.classes`for MasterObservers
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Coprocessor can be broadly divided into two categories: Observer and Endpoint.
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.Example RegionObserver Configuration
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====
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In this example, one RegionObserver is configured for all the HBase tables.
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=== Observer
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Observer Coprocessor are easy to understand. People coming from RDBMS background can compare them
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to the triggers available in relational databases. Folks coming from programming background can
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visualize it like advice (before and after only) available in AOP (Aspect Oriented Programming).
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See <<cp_analogies, Coprocessor Analogy>> +
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Coprocessors allows you to hook your custom code in two places during the life cycle of an event. +
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First is just _before_ the occurrence of the event (just like 'before' advice in AOP or triggers
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like 'before update'). All methods providing this kind feature will start with the prefix `pre`. +
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For example if you want your custom code to get executed just before the `Put` operation, you can
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use the override the
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// Below URL is more than 100 characters long.
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link:http://hbase.apache.org/devapidocs/org/apache/hadoop/hbase/coprocessor/RegionObserver.html#prePut%28org.apache.hadoop.hbase.coprocessor.ObserverContext,%20org.apache.hadoop.hbase.client.Put,%20org.apache.hadoop.hbase.regionserver.wal.WALEdit,%20org.apache.hadoop.hbase.client.Durability%29[`prePut`]
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method of
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// Below URL is more than 100 characters long.
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link:http://hbase.apache.org/devapidocs/org/apache/hadoop/hbase/coprocessor/RegionObserver.html[RegionCoprocessor].
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This method has following signature:
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[source,java]
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----
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public void prePut (final ObserverContext e, final Put put, final WALEdit edit,final Durability
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durability) throws IOException;
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----
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Secondly, the Observer Coprocessor also provides hooks for your code to get executed just _after_
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the occurrence of the event (similar to after advice in AOP terminology or 'after update' triggers
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). The methods giving this functionality will start with the prefix `post`. For example, if you
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want your code to be executed after the 'Put' operation, you should consider overriding
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// Below URL is more than 100 characters long.
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link:http://hbase.apache.org/devapidocs/org/apache/hadoop/hbase/coprocessor/RegionObserver.html#postPut%28org.apache.hadoop.hbase.coprocessor.ObserverContext,%20org.apache.hadoop.hbase.client.Put,%20org.apache.hadoop.hbase.regionserver.wal.WALEdit,%20org.apache.hadoop.hbase.client.Durability%29[`postPut`]
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method of
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// Below URL is more than 100 characters long.
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link:http://hbase.apache.org/devapidocs/org/apache/hadoop/hbase/coprocessor/RegionObserver.html[RegionCoprocessor]:
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[source,java]
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----
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public void postPut(final ObserverContext e, final Put put, final WALEdit edit, final Durability
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durability) throws IOException;
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----
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In short, the following conventions are generally followed: +
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Override _preXXX()_ method if you want your code to be executed just before the occurrence of the
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event. +
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Override _postXXX()_ method if you want your code to be executed just after the occurrence of the
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event. +
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.Use Cases for Observer Coprocessors:
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Few use cases of the Observer Coprocessor are:
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. *Security*: Before performing any operation (like 'Get', 'Put') you can check for permission in
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the 'preXXX' methods.
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. *Referential Integrity*: Unlike traditional RDBMS, HBase doesn't have the concept of referential
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integrity (foreign key). Suppose for example you have a requirement that whenever you insert a
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record in 'users' table, a corresponding entry should also be created in 'user_daily_attendance'
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table. One way you could solve this is by using two 'Put' one for each table, this way you are
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throwing the responsibility (of the referential integrity) to the user. A better way is to use
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Coprocessor and overriding 'postPut' method in which you write the code to insert the record in
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'user_daily_attendance' table. This way client code is more lean and clean.
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. *Secondary Index*: Coprocessor can be used to maintain secondary indexes. For more information
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see link:http://wiki.apache.org/hadoop/Hbase/SecondaryIndexing[SecondaryIndexing].
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==== Types of Observer Coprocessor
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Observer Coprocessor comes in following flavors:
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. *RegionObserver*: This Coprocessor provides the facility to hook your code when the events on
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region are triggered. Most common example include 'preGet' and 'postGet' for 'Get' operation and
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'prePut' and 'postPut' for 'Put' operation. For exhaustive list of supported methods (events) see
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// Below URL is more than 100 characters long.
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link:https://hbase.apache.org/devapidocs/org/apache/hadoop/hbase/coprocessor/RegionObserver.html[RegionObserver].
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. *Region Server Observer*: Provides hook for the events related to the RegionServer, such as
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stopping the RegionServer and performing operations before or after merges, commits, or rollbacks.
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For more details please refer
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link:https://hbase.apache.org/devapidocs/org/apache/hadoop/hbase/coprocessor/RegionServerObserver.html[RegionServerObserver].
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. *Master Observer*: This observer provides hooks for DDL like operation, such as create, delete,
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modify table. For entire list of available methods see
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// Below URL is more than 100 characters long.
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link:https://hbase.apache.org/devapidocs/org/apache/hadoop/hbase/coprocessor/MasterObserver.html[MasterObserver].
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. *WAL Observer*: Provides hooks for WAL (Write-Ahead-Log) related operation. It has only two
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method 'preWALWrite()' and 'postWALWrite()'. For more details see
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// Below URL is more than 100 characters long.
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link:http://hbase.apache.org/devapidocs/org/apache/hadoop/hbase/coprocessor/WALObserver.html[WALObserver].
