From a7816d88bd5a09d880f0ae5b85ad3f51c34f6496 Mon Sep 17 00:00:00 2001 From: Misty Stanley-Jones Date: Fri, 30 Jan 2015 08:57:45 +1000 Subject: [PATCH] HBASE-12922 Post-asciidoc conversion fix-ups part 2 --- src/main/asciidoc/_chapters/architecture.adoc | 1229 ++++++++--------- src/main/asciidoc/_chapters/case_studies.adoc | 68 +- .../asciidoc/_chapters/configuration.adoc | 396 +++--- src/main/asciidoc/_chapters/cp.adoc | 107 +- src/main/asciidoc/_chapters/datamodel.adoc | 179 ++- .../asciidoc/_chapters/external_apis.adoc | 22 +- .../asciidoc/_chapters/getting_started.adoc | 170 ++- src/main/asciidoc/_chapters/hbase_apis.adoc | 59 +- src/main/asciidoc/_chapters/mapreduce.adoc | 277 ++-- src/main/asciidoc/_chapters/ops_mgt.adoc | 323 +++-- src/main/asciidoc/_chapters/orca.adoc | 5 +- src/main/asciidoc/_chapters/performance.adoc | 367 +++-- src/main/asciidoc/_chapters/preface.adoc | 17 +- .../asciidoc/_chapters/schema_design.adoc | 360 +++-- src/main/asciidoc/_chapters/security.adoc | 337 +++-- src/main/asciidoc/_chapters/shell.adoc | 86 +- .../_chapters/thrift_filter_language.adoc | 78 +- .../asciidoc/_chapters/troubleshooting.adoc | 586 ++++---- src/main/asciidoc/_chapters/upgrading.adoc | 88 +- 19 files changed, 2318 insertions(+), 2436 deletions(-) diff --git a/src/main/asciidoc/_chapters/architecture.adoc b/src/main/asciidoc/_chapters/architecture.adoc index 9e0b0c2e906..cd9a4a971bb 100644 --- a/src/main/asciidoc/_chapters/architecture.adoc +++ b/src/main/asciidoc/_chapters/architecture.adoc @@ -35,25 +35,25 @@ === NoSQL? HBase is a type of "NoSQL" database. -"NoSQL" is a general term meaning that the database isn't an RDBMS which supports SQL as its primary access language, but there are many types of NoSQL databases: BerkeleyDB is an example of a local NoSQL database, whereas HBase is very much a distributed database. -Technically speaking, HBase is really more a "Data Store" than "Data Base" because it lacks many of the features you find in an RDBMS, such as typed columns, secondary indexes, triggers, and advanced query languages, etc. +"NoSQL" is a general term meaning that the database isn't an RDBMS which supports SQL as its primary access language, but there are many types of NoSQL databases: BerkeleyDB is an example of a local NoSQL database, whereas HBase is very much a distributed database. +Technically speaking, HBase is really more a "Data Store" than "Data Base" because it lacks many of the features you find in an RDBMS, such as typed columns, secondary indexes, triggers, and advanced query languages, etc. However, HBase has many features which supports both linear and modular scaling. HBase clusters expand by adding RegionServers that are hosted on commodity class servers. If a cluster expands from 10 to 20 RegionServers, for example, it doubles both in terms of storage and as well as processing capacity. RDBMS can scale well, but only up to a point - specifically, the size of a single database server - and for the best performance requires specialized hardware and storage devices. -HBase features of note are: +HBase features of note are: * Strongly consistent reads/writes: HBase is not an "eventually consistent" DataStore. This makes it very suitable for tasks such as high-speed counter aggregation. -* Automatic sharding: HBase tables are distributed on the cluster via regions, and regions are automatically split and re-distributed as your data grows. +* Automatic sharding: HBase tables are distributed on the cluster via regions, and regions are automatically split and re-distributed as your data grows. * Automatic RegionServer failover -* Hadoop/HDFS Integration: HBase supports HDFS out of the box as its distributed file system. -* MapReduce: HBase supports massively parallelized processing via MapReduce for using HBase as both source and sink. -* Java Client API: HBase supports an easy to use Java API for programmatic access. -* Thrift/REST API: HBase also supports Thrift and REST for non-Java front-ends. -* Block Cache and Bloom Filters: HBase supports a Block Cache and Bloom Filters for high volume query optimization. -* Operational Management: HBase provides build-in web-pages for operational insight as well as JMX metrics. +* Hadoop/HDFS Integration: HBase supports HDFS out of the box as its distributed file system. +* MapReduce: HBase supports massively parallelized processing via MapReduce for using HBase as both source and sink. +* Java Client API: HBase supports an easy to use Java API for programmatic access. +* Thrift/REST API: HBase also supports Thrift and REST for non-Java front-ends. +* Block Cache and Bloom Filters: HBase supports a Block Cache and Bloom Filters for high volume query optimization. +* Operational Management: HBase provides build-in web-pages for operational insight as well as JMX metrics. [[arch.overview.when]] === When Should I Use HBase? @@ -62,15 +62,15 @@ HBase isn't suitable for every problem. First, make sure you have enough data. If you have hundreds of millions or billions of rows, then HBase is a good candidate. -If you only have a few thousand/million rows, then using a traditional RDBMS might be a better choice due to the fact that all of your data might wind up on a single node (or two) and the rest of the cluster may be sitting idle. +If you only have a few thousand/million rows, then using a traditional RDBMS might be a better choice due to the fact that all of your data might wind up on a single node (or two) and the rest of the cluster may be sitting idle. Second, make sure you can live without all the extra features that an RDBMS provides (e.g., typed columns, secondary indexes, transactions, advanced query languages, etc.) An application built against an RDBMS cannot be "ported" to HBase by simply changing a JDBC driver, for example. -Consider moving from an RDBMS to HBase as a complete redesign as opposed to a port. +Consider moving from an RDBMS to HBase as a complete redesign as opposed to a port. Third, make sure you have enough hardware. -Even HDFS doesn't do well with anything less than 5 DataNodes (due to things such as HDFS block replication which has a default of 3), plus a NameNode. +Even HDFS doesn't do well with anything less than 5 DataNodes (due to things such as HDFS block replication which has a default of 3), plus a NameNode. -HBase can run quite well stand-alone on a laptop - but this should be considered a development configuration only. +HBase can run quite well stand-alone on a laptop - but this should be considered a development configuration only. [[arch.overview.hbasehdfs]] === What Is The Difference Between HBase and Hadoop/HDFS? @@ -80,12 +80,12 @@ Its documentation states that it is not, however, a general purpose file system, HBase, on the other hand, is built on top of HDFS and provides fast record lookups (and updates) for large tables. This can sometimes be a point of conceptual confusion. HBase internally puts your data in indexed "StoreFiles" that exist on HDFS for high-speed lookups. -See the <> and the rest of this chapter for more information on how HBase achieves its goals. +See the <> and the rest of this chapter for more information on how HBase achieves its goals. [[arch.catalog]] == Catalog Tables -The catalog table `hbase:meta` exists as an HBase table and is filtered out of the HBase shell's `list` command, but is in fact a table just like any other. +The catalog table `hbase:meta` exists as an HBase table and is filtered out of the HBase shell's `list` command, but is in fact a table just like any other. [[arch.catalog.root]] === -ROOT- @@ -94,87 +94,94 @@ NOTE: The `-ROOT-` table was removed in HBase 0.96.0. Information here should be considered historical. The `-ROOT-` table kept track of the location of the `.META` table (the previous name for the table now called `hbase:meta`) prior to HBase 0.96. -The `-ROOT-` table structure was as follows: +The `-ROOT-` table structure was as follows: -* .Key.META. +.Key + +* .META. region key (`.META.,,1`) -* .Values`info:regioninfo` (serialized link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/HRegionInfo.html[HRegionInfo] instance of hbase:meta) -* `info:server` (server:port of the RegionServer holding hbase:meta) -* `info:serverstartcode` (start-time of the RegionServer process holding hbase:meta) +.Values + +* `info:regioninfo` (serialized link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/HRegionInfo.html[HRegionInfo] instance of `hbase:meta`) +* `info:server` (server:port of the RegionServer holding `hbase:meta`) +* `info:serverstartcode` (start-time of the RegionServer process holding `hbase:meta`) [[arch.catalog.meta]] === hbase:meta The `hbase:meta` table (previously called `.META.`) keeps a list of all regions in the system. -The location of `hbase:meta` was previously tracked within the `-ROOT-` table, but is now stored in Zookeeper. +The location of `hbase:meta` was previously tracked within the `-ROOT-` table, but is now stored in ZooKeeper. -The `hbase:meta` table structure is as follows: +The `hbase:meta` table structure is as follows: -* .KeyRegion key of the format (`[table],[region start key],[region id]`) +.Key -* .Values`info:regioninfo` (serialized link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/HRegionInfo.html[ - HRegionInfo] instance for this region) +* Region key of the format (`[table],[region start key],[region id]`) + +.Values + +* `info:regioninfo` (serialized link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/HRegionInfo.html[HRegionInfo] instance for this region) * `info:server` (server:port of the RegionServer containing this region) * `info:serverstartcode` (start-time of the RegionServer process containing this region) When a table is in the process of splitting, two other columns will be created, called `info:splitA` and `info:splitB`. These columns represent the two daughter regions. The values for these columns are also serialized HRegionInfo instances. -After the region has been split, eventually this row will be deleted. +After the region has been split, eventually this row will be deleted. .Note on HRegionInfo [NOTE] ==== The empty key is used to denote table start and table end. A region with an empty start key is the first region in a table. -If a region has both an empty start and an empty end key, it is the only region in the table +If a region has both an empty start and an empty end key, it is the only region in the table ==== -In the (hopefully unlikely) event that programmatic processing of catalog metadata is required, see the link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/util/Writables.html#getHRegionInfo%28byte[]%29[Writables] utility. +In the (hopefully unlikely) event that programmatic processing of catalog metadata is required, see the link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/util/Writables.html#getHRegionInfo%28byte[]%29[Writables] utility. [[arch.catalog.startup]] === Startup Sequencing -First, the location of `hbase:meta` is looked up in Zookeeper. +First, the location of `hbase:meta` is looked up in ZooKeeper. Next, `hbase:meta` is updated with server and startcode values. -For information on region-RegionServer assignment, see <>. +For information on region-RegionServer assignment, see <>. [[architecture.client]] == Client The HBase client finds the RegionServers that are serving the particular row range of interest. It does this by querying the `hbase:meta` table. -See <> for details. +See <> for details. After locating the required region(s), the client contacts the RegionServer serving that region, rather than going through the master, and issues the read or write request. This information is cached in the client so that subsequent requests need not go through the lookup process. -Should a region be reassigned either by the master load balancer or because a RegionServer has died, the client will requery the catalog tables to determine the new location of the user region. +Should a region be reassigned either by the master load balancer or because a RegionServer has died, the client will requery the catalog tables to determine the new location of the user region. -See <> for more information about the impact of the Master on HBase Client communication. +See <> for more information about the impact of the Master on HBase Client communication. -Administrative functions are done via an instance of link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Admin.html[Admin] +Administrative functions are done via an instance of link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Admin.html[Admin] [[client.connections]] === Cluster Connections -The API changed in HBase 1.0. +The API changed in HBase 1.0. For connection configuration information, see <>. + +==== API as of HBase 1.0.0 + Its been cleaned up and users are returned Interfaces to work against rather than particular types. -In HBase 1.0, obtain a cluster Connection from ConnectionFactory and thereafter, get from it instances of Table, Admin, and RegionLocator on an as-need basis. -When done, close obtained instances. -Finally, be sure to cleanup your Connection instance before exiting. -Connections are heavyweight objects. -Create once and keep an instance around. -Table, Admin and RegionLocator instances are lightweight. +In HBase 1.0, obtain a `Connection` object from `ConnectionFactory` and thereafter, get from it instances of `Table`, `Admin`, and `RegionLocator` on an as-need basis. +When done, close the obtained instances. +Finally, be sure to cleanup your `Connection` instance before exiting. +`Connections` are heavyweight objects but thread-safe so you can create one for your application and keep the instance around. +`Table`, `Admin` and `RegionLocator` instances are lightweight. Create as you go and then let go as soon as you are done by closing them. -See the link:/Users/stack/checkouts/hbase.git/target/site/apidocs/org/apache/hadoop/hbase/client/package-summary.html[Client Package Javadoc Description] for example usage of the new HBase 1.0 API. +See the link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/package-summary.html[Client Package Javadoc Description] for example usage of the new HBase 1.0 API. -For connection configuration information, see <>. +==== API before HBase 1.0.0 -_link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Table.html[Table] - instances are not thread-safe_. -Only one thread can use an instance of Table at any given time. -When creating Table instances, it is advisable to use the same link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/HBaseConfiguration[HBaseConfiguration] instance. +Instances of `HTable` are the way to interact with an HBase cluster earlier than 1.0.0. _link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Table.html[Table] instances are not thread-safe_. Only one thread can use an instance of Table at any given time. +When creating Table instances, it is advisable to use the same link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/HBaseConfiguration[HBaseConfiguration] instance. This will ensure sharing of ZooKeeper and socket instances to the RegionServers which is usually what you want. For example, this is preferred: @@ -195,10 +202,10 @@ HBaseConfiguration conf2 = HBaseConfiguration.create(); HTable table2 = new HTable(conf2, "myTable"); ---- -For more information about how connections are handled in the HBase client, see link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/HConnectionManager.html[HConnectionManager]. +For more information about how connections are handled in the HBase client, see link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/HConnectionManager.html[HConnectionManager]. [[client.connection.pooling]] -==== Connection Pooling +===== Connection Pooling For applications which require high-end multithreaded access (e.g., web-servers or application servers that may serve many application threads in a single JVM), you can pre-create an `HConnection`, as shown in the following example: @@ -228,27 +235,27 @@ Please use link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/H [[client.writebuffer]] === WriteBuffer and Batch Methods -If <> is turned off on link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/HTable.html[HTable], `Put`s are sent to RegionServers when the writebuffer is filled. +If <> is turned off on link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/HTable.html[HTable], ``Put``s are sent to RegionServers when the writebuffer is filled. The writebuffer is 2MB by default. -Before an HTable instance is discarded, either [method]+close()+ or [method]+flushCommits()+ should be invoked so Puts will not be lost. +Before an (H)Table instance is discarded, either `close()` or `flushCommits()` should be invoked so Puts will not be lost. -Note: `htable.delete(Delete);` does not go in the writebuffer! This only applies to Puts. +NOTE: `htable.delete(Delete);` does not go in the writebuffer! This only applies to Puts. -For additional information on write durability, review the link:../acid-semantics.html[ACID semantics] page. +For additional information on write durability, review the link:../acid-semantics.html[ACID semantics] page. -For fine-grained control of batching of `Put`s or `Delete`s, see the link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/HTable.html#batch%28java.util.List%29[batch] methods on HTable. +For fine-grained control of batching of ``Put``s or ``Delete``s, see the link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/HTable.html#batch%28java.util.List%29[batch] methods on HTable. [[client.external]] === External Clients -Information on non-Java clients and custom protocols is covered in <> +Information on non-Java clients and custom protocols is covered in <> [[client.filter]] == Client Request Filters -link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Get.html[Get] and link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Scan.html[Scan] instances can be optionally configured with link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/filter/Filter.html[filters] which are applied on the RegionServer. +link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Get.html[Get] and link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Scan.html[Scan] instances can be optionally configured with link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/filter/Filter.html[filters] which are applied on the RegionServer. -Filters can be confusing because there are many different types, and it is best to approach them by understanding the groups of Filter functionality. +Filters can be confusing because there are many different types, and it is best to approach them by understanding the groups of Filter functionality. [[client.filter.structural]] === Structural @@ -258,25 +265,25 @@ Structural Filters contain other Filters. [[client.filter.structural.fl]] ==== FilterList -link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/filter/FilterList.html[FilterList] represents a list of Filters with a relationship of `FilterList.Operator.MUST_PASS_ALL` or `FilterList.Operator.MUST_PASS_ONE` between the Filters. +link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/filter/FilterList.html[FilterList] represents a list of Filters with a relationship of `FilterList.Operator.MUST_PASS_ALL` or `FilterList.Operator.MUST_PASS_ONE` between the Filters. The following example shows an 'or' between two Filters (checking for either 'my value' or 'my other value' on the same attribute). [source,java] ---- FilterList list = new FilterList(FilterList.Operator.MUST_PASS_ONE); SingleColumnValueFilter filter1 = new SingleColumnValueFilter( - cf, - column, - CompareOp.EQUAL, - Bytes.toBytes("my value") - ); + cf, + column, + CompareOp.EQUAL, + Bytes.toBytes("my value") + ); list.add(filter1); SingleColumnValueFilter filter2 = new SingleColumnValueFilter( - cf, - column, - CompareOp.EQUAL, - Bytes.toBytes("my other value") - ); + cf, + column, + CompareOp.EQUAL, + Bytes.toBytes("my other value") + ); list.add(filter2); scan.setFilter(list); ---- @@ -287,16 +294,16 @@ scan.setFilter(list); [[client.filter.cv.scvf]] ==== SingleColumnValueFilter -link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/filter/SingleColumnValueFilter.html[SingleColumnValueFilter] can be used to test column values for equivalence (`CompareOp.EQUAL`), inequality (`CompareOp.NOT_EQUAL`), or ranges (e.g., `CompareOp.GREATER`). The following is example of testing equivalence a column to a String value "my value"... +link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/filter/SingleColumnValueFilter.html[SingleColumnValueFilter] can be used to test column values for equivalence (`CompareOp.EQUAL`), inequality (`CompareOp.NOT_EQUAL`), or ranges (e.g., `CompareOp.GREATER`). The following is example of testing equivalence a column to a String value "my value"... [source,java] ---- SingleColumnValueFilter filter = new SingleColumnValueFilter( - cf, - column, - CompareOp.EQUAL, - Bytes.toBytes("my value") - ); + cf, + column, + CompareOp.EQUAL, + Bytes.toBytes("my value") + ); scan.setFilter(filter); ---- @@ -304,44 +311,43 @@ scan.setFilter(filter); === Column Value Comparators There are several Comparator classes in the Filter package that deserve special mention. -These Comparators are used in concert with other Filters, such as <>. +These Comparators are used in concert with other Filters, such as <>. [[client.filter.cvp.rcs]] ==== RegexStringComparator -link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/filter/RegexStringComparator.html[RegexStringComparator] supports regular expressions for value comparisons. +link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/filter/RegexStringComparator.html[RegexStringComparator] supports regular expressions for value comparisons. [source,java] ---- RegexStringComparator comp = new RegexStringComparator("my."); // any value that starts with 'my' SingleColumnValueFilter filter = new SingleColumnValueFilter( - cf, - column, - CompareOp.EQUAL, - comp - ); + cf, + column, + CompareOp.EQUAL, + comp + ); scan.setFilter(filter); ---- -See the Oracle JavaDoc for link:http://download.oracle.com/javase/6/docs/api/java/util/regex/Pattern.html[supported - RegEx patterns in Java]. +See the Oracle JavaDoc for link:http://download.oracle.com/javase/6/docs/api/java/util/regex/Pattern.html[supported RegEx patterns in Java]. [[client.filter.cvp.substringcomparator]] ==== SubstringComparator -link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/filter/SubstringComparator.html[SubstringComparator] can be used to determine if a given substring exists in a value. -The comparison is case-insensitive. +link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/filter/SubstringComparator.html[SubstringComparator] can be used to determine if a given substring exists in a value. +The comparison is case-insensitive. [source,java] ---- SubstringComparator comp = new SubstringComparator("y val"); // looking for 'my value' SingleColumnValueFilter filter = new SingleColumnValueFilter( - cf, - column, - CompareOp.EQUAL, - comp - ); + cf, + column, + CompareOp.EQUAL, + comp + ); scan.setFilter(filter); ---- @@ -358,29 +364,29 @@ See link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/filter/BinaryCo [[client.filter.kvm]] === KeyValue Metadata -As HBase stores data internally as KeyValue pairs, KeyValue Metadata Filters evaluate the existence of keys (i.e., ColumnFamily:Column qualifiers) for a row, as opposed to values the previous section. +As HBase stores data internally as KeyValue pairs, KeyValue Metadata Filters evaluate the existence of keys (i.e., ColumnFamily:Column qualifiers) for a row, as opposed to values the previous section. [[client.filter.kvm.ff]] ==== FamilyFilter -link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/filter/FamilyFilter.html[FamilyFilter] can be used to filter on the ColumnFamily. +link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/filter/FamilyFilter.html[FamilyFilter] can be used to filter on the ColumnFamily. It is generally a better idea to select ColumnFamilies in the Scan than to do it with a Filter. [[client.filter.kvm.qf]] ==== QualifierFilter -link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/filter/QualifierFilter.html[QualifierFilter] can be used to filter based on Column (aka Qualifier) name. +link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/filter/QualifierFilter.html[QualifierFilter] can be used to filter based on Column (aka Qualifier) name. [[client.filter.kvm.cpf]] ==== ColumnPrefixFilter -link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/filter/ColumnPrefixFilter.html[ColumnPrefixFilter] can be used to filter based on the lead portion of Column (aka Qualifier) names. +link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/filter/ColumnPrefixFilter.html[ColumnPrefixFilter] can be used to filter based on the lead portion of Column (aka Qualifier) names. A ColumnPrefixFilter seeks ahead to the first column matching the prefix in each row and for each involved column family. -It can be used to efficiently get a subset of the columns in very wide rows. +It can be used to efficiently get a subset of the columns in very wide rows. Note: The same column qualifier can be used in different column families. -This filter returns all matching columns. +This filter returns all matching columns. Example: Find all columns in a row and family that start with "abc" @@ -407,10 +413,10 @@ rs.close(); [[client.filter.kvm.mcpf]] ==== MultipleColumnPrefixFilter -link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/filter/MultipleColumnPrefixFilter.html[MultipleColumnPrefixFilter] behaves like ColumnPrefixFilter but allows specifying multiple prefixes. +link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/filter/MultipleColumnPrefixFilter.html[MultipleColumnPrefixFilter] behaves like ColumnPrefixFilter but allows specifying multiple prefixes. Like ColumnPrefixFilter, MultipleColumnPrefixFilter efficiently seeks ahead to the first column matching the lowest prefix and also seeks past ranges of columns between prefixes. -It can be used to efficiently get discontinuous sets of columns from very wide rows. +It can be used to efficiently get discontinuous sets of columns from very wide rows. Example: Find all columns in a row and family that start with "abc" or "xyz" @@ -437,15 +443,15 @@ rs.close(); [[client.filter.kvm.crf]] ==== ColumnRangeFilter -A link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/filter/ColumnRangeFilter.html[ColumnRangeFilter] allows efficient intra row scanning. +A link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/filter/ColumnRangeFilter.html[ColumnRangeFilter] allows efficient intra row scanning. A ColumnRangeFilter can seek ahead to the first matching column for each involved column family. It can be used to efficiently get a 'slice' of the columns of a very wide row. i.e. -you have a million columns in a row but you only want to look at columns bbbb-bbdd. +you have a million columns in a row but you only want to look at columns bbbb-bbdd. Note: The same column qualifier can be used in different column families. -This filter returns all matching columns. +This filter returns all matching columns. Example: Find all columns in a row and family between "bbbb" (inclusive) and "bbdd" (inclusive) @@ -493,66 +499,65 @@ See link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/filter/FirstKey `HMaster` is the implementation of the Master Server. The Master server is responsible for monitoring all RegionServer instances in the cluster, and is the interface for all metadata changes. -In a distributed cluster, the Master typically runs on the <>. -J Mohamed Zahoor goes into some more detail on the Master Architecture in this blog posting, link:http://blog.zahoor.in/2012/08/hbase-hmaster-architecture/[HBase HMaster - Architecture ]. +In a distributed cluster, the Master typically runs on the <>. +J Mohamed Zahoor goes into some more detail on the Master Architecture in this blog posting, link:http://blog.zahoor.in/2012/08/hbase-hmaster-architecture/[HBase HMaster Architecture ]. [[master.startup]] === Startup Behavior If run in a multi-Master environment, all Masters compete to run the cluster. -If the active Master loses its lease in ZooKeeper (or the Master shuts down), then then the remaining Masters jostle to take over the Master role. +If the active Master loses its lease in ZooKeeper (or the Master shuts down), then the remaining Masters jostle to take over the Master role. [[master.runtime]] === Runtime Impact A common dist-list question involves what happens to an HBase cluster when the Master goes down. -Because the HBase client talks directly to the RegionServers, the cluster can still function in a "steady state." Additionally, per <>, `hbase:meta` exists as an HBase table and is not resident in the Master. +Because the HBase client talks directly to the RegionServers, the cluster can still function in a "steady state". Additionally, per <>, `hbase:meta` exists as an HBase table and is not resident in the Master. However, the Master controls critical functions such as RegionServer failover and completing region splits. -So while the cluster can still run for a short time without the Master, the Master should be restarted as soon as possible. +So while the cluster can still run for a short time without the Master, the Master should be restarted as soon as possible. [[master.api]] === Interface -The methods exposed by `HMasterInterface` are primarily metadata-oriented methods: +The methods exposed by `HMasterInterface` are primarily metadata-oriented methods: -* Table (createTable, modifyTable, removeTable, enable, disable) -* ColumnFamily (addColumn, modifyColumn, removeColumn) -* Region (move, assign, unassign) For example, when the `HBaseAdmin` method `disableTable` is invoked, it is serviced by the Master server. +* Table (createTable, modifyTable, removeTable, enable, disable) +* ColumnFamily (addColumn, modifyColumn, removeColumn) +* Region (move, assign, unassign) For example, when the `HBaseAdmin` method `disableTable` is invoked, it is serviced by the Master server. [[master.processes]] === Processes -The Master runs several background threads: +The Master runs several background threads: [[master.processes.loadbalancer]] ==== LoadBalancer Periodically, and when there are no regions in transition, a load balancer will run and move regions around to balance the cluster's load. -See <> for configuring this property. +See <> for configuring this property. -See <> for more information on region assignment. +See <> for more information on region assignment. [[master.processes.catalog]] ==== CatalogJanitor -Periodically checks and cleans up the hbase:meta table. -See <> for more information on META. +Periodically checks and cleans up the `hbase:meta` table. +See > for more information on the meta table. [[regionserver.arch]] == RegionServer `HRegionServer` is the RegionServer implementation. It is responsible for serving and managing regions. -In a distributed cluster, a RegionServer runs on a <>. +In a distributed cluster, a RegionServer runs on a <>. [[regionserver.arch.api]] === Interface -The methods exposed by `HRegionRegionInterface` contain both data-oriented and region-maintenance methods: +The methods exposed by `HRegionRegionInterface` contain both data-oriented and region-maintenance methods: * Data (get, put, delete, next, etc.) -* Region (splitRegion, compactRegion, etc.) For example, when the `HBaseAdmin` method `majorCompact` is invoked on a table, the client is actually iterating through all regions for the specified table and requesting a major compaction directly to each region. +* Region (splitRegion, compactRegion, etc.) For example, when the `HBaseAdmin` method `majorCompact` is invoked on a table, the client is actually iterating through all regions for the specified table and requesting a major compaction directly to each region. [[regionserver.arch.processes]] === Processes @@ -582,94 +587,92 @@ Periodically checks the RegionServer's WAL. === Coprocessors Coprocessors were added in 0.92. -There is a thorough link:https://blogs.apache.org/hbase/entry/coprocessor_introduction[Blog Overview - of CoProcessors] posted. -Documentation will eventually move to this reference guide, but the blog is the most current information available at this time. +There is a thorough link:https://blogs.apache.org/hbase/entry/coprocessor_introduction[Blog Overview of CoProcessors] posted. +Documentation will eventually move to this reference guide, but the blog is the most current information available at this time. [[block.cache]] === Block Cache -HBase provides two different BlockCache implementations: the default onheap LruBlockCache and BucketCache, which is (usually) offheap. +HBase provides two different BlockCache implementations: the default on-heap `LruBlockCache` and the `BucketCache`, which is (usually) off-heap. This section discusses benefits and drawbacks of each implementation, how to choose the appropriate option, and configuration options for each. .Block Cache Reporting: UI [NOTE] ==== See the RegionServer UI for detail on caching deploy. -Since HBase-0.98.4, the Block Cache detail has been significantly extended showing configurations, sizings, current usage, time-in-the-cache, and even detail on block counts and types. +Since HBase 0.98.4, the Block Cache detail has been significantly extended showing configurations, sizings, current usage, time-in-the-cache, and even detail on block counts and types. ==== ==== Cache Choices -`LruBlockCache` is the original implementation, and is entirely within the Java heap. `BucketCache` is mainly intended for keeping blockcache data offheap, although