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For example see <<cp_example,Examples>>
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=== Endpoint Coprocessor
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Endpoint Coprocessor can be compared to stored procedure found in RDBMS.
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See <<cp_analogies, Coprocessor Analogy>>. They help in performing computation which is not
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possible either through Observer Coprocessor or otherwise. For example, calculating average or
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summation over the entire table that spans across multiple regions. They do so by providing a hook
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for your custom code and then running it across all regions. +
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With Endpoints Coprocessor you can create your own dynamic RPC protocol and thus can provide
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communication between client and region server, hence enabling you to run your custom code on
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region server (on each region of a table). +
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Unlike observer Coprocessor (where your custom code is
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executed transparently when events like 'Get' operation occurs), in Endpoint Coprocessor you have
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to explicitly invoke the Coprocessor by using the
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// Below URL is more than 100 characters long.
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link:https://hbase.apache.org/devapidocs/org/apache/hadoop/hbase/client/Table.html#coprocessorService%28java.lang.Class,%20byte%5B%5D,%20byte%5B%5D,%20org.apache.hadoop.hbase.client.coprocessor.Batch.Call%29[CoprocessorService()]
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method available in
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link:https://hbase.apache.org/devapidocs/org/apache/hadoop/hbase/client/Table.html[Table]
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(or
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// Below URL is more than 100 characters long.
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link:https://hbase.apache.org/devapidocs/org/apache/hadoop/hbase/client/HTableInterface.html[HTableInterface]
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or
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link:https://hbase.apache.org/devapidocs/org/apache/hadoop/hbase/client/HTable.html[HTable]).
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From version 0.96, implementing Endpoint Coprocessor is not straight forward. Now it is done with
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the help of Google's Protocol Buffer. For more details on Protocol Buffer, please see
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link:https://developers.google.com/protocol-buffers/docs/proto[Protocol Buffer Guide].
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Endpoints Coprocessor written in version 0.94 are not compatible with with version 0.96 or later
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(for more details, see
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link:https://issues.apache.org/jira/browse/HBASE-5448[HBASE-5448]),
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so if your are upgrading your HBase cluster from version 0.94 (or before) to 0.96 (or later) you
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have to rewrite your Endpoint coprocessor.
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For example see <<cp_example,Examples>>
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[[cp_loading]]
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== Loading Coprocessors
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_Loading of Coprocessor refers to the process of making your custom Coprocessor implementation
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available to the the HBase, so that when a requests comes in or an event takes place the desired
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functionality implemented in your custom code gets executed. +
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Coprocessor can be loaded broadly in two ways. One is static (loading through configuration files)
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and the other one is dynamic loading (using hbase shell or java code).
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=== Static Loading
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Static loading means that your Coprocessor will take effect only when you restart your HBase and
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there is a reason for it. In this you make changes 'hbase-site.xml' and therefore have to restart
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HBase for your changes to take place. +
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Following are the steps for loading Coprocessor statically.
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. Define the Coprocessor in hbase-site.xml: Define a <property> element which consist of two
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sub elements <name> and <value> respectively.
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+
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.. <name> can have one of the following values:
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+
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... 'hbase.coprocessor.region.classes' for RegionObservers and Endpoints.
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... 'hbase.coprocessor.wal.classes' for WALObservers.
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... 'hbase.coprocessor.master.classes' for MasterObservers.
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.. <value> must contain the fully qualified class name of your class implmenting the Coprocessor.
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+
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For example to load a Coprocessor (implemented in class SumEndPoint.java) you have to create
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following entry in RegionServer's 'hbase-site.xml' file (generally located under 'conf' directiory):
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+
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[source,xml]
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----
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<property>
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<name>hbase.coprocessor.region.classes</name>
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<value>org.apache.hadoop.hbase.coprocessor.AggregateImplementation</value>
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<name>hbase.coprocessor.region.classes</name>
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<value>org.myname.hbase.coprocessor.endpoint.SumEndPoint</value>
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</property>
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----
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====
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If multiple classes are specified for loading, the class names must be comma-separated.
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The framework attempts to load all the configured classes using the default class loader.
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Therefore, the jar file must reside on the server-side HBase classpath.
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+
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Coprocessors which are loaded in this way will be active on all regions of all tables.
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These are the system coprocessor introduced earlier.
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The first listed coprocessors will be assigned the priority `Coprocessor.Priority.SYSTEM`.
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Each subsequent coprocessor in the list will have its priority value incremented by one (which reduces its priority, because priorities have the natural sort order of Integers).
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When calling out to registered observers, the framework executes their callbacks methods in the sorted order of their priority.
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These are also called system Coprocessor.
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The first listed Coprocessors will be assigned the priority `Coprocessor.Priority.SYSTEM`.
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Each subsequent coprocessor in the list will have its priority value incremented by one (which
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reduces its priority, because priorities have the natural sort order of Integers).
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+
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When calling out to registered observers, the framework executes their callbacks methods in the
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sorted order of their priority. +
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Ties are broken arbitrarily.
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=== Load from the HBase Shell
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. Put your code on classpth of HBase: There are various ways to do so, like adding jars on
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classpath etc. One easy way to do this is to drop the jar (containing you code and all the
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dependencies) in 'lib' folder of the HBase installation.
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You can load a coprocessor on a specific table via a table attribute.