BucketCache can also keep data onheap and serve from a file-backed cache. +`LruBlockCache` is the original implementation, and is entirely within the Java heap. `BucketCache` is mainly intended for keeping block cache data off-heap, although `BucketCache` can also keep data on-heap and serve from a file-backed cache. -.BucketCache is production ready as of hbase-0.98.6 +.BucketCache is production ready as of HBase 0.98.6 [NOTE] ==== To run with BucketCache, you need HBASE-11678. -This was included in hbase-0.98.6. -==== +This was included in 0.98.6. +==== -Fetching will always be slower when fetching from BucketCache, as compared to the native onheap LruBlockCache. +Fetching will always be slower when fetching from BucketCache, as compared to the native on-heap LruBlockCache. However, latencies tend to be less erratic across time, because there is less garbage collection when you use BucketCache since it is managing BlockCache allocations, not the GC. -If the BucketCache is deployed in offheap mode, this memory is not managed by the GC at all. +If the BucketCache is deployed in off-heap mode, this memory is not managed by the GC at all. This is why you'd use BucketCache, so your latencies are less erratic and to mitigate GCs and heap fragmentation. -See Nick Dimiduk's link:http://www.n10k.com/blog/blockcache-101/[BlockCache 101] for comparisons running onheap vs offheap tests. -Also see link:http://people.apache.org/~stack/bc/[Comparing BlockCache Deploys] which finds that if your dataset fits inside your LruBlockCache deploy, use it otherwise if you are experiencing cache churn (or you want your cache to exist beyond the vagaries of java GC), use BucketCache. +See Nick Dimiduk's link:http://www.n10k.com/blog/blockcache-101/[BlockCache 101] for comparisons running on-heap vs off-heap tests. +Also see link:http://people.apache.org/~stack/bc/[Comparing BlockCache Deploys] which finds that if your dataset fits inside your LruBlockCache deploy, use it otherwise if you are experiencing cache churn (or you want your cache to exist beyond the vagaries of java GC), use BucketCache. -When you enable BucketCache, you are enabling a two tier caching system, an L1 cache which is implemented by an instance of LruBlockCache and an offheap L2 cache which is implemented by BucketCache. +When you enable BucketCache, you are enabling a two tier caching system, an L1 cache which is implemented by an instance of LruBlockCache and an off-heap L2 cache which is implemented by BucketCache. Management of these two tiers and the policy that dictates how blocks move between them is done by `CombinedBlockCache`. -It keeps all DATA blocks in the L2 BucketCache and meta blocks -- INDEX and BLOOM blocks -- onheap in the L1 `LruBlockCache`. -See <> for more detail on going offheap. +It keeps all DATA blocks in the L2 BucketCache and meta blocks -- INDEX and BLOOM blocks -- on-heap in the L1 `LruBlockCache`. +See <> for more detail on going off-heap. [[cache.configurations]] ==== General Cache Configurations Apart from the cache implementation itself, you can set some general configuration options to control how the cache performs. -See link:http://hbase.apache.org/devapidocs/org/apache/hadoop/hbase/io/hfile/CacheConfig.html. +See http://hbase.apache.org/devapidocs/org/apache/hadoop/hbase/io/hfile/CacheConfig.html. After setting any of these options, restart or rolling restart your cluster for the configuration to take effect. Check logs for errors or unexpected behavior. -See also <>, which discusses a new option introduced in link:https://issues.apache.org/jira/browse/HBASE-9857[HBASE-9857]. +See also <>, which discusses a new option introduced in link:https://issues.apache.org/jira/browse/HBASE-9857[HBASE-9857]. [[block.cache.design]] ==== LruBlockCache Design -The LruBlockCache is an LRU cache that contains three levels of block priority to allow for scan-resistance and in-memory ColumnFamilies: +The LruBlockCache is an LRU cache that contains three levels of block priority to allow for scan-resistance and in-memory ColumnFamilies: * Single access priority: The first time a block is loaded from HDFS it normally has this priority and it will be part of the first group to be considered during evictions. The advantage is that scanned blocks are more likely to get evicted than blocks that are getting more usage. -* Mutli access priority: If a block in the previous priority group is accessed again, it upgrades to this priority. +* Multi access priority: If a block in the previous priority group is accessed again, it upgrades to this priority. It is thus part of the second group considered during evictions. * In-memory access priority: If the block's family was configured to be "in-memory", it will be part of this priority disregarding the number of times it was accessed. Catalog tables are configured like this. This group is the last one considered during evictions. + -To mark a column family as in-memory, call +To mark a column family as in-memory, call [source,java] ---- HColumnDescriptor.setInMemory(true); ----- +---- + +if creating a table from java, or set `IN_MEMORY => true` when creating or altering a table in the shell: e.g. -if creating a table from java, or set +IN_MEMORY => true+ when creating or altering a table in the shell: e.g. - [source] ---- hbase(main):003:0> create 't', {NAME => 'f', IN_MEMORY => 'true'} ---- -For more information, see the link:http://hbase.apache.org/xref/org/apache/hadoop/hbase/io/hfile/LruBlockCache.html[LruBlockCache - source] +For more information, see the link:http://hbase.apache.org/xref/org/apache/hadoop/hbase/io/hfile/LruBlockCache.html[LruBlockCache source] [[block.cache.usage]] ==== LruBlockCache Usage Block caching is enabled by default for all the user tables which means that any read operation will load the LRU cache. This might be good for a large number of use cases, but further tunings are usually required in order to achieve better performance. -An important concept is the link:http://en.wikipedia.org/wiki/Working_set_size[working set size], or WSS, which is: "the amount of memory needed to compute the answer to a problem". For a website, this would be the data that's needed to answer the queries over a short amount of time. +An important concept is the link:http://en.wikipedia.org/wiki/Working_set_size[working set size], or WSS, which is: "the amount of memory needed to compute the answer to a problem". For a website, this would be the data that's needed to answer the queries over a short amount of time. -The way to calculate how much memory is available in HBase for caching is: +The way to calculate how much memory is available in HBase for caching is: [source] ---- @@ -679,47 +682,46 @@ number of region servers * heap size * hfile.block.cache.size * 0.99 The default value for the block cache is 0.25 which represents 25% of the available heap. The last value (99%) is the default acceptable loading factor in the LRU cache after which eviction is started. The reason it is included in this equation is that it would be unrealistic to say that it is possible to use 100% of the available memory since this would make the process blocking from the point where it loads new blocks. -Here are some examples: +Here are some examples: * One region server with the default heap size (1 GB) and the default block cache size will have 253 MB of block cache available. * 20 region servers with the heap size set to 8 GB and a default block cache size will have 39.6 of block cache. * 100 region servers with the heap size set to 24 GB and a block cache size of 0.5 will have about 1.16 TB of block cache. Your data is not the only resident of the block cache. -Here are others that you may have to take into account: +Here are others that you may have to take into account: Catalog Tables:: - The `-ROOT-` (prior to HBase 0.96. - See <>) and `hbase:meta` tables are forced into the block cache and have the in-memory priority which means that they are harder to evict. - The former never uses more than a few hundreds of bytes while the latter can occupy a few MBs (depending on the number of regions). + The `-ROOT-` (prior to HBase 0.96, see <>) and `hbase:meta` tables are forced into the block cache and have the in-memory priority which means that they are harder to evict. + The former never uses more than a few hundreds bytes while the latter can occupy a few MBs (depending on the number of regions). HFiles Indexes:: - An [firstterm]_hfile_ is the file format that HBase uses to store data in HDFS. + An _HFile_ is the file format that HBase uses to store data in HDFS. It contains a multi-layered index which allows HBase to seek to the data without having to read the whole file. The size of those indexes is a factor of the block size (64KB by default), the size of your keys and the amount of data you are storing. For big data sets it's not unusual to see numbers around 1GB per region server, although not all of it will be in cache because the LRU will evict indexes that aren't used. Keys:: - The values that are stored are only half the picture, since each value is stored along with its keys (row key, family qualifier, and timestamp). See <>. + The values that are stored are only half the picture, since each value is stored along with its keys (row key, family qualifier, and timestamp). See <>. Bloom Filters:: Just like the HFile indexes, those data structures (when enabled) are stored in the LRU. Currently the recommended way to measure HFile indexes and bloom filters sizes is to look at the region server web UI and checkout the relevant metrics. For keys, sampling can be done by using the HFile command line tool and look for the average key size metric. -Since HBase 0.98.3, you can view detail on BlockCache stats and metrics in a special Block Cache section in the UI. +Since HBase 0.98.3, you can view details on BlockCache stats and metrics in a special Block Cache section in the UI. It's generally bad to use block caching when the WSS doesn't fit in memory. This is the case when you have for example 40GB available across all your region servers' block caches but you need to process 1TB of data. One of the reasons is that the churn generated by the evictions will trigger more garbage collections unnecessarily. -Here are two use cases: +Here are two use cases: * Fully random reading pattern: This is a case where you almost never access the same row twice within a short amount of time such that the chance of hitting a cached block is close to 0. Setting block caching on such a table is a waste of memory and CPU cycles, more so that it will generate more garbage to pick up by the JVM. - For more information on monitoring GC, see <>. + For more information on monitoring GC, see <>. * Mapping a table: In a typical MapReduce job that takes a table in input, every row will be read only once so there's no need to put them into the block cache. The Scan object has the option of turning this off via the setCaching method (set it to false). You can still keep block caching turned on on this table if you need fast random read access. - An example would be counting the number of rows in a table that serves live traffic, caching every block of that table would create massive churn and would surely evict data that's currently in use. + An example would be counting the number of rows in a table that serves live traffic, caching every block of that table would create massive churn and would surely evict data that's currently in use. [[data.blocks.in.fscache]] ===== Caching META blocks only (DATA blocks in fscache) @@ -727,57 +729,55 @@ Here are two use cases: An interesting setup is one where we cache META blocks only and we read DATA blocks in on each access. If the DATA blocks fit inside fscache, this alternative may make sense when access is completely random across a very large dataset. To enable this setup, alter your table and for each column family set `BLOCKCACHE => 'false'`. -You are 'disabling' the BlockCache for this column family only you can never disable the caching of META blocks. -Since link:https://issues.apache.org/jira/browse/HBASE-4683[HBASE-4683 Always cache index and bloom blocks], we will cache META blocks even if the BlockCache is disabled. +You are 'disabling' the BlockCache for this column family only. You can never disable the caching of META blocks. +Since link:https://issues.apache.org/jira/browse/HBASE-4683[HBASE-4683 Always cache index and bloom blocks], we will cache META blocks even if the BlockCache is disabled. [[offheap.blockcache]] -==== Offheap Block Cache +==== Off-heap Block Cache [[enable.bucketcache]] ===== How to Enable BucketCache -The usual deploy of BucketCache is via a managing class that sets up two caching tiers: an L1 onheap cache implemented by LruBlockCache and a second L2 cache implemented with BucketCache. +The usual deploy of BucketCache is via a managing class that sets up two caching tiers: an L1 on-heap cache implemented by LruBlockCache and a second L2 cache implemented with BucketCache. The managing class is link:http://hbase.apache.org/devapidocs/org/apache/hadoop/hbase/io/hfile/CombinedBlockCache.html[CombinedBlockCache] by default. -The just-previous link describes the caching 'policy' implemented by CombinedBlockCache. -In short, it works by keeping meta blocks -- INDEX and BLOOM in the L1, onheap LruBlockCache tier -- and DATA blocks are kept in the L2, BucketCache tier. -It is possible to amend this behavior in HBase since version 1.0 and ask that a column family have both its meta and DATA blocks hosted onheap in the L1 tier by setting `cacheDataInL1` via `(HColumnDescriptor.setCacheDataInL1(true)` or in the shell, creating or amending column families setting `CACHE_DATA_IN_L1` to true: e.g. +The previous link describes the caching 'policy' implemented by CombinedBlockCache. +In short, it works by keeping meta blocks -- INDEX and BLOOM in the L1, on-heap LruBlockCache tier -- and DATA blocks are kept in the L2, BucketCache tier. +It is possible to amend this behavior in HBase since version 1.0 and ask that a column family have both its meta and DATA blocks hosted on-heap in the L1 tier by setting `cacheDataInL1` via `(HColumnDescriptor.setCacheDataInL1(true)` or in the shell, creating or amending column families setting `CACHE_DATA_IN_L1` to true: e.g. [source] ---- hbase(main):003:0> create 't', {NAME => 't', CONFIGURATION => {CACHE_DATA_IN_L1 => 'true'}} ---- -The BucketCache Block Cache can be deployed onheap, offheap, or file based. +The BucketCache Block Cache can be deployed on-heap, off-heap, or file based. You set which via the `hbase.bucketcache.ioengine` setting. -Setting it to `heap` will have BucketCache deployed inside the allocated java heap. -Setting it to `offheap` will have BucketCache make its allocations offheap, and an ioengine setting of `file:PATH_TO_FILE` will direct BucketCache to use a file caching (Useful in particular if you have some fast i/o attached to the box such as SSDs). +Setting it to `heap` will have BucketCache deployed inside the allocated Java heap. +Setting it to `offheap` will have BucketCache make its allocations off-heap, and an ioengine setting of `file:PATH_TO_FILE` will direct BucketCache to use a file caching (Useful in particular if you have some fast I/O attached to the box such as SSDs). It is possible to deploy an L1+L2 setup where we bypass the CombinedBlockCache policy and have BucketCache working as a strict L2 cache to the L1 LruBlockCache. For such a setup, set `CacheConfig.BUCKET_CACHE_COMBINED_KEY` to `false`. In this mode, on eviction from L1, blocks go to L2. When a block is cached, it is cached first in L1. When we go to look for a cached block, we look first in L1 and if none found, then search L2. -Let us call this deploy format, -_(((Raw L1+L2)))_. +Let us call this deploy format, _Raw L1+L2_. Other BucketCache configs include: specifying a location to persist cache to across restarts, how many threads to use writing the cache, etc. -See the link:https://hbase.apache.org/apidocs/org/apache/hadoop/hbase/io/hfile/CacheConfig.html[CacheConfig.html] class for configuration options and descriptions. +See the link:https://hbase.apache.org/apidocs/org/apache/hadoop/hbase/io/hfile/CacheConfig.html[CacheConfig.html] class for configuration options and descriptions. ====== BucketCache Example Configuration -This sample provides a configuration for a 4 GB offheap BucketCache with a 1 GB onheap cache. +This sample provides a configuration for a 4 GB off-heap BucketCache with a 1 GB on-heap cache. Configuration is performed on the RegionServer. -Setting `hbase.bucketcache.ioengine` and `hbase.bucketcache.size` > 0 enables CombinedBlockCache. -Let us presume that the RegionServer has been set to run with a 5G heap: i.e. -HBASE_HEAPSIZE=5g. +Setting `hbase.bucketcache.ioengine` and `hbase.bucketcache.size` > 0 enables `CombinedBlockCache`. +Let us presume that the RegionServer has been set to run with a 5G heap: i.e. `HBASE_HEAPSIZE=5g`. -. First, edit the RegionServer's _hbase-env.sh_ and set `HBASE_OFFHEAPSIZE` to a value greater than the offheap size wanted, in this case, 4 GB (expressed as 4G). Lets set it to 5G. - That'll be 4G for our offheap cache and 1G for any other uses of offheap memory (there are other users of offheap memory other than BlockCache; e.g. - DFSClient in RegionServer can make use of offheap memory). See <>. - + +. First, edit the RegionServer's _hbase-env.sh_ and set `HBASE_OFFHEAPSIZE` to a value greater than the off-heap size wanted, in this case, 4 GB (expressed as 4G). Let's set it to 5G. + That'll be 4G for our off-heap cache and 1G for any other uses of off-heap memory (there are other users of off-heap memory other than BlockCache; e.g. + DFSClient in RegionServer can make use of off-heap memory). See <>. ++ [source] ---- HBASE_OFFHEAPSIZE=5G @@ -804,14 +804,15 @@ HBASE_OFFHEAPSIZE=5G . Restart or rolling restart your cluster, and check the logs for any issues. -In the above, we set bucketcache to be 4G. -The onheap lrublockcache we configured to have 0.2 of the RegionServer's heap size (0.2 * 5G = 1G). In other words, you configure the L1 LruBlockCache as you would normally, as you would when there is no L2 BucketCache present. +In the above, we set the BucketCache to be 4G. +We configured the on-heap LruBlockCache have 20% (0.2) of the RegionServer's heap size (0.2 * 5G = 1G). In other words, you configure the L1 LruBlockCache as you would normally (as if there were no L2 cache present). -link:https://issues.apache.org/jira/browse/HBASE-10641[HBASE-10641] introduced the ability to configure multiple sizes for the buckets of the bucketcache, in HBase 0.98 and newer. -To configurable multiple bucket sizes, configure the new property +hfile.block.cache.sizes+ (instead of +hfile.block.cache.size+) to a comma-separated list of block sizes, ordered from smallest to largest, with no spaces. +link:https://issues.apache.org/jira/browse/HBASE-10641[HBASE-10641] introduced the ability to configure multiple sizes for the buckets of the BucketCache, in HBase 0.98 and newer. +To configurable multiple bucket sizes, configure the new property `hfile.block.cache.sizes` (instead of `hfile.block.cache.size`) to a comma-separated list of block sizes, ordered from smallest to largest, with no spaces. The goal is to optimize the bucket sizes based on your data access patterns. The following example configures buckets of size 4096 and 8192. +[source,xml] ---- hfile.block.cache.sizes @@ -819,21 +820,21 @@ The following example configures buckets of size 4096 and 8192. ---- +[[direct.memory]] .Direct Memory Usage In HBase [NOTE] ==== The default maximum direct memory varies by JVM. Traditionally it is 64M or some relation to allocated heap size (-Xmx) or no limit at all (JDK7 apparently). HBase servers use direct memory, in particular short-circuit reading, the hosted DFSClient will allocate direct memory buffers. -If you do offheap block caching, you'll be making use of direct memory. -Starting your JVM, make sure the `-XX:MaxDirectMemorySize` setting in _conf/hbase-env.sh_ is set to some value that is higher than what you have allocated to your offheap blockcache (`hbase.bucketcache.size`). It should be larger than your offheap block cache and then some for DFSClient usage (How much the DFSClient uses is not easy to quantify; it is the number of open hfiles * `hbase.dfs.client.read.shortcircuit.buffer.size` where hbase.dfs.client.read.shortcircuit.buffer.size is set to 128k in HBase -- see _hbase-default.xml_ default configurations). Direct memory, which is part of the Java process heap, is separate from the object heap allocated by -Xmx. -The value allocated by MaxDirectMemorySize must not exceed physical RAM, and is likely to be less than the total available RAM due to other memory requirements and system constraints. +If you do off-heap block caching, you'll be making use of direct memory. +Starting your JVM, make sure the `-XX:MaxDirectMemorySize` setting in _conf/hbase-env.sh_ is set to some value that is higher than what you have allocated to your off-heap BlockCache (`hbase.bucketcache.size`). It should be larger than your off-heap block cache and then some for DFSClient usage (How much the DFSClient uses is not easy to quantify; it is the number of open HFiles * `hbase.dfs.client.read.shortcircuit.buffer.size` where `hbase.dfs.client.read.shortcircuit.buffer.size` is set to 128k in HBase -- see _hbase-default.xml_ default configurations). Direct memory, which is part of the Java process heap, is separate from the object heap allocated by -Xmx. +The value allocated by `MaxDirectMemorySize` must not exceed physical RAM, and is likely to be less than the total available RAM due to other memory requirements and system constraints. -You can see how much memory -- onheap and offheap/direct -- a RegionServer is configured to use and how much it is using at any one time by looking at the _Server Metrics: Memory_ tab in the UI. +You can see how much memory -- on-heap and off-heap/direct -- a RegionServer is configured to use and how much it is using at any one time by looking at the _Server Metrics: Memory_ tab in the UI. It can also be gotten via JMX. In particular the direct memory currently used by the server can be found on the `java.nio.type=BufferPool,name=direct` bean. -Terracotta has a link:http://terracotta.org/documentation/4.0/bigmemorygo/configuration/storage-options[good write up] on using offheap memory in java. -It is for their product BigMemory but alot of the issues noted apply in general to any attempt at going offheap. -Check it out. +Terracotta has a link:http://terracotta.org/documentation/4.0/bigmemorygo/configuration/storage-options[good write up] on using off-heap memory in Java. +It is for their product BigMemory but a lot of the issues noted apply in general to any attempt at going off-heap. Check it out. ==== .hbase.bucketcache.percentage.in.combinedcache @@ -842,24 +843,22 @@ Check it out. This is a pre-HBase 1.0 configuration removed because it was confusing. It was a float that you would set to some value between 0.0 and 1.0. Its default was 0.9. -If the deploy was using CombinedBlockCache, then the LruBlockCache L1 size was calculated to be (1 - `hbase.bucketcache.percentage.in.combinedcache`) * `size-of-bucketcache` and the BucketCache size was `hbase.bucketcache.percentage.in.combinedcache` * size-of-bucket-cache. -where size-of-bucket-cache itself is EITHER the value of the configuration hbase.bucketcache.size IF it was specified as megabytes OR `hbase.bucketcache.size` * `-XX:MaxDirectMemorySize` if `hbase.bucketcache.size` between 0 and 1.0. +If the deploy was using CombinedBlockCache, then the LruBlockCache L1 size was calculated to be `(1 - hbase.bucketcache.percentage.in.combinedcache) * size-of-bucketcache` and the BucketCache size was `hbase.bucketcache.percentage.in.combinedcache * size-of-bucket-cache`. +where size-of-bucket-cache itself is EITHER the value of the configuration `hbase.bucketcache.size` IF it was specified as Megabytes OR `hbase.bucketcache.size` * `-XX:MaxDirectMemorySize` if `hbase.bucketcache.size` is between 0 and 1.0. In 1.0, it should be more straight-forward. -L1 LruBlockCache size is set as a fraction of java heap using hfile.block.cache.size setting (not the best name) and L2 is set as above either in absolute megabytes or as a fraction of allocated maximum direct memory. +L1 LruBlockCache size is set as a fraction of java heap using `hfile.block.cache.size setting` (not the best name) and L2 is set as above either in absolute Megabytes or as a fraction of allocated maximum direct memory. ==== -==== Comprewssed Blockcache +==== Compressed BlockCache -link:https://issues.apache.org/jira/browse/HBASE-11331[HBASE-11331] introduced lazy blockcache decompression, more simply referred to as compressed blockcache. -When compressed blockcache is enabled. -data and encoded data blocks are cached in the blockcache in their on-disk format, rather than being decompressed and decrypted before caching. +link:https://issues.apache.org/jira/browse/HBASE-11331[HBASE-11331] introduced lazy BlockCache decompression, more simply referred to as compressed BlockCache. +When compressed BlockCache is enabled data and encoded data blocks are cached in the BlockCache in their on-disk format, rather than being decompressed and decrypted before caching. For a RegionServer hosting more data than can fit into cache, enabling this feature with SNAPPY compression has been shown to result in 50% increase in throughput and 30% improvement in mean latency while, increasing garbage collection by 80% and increasing overall CPU load by 2%. See HBASE-11331 for more details about how performance was measured and achieved. For a RegionServer hosting data that can comfortably fit into cache, or if your workload is sensitive to extra CPU or garbage-collection load, you may receive less benefit. -Compressed blockcache is disabled by default. -To enable it, set `hbase.block.data.cachecompressed` to `true` in _hbase-site.xml_ on all RegionServers. +The compressed BlockCache is disabled by default. To enable it, set `hbase.block.data.cachecompressed` to `true` in _hbase-site.xml_ on all RegionServers. [[wal]] === Write Ahead Log (WAL) @@ -867,31 +866,31 @@ To enable it, set `hbase.block.data.cachecompressed` to `true` in _hbase-site.xm [[purpose.wal]] ==== Purpose -The [firstterm]_Write Ahead Log (WAL)_ records all changes to data in HBase, to file-based storage. +The _Write Ahead Log (WAL)_ records all changes to data in HBase, to file-based storage. Under normal operations, the WAL is not needed because data changes move from the MemStore to StoreFiles. However, if a RegionServer crashes or becomes unavailable before the MemStore is flushed, the WAL ensures that the changes to the data can be replayed. If writing to the WAL fails, the entire operation to modify the data fails. HBase uses an implementation of the link:http://hbase.apache.org/devapidocs/org/apache/hadoop/hbase/wal/WAL.html[WAL] interface. Usually, there is only one instance of a WAL per RegionServer. -The RegionServer records Puts and Deletes to it, before recording them to the <> for the affected <>. +The RegionServer records Puts and Deletes to it, before recording them to the <> for the affected <>. .The HLog [NOTE] ==== Prior to 2.0, the interface for WALs in HBase was named `HLog`. In 0.94, HLog was the name of the implementation of the WAL. -You will likely find references to the HLog in documentation tailored to these older versions. +You will likely find references to the HLog in documentation tailored to these older versions. ==== The WAL resides in HDFS in the _/hbase/WALs/_ directory (prior to HBase 0.94, they were stored in _/hbase/.logs/_), with subdirectories per region. -For more general information about the concept of write ahead logs, see the Wikipedia link:http://en.wikipedia.org/wiki/Write-ahead_logging[Write-Ahead Log] article. +For more general information about the concept of write ahead logs, see the Wikipedia link:http://en.wikipedia.org/wiki/Write-ahead_logging[Write-Ahead Log] article. [[wal_flush]] ==== WAL Flushing -TODO (describe). +TODO (describe). ==== WAL Splitting @@ -900,8 +899,7 @@ All of the regions in a region server share the same active WAL file. Each edit in the WAL file includes information about which region it belongs to. When a region is opened, the edits in the WAL file which belong to that region need to be replayed. Therefore, edits in the WAL file must be grouped by region so that particular sets can be replayed to regenerate the data in a particular region. -The process of grouping the WAL edits by region is called [firstterm]_log - splitting_. +The process of grouping the WAL edits by region is called _log splitting_. It is a critical process for recovering data if a region server fails. Log splitting is done by the HMaster during cluster start-up or by the ServerShutdownHandler as a region server shuts down. @@ -945,8 +943,7 @@ After log splitting completes, the _.temp_ file is renamed to the sequence ID of To determine whether all edits have been written, the sequence ID is compared to the sequence of the last edit that was written to the HFile. If the sequence of the last edit is greater than or equal to the sequence ID included in the file name, it is clear that all writes from the edit file have been completed. -. After log splitting is complete, each affected region is assigned to a - RegionServer. +. After log splitting is complete, each affected region is assigned to a RegionServer. + When the region is opened, the _recovered.edits_ folder is checked for recovered edits files. If any such files are present, they are replayed by reading the edits and saving them to the MemStore. @@ -955,60 +952,57 @@ After all edit files are replayed, the contents of the MemStore are written to d ===== Handling of Errors During Log Splitting -If you set the `hbase.hlog.split.skip.errors` option to [constant]+true+, errors are treated as follows: +If you set the `hbase.hlog.split.skip.errors` option to `true`, errors are treated as follows: * Any error encountered during splitting will be logged. -* The problematic WAL log will be moved into the _.corrupt_ directory under the hbase `rootdir`, +* The problematic WAL log will be moved into the _.corrupt_ directory under the hbase `rootdir`, * Processing of the WAL will continue -If the `hbase.hlog.split.skip.errors` optionset to `false`, the default, the exception will be propagated and the split will be logged as failed. -See link:https://issues.apache.org/jira/browse/HBASE-2958[HBASE-2958 When -hbase.hlog.split.skip.errors is set to false, we fail the split but thats -it]. +If the `hbase.hlog.split.skip.errors` option is set to `false`, the default, the exception will be propagated and the split will be logged as failed. +See link:https://issues.apache.org/jira/browse/HBASE-2958[HBASE-2958 When hbase.hlog.split.skip.errors is set to false, we fail the split but thats it]. We need to do more than just fail split if this flag is set. -====== How EOFExceptions are treated when splitting a crashed RegionServers'WALs +====== How EOFExceptions are treated when splitting a crashed RegionServer's WALs If an EOFException occurs while splitting logs, the split proceeds even when `hbase.hlog.split.skip.errors` is set to `false`. -An EOFException while reading the last log in the set of files to split is likely, because the RegionServer is likely to be in the process of writing a record at the time of a crash. -For background, see link:https://issues.apache.org/jira/browse/HBASE-2643[HBASE-2643 - Figure how to deal with eof splitting logs] +An EOFException while reading the last log in the set of files to split is likely, because the RegionServer was likely in the process of writing a record at the time of a crash. +For background, see link:https://issues.apache.org/jira/browse/HBASE-2643[HBASE-2643 Figure how to deal with eof splitting logs] ===== Performance Improvements during Log Splitting -WAL log splitting and recovery can be resource intensive and take a long time, depending on the number of RegionServers involved in the crash and the size of the regions. <> and <> were developed to improve performance during log splitting. +WAL log splitting and recovery can be resource intensive and take a long time, depending on the number of RegionServers involved in the crash and the size of the regions. <> and <> were developed to improve performance during log splitting. [[distributed.log.splitting]] ====== Distributed Log Splitting -[firstterm]_Distributed Log Splitting_ was added in HBase version 0.92 (link:https://issues.apache.org/jira/browse/HBASE-1364[HBASE-1364]) by Prakash Khemani from Facebook. +_Distributed Log Splitting_ was added in HBase version 0.92 (link:https://issues.apache.org/jira/browse/HBASE-1364[HBASE-1364]) by Prakash Khemani from Facebook. It reduces the time to complete log splitting dramatically, improving the availability of regions and tables. For example, recovering a crashed cluster took around 9 hours with single-threaded log splitting, but only about six minutes with distributed log splitting. -The information in this section is sourced from Jimmy Xiang's blog post at link:http://blog.cloudera.com/blog/2012/07/hbase-log-splitting/. +The information in this section is sourced from Jimmy Xiang's blog post at http://blog.cloudera.com/blog/2012/07/hbase-log-splitting/. .Enabling or Disabling Distributed Log Splitting Distributed log processing is enabled by default since HBase 0.92. -The setting is controlled by the +hbase.master.distributed.log.splitting+ property, which can be set to `true` or `false`, but