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The following example will load the `FooRegionObserver` observer when table `t1` is read or re-read.
|
||||
. Restart the HBase.
|
||||
|
||||
.Load a Coprocessor On a Table Using HBase Shell
|
||||
|
||||
==== Unloading Static Coprocessor
|
||||
Unloading static Coprocessor is easy. Following are the steps:
|
||||
|
||||
. Delete the Coprocessor's entry from the 'hbase-site.xml' i.e. remove the <property> tag.
|
||||
|
||||
. Restart the Hbase.
|
||||
|
||||
. Optionally remove the Coprocessor jar file from the classpath (or from the lib directory if you
|
||||
copied it over there). Removing the coprocessor JARs from HBase’s classpath is a good practice.
|
||||
|
||||
=== Dynamic Loading
|
||||
Dynamic loading refers to the process of loading Coprocessor without restarting HBase. This may
|
||||
sound better than the static loading (and in some scenarios it may) but there is a caveat, dynamic
|
||||
loaded Coprocessor applies to the table only for which it was loaded while same is not true for
|
||||
static loading as it applies to all the tables. Due to this difference sometimes dynamically
|
||||
loaded Coprocessor are also called *Table Coprocessor* (as they applies only to a single table)
|
||||
while statically loaded Coprocessor are called *System Coprocessor* (as they applies to all the
|
||||
tables). +
|
||||
To dynamically load the Coprocessor you have to take the table offline hence during this time you
|
||||
won't be able to process any request involving this table. +
|
||||
There are three ways to dynamically load Coprocessor as shown below:
|
||||
|
||||
[NOTE]
|
||||
.Assumptions
|
||||
====
|
||||
----
|
||||
hbase(main):005:0> alter 't1', METHOD => 'table_att',
|
||||
'coprocessor'=>'hdfs:///foo.jar|com.foo.FooRegionObserver|1001|arg1=1,arg2=2'
|
||||
Updating all regions with the new schema...
|
||||
1/1 regions updated.
|
||||
Done.
|
||||
0 row(s) in 1.0730 seconds
|
||||
The below mentioned instructions makes the following assumptions:
|
||||
|
||||
hbase(main):006:0> describe 't1'
|
||||
DESCRIPTION ENABLED
|
||||
{NAME => 't1', coprocessor$1 => 'hdfs:///foo.jar|com.foo.FooRegio false
|
||||
nObserver|1001|arg1=1,arg2=2', FAMILIES => [{NAME => 'c1', DATA_B
|
||||
LOCK_ENCODING => 'NONE', BLOOMFILTER => 'NONE', REPLICATION_SCOPE
|
||||
=> '0', VERSIONS => '3', COMPRESSION => 'NONE', MIN_VERSIONS =>
|
||||
'0', TTL => '2147483647', KEEP_DELETED_CELLS => 'false', BLOCKSIZ
|
||||
E => '65536', IN_MEMORY => 'false', ENCODE_ON_DISK => 'true', BLO
|
||||
CKCACHE => 'true'}, {NAME => 'f1', DATA_BLOCK_ENCODING => 'NONE',
|
||||
BLOOMFILTER => 'NONE', REPLICATION_SCOPE => '0', VERSIONS => '3'
|
||||
, COMPRESSION => 'NONE', MIN_VERSIONS => '0', TTL => '2147483647'
|
||||
, KEEP_DELETED_CELLS => 'false', BLOCKSIZE => '65536', IN_MEMORY
|
||||
=> 'false', ENCODE_ON_DISK => 'true', BLOCKCACHE => 'true'}]}
|
||||
1 row(s) in 0.0190 seconds
|
||||
----
|
||||
* A JAR called `coprocessor.jar` contains the Coprocessor implementation along with all of its
|
||||
dependencies if any.
|
||||
* The JAR is available in HDFS in some location like
|
||||
`hdfs://<namenode>:<port>/user/<hadoop-user>/coprocessor.jar`.
|
||||
====
|
||||
|
||||
The coprocessor framework will try to read the class information from the coprocessor table attribute value.
|
||||
The value contains four pieces of information which are separated by the `|` character.
|
||||
. *Using Shell*: You can load the Coprocessor using the HBase shell as follows:
|
||||
.. Disable Table: Take table offline by disabling it. Suppose if the table name is 'users', then
|
||||
to disable it enter following command:
|
||||
+
|
||||
[source]
|
||||
----
|
||||
hbase(main):001:0> disable 'users'
|
||||
----
|
||||
|
||||
* File path: The jar file containing the coprocessor implementation must be in a location where all region servers can read it.
|
||||
You could copy the file onto the local disk on each region server, but it is recommended to store it in HDFS.
|
||||
* Class name: The full class name of the coprocessor.
|
||||
* Priority: An integer.
|
||||
The framework will determine the execution sequence of all configured observers registered at the same hook using priorities.
|
||||
This field can be left blank.
|
||||
In that case the framework will assign a default priority value.
|
||||
* Arguments: This field is passed to the coprocessor implementation.
|
||||
.. Load the Coprocessor: The Coprocessor jar should be on HDFS and should be accessible to HBase,
|
||||
to load the Coprocessor use following command:
|
||||
+
|
||||
[source]
|
||||
----
|
||||
hbase(main):002:0> alter 'users', METHOD => 'table_att', 'Coprocessor'=>'hdfs://<namenode>:<port>/
|
||||
user/<hadoop-user>/coprocessor.jar| org.myname.hbase.Coprocessor.RegionObserverExample|1073741823|
|
||||
arg1=1,arg2=2'
|
||||
----
|
||||
+
|
||||
The Coprocessor framework will try to read the class information from the coprocessor table
|
||||
attribute value.
|
||||
The value contains four pieces of information which are separated by the pipe (`|`) character.