defaults to `true`. +The setting is controlled by the `hbase.master.distributed.log.splitting` property, which can be set to `true` or `false`, but defaults to `true`. [[log.splitting.step.by.step]] .Distributed Log Splitting, Step by Step After configuring distributed log splitting, the HMaster controls the process. The HMaster enrolls each RegionServer in the log splitting process, and the actual work of splitting the logs is done by the RegionServers. -The general process for log splitting, as described in <> still applies here. +The general process for log splitting, as described in <> still applies here. -. If distributed log processing is enabled, the HMaster creates a [firstterm]_split log manager_ instance when the cluster is started. +. If distributed log processing is enabled, the HMaster creates a _split log manager_ instance when the cluster is started. .. The split log manager manages all log files which need to be scanned and split. .. The split log manager places all the logs into the ZooKeeper splitlog node (_/hbase/splitlog_) as tasks. - .. You can view the contents of the splitlog by issuing the following +zkcli+ command. Example output is shown. + .. You can view the contents of the splitlog by issuing the following `zkCli` command. Example output is shown. + [source,bash] ---- ls /hbase/splitlog -[hdfs%3A%2F%2Fhost2.sample.com%3A56020%2Fhbase%2F.logs%2Fhost8.sample.com%2C57020%2C1340474893275-splitting%2Fhost8.sample.com%253A57020.1340474893900, -hdfs%3A%2F%2Fhost2.sample.com%3A56020%2Fhbase%2F.logs%2Fhost3.sample.com%2C57020%2C1340474893299-splitting%2Fhost3.sample.com%253A57020.1340474893931, +[hdfs%3A%2F%2Fhost2.sample.com%3A56020%2Fhbase%2F.logs%2Fhost8.sample.com%2C57020%2C1340474893275-splitting%2Fhost8.sample.com%253A57020.1340474893900, +hdfs%3A%2F%2Fhost2.sample.com%3A56020%2Fhbase%2F.logs%2Fhost3.sample.com%2C57020%2C1340474893299-splitting%2Fhost3.sample.com%253A57020.1340474893931, hdfs%3A%2F%2Fhost2.sample.com%3A56020%2Fhbase%2F.logs%2Fhost4.sample.com%2C57020%2C1340474893287-splitting%2Fhost4.sample.com%253A57020.1340474893946] ---- + @@ -1018,10 +1012,10 @@ When decoded, it looks much more simple: ---- [hdfs://host2.sample.com:56020/hbase/.logs /host8.sample.com,57020,1340474893275-splitting -/host8.sample.com%3A57020.1340474893900, +/host8.sample.com%3A57020.1340474893900, hdfs://host2.sample.com:56020/hbase/.logs /host3.sample.com,57020,1340474893299-splitting -/host3.sample.com%3A57020.1340474893931, +/host3.sample.com%3A57020.1340474893931, hdfs://host2.sample.com:56020/hbase/.logs /host4.sample.com,57020,1340474893287-splitting /host4.sample.com%3A57020.1340474893946] @@ -1047,12 +1041,12 @@ The split log manager is responsible for the following ongoing tasks: * The split log manager watches the HBase split log znodes constantly. If any split log task node data is changed, the split log manager retrieves the node data. The node data contains the current state of the task. - You can use the +zkcli+ +get+ command to retrieve the current state of a task. + You can use the `zkCli` `get` command to retrieve the current state of a task. In the example output below, the first line of the output shows that the task is currently unassigned. + ---- get /hbase/splitlog/hdfs%3A%2F%2Fhost2.sample.com%3A56020%2Fhbase%2F.logs%2Fhost6.sample.com%2C57020%2C1340474893287-splitting%2Fhost6.sample.com%253A57020.1340474893945 - + unassigned host2.sample.com:57000 cZxid = 0×7115 ctime = Sat Jun 23 11:13:40 PDT 2012 @@ -1063,43 +1057,46 @@ Based on the state of the task whose data is changed, the split log manager does + * Resubmit the task if it is unassigned * Heartbeat the task if it is assigned -* Resubmit or fail the task if it is resigned (see <>) -* Resubmit or fail the task if it is completed with errors (see <>) -* Resubmit or fail the task if it could not complete due to errors (see <>) +* Resubmit or fail the task if it is resigned (see <>) +* Resubmit or fail the task if it is completed with errors (see <>) +* Resubmit or fail the task if it could not complete due to errors (see <>) * Delete the task if it is successfully completed or failed + -* .Reasons a Task Will FailThe task has been deleted. +[[distributed.log.replay.failure.reasons]] +[NOTE] +.Reasons a Task Will Fail +==== +* The task has been deleted. * The node no longer exists. -* The log status manager failed to move the state of the task to TASK_UNASSIGNED. +* The log status manager failed to move the state of the task to `TASK_UNASSIGNED`. * The number of resubmits is over the resubmit threshold. - +==== . Each RegionServer's split log worker performs the log-splitting tasks. + -Each RegionServer runs a daemon thread called the [firstterm]_split log - worker_, which does the work to split the logs. +Each RegionServer runs a daemon thread called the _split log worker_, which does the work to split the logs. The daemon thread starts when the RegionServer starts, and registers itself to watch HBase znodes. If any splitlog znode children change, it notifies a sleeping worker thread to wake up and grab more tasks. If if a worker's current task's node data is changed, the worker checks to see if the task has been taken by another worker. If so, the worker thread stops work on the current task. + The worker monitors the splitlog znode constantly. -When a new task appears, the split log worker retrieves the task paths and checks each one until it finds an unclaimed task, which it attempts to claim. -If the claim was successful, it attempts to perform the task and updates the task's +state+ property based on the splitting outcome. +When a new task appears, the split log worker retrieves the task paths and checks each one until it finds an unclaimed task, which it attempts to claim. +If the claim was successful, it attempts to perform the task and updates the task's `state` property based on the splitting outcome. At this point, the split log worker scans for another unclaimed task. + -* .How the Split Log Worker Approaches a TaskIt queries the task state and only takes action if the task is in `TASK_UNASSIGNED `state. +.How the Split Log Worker Approaches a Task +* It queries the task state and only takes action if the task is in `TASK_UNASSIGNED `state. * If the task is is in `TASK_UNASSIGNED` state, the worker attempts to set the state to `TASK_OWNED` by itself. If it fails to set the state, another worker will try to grab it. The split log manager will also ask all workers to rescan later if the task remains unassigned. * If the worker succeeds in taking ownership of the task, it tries to get the task state again to make sure it really gets it asynchronously. - In the meantime, it starts a split task executor to do the actual work: -+ -* Get the HBase root folder, create a temp folder under the root, and split the log file to the temp folder. -* If the split was successful, the task executor sets the task to state `TASK_DONE`. -* If the worker catches an unexpected IOException, the task is set to state `TASK_ERR`. -* If the worker is shutting down, set the the task to state `TASK_RESIGNED`. -* If the task is taken by another worker, just log it. + In the meantime, it starts a split task executor to do the actual work: +** Get the HBase root folder, create a temp folder under the root, and split the log file to the temp folder. +** If the split was successful, the task executor sets the task to state `TASK_DONE`. +** If the worker catches an unexpected IOException, the task is set to state `TASK_ERR`. +** If the worker is shutting down, set the the task to state `TASK_RESIGNED`. +** If the task is taken by another worker, just log it. . The split log manager monitors for uncompleted tasks. @@ -1114,11 +1111,11 @@ If none are found, it throws an exception so that the log splitting can be retri [[distributed.log.replay]] ====== Distributed Log Replay -After a RegionServer fails, its failed region is assigned to another RegionServer, which is marked as "recovering" in ZooKeeper. -A split log worker directly replays edits from the WAL of the failed region server to the region at its new location. -When a region is in "recovering" state, it can accept writes but no reads (including Append and Increment), region splits or merges. +After a RegionServer fails, its failed regions are assigned to another RegionServer, which are marked as "recovering" in ZooKeeper. +A split log worker directly replays edits from the WAL of the failed RegionServer to the regions at its new location. +When a region is in "recovering" state, it can accept writes but no reads (including Append and Increment), region splits or merges. -Distributed Log Replay extends the <> framework. +Distributed Log Replay extends the <> framework. It works by directly replaying WAL edits to another RegionServer instead of creating _recovered.edits_ files. It provides the following advantages over distributed log splitting alone: @@ -1129,7 +1126,7 @@ It provides the following advantages over distributed log splitting alone: It only takes seconds for a recovering region to accept writes again. .Enabling Distributed Log Replay -To enable distributed log replay, set `hbase.master.distributed.log.replay` to true. +To enable distributed log replay, set `hbase.master.distributed.log.replay` to `true`. This will be the default for HBase 0.99 (link:https://issues.apache.org/jira/browse/HBASE-10888[HBASE-10888]). You must also enable HFile version 3 (which is the default HFile format starting in HBase 0.99. @@ -1138,7 +1135,7 @@ See link:https://issues.apache.org/jira/browse/HBASE-10855[HBASE-10855]). Distri [[wal.disable]] ==== Disabling the WAL -It is possible to disable the WAL, to improve performace in certain specific situations. +It is possible to disable the WAL, to improve performance in certain specific situations. However, disabling the WAL puts your data at risk. The only situation where this is recommended is during a bulk load. This is because, in the event of a problem, the bulk load can be re-run with no risk of data loss. @@ -1153,18 +1150,18 @@ WARNING: If you disable the WAL for anything other than bulk loads, your data is == Regions Regions are the basic element of availability and distribution for tables, and are comprised of a Store per Column Family. -The heirarchy of objects is as follows: +The hierarchy of objects is as follows: ---- -Table (HBase table) - Region (Regions for the table) - Store (Store per ColumnFamily for each Region for the table) - MemStore (MemStore for each Store for each Region for the table) - StoreFile (StoreFiles for each Store for each Region for the table) - Block (Blocks within a StoreFile within a Store for each Region for the table) ----- +Table (HBase table) + Region (Regions for the table) + Store (Store per ColumnFamily for each Region for the table) + MemStore (MemStore for each Store for each Region for the table) + StoreFile (StoreFiles for each Store for each Region for the table) + Block (Blocks within a StoreFile within a Store for each Region for the table) +---- -For a description of what HBase files look like when written to HDFS, see <>. +For a description of what HBase files look like when written to HDFS, see <>. [[arch.regions.size]] === Considerations for Number of Regions @@ -1173,49 +1170,49 @@ In general, HBase is designed to run with a small (20-200) number of relatively The considerations for this are as follows: [[too_many_regions]] -==== Why cannot I have too many regions? +==== Why should I keep my Region count low? Typically you want to keep your region count low on HBase for numerous reasons. Usually right around 100 regions per RegionServer has yielded the best results. Here are some of the reasons below for keeping region count low: -. MSLAB requires 2mb per memstore (that's 2mb per family per region). 1000 regions that have 2 families each is 3.9GB of heap used, and it's not even storing data yet. - NB: the 2MB value is configurable. +. MSLAB (MemStore-local allocation buffer) requires 2MB per MemStore (that's 2MB per family per region). 1000 regions that have 2 families each is 3.9GB of heap used, and it's not even storing data yet. + NB: the 2MB value is configurable. . If you fill all the regions at somewhat the same rate, the global memory usage makes it that it forces tiny flushes when you have too many regions which in turn generates compactions. Rewriting the same data tens of times is the last thing you want. - An example is filling 1000 regions (with one family) equally and let's consider a lower bound for global memstore usage of 5GB (the region server would have a big heap). Once it reaches 5GB it will force flush the biggest region, at that point they should almost all have about 5MB of data so it would flush that amount. + An example is filling 1000 regions (with one family) equally and let's consider a lower bound for global MemStore usage of 5GB (the region server would have a big heap). Once it reaches 5GB it will force flush the biggest region, at that point they should almost all have about 5MB of data so it would flush that amount. 5MB inserted later, it would flush another region that will now have a bit over 5MB of data, and so on. - This is currently the main limiting factor for the number of regions; see <> for detailed formula. + This is currently the main limiting factor for the number of regions; see <> for detailed formula. . The master as is is allergic to tons of regions, and will take a lot of time assigning them and moving them around in batches. - The reason is that it's heavy on ZK usage, and it's not very async at the moment (could really be improved -- and has been imporoved a bunch in 0.96 hbase). -. In older versions of HBase (pre-v2 hfile, 0.90 and previous), tons of regions on a few RS can cause the store file index to rise, increasing heap usage and potentially creating memory pressure or OOME on the RSs + The reason is that it's heavy on ZK usage, and it's not very async at the moment (could really be improved -- and has been improved a bunch in 0.96 HBase). +. In older versions of HBase (pre-HFile v2, 0.90 and previous), tons of regions on a few RS can cause the store file index to rise, increasing heap usage and potentially creating memory pressure or OOME on the RSs -Another issue is the effect of the number of regions on mapreduce jobs; it is typical to have one mapper per HBase region. -Thus, hosting only 5 regions per RS may not be enough to get sufficient number of tasks for a mapreduce job, while 1000 regions will generate far too many tasks. +Another issue is the effect of the number of regions on MapReduce jobs; it is typical to have one mapper per HBase region. +Thus, hosting only 5 regions per RS may not be enough to get sufficient number of tasks for a MapReduce job, while 1000 regions will generate far too many tasks. -See <> for configuration guidelines. +See <> for configuration guidelines. [[regions.arch.assignment]] === Region-RegionServer Assignment -This section describes how Regions are assigned to RegionServers. +This section describes how Regions are assigned to RegionServers. [[regions.arch.assignment.startup]] ==== Startup -When HBase starts regions are assigned as follows (short version): +When HBase starts regions are assigned as follows (short version): . The Master invokes the `AssignmentManager` upon startup. -. The `AssignmentManager` looks at the existing region assignments in META. +. The `AssignmentManager` looks at the existing region assignments in `hbase:meta`. . If the region assignment is still valid (i.e., if the RegionServer is still online) then the assignment is kept. . If the assignment is invalid, then the `LoadBalancerFactory` is invoked to assign the region. - The `DefaultLoadBalancer` will randomly assign the region to a RegionServer. -. META is updated with the RegionServer assignment (if needed) and the RegionServer start codes (start time of the RegionServer process) upon region opening by the RegionServer. + The load balancer (`StochasticLoadBalancer` by default in HBase 1.0) assign the region to a RegionServer. +. `hbase:meta` is updated with the RegionServer assignment (if needed) and the RegionServer start codes (start time of the RegionServer process) upon region opening by the RegionServer. [[regions.arch.assignment.failover]] ==== Failover -When a RegionServer fails: +When a RegionServer fails: . The regions immediately become unavailable because the RegionServer is down. . The Master will detect that the RegionServer has failed. @@ -1227,35 +1224,35 @@ When a RegionServer fails: ---- ZooKeeper session timeout + split time + assignment/replay time ---- - + [[regions.arch.balancer]] ==== Region Load Balancing -Regions can be periodically moved by the <>. +Regions can be periodically moved by the <>. [[regions.arch.states]] ==== Region State Transition -HBase maintains a state for each region and persists the state in META. -The state of the META region itself is persisted in ZooKeeper. +HBase maintains a state for each region and persists the state in `hbase:meta`. +The state of the `hbase:meta` region itself is persisted in ZooKeeper. You can see the states of regions in transition in the Master web UI. Following is the list of possible region states. .Possible Region States -* OFFLINE: the region is offline and not opening -* OPENING: the region is in the process of being opened -* OPEN: the region is open and the region server has notified the master -* FAILED_OPEN: the region server failed to open the region -* CLOSING: the region is in the process of being closed -* CLOSED: the region server has closed the region and notified the master -* FAILED_CLOSE: the region server failed to close the region -* SPLITTING: the region server notified the master that the region is splitting -* SPLIT: the region server notified the master that the region has finished splitting -* SPLITTING_NEW: this region is being created by a split which is in progress -* MERGING: the region server notified the master that this region is being merged with another region -* MERGED: the region server notified the master that this region has been merged -* MERGING_NEW: this region is being created by a merge of two regions +* `OFFLINE`: the region is offline and not opening +* `OPENING`: the region is in the process of being opened +* `OPEN`: the region is open and the RegionServer has notified the master +* `FAILED_OPEN`: the RegionServer failed to open the region +* `CLOSING`: the region is in the process of being closed +* `CLOSED`: the RegionServer has closed the region and notified the master +* `FAILED_CLOSE`: the RegionServer failed to close the region +* `SPLITTING`: the RegionServer notified the master that the region is splitting +* `SPLIT`: the RegionServer notified the master that the region has finished splitting +* `SPLITTING_NEW`: this region is being created by a split which is in progress +* `MERGING`: the RegionServer notified the master that this region is being merged with another region +* `MERGED`: the RegionServer notified the master that this region has been merged +* `MERGING_NEW`: this region is being created by a merge of two regions .Region State Transitions image::region_states.png[] @@ -1269,41 +1266,41 @@ image::region_states.png[] * Grey: Initial states of regions created through split/merge .Transition State Descriptions -. The master moves a region from `OFFLINE` to `OPENING` state and tries to assign the region to a region server. - The region server may or may not have received the open region request. - The master retries sending the open region request to the region server until the RPC goes through or the master runs out of retries. - After the region server receives the open region request, the region server begins opening the region. -. If the master is running out of retries, the master prevents the region server from opening the region by moving the region to `CLOSING` state and trying to close it, even if the region server is starting to open the region. -. After the region server opens the region, it continues to try to notify the master until the master moves the region to `OPEN` state and notifies the region server. +. The master moves a region from `OFFLINE` to `OPENING` state and tries to assign the region to a RegionServer. + The RegionServer may or may not have received the open region request. + The master retries sending the open region request to the RegionServer until the RPC goes through or the master runs out of retries. + After the RegionServer receives the open region request, the RegionServer begins opening the region. +. If the master is running out of retries, the master prevents the RegionServer from opening the region by moving the region to `CLOSING` state and trying to close it, even if the RegionServer is starting to open the region. +. After the RegionServer opens the region, it continues to try to notify the master until the master moves the region to `OPEN` state and notifies the RegionServer. The region is now open. -. If the region server cannot open the region, it notifies the master. - The master moves the region to `CLOSED` state and tries to open the region on a different region server. +. If the RegionServer cannot open the region, it notifies the master. + The master moves the region to `CLOSED` state and tries to open the region on a different RegionServer. . If the master cannot open the region on any of a certain number of regions, it moves the region to `FAILED_OPEN` state, and takes no further action until an operator intervenes from the HBase shell, or the server is dead. . The master moves a region from `OPEN` to `CLOSING` state. - The region server holding the region may or may not have received the close region request. + The RegionServer holding the region may or may not have received the close region request. The master retries sending the close request to the server until the RPC goes through or the master runs out of retries. -. If the region server is not online, or throws `NotServingRegionException`, the master moves the region to `OFFLINE` state and re-assigns it to a different region server. -. If the region server is online, but not reachable after the master runs out of retries, the master moves the region to `FAILED_CLOSE` state and takes no further action until an operator intervenes from the HBase shell, or the server is dead. -. If the region server gets the close region request, it closes the region and notifies the master. - The master moves the region to `CLOSED` state and re-assigns it to a different region server. +. If the RegionServer is not online, or throws `NotServingRegionException`, the master moves the region to `OFFLINE` state and re-assigns it to a different RegionServer. +. If the RegionServer is online, but not reachable after the master runs out of retries, the master moves the region to `FAILED_CLOSE` state and takes no further action until an operator intervenes from the HBase shell, or the server is dead. +. If the RegionServer gets the close region request, it closes the region and notifies the master. + The master moves the region to `CLOSED` state and re-assigns it to a different RegionServer. . Before assigning a region, the master moves the region to `OFFLINE` state automatically if it is in `CLOSED` state. -. When a region server is about to split a region, it notifies the master. - The master moves the region to be split from `OPEN` to `SPLITTING` state and add the two new regions to be created to the region server. +. When a RegionServer is about to split a region, it notifies the master. + The master moves the region to be split from `OPEN` to `SPLITTING` state and add the two new regions to be created to the RegionServer. These two regions are in `SPLITING_NEW` state initially. -. After notifying the master, the region server starts to split the region. - Once past the point of no return, the region server notifies the master again so the master can update the META. +. After notifying the master, the RegionServer starts to split the region. + Once past the point of no return, the RegionServer notifies the master again so the master can update the `hbase:meta` table. However, the master does not update the region states until it is notified by the server that the split is done. If the split is successful, the splitting region is moved from `SPLITTING` to `SPLIT` state and the two new regions are moved from `SPLITTING_NEW` to `OPEN` state. . If the split fails, the splitting region is moved from `SPLITTING` back to `OPEN` state, and the two new regions which were created are moved from `SPLITTING_NEW` to `OFFLINE` state. -. When a region server is about to merge two regions, it notifies the master first. - The master moves the two regions to be merged from `OPEN` to `MERGING`state, and adds the new region which will hold the contents of the merged regions region to the region server. +. When a RegionServer is about to merge two regions, it notifies the master first. + The master moves the two regions to be merged from `OPEN` to `MERGING` state, and adds the new region which will hold the contents of the merged regions region to the RegionServer. The new region is in `MERGING_NEW` state initially. -. After notifying the master, the region server starts to merge the two regions. - Once past the point of no return, the region server notifies the master again so the master can update the META. - However, the master does not update the region states until it is notified by the region server that the merge has completed. +. After notifying the master, the RegionServer starts to merge the two regions. + Once past the point of no return, the RegionServer notifies the master again so the master can update the META. + However, the master does not update the region states until it is notified by the RegionServer that the merge has completed. If the merge is successful, the two merging regions are moved from `MERGING` to `MERGED` state and the new region is moved from `MERGING_NEW` to `OPEN` state. . If the merge fails, the two merging regions are moved from `MERGING` back to `OPEN` state, and the new region which was created to hold the contents of the merged regions is moved from `MERGING_NEW` to `OFFLINE` state. -. For regions in `FAILED_OPEN` or `FAILED_CLOSE` states , the master tries to close them again when they are reassigned by an operator via HBase Shell. +. For regions in `FAILED_OPEN` or `FAILED_CLOSE` states, the master tries to close them again when they are reassigned by an operator via HBase Shell. [[regions.arch.locality]] === Region-RegionServer Locality @@ -1318,32 +1315,31 @@ The HDFS client does the following by default when choosing locations to write r See _Replica Placement: The First Baby Steps_ on this page: link:http://hadoop.apache.org/docs/stable/hadoop-project-dist/hadoop-hdfs/HdfsDesign.html[HDFS Architecture] Thus, HBase eventually achieves locality for a region after a flush or a compaction. -In a RegionServer failover situation a RegionServer may be assigned regions with non-local StoreFiles (because none of the replicas are local), however as new data is written in the region, or the table is compacted and StoreFiles are re-written, they will become "local" to the RegionServer. +In a RegionServer failover situation a RegionServer may be assigned regions with non-local StoreFiles (because none of the replicas are local), however as new data is written in the region, or the table is compacted and StoreFiles are re-written, they will become "local" to the RegionServer. -For more information, see _Replica Placement: The First Baby Steps_ on this page: link:http://hadoop.apache.org/docs/stable/hadoop-project-dist/hadoop-hdfs/HdfsDesign.html[HDFS Architecture] and also Lars George's blog on link:http://www.larsgeorge.com/2010/05/hbase-file-locality-in-hdfs.html[HBase and HDFS locality]. +For more information, see _Replica Placement: The First Baby Steps_ on this page: link:http://hadoop.apache.org/docs/stable/hadoop-project-dist/hadoop-hdfs/HdfsDesign.html[HDFS Architecture] and also Lars George's blog on link:http://www.larsgeorge.com/2010/05/hbase-file-locality-in-hdfs.html[HBase and HDFS locality]. [[arch.region.splits]] === Region Splits Regions split when they reach a configured threshold. Below we treat the topic in short. -For a longer exposition, see link:http://hortonworks.com/blog/apache-hbase-region-splitting-and-merging/[Apache HBase Region Splitting and Merging] by our Enis Soztutar. +For a longer exposition, see link:http://hortonworks.com/blog/apache-hbase-region-splitting-and-merging/[Apache HBase Region Splitting and Merging] by our Enis Soztutar. -Splits run unaided on the RegionServer; i.e. -the Master does not participate. -The RegionServer splits a region, offlines the split region and then adds the daughter regions to META, opens daughters on the parent's hosting RegionServer and then reports the split to the Master. -See <> for how to manually manage splits (and for why you might do this) +Splits run unaided on the RegionServer; i.e. the Master does not participate. +The RegionServer splits a region, offlines the split region and then adds the daughter regions to `hbase:meta`, opens daughters on the parent's hosting RegionServer and then reports the split to the Master. +See <> for how to manually manage splits (and for why you might do this). ==== Custom Split Policies -The default split policy can be overwritten using a custom link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/regionserver/RegionSplitPolicy.html[RegionSplitPolicy(HBase 0.94+)]. Typically a custom split policy should extend HBase's default split policy: link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/regionserver/ConstantSizeRegionSplitPolicy.html[ConstantSizeRegionSplitPolicy]. +The default split policy can be overwritten using a custom link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/regionserver/RegionSplitPolicy.html[RegionSplitPolicy(HBase 0.94+)]. Typically a custom split policy should extend HBase's default split policy: link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/regionserver/ConstantSizeRegionSplitPolicy.html[ConstantSizeRegionSplitPolicy]. -The policy can set globally through the HBaseConfiguration used or on a per table basis: +The policy can be set globally through the HBaseConfiguration used or on a per table basis: [source,java] ---- HTableDescriptor myHtd = ...; myHtd.setValue(HTableDescriptor.SPLIT_POLICY, MyCustomSplitPolicy.class.getName()); ----- +---- [[manual_region_splitting_decisions]] === Manual Region Splitting @@ -1353,16 +1349,16 @@ You might choose to split your region for one or more of the following reasons. There may be other valid reasons, but the need to manually split your table might also point to problems with your schema design. .Reasons to Manually Split Your Table -*Your data is sorted by timeseries or another similar algorithm that sorts new data at the end of the table. +* Your data is sorted by timeseries or another similar algorithm that sorts new data at the end of the table. This means that the Region Server holding the last region is always under load, and the other Region Servers are idle, or mostly idle. - See also <>. + See also <>. * You have developed an unexpected hotspot in one region of your table. For instance, an application which tracks web searches might be inundated by a lot of searches for a celebrity in the event of news about that celebrity. See <> for more discussion about this particular scenario. -* After a big increase to the number of Region Servers in your cluster, to get the load spread out quickly. +* After a big increase in the number of RegionServers in your cluster, to get the load spread out quickly. * Before a bulk-load which is likely to cause unusual and uneven load across regions. -See <> for a discussion about the dangers and possible benefits of managing splitting completely manually. +See <> for a discussion about the dangers and possible benefits of managing splitting completely manually. ==== Determining Split Points @@ -1376,83 +1372,83 @@ Alphanumeric Rowkeys:: For instance, the following command creates a table with regions that split at each vowel, so the first region has A-D, the second region has E-H, the third region has I-N, the fourth region has O-V, and the fifth region has U-Z. Using a Custom Algorithm:: - The RegionSplitter tool is provided with HBase, and uses a [firstterm]_SplitAlgorithm_ to determine split points for you. + The RegionSplitter tool is provided with HBase, and uses a _SplitAlgorithm_ to determine split points for you. As parameters, you give it the algorithm, desired number of regions, and column families. It includes two split algorithms. - The first is the `HexStringSplit` algorithm, which assumes the row keys are hexadecimal strings. - The second, link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/util/RegionSplitter.UniformSplit.html[UniformSplit], assumes the row keys are random byte arrays. - You will probably need to develop your own SplitAlgorithm, using the provided ones as models. + The first is the `link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/util/RegionSplitter.HexStringSplit.html[HexStringSplit]` algorithm, which assumes the row keys are hexadecimal strings. + The second, `link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/util/RegionSplitter.UniformSplit.html[UniformSplit]`, assumes the row keys are random byte arrays. + You will probably need to develop your own `link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/util/RegionSplitter.SplitAlgorithm.html[SplitAlgorithm]`, using the provided ones as models. === Online Region Merges -Both Master and Regionserver participate in the event