|
||||
+
|
||||
* File path: The jar file containing the Coprocessor implementation must be in a location where
|
||||
all region servers can read it. +
|
||||
You could copy the file onto the local disk on each region server, but it is recommended to store
|
||||
it in HDFS.
|
||||
* Class name: The full class name of the Coprocessor.
|
||||
* Priority: An integer. The framework will determine the execution sequence of all configured
|
||||
observers registered at the same hook using priorities. This field can be left blank. In that
|
||||
case the framework will assign a default priority value.
|
||||
* Arguments (Optional): This field is passed to the Coprocessor implementation. This is optional.
|
||||
|
||||
.. Enable the table: To enable table type following command:
|
||||
+
|
||||
----
|
||||
hbase(main):003:0> enable 'users'
|
||||
----
|
||||
.. Verification: This is optional but generally good practice to see if your Coprocessor is
|
||||
loaded successfully. Enter following command:
|
||||
+
|
||||
----
|
||||
hbase(main):04:0> describe 'users'
|
||||
----
|
||||
+
|
||||
You must see some output like this:
|
||||
+
|
||||
----
|
||||
DESCRIPTION ENABLED
|
||||
'users', {TABLE_ATTRIBUTES => {coprocessor$1 => true 'hdfs://<namenode>:<port>/user/<hadoop-user>/
|
||||
coprocessor.jar| org.myname.hbase.Coprocessor.RegionObserverExample|1073741823|'}, {NAME =>
|
||||
'personalDet'.....
|
||||
----
|
||||
|
||||
|
||||
. *Using setValue()* method of HTableDescriptor: This is done entirely in Java as follows:
|
||||
+
|
||||
[source,java]
|
||||
----
|
||||
String tableName = "users";
|
||||
String path = "hdfs://<namenode>:<port>/user/<hadoop-user>/coprocessor.jar";
|
||||
Configuration conf = HBaseConfiguration.create();
|
||||
HBaseAdmin admin = new HBaseAdmin(conf);
|
||||
admin.disableTable(tableName);
|
||||
HTableDescriptor hTableDescriptor = new HTableDescriptor(tableName);
|
||||
HColumnDescriptor columnFamily1 = new HColumnDescriptor("personalDet");
|
||||
columnFamily1.setMaxVersions(3);
|
||||
hTableDescriptor.addFamily(columnFamily1);
|
||||
HColumnDescriptor columnFamily2 = new HColumnDescriptor("salaryDet");
|
||||
columnFamily2.setMaxVersions(3);
|
||||
hTableDescriptor.addFamily(columnFamily2);
|
||||
hTableDescriptor.setValue("COPROCESSOR$1", path + "|"
|
||||
+ RegionObserverExample.class.getCanonicalName() + "|"
|
||||
+ Coprocessor.PRIORITY_USER);
|
||||
admin.modifyTable(tableName, hTableDescriptor);
|
||||
admin.enableTable(tableName);
|
||||
----
|
||||
|
||||
. *Using addCoprocessor()* method of HTableDescriptor: This method is available from 0.96 version
|
||||
onwards.
|
||||
+
|
||||
[source,java]
|
||||
----
|
||||
String tableName = "users";
|
||||
String path = "hdfs://<namenode>:<port>/user/<hadoop-user>/coprocessor.jar";
|
||||
Configuration conf = HBaseConfiguration.create();
|
||||
HBaseAdmin admin = new HBaseAdmin(conf);
|
||||
admin.disableTable(tableName);
|
||||
HTableDescriptor hTableDescriptor = new HTableDescriptor(tableName);
|
||||
HColumnDescriptor columnFamily1 = new HColumnDescriptor("personalDet");
|
||||
columnFamily1.setMaxVersions(3);
|
||||
hTableDescriptor.addFamily(columnFamily1);
|
||||
HColumnDescriptor columnFamily2 = new HColumnDescriptor("salaryDet");
|
||||
columnFamily2.setMaxVersions(3);
|
||||
hTableDescriptor.addFamily(columnFamily2);
|
||||
hTableDescriptor.addCoprocessor(RegionObserverExample.class.getCanonicalName(), path,
|
||||
Coprocessor.PRIORITY_USER, null);
|
||||
admin.modifyTable(tableName, hTableDescriptor);
|
||||
admin.enableTable(tableName);
|
||||
----
|
||||
|
||||
.Unload a Coprocessor From a Table Using HBase Shell
|
||||
====
|
||||
----
|
||||
|
||||
hbase(main):007:0> alter 't1', METHOD => 'table_att_unset',
|
||||
hbase(main):008:0* NAME => 'coprocessor$1'
|
||||
Updating all regions with the new schema...
|
||||
1/1 regions updated.
|
||||
Done.
|
||||
0 row(s) in 1.1130 seconds
|
||||
|
||||
hbase(main):009:0> describe 't1'
|
||||
DESCRIPTION ENABLED
|
||||
{NAME => 't1', FAMILIES => [{NAME => 'c1', DATA_BLOCK_ENCODING => false
|
||||
'NONE', BLOOMFILTER => 'NONE', REPLICATION_SCOPE => '0', VERSION
|
||||
S => '3', COMPRESSION => 'NONE', MIN_VERSIONS => '0', TTL => '214
|
||||
7483647', KEEP_DELETED_CELLS => 'false', BLOCKSIZE => '65536', IN
|
||||
_MEMORY => 'false', ENCODE_ON_DISK => 'true', BLOCKCACHE => 'true
|
||||
'}, {NAME => 'f1', DATA_BLOCK_ENCODING => 'NONE', BLOOMFILTER =>
|
||||
'NONE', REPLICATION_SCOPE => '0', VERSIONS => '3', COMPRESSION =>
|
||||
'NONE', MIN_VERSIONS => '0', TTL => '2147483647', KEEP_DELETED_C
|
||||
ELLS => 'false', BLOCKSIZE => '65536', IN_MEMORY => 'false', ENCO
|
||||
DE_ON_DISK => 'true', BLOCKCACHE => 'true'}]}
|
||||
1 row(s) in 0.0180 seconds
|
||||
----
|
||||
WARNING: There is no guarantee that the framework will load a given Coprocessor successfully.
|
||||
For example, the shell command neither guarantees a jar file exists at a particular location nor
|
||||
verifies whether the given class is actually contained in the jar file.
|
||||
====
|
||||
|
||||
WARNING: There is no guarantee that the framework will load a given coprocessor successfully.
|
||||
For example, the shell command neither guarantees a jar file exists at a particular location nor verifies whether the given class is actually contained in the jar file.
|
||||
|
||||
== Check the Status of a Coprocessor
|
||||
|
||||
To check the status of a coprocessor after it has been configured, use the `status` HBase Shell command.
|
||||
|
||||
==== Unloading Dynamic Coprocessor
|
||||
. Using shell: Run following command from HBase shell to remove Coprocessor from a table.
|
||||
+
|
||||
[source]
|
||||
----
|
||||
hbase(main):003:0> alter 'users', METHOD => 'table_att_unset',
|
||||
hbase(main):004:0* NAME => 'coprocessor$1'
|
||||
----
|
||||
|
||||
hbase(main):020:0> status 'detailed'
|
||||
version 0.92-tm-6
|
||||
0 regionsInTransition
|
||||
master coprocessors: []
|
||||
1 live servers
|
||||
localhost:52761 1328082515520
|
||||
requestsPerSecond=3, numberOfOnlineRegions=3, usedHeapMB=32, maxHeapMB=995
|
||||
-ROOT-,,0
|
||||
numberOfStores=1, numberOfStorefiles=1, storefileUncompressedSizeMB=0, storefileSizeMB=0, memstoreSizeMB=0,
|
||||
storefileIndexSizeMB=0, readRequestsCount=54, writeRequestsCount=1, rootIndexSizeKB=0, totalStaticIndexSizeKB=0,
|
||||
totalStaticBloomSizeKB=0, totalCompactingKVs=0, currentCompactedKVs=0, compactionProgressPct=NaN, coprocessors=[]
|
||||
.META.,,1
|
||||
numberOfStores=1, numberOfStorefiles=0, storefileUncompressedSizeMB=0, storefileSizeMB=0, memstoreSizeMB=0,
|
||||
storefileIndexSizeMB=0, readRequestsCount=97, writeRequestsCount=4, rootIndexSizeKB=0, totalStaticIndexSizeKB=0,
|
||||
totalStaticBloomSizeKB=0, totalCompactingKVs=0, currentCompactedKVs=0, compactionProgressPct=NaN, coprocessors=[]
|
||||
t1,,1328082575190.c0491168a27620ffe653ec6c04c9b4d1.
|
||||
numberOfStores=2, numberOfStorefiles=1, storefileUncompressedSizeMB=0, storefileSizeMB=0, memstoreSizeMB=0,
|
||||
storefileIndexSizeMB=0, readRequestsCount=0, writeRequestsCount=0, rootIndexSizeKB=0, totalStaticIndexSizeKB=0,
|
||||
totalStaticBloomSizeKB=0, totalCompactingKVs=0, currentCompactedKVs=0, compactionProgressPct=NaN,
|
||||
coprocessors=[AggregateImplementation]
|
||||
0 dead servers
|
||||
. Using HtableDescriptor: Simply reload the table definition _without_ setting the value of
|
||||
Coprocessor either in setValue() or addCoprocessor() methods. This will remove the Coprocessor
|
||||
attached to this table, if any. For example:
|
||||
+
|
||||
[source,java]
|
||||
----
|
||||
String tableName = "users";
|
||||
String path = "hdfs://<namenode>:<port>/user/<hadoop-user>/coprocessor.jar";
|
||||
Configuration conf = HBaseConfiguration.create();
|
||||
HBaseAdmin admin = new HBaseAdmin(conf);
|
||||
admin.disableTable(tableName);
|
||||
HTableDescriptor hTableDescriptor = new HTableDescriptor(tableName);
|
||||
HColumnDescriptor columnFamily1 = new HColumnDescriptor("personalDet");
|
||||
columnFamily1.setMaxVersions(3);
|
||||
hTableDescriptor.addFamily(columnFamily1);
|
||||
HColumnDescriptor columnFamily2 = new HColumnDescriptor("salaryDet");
|
||||
columnFamily2.setMaxVersions(3);
|
||||
hTableDescriptor.addFamily(columnFamily2);
|
||||
admin.modifyTable(tableName, hTableDescriptor);
|
||||
admin.enableTable(tableName);
|
||||
----
|
||||
+
|
||||
Optionally you can also use removeCoprocessor() method of HTableDescriptor class.
|
||||
|
||||
|
||||
|
||||
[[cp_example]]
|
||||
== Examples
|
||||
HBase ships Coprocessor examples for Observer Coprocessor see
|
||||
// Below URL is more than 100 characters long.