of online region merges. -Client sends merge RPC to master, then master moves the regions together to the same regionserver where the more heavily loaded region resided, finally master send merge request to this regionserver and regionserver run the region merges. -Similar with process of region splits, region merges run as a local transaction on the regionserver, offlines the regions and then merges two regions on the file system, atomically delete merging regions from META and add merged region to the META, opens merged region on the regionserver and reports the merge to Master at last. +Both Master and RegionServer participate in the event of online region merges. +Client sends merge RPC to the master, then the master moves the regions together to the RegionServer where the more heavily loaded region resided. Finally the master sends the merge request to this RegionServer which then runs the merge. +Similar to process of region splitting, region merges run as a local transaction on the RegionServer. It offlines the regions and then merges two regions on the file system, atomically delete merging regions from `hbase:meta` and adds the merged region to `hbase:meta`, opens the merged region on the RegionServer and reports the merge to the Master. -An example of region merges in the hbase shell +An example of region merges in the HBase shell [source,bourne] ---- $ hbase> merge_region 'ENCODED_REGIONNAME', 'ENCODED_REGIONNAME' - hbase> merge_region 'ENCODED_REGIONNAME', 'ENCODED_REGIONNAME', true ----- +$ hbase> merge_region 'ENCODED_REGIONNAME', 'ENCODED_REGIONNAME', true +---- It's an asynchronous operation and call returns immediately without waiting merge completed. -Passing 'true' as the optional third parameter will force a merge ('force' merges regardless else merge will fail unless passed adjacent regions. -'force' is for expert use only) +Passing `true` as the optional third parameter will force a merge. Normally only adjacent regions can be merged. +The `force` parameter overrides this behaviour and is for expert use only. === Store -A Store hosts a MemStore and 0 or more StoreFiles (HFiles). A Store corresponds to a column family for a table for a given region. +A Store hosts a MemStore and 0 or more StoreFiles (HFiles). A Store corresponds to a column family for a table for a given region. [[store.memstore]] ==== MemStore The MemStore holds in-memory modifications to the Store. Modifications are Cells/KeyValues. -When a flush is requested, the current memstore is moved to a snapshot and is cleared. -HBase continues to serve edits from the new memstore and backing snapshot until the flusher reports that the flush succeeded. +When a flush is requested, the current MemStore is moved to a snapshot and is cleared. +HBase continues to serve edits from the new MemStore and backing snapshot until the flusher reports that the flush succeeded. At this point, the snapshot is discarded. -Note that when the flush happens, Memstores that belong to the same region will all be flushed. +Note that when the flush happens, MemStores that belong to the same region will all be flushed. -==== MemStoreFlush +==== MemStore Flush A MemStore flush can be triggered under any of the conditions listed below. The minimum flush unit is per region, not at individual MemStore level. -. When a MemStore reaches the value specified by `hbase.hregion.memstore.flush.size`, all MemStores that belong to its region will be flushed out to disk. -. When overall memstore usage reaches the value specified by `hbase.regionserver.global.memstore.upperLimit`, MemStores from various regions will be flushed out to disk to reduce overall MemStore usage in a Region Server. +. When a MemStore reaches the size specified by `hbase.hregion.memstore.flush.size`, all MemStores that belong to its region will be flushed out to disk. +. When the overall MemStore usage reaches the value specified by `hbase.regionserver.global.memstore.upperLimit`, MemStores from various regions will be flushed out to disk to reduce overall MemStore usage in a RegionServer. The flush order is based on the descending order of a region's MemStore usage. - Regions will have their MemStores flushed until the overall MemStore usage drops to or slightly below `hbase.regionserver.global.memstore.lowerLimit`. + Regions will have their MemStores flushed until the overall MemStore usage drops to or slightly below `hbase.regionserver.global.memstore.lowerLimit`. . When the number of WAL per region server reaches the value specified in `hbase.regionserver.max.logs`, MemStores from various regions will be flushed out to disk to reduce WAL count. The flush order is based on time. - Regions with the oldest MemStores are flushed first until WAL count drops below `hbase.regionserver.max.logs`. + Regions with the oldest MemStores are flushed first until WAL count drops below `hbase.regionserver.max.logs`. [[hregion.scans]] ==== Scans -* When a client issues a scan against a table, HBase generates `RegionScanner` objects, one per region, to serve the scan request. -* The `RegionScanner` object contains a list of `StoreScanner` objects, one per column family. -* Each `StoreScanner` object further contains a list of `StoreFileScanner` objects, corresponding to each StoreFile and HFile of the corresponding column family, and a list of `KeyValueScanner` objects for the MemStore. -* The two lists are merge into one, which is sorted in ascending order with the scan object for the MemStore at the end of the list. -* When a `StoreFileScanner` object is constructed, it is associated with a `MultiVersionConsistencyControl` read point, which is the current `memstoreTS`, filtering out any new updates beyond the read point. +* When a client issues a scan against a table, HBase generates `RegionScanner` objects, one per region, to serve the scan request. +* The `RegionScanner` object contains a list of `StoreScanner` objects, one per column family. +* Each `StoreScanner` object further contains a list of `StoreFileScanner` objects, corresponding to each StoreFile and HFile of the corresponding column family, and a list of `KeyValueScanner` objects for the MemStore. +* The two lists are merged into one, which is sorted in ascending order with the scan object for the MemStore at the end of the list. +* When a `StoreFileScanner` object is constructed, it is associated with a `MultiVersionConsistencyControl` read point, which is the current `memstoreTS`, filtering out any new updates beyond the read point. [[hfile]] ==== StoreFile (HFile) -StoreFiles are where your data lives. +StoreFiles are where your data lives. ===== HFile Format -The _hfile_ file format is based on the SSTable file described in the link:http://research.google.com/archive/bigtable.html[BigTable [2006]] paper and on Hadoop's link:http://hadoop.apache.org/common/docs/current/api/org/apache/hadoop/io/file/tfile/TFile.html[tfile] (The unit test suite and the compression harness were taken directly from tfile). Schubert Zhang's blog post on link:http://cloudepr.blogspot.com/2009/09/hfile-block-indexed-file-format-to.html[HFile: A Block-Indexed File Format to Store Sorted Key-Value Pairs] makes for a thorough introduction to HBase's hfile. -Matteo Bertozzi has also put up a helpful description, link:http://th30z.blogspot.com/2011/02/hbase-io-hfile.html?spref=tw[HBase I/O: HFile]. +The _HFile_ file format is based on the SSTable file described in the link:http://research.google.com/archive/bigtable.html[BigTable [2006]] paper and on Hadoop's link:http://hadoop.apache.org/common/docs/current/api/org/apache/hadoop/io/file/tfile/TFile.html[TFile] (The unit test suite and the compression harness were taken directly from TFile). Schubert Zhang's blog post on link:http://cloudepr.blogspot.com/2009/09/hfile-block-indexed-file-format-to.html[HFile: A Block-Indexed File Format to Store Sorted Key-Value Pairs] makes for a thorough introduction to HBase's HFile. +Matteo Bertozzi has also put up a helpful description, link:http://th30z.blogspot.com/2011/02/hbase-io-hfile.html?spref=tw[HBase I/O: HFile]. For more information, see the link:http://hbase.apache.org/xref/org/apache/hadoop/hbase/io/hfile/HFile.html[HFile source code]. -Also see <> for information about the HFile v2 format that was included in 0.92. +Also see <> for information about the HFile v2 format that was included in 0.92. ===== HFile Tool -To view a textualized version of hfile content, you can do use the `org.apache.hadoop.hbase.io.hfile.HFile - `tool. +To view a textualized version of HFile content, you can use the `org.apache.hadoop.hbase.io.hfile.HFile` tool. Type the following to see usage: + [source,bash] ---- $ ${HBASE_HOME}/bin/hbase org.apache.hadoop.hbase.io.hfile.HFile @@ -1462,38 +1458,38 @@ For example, to view the content of the file _hdfs://10.81.47.41:8020/hbase/TEST ---- $ ${HBASE_HOME}/bin/hbase org.apache.hadoop.hbase.io.hfile.HFile -v -f hdfs://10.81.47.41:8020/hbase/TEST/1418428042/DSMP/4759508618286845475 ---- -If you leave off the option -v to see just a summary on the hfile. -See usage for other things to do with the `HFile` tool. +If you leave off the option -v to see just a summary on the HFile. +See usage for other things to do with the `HFile` tool. [[store.file.dir]] ===== StoreFile Directory Structure on HDFS -For more information of what StoreFiles look like on HDFS with respect to the directory structure, see <>. +For more information of what StoreFiles look like on HDFS with respect to the directory structure, see <>. [[hfile.blocks]] ==== Blocks StoreFiles are composed of blocks. -The blocksize is configured on a per-ColumnFamily basis. +The blocksize is configured on a per-ColumnFamily basis. Compression happens at the block level within StoreFiles. -For more information on compression, see <>. +For more information on compression, see <>. -For more information on blocks, see the link:http://hbase.apache.org/xref/org/apache/hadoop/hbase/io/hfile/HFileBlock.html[HFileBlock source code]. +For more information on blocks, see the link:http://hbase.apache.org/xref/org/apache/hadoop/hbase/io/hfile/HFileBlock.html[HFileBlock source code]. ==== KeyValue The KeyValue class is the heart of data storage in HBase. -KeyValue wraps a byte array and takes offsets and lengths into passed array at where to start interpreting the content as KeyValue. +KeyValue wraps a byte array and takes offsets and lengths into the passed array which specify where to start interpreting the content as KeyValue. -The KeyValue format inside a byte array is: +The KeyValue format inside a byte array is: * keylength * valuelength * key -* value +* value -The Key is further decomposed as: +The Key is further decomposed as: * rowlength * row (i.e., the rowkey) @@ -1501,41 +1497,41 @@ The Key is further decomposed as: * columnfamily * columnqualifier * timestamp -* keytype (e.g., Put, Delete, DeleteColumn, DeleteFamily) +* keytype (e.g., Put, Delete, DeleteColumn, DeleteFamily) KeyValue instances are _not_ split across blocks. For example, if there is an 8 MB KeyValue, even if the block-size is 64kb this KeyValue will be read in as a coherent block. -For more information, see the link:http://hbase.apache.org/xref/org/apache/hadoop/hbase/KeyValue.html[KeyValue source code]. +For more information, see the link:http://hbase.apache.org/xref/org/apache/hadoop/hbase/KeyValue.html[KeyValue source code]. [[keyvalue.example]] ===== Example To emphasize the points above, examine what happens with two Puts for two different columns for the same row: -* Put #1: `rowkey=row1, cf:attr1=value1` -* Put #2: `rowkey=row1, cf:attr2=value2` +* Put #1: `rowkey=row1, cf:attr1=value1` +* Put #2: `rowkey=row1, cf:attr2=value2` Even though these are for the same row, a KeyValue is created for each column: -Key portion for Put #1: +Key portion for Put #1: -* rowlength `------------> 4` -* row `-----------------> row1` -* columnfamilylength `---> 2` -* columnfamily `--------> cf` -* columnqualifier `------> attr1` -* timestamp `-----------> server time of Put` -* keytype `-------------> Put` +* `rowlength ------------> 4` +* `row ------------------> row1` +* `columnfamilylength ---> 2` +* `columnfamily ---------> cf` +* `columnqualifier ------> attr1` +* `timestamp ------------> server time of Put` +* `keytype --------------> Put` -Key portion for Put #2: +Key portion for Put #2: -* rowlength `------------> 4` -* row `-----------------> row1` -* columnfamilylength `---> 2` -* columnfamily `--------> cf` -* columnqualifier `------> attr2` -* timestamp `-----------> server time of Put` -* keytype `-------------> Put` +* `rowlength ------------> 4` +* `row ------------------> row1` +* `columnfamilylength ---> 2` +* `columnfamily ---------> cf` +* `columnqualifier ------> attr2` +* `timestamp ------------> server time of Put` +* `keytype --------------> Put` It is critical to understand that the rowkey, ColumnFamily, and column (aka columnqualifier) are embedded within the KeyValue instance. The longer these identifiers are, the bigger the KeyValue is. @@ -1543,39 +1539,38 @@ The longer these identifiers are, the bigger the KeyValue is. ==== Compaction .Ambiguous Terminology -*A [firstterm]_StoreFile_ is a facade of HFile. +* A _StoreFile_ is a facade of HFile. In terms of compaction, use of StoreFile seems to have prevailed in the past. -* A [firstterm]_Store_ is the same thing as a ColumnFamily. +* A _Store_ is the same thing as a ColumnFamily. StoreFiles are related to a Store, or ColumnFamily. * If you want to read more about StoreFiles versus HFiles and Stores versus ColumnFamilies, see link:https://issues.apache.org/jira/browse/HBASE-11316[HBASE-11316]. -When the MemStore reaches a given size (`hbase.hregion.memstore.flush.size)`, it flushes its contents to a StoreFile. -The number of StoreFiles in a Store increases over time. [firstterm]_Compaction_ is an operation which reduces the number of StoreFiles in a Store, by merging them together, in order to increase performance on read operations. -Compactions can be resource-intensive to perform, and can either help or hinder performance depending on many factors. +When the MemStore reaches a given size (`hbase.hregion.memstore.flush.size`), it flushes its contents to a StoreFile. +The number of StoreFiles in a Store increases over time. _Compaction_ is an operation which reduces the number of StoreFiles in a Store, by merging them together, in order to increase performance on read operations. +Compactions can be resource-intensive to perform, and can either help or hinder performance depending on many factors. Compactions fall into two categories: minor and major. Minor and major compactions differ in the following ways. -[firstterm]_Minor compactions_ usually select a small number of small, adjacent StoreFiles and rewrite them as a single StoreFile. +_Minor compactions_ usually select a small number of small, adjacent StoreFiles and rewrite them as a single StoreFile. Minor compactions do not drop (filter out) deletes or expired versions, because of potential side effects. -See <> and <> for information on how deletes and versions are handled in relation to compactions. +See <> and <> for information on how deletes and versions are handled in relation to compactions. The end result of a minor compaction is fewer, larger StoreFiles for a given Store. -The end result of a [firstterm]_major compaction_ is a single StoreFile per Store. +The end result of a _major compaction_ is a single StoreFile per Store. Major compactions also process delete markers and max versions. -See <> and <> for information on how deletes and versions are handled in relation to compactions. +See <> and <> for information on how deletes and versions are handled in relation to compactions. .Compaction and Deletions When an explicit deletion occurs in HBase, the data is not actually deleted. -Instead, a [firstterm]_tombstone_ marker is written. +Instead, a _tombstone_ marker is written. The tombstone marker prevents the data from being returned with queries. During a major compaction, the data is actually deleted, and the tombstone marker is removed from the StoreFile. If the deletion happens because of an expired TTL, no tombstone is created. Instead, the expired data is filtered out and is not written back to the compacted StoreFile. .Compaction and Versions -When you create a Column Family, you can specify the maximum number of versions to keep, by specifying `HColumnDescriptor.setMaxVersions(int - versions)`. +When you create a Column Family, you can specify the maximum number of versions to keep, by specifying `HColumnDescriptor.setMaxVersions(int versions)`. The default value is `3`. If more versions than the specified maximum exist, the excess versions are filtered out and not written back to the compacted StoreFile. @@ -1583,8 +1578,8 @@ If more versions than the specified maximum exist, the