|
||||
link:http://hbase.apache.org/xref/org/apache/hadoop/hbase/coprocessor/example/ZooKeeperScanPolicyObserver.html[ZooKeeperScanPolicyObserver]
|
||||
and for Endpoint Coprocessor see
|
||||
// Below URL is more than 100 characters long.
|
||||
link:http://hbase.apache.org/xref/org/apache/hadoop/hbase/coprocessor/example/RowCountEndpoint.html[RowCountEndpoint]
|
||||
|
||||
A more detailed example is given below.
|
||||
|
||||
For the sake of example let's take an hypothetical case. Suppose there is a HBase table called
|
||||
'users'. The table has two column families 'personalDet' and 'salaryDet' containing personal
|
||||
details and salary details respectively. Below is the graphical representation of the 'users'
|
||||
table.
|
||||
|
||||
.Users Table
|
||||
[width="100%",cols="7",options="header,footer"]
|
||||
|====================
|
||||
| 3+|personalDet 3+|salaryDet
|
||||
|*rowkey* |*name* |*lastname* |*dob* |*gross* |*net* |*allowances*
|
||||
|admin |Admin |Admin | 3+|
|
||||
|cdickens |Charles |Dickens |02/07/1812 |10000 |8000 |2000
|
||||
|jverne |Jules |Verne |02/08/1828 |12000 |9000 |3000
|
||||
|====================
|
||||
|
||||
|
||||
|
||||
=== Observer Example
|
||||
For the purpose of demonstration of Coprocessor we are assuming that 'admin' is a special person
|
||||
and his details shouldn't be visible or returned to any client querying the 'users' table. +
|
||||
To implement this functionality we will take the help of Observer Coprocessor.
|
||||
Following are the implementation steps:
|
||||
|
||||
. Write a class that extends the
|
||||
// Below URL is more than 100 characters long.
|
||||
link:https://hbase.apache.org/apidocs/org/apache/hadoop/hbase/coprocessor/BaseRegionObserver.html[BaseRegionObserver]
|
||||
class.
|
||||
|
||||
. Override the 'preGetOp()' method (Note that 'preGet()' method is now deprecated). The reason for
|
||||
overriding this method is to check if the client has queried for the rowkey with value 'admin' or
|
||||
not. If the client has queried rowkey with 'admin' value then return the call without allowing the
|
||||
system to perform the get operation thus saving on performance, otherwise process the request as
|
||||
normal.
|
||||
|
||||
. Put your code and dependencies in the jar file.
|
||||
|
||||
. Place the jar in HDFS where HBase can locate it.
|
||||
|
||||
. Load the Coprocessor.
|
||||
|
||||
. Write a simple program to test it.
|
||||
|
||||
Following are the implementation of the above steps:
|
||||
|
||||
. For Step 1 and Step 2, below is the code.
|
||||
+
|
||||
[source,java]
|
||||
----
|
||||
public class RegionObserverExample extends BaseRegionObserver {
|
||||
|
||||
private static final byte[] ADMIN = Bytes.toBytes("admin");
|
||||
private static final byte[] COLUMN_FAMILY = Bytes.toBytes("details");
|
||||
private static final byte[] COLUMN = Bytes.toBytes("Admin_det");
|
||||
private static final byte[] VALUE = Bytes.toBytes("You can't see Admin details");
|
||||
|
||||
@Override
|
||||
public void preGetOp(final ObserverContext e, final Get get, final List results)
|
||||
throws IOException {
|
||||
|
||||
if (Bytes.equals(get.getRow(),ADMIN)) {
|
||||
Cell c = CellUtil.createCell(get.getRow(),COLUMN _FAMILY, COLUMN,
|
||||
System.currentTimeMillis(), (byte)4, VALUE);
|
||||
results.add(c);
|
||||
e.bypass();
|
||||
}
|
||||
|
||||
List kvs = new ArrayList(results.size());
|
||||
for (Cell c : results) {
|
||||
kvs.add(KeyValueUtil.ensureKeyValue(c));
|
||||
}
|
||||
preGet(e, get, kvs);
|
||||
results.clear();
|
||||
results.addAll(kvs);
|
||||
}
|
||||
}
|
||||
----
|
||||
Overriding the 'preGetOp()' will only work for 'Get' operation. For 'Scan' operation it won't help
|
||||
you. To deal with it you have to override another method called 'preScannerOpen()' method, and
|
||||
add a Filter explicitly for admin as shown below:
|
||||
+
|
||||
[source,java]
|
||||
----
|
||||
@Override
|
||||
public RegionScanner preScannerOpen(final ObserverContext e, final Scan scan,
|
||||
final RegionScanner s) throws IOException {
|
||||
|
||||
Filter filter = new RowFilter(CompareOp.NOT_EQUAL, new BinaryComparator(ADMIN));
|
||||
scan.setFilter(filter);
|
||||
return s;
|
||||
}
|
||||
----
|
||||
+
|
||||
This method works but there is a _side effect_. If the client has used any Filter in his scan,
|
||||
then that Filter won't have any effect because our filter has replaced it. +
|
||||
Another option you can try is to deliberately remove the admin from result. This approach is
|
||||
shown below:
|
||||
+
|
||||
[source,java]
|
||||
----
|
||||
@Override
|
||||
public boolean postScannerNext(final ObserverContext e, final InternalScanner s,
|
||||
final List results, final int limit, final boolean hasMore) throws IOException {
|
||||
Result result = null;
|
||||
Iterator iterator = results.iterator();
|
||||
while (iterator.hasNext()) {
|
||||
result = iterator.next();
|
||||
if (Bytes.equals(result.getRow(), ROWKEY)) {
|
||||
iterator.remove();
|
||||
break;
|
||||
}
|
||||
}
|
||||
return hasMore;
|
||||
}
|
||||
----
|
||||
|
||||
. Step 3: It's pretty convenient to export the above program in a jar file. Let's assume that was
|
||||
exported in a file called 'coprocessor.jar'.
|
||||
|
||||
. Step 4: Copy the jar to HDFS. You may use command like this:
|
||||
+
|
||||
[source]
|
||||
----
|
||||
hadoop fs -copyFromLocal coprocessor.jar coprocessor.jar
|
||||
----
|
||||
|
||||
. Step 5: Load the Coprocessor, see <<cp_loading,Loading of Coprocessor>>.
|
||||
|
||||
. Step 6: Run the following program to test. The first part is testing 'Get' and second 'Scan'.
|
||||
+
|
||||
[source,java]
|
||||
----
|
||||
Configuration conf = HBaseConfiguration.create();
|
||||
// Use below code for HBase verion 1.x.x or above.
|
||||
Connection connection = ConnectionFactory.createConnection(conf);
|
||||
TableName tableName = TableName.valueOf("users");
|
||||
Table table = connection.getTable(tableName);
|
||||
|
||||
//Use below code HBase verion 0.98.xx or below.
|
||||
//HConnection connection = HConnectionManager.createConnection(conf);
|
||||
//HTableInterface table = connection.getTable("users");
|
||||
|
||||
Get get = new Get(Bytes.toBytes("admin"));
|
||||
Result result = table.get(get);
|
||||
for (Cell c : result.rawCells()) {
|
||||
System.out.println(Bytes.toString(CellUtil.cloneRow(c))
|
||||
+ "==> " + Bytes.toString(CellUtil.cloneFamily(c))
|
||||
+ "{" + Bytes.toString(CellUtil.cloneQualifier(c))
|
||||
+ ":" + Bytes.toLong(CellUtil.cloneValue(c)) + "}");
|
||||
}
|
||||
Scan scan = new Scan();
|
||||
ResultScanner scanner = table.getScanner(scan);
|
||||
for (Result res : scanner) {
|
||||
for (Cell c : res.rawCells()) {
|
||||
System.out.println(Bytes.toString(CellUtil.cloneRow(c))
|
||||
+ " ==> " + Bytes.toString(CellUtil.cloneFamily(c))
|
||||
+ " {" + Bytes.toString(CellUtil.cloneQualifier(c))
|
||||
+ ":" + Bytes.toLong(CellUtil.cloneValue(c))
|
||||
+ "}");
|
||||
}
|
||||
}
|
||||
----
|
||||
|
||||
=== Endpoint Example
|
||||
|
||||
In our hypothetical example (See Users Table), to demonstrate the Endpoint Coprocessor we see a
|
||||
trivial use case in which we will try to calculate the total (Sum) of gross salary of all
|
||||
employees. One way of implementing Endpoint Coprocessor (for version 0.96 and above) is as follows:
|
||||
|
||||
. Create a '.proto' file defining your service.
|
||||
|
||||
. Execute the 'protoc' command to generate the Java code from the above '.proto' file.
|
||||
|
||||
. Write a class that should:
|
||||
.. Extend the above generated service class.
|
||||
.. It should also implement two interfaces Coprocessor and CoprocessorService.
|
||||
.. Override the service method.
|
||||
|
||||
. Load the Coprocessor.
|
||||
|
||||
. Write a client code to call Coprocessor.
|
||||
|
||||
Implementation detail of the above steps is as follows:
|
||||
|
||||
. Step 1: Create a 'proto' file to define your service, request and response. Let's call this file
|
||||
"sum.proto". Below is the content of the 'sum.proto' file.
|
||||
+
|
||||
[source]
|
||||
----
|
||||
option java_package = "org.myname.hbase.coprocessor.autogenerated";
|
||||
option java_outer_classname = "Sum";
|
||||
option java_generic_services = true;
|
||||
option java_generate_equals_and_hash = true;
|
||||
option optimize_for = SPEED;
|
||||
message SumRequest {
|
||||
required string family = 1;
|
||||
required string column = 2;
|
||||
}
|
||||
|
||||
message SumResponse {
|
||||
required int64 sum = 1 [default = 0];
|
||||
}
|
||||
|
||||
service SumService {
|
||||
rpc getSum(SumRequest)
|
||||
returns (SumResponse);
|
||||
}
|
||||
----
|
||||
|
||||
. Step 2: Compile the proto file using proto compiler (for detailed instructions see the
|
||||
link:https://developers.google.com/protocol-buffers/docs/overview[official documentation]).
|
||||
+
|
||||
[source]
|
||||
----
|
||||
$ protoc --java_out=src ./sum.proto
|
||||
----
|
||||
+
|
||||
[note]
|
||||
----
|
||||
(Note: It is necessary for you to create the src folder).
|
||||
This will generate a class call "Sum.java".
|
||||
----
|
||||
|
||||
. Step 3: Write your Endpoint Coprocessor: Firstly your class should extend the service just
|
||||
defined above (i.e. Sum.SumService). Second it should implement Coprocessor and CoprocessorService
|
||||
interfaces. Third, override the 'getService()', 'start()', 'stop()' and 'getSum()' methods.
|
||||
Below is the full code:
|
||||
+
|
||||
[source,java]
|
||||
----
|
||||
public class SumEndPoint extends SumService implements Coprocessor, CoprocessorService {
|
||||
|
||||
private RegionCoprocessorEnvironment env;
|
||||
|
||||
@Override
|
||||
public Service getService() {
|
||||
return this;
|
||||
}
|
||||
|
||||
@Override
|
||||
public void start(CoprocessorEnvironment env) throws IOException {
|
||||
if (env instanceof RegionCoprocessorEnvironment) {
|
||||
this.env = (RegionCoprocessorEnvironment)env;
|
||||
} else {
|
||||
throw new CoprocessorException("Must be loaded on a table region!");
|
||||
}
|
||||
}
|
||||
|
||||
@Override
|
||||
public void stop(CoprocessorEnvironment env) throws IOException {
|
||||
// do mothing
|
||||
}
|
||||
|
||||
@Override
|
||||
public void getSum(RpcController controller, SumRequest request, RpcCallback done) {
|
||||
Scan scan = new Scan();
|
||||
scan.addFamily(Bytes.toBytes(request.getFamily()));
|
||||
scan.addColumn(Bytes.toBytes(request.getFamily()), Bytes.toBytes(request.getColumn()));
|
||||
SumResponse response = null;
|
||||
InternalScanner scanner = null;
|
||||
try {
|
||||
scanner = env.getRegion().getScanner(scan);
|
||||
List results = new ArrayList();
|
||||
boolean hasMore = false;
|
||||
long sum = 0L;
|
||||
do {
|
||||
hasMore = scanner.next(results);
|
||||
for (Cell cell : results) {
|
||||
sum = sum + Bytes.toLong(CellUtil.cloneValue(cell));
|
||||
}
|
||||
results.clear();
|
||||
} while (hasMore);
|
||||
|
||||
response = SumResponse.newBuilder().setSum(sum).build();
|
||||
|
||||
} catch (IOException ioe) {
|
||||
ResponseConverter.setControllerException(controller, ioe);
|
||||
} finally {
|
||||
if (scanner != null) {
|
||||
try {
|
||||
scanner.close();
|
||||
} catch (IOException ignored) {}
|
||||
}
|
||||
}
|
||||
done.run(response);
|
||||
}
|
||||
}
|
||||
----
|
||||
|
||||
. Step 4: Load the Coprocessor. See <<cp_loading,loading of Coprocessor>>.
|
||||
|
||||
. Step 5: Now we have to write the client code to test it. To do so in your main method, write the
|
||||
following code as shown below:
|
||||
+
|
||||
[source,java]
|
||||
----
|
||||
|
||||
Configuration conf = HBaseConfiguration.create();
|
||||
// Use below code for HBase verion 1.x.x or above.
|
||||
Connection connection = ConnectionFactory.createConnection(conf);
|
||||
TableName tableName = TableName.valueOf("users");
|
||||
Table table = connection.getTable(tableName);
|
||||
|
||||
//Use below code HBase verion 0.98.xx or below.
|
||||
//HConnection connection = HConnectionManager.createConnection(conf);
|
||||
//HTableInterface table = connection.getTable("users");
|
||||
|
||||
final SumRequest request = SumRequest.newBuilder().setFamily("salaryDet").setColumn("gross")
|
||||
.build();
|
||||
try {
|
||||
Map<byte[], Long> results = table.CoprocessorService (SumService.class, null, null,
|
||||
new Batch.Call<SumService, Long>() {
|
||||
@Override
|
||||
public Long call(SumService aggregate) throws IOException {
|
||||
BlockingRpcCallback rpcCallback = new BlockingRpcCallback();
|
||||
aggregate.getSum(null, request, rpcCallback);
|
||||
SumResponse response = rpcCallback.get();
|
||||
return response.hasSum() ? response.getSum() : 0L;
|
||||
}
|
||||
});
|
||||
for (Long sum : results.values()) {
|
||||
System.out.println("Sum = " + sum);
|
||||
}
|
||||
} catch (ServiceException e) {
|
||||
e.printStackTrace();
|
||||
} catch (Throwable e) {
|
||||
e.printStackTrace();
|
||||
}
|
||||
----
|
||||
|
||||
|
||||
== Monitor Time Spent in Coprocessors
|
||||
|
||||
HBase 0.98.5 introduced the ability to monitor some statistics relating to the amount of time spent executing a given coprocessor.
|
||||
You can see these statistics via the HBase Metrics framework (see <<hbase_metrics>> or the Web UI for a given Region Server, via the _Coprocessor Metrics_ tab.
|
||||
These statistics are valuable for debugging and benchmarking the performance impact of a given coprocessor on your cluster.
|
||||
HBase 0.98.5 introduced the ability to monitor some statistics relating to the amount of time
|
||||
spent executing a given Coprocessor.
|
||||
You can see these statistics via the HBase Metrics framework (see <<hbase_metrics>> or the Web UI
|
||||
for a given Region Server, via the _Coprocessor Metrics_ tab.
|
||||
These statistics are valuable for debugging and benchmarking the performance impact of a given
|
||||
Coprocessor on your cluster.
|
||||
Tracked statistics include min, max, average, and 90th, 95th, and 99th percentile.
|
||||
All times are shown in milliseconds.
|
||||
The statistics are calculated over coprocessor execution samples recorded during the reporting interval, which is 10 seconds by default.
|
||||
The statistics are calculated over Coprocessor execution samples recorded during the reporting
|
||||
interval, which is 10 seconds by default.
|
||||
The metrics sampling rate as described in <<hbase_metrics>>.
|
||||
|
||||
.Coprocessor Metrics UI
|
||||
|
|
Loading…
Reference in New Issue