excess versions are filte [NOTE] ==== In some situations, older versions can be inadvertently resurrected if a newer version is explicitly deleted. -See <> for a more in-depth explanation. -This situation is only possible before the compaction finishes. +See <> for a more in-depth explanation. +This situation is only possible before the compaction finishes. ==== In theory, major compactions improve performance. @@ -1592,22 +1587,21 @@ However, on a highly loaded system, major compactions can require an inappropria In a default configuration, major compactions are scheduled automatically to run once in a 7-day period. This is sometimes inappropriate for systems in production. You can manage major compactions manually. -See <>. +See <>. Compactions do not perform region merges. -See <> for more information on region merging. +See <> for more information on region merging. [[compaction.file.selection]] ===== Compaction Policy - HBase 0.96.x and newer Compacting large StoreFiles, or too many StoreFiles at once, can cause more IO load than your cluster is able to handle without causing performance problems. -The method by which HBase selects which StoreFiles to include in a compaction (and whether the compaction is a minor or major compaction) is called the [firstterm]_compaction - policy_. +The method by which HBase selects which StoreFiles to include in a compaction (and whether the compaction is a minor or major compaction) is called the _compaction policy_. Prior to HBase 0.96.x, there was only one compaction policy. -That original compaction policy is still available as [systemitem]+RatioBasedCompactionPolicy+ The new compaction default policy, called [systemitem]+ExploringCompactionPolicy+, was subsequently backported to HBase 0.94 and HBase 0.95, and is the default in HBase 0.96 and newer. +That original compaction policy is still available as `RatioBasedCompactionPolicy`. The new compaction default policy, called `ExploringCompactionPolicy`, was subsequently backported to HBase 0.94 and HBase 0.95, and is the default in HBase 0.96 and newer. It was implemented in link:https://issues.apache.org/jira/browse/HBASE-7842[HBASE-7842]. -In short, [systemitem]+ExploringCompactionPolicy+ attempts to select the best possible set of StoreFiles to compact with the least amount of work, while the [systemitem]+RatioBasedCompactionPolicy+ selects the first set that meets the criteria. +In short, `ExploringCompactionPolicy` attempts to select the best possible set of StoreFiles to compact with the least amount of work, while the `RatioBasedCompactionPolicy` selects the first set that meets the criteria. Regardless of the compaction policy used, file selection is controlled by several configurable parameters and happens in a multi-step approach. These parameters will be explained in context, and then will be given in a table which shows their descriptions, defaults, and implications of changing them. @@ -1616,23 +1610,23 @@ These parameters will be explained in context, and then will be given in a table ====== Being Stuck When the MemStore gets too large, it needs to flush its contents to a StoreFile. -However, a Store can only have `hbase.hstore.blockingStoreFiles` files, so the MemStore needs to wait for the number of StoreFiles to be reduced by one or more compactions. +However, a Store can only have `hbase.hstore.blockingStoreFiles` files, so the MemStore needs to wait for the number of StoreFiles to be reduced by one or more compactions. However, if the MemStore grows larger than `hbase.hregion.memstore.flush.size`, it is not able to flush its contents to a StoreFile. -If the MemStore is too large and the number of StpreFo;es is also too high, the algorithm is said to be "stuck". The compaction algorithm checks for this "stuck" situation and provides mechanisms to alleviate it. +If the MemStore is too large and the number of StoreFiles is also too high, the algorithm is said to be "stuck". The compaction algorithm checks for this "stuck" situation and provides mechanisms to alleviate it. [[exploringcompaction.policy]] ====== The ExploringCompactionPolicy Algorithm -The ExploringCompactionPolicy algorithm considers each possible set of adjacent StoreFiles before choosing the set where compaction will have the most benefit. +The ExploringCompactionPolicy algorithm considers each possible set of adjacent StoreFiles before choosing the set where compaction will have the most benefit. One situation where the ExploringCompactionPolicy works especially well is when you are bulk-loading data and the bulk loads create larger StoreFiles than the StoreFiles which are holding data older than the bulk-loaded data. This can "trick" HBase into choosing to perform a major compaction each time a compaction is needed, and cause a lot of extra overhead. With the ExploringCompactionPolicy, major compactions happen much less frequently because minor compactions are more efficient. In general, ExploringCompactionPolicy is the right choice for most situations, and thus is the default compaction policy. -You can also use ExploringCompactionPolicy along with <>. +You can also use ExploringCompactionPolicy along with <>. -The logic of this policy can be examined in _hbase-server/src/main/java/org/apache/hadoop/hbase/regionserver/compactions/ExploringCompactionPolicy.java_. +The logic of this policy can be examined in _link:http://hbase.apache.org/xref/org/apache/hadoop/hbase/regionserver/compactions/ExploringCompactionPolicy.html[hbase-server/src/main/java/org/apache/hadoop/hbase/regionserver/compactions/ExploringCompactionPolicy.java]_. The following is a walk-through of the logic of the ExploringCompactionPolicy. @@ -1647,7 +1641,7 @@ The following is a walk-through of the logic of the ExploringCompactionPolicy. * StoreFiles that are larger than `hbase.hstore.compaction.max.size` * StoreFiles that were created by a bulk-load operation which explicitly excluded compaction. You may decide to exclude StoreFiles resulting from bulk loads, from compaction. - To do this, specify the `hbase.mapreduce.hfileoutputformat.compaction.exclude` parameter during the bulk load operation. + To do this, specify the `hbase.mapreduce.hfileoutputformat.compaction.exclude` parameter during the bulk load operation. . Iterate through the list from step 1, and make a list of all potential sets of StoreFiles to compact together. A potential set is a grouping of `hbase.hstore.compaction.min` contiguous StoreFiles in the list. @@ -1656,22 +1650,19 @@ The following is a walk-through of the logic of the ExploringCompactionPolicy. * If the number of StoreFiles in this set (not the size of the StoreFiles) is fewer than `hbase.hstore.compaction.min` or more than `hbase.hstore.compaction.max`, take it out of consideration. * Compare the size of this set of StoreFiles with the size of the smallest possible compaction that has been found in the list so far. If the size of this set of StoreFiles represents the smallest compaction that could be done, store it to be used as a fall-back if the algorithm is "stuck" and no StoreFiles would otherwise be chosen. - See <>. + See <>. * Do size-based sanity checks against each StoreFile in this set of StoreFiles. +** If the size of this StoreFile is larger than `hbase.hstore.compaction.max.size`, take it out of consideration. +** If the size is greater than or equal to `hbase.hstore.compaction.min.size`, sanity-check it against the file-based ratio to see whether it is too large to be considered. + -* If the size of this StoreFile is larger than `hbase.hstore.compaction.max.size`, take it out of consideration. -* If the size is greater than or equal to `hbase.hstore.compaction.min.size`, sanity-check it against the file-based ratio to see whether it is too large to be considered. - The sanity-checking is successful if: -+ -* There is only one StoreFile in this set, or -* For each StoreFile, its size multiplied by `hbase.hstore.compaction.ratio` (or `hbase.hstore.compaction.ratio.offpeak` if off-peak hours are configured and it is during off-peak hours) is less than the sum of the sizes of the other HFiles in the set. - - +The sanity-checking is successful if: +** There is only one StoreFile in this set, or +** For each StoreFile, its size multiplied by `hbase.hstore.compaction.ratio` (or `hbase.hstore.compaction.ratio.offpeak` if off-peak hours are configured and it is during off-peak hours) is less than the sum of the sizes of the other HFiles in the set. . If this set of StoreFiles is still in consideration, compare it to the previously-selected best compaction. If it is better, replace the previously-selected best compaction with this one. . When the entire list of potential compactions has been processed, perform the best compaction that was found. - If no StoreFiles were selected for compaction, but there are multiple StoreFiles, assume the algorithm is stuck (see <>) and if so, perform the smallest compaction that was found in step 3. + If no StoreFiles were selected for compaction, but there are multiple StoreFiles, assume the algorithm is stuck (see <>) and if so, perform the smallest compaction that was found in step 3. [[compaction.ratiobasedcompactionpolicy.algorithm]] ====== RatioBasedCompactionPolicy Algorithm @@ -1687,17 +1678,17 @@ The following section walks you through the algorithm used to select StoreFiles A list is created of all StoreFiles not already in the compaction queue, and all StoreFiles newer than the newest file that is currently being compacted. This list of StoreFiles is ordered by the sequence ID. The sequence ID is generated when a Put is appended to the write-ahead log (WAL), and is stored in the metadata of the HFile. -. Check to see if the algorithm is stuck (see <>, and if so, a major compaction is forced. - This is a key area where <> is often a better choice than the RatioBasedCompactionPolicy. +. Check to see if the algorithm is stuck (see <>, and if so, a major compaction is forced. + This is a key area where <> is often a better choice than the RatioBasedCompactionPolicy. . If the compaction was user-requested, try to perform the type of compaction that was requested. - Note that a major compaction may not be possible if all HFiles are not available for compaction or if too may StoreFiles exist (more than `hbase.hstore.compaction.max`). + Note that a major compaction may not be possible if all HFiles are not available for compaction or if too many StoreFiles exist (more than `hbase.hstore.compaction.max`). . Some StoreFiles are automatically excluded from consideration. These include: + * StoreFiles that are larger than `hbase.hstore.compaction.max.size` * StoreFiles that were created by a bulk-load operation which explicitly excluded compaction. You may decide to exclude StoreFiles resulting from bulk loads, from compaction. - To do this, specify the `hbase.mapreduce.hfileoutputformat.compaction.exclude` parameter during the bulk load operation. + To do this, specify the `hbase.mapreduce.hfileoutputformat.compaction.exclude` parameter during the bulk load operation. . The maximum number of StoreFiles allowed in a major compaction is controlled by the `hbase.hstore.compaction.max` parameter. If the list contains more than this number of StoreFiles, a minor compaction is performed even if a major compaction would otherwise have been done. @@ -1706,14 +1697,14 @@ The following section walks you through the algorithm used to select StoreFiles Note that a major compaction can be performed on a single HFile. Its function is to remove deletes and expired versions, and reset locality on the StoreFile. . The value of the `hbase.hstore.compaction.ratio` parameter is multiplied by the sum of StoreFiles smaller than a given file, to determine whether that StoreFile is selected for compaction during a minor compaction. - For instance, if hbase.hstore.compaction.ratio is 1.2, FileX is 5 mb, FileY is 2 mb, and FileZ is 3 mb: + For instance, if hbase.hstore.compaction.ratio is 1.2, FileX is 5MB, FileY is 2MB, and FileZ is 3MB: + ---- -5 <= 1.2 x (2 + 3) or 5 <= 6 +5 <= 1.2 x (2 + 3) or 5 <= 6 ---- + In this scenario, FileX is eligible for minor compaction. -If FileX were 7 mb, it would not be eligible for minor compaction. +If FileX were 7MB, it would not be eligible for minor compaction. This ratio favors smaller StoreFile. You can configure a different ratio for use in off-peak hours, using the parameter `hbase.hstore.compaction.ratio.offpeak`, if you also configure `hbase.offpeak.start.hour` and `hbase.offpeak.end.hour`. @@ -1730,34 +1721,38 @@ This list is not exhaustive. To tune these parameters from the defaults, edit the _hbase-default.xml_ file. For a full list of all configuration parameters available, see <> -[cols="1,1,1", options="header"] +[cols="1,1a,1", options="header"] |=== | Parameter | Description | Default |`hbase.hstore.compaction.min` -| The minimum number of StoreFiles which must be eligible for compaction before compaction can run. The goal of tuning `hbase.hstore.compaction.min` is to avoid ending up with too many tiny StoreFiles to compact. Setting this value to 2 would cause a minor compaction each time you have two StoreFiles in a Store, and this is probably not appropriate. If you set this value too high, all the other values will need to be adjusted accordingly. For most cases, the default value is appropriate. In previous versions of HBase, the parameter hbase.hstore.compaction.min was called `hbase.hstore.compactionThreshold`. +| The minimum number of StoreFiles which must be eligible for compaction before compaction can run. The goal of tuning `hbase.hstore.compaction.min` is to avoid ending up with too many tiny StoreFiles to compact. Setting this value to 2 would cause a minor compaction each time you have two StoreFiles in a Store, and this is probably not appropriate. If you set this value too high, all the other values will need to be adjusted accordingly. For most cases, the default value is appropriate. In previous versions of HBase, the parameter hbase.hstore.compaction.min was called `hbase.hstore.compactionThreshold`. |3 |`hbase.hstore.compaction.max` | The maximum number of StoreFiles which will be selected for a single minor compaction, regardless of the number of eligible StoreFiles. Effectively, the value of hbase.hstore.compaction.max controls the length of time it takes a single compaction to complete. Setting it larger means that more StoreFiles are included in a compaction. For most cases, the default value is appropriate. |10 - + |`hbase.hstore.compaction.min.size` | A StoreFile smaller than this size will always be eligible for minor compaction. StoreFiles this size or larger are evaluated by `hbase.hstore.compaction.ratio` to determine if they are eligible. Because this limit represents the "automatic include" limit for all StoreFiles smaller than this value, this value may need to be reduced in write-heavy environments where many files in the 1-2 MB range are being flushed, because every StoreFile will be targeted for compaction and the resulting StoreFiles may still be under the minimum size and require further compaction. If this parameter is lowered, the ratio check is triggered more quickly. This addressed some issues seen in earlier versions of HBase but changing this parameter is no longer necessary in most situations. |128 MB - + |`hbase.hstore.compaction.max.size` -| An StoreFile larger than this size will be excluded from compaction. The effect of raising hbase.hstore.compaction.max.size is fewer, larger StoreFiles that do not get compacted often. If you feel that compaction is happening too often without much benefit, you can try raising this value. +| An StoreFile larger than this size will be excluded from compaction. The effect of raising `hbase.hstore.compaction.max.size` is fewer, larger StoreFiles that do not get compacted often. If you feel that compaction is happening too often without much benefit, you can try raising this value. |`Long.MAX_VALUE` |`hbase.hstore.compaction.ratio` -| For minor compaction, this ratio is used to determine whether a given StoreFile which is larger than hbase.hstore.compaction.min.size is eligible for compaction. Its effect is to limit compaction of large StoreFile. The value of hbase.hstore.compaction.ratio is expressed as a floating-point decimal. + A large ratio, such as 10, will produce a single giant StoreFile. Conversely, a value of .25, will produce behavior similar to the BigTable compaction algorithm, producing four StoreFiles. + A moderate value of between 1.0 and 1.4 is recommended. When tuning this value, you are balancing write costs with read costs. Raising the value (to something like 1.4) will have more write costs, because you will compact larger StoreFiles. However, during reads, HBase will need to seek through fewer StpreFo;es to accomplish the read. Consider this approach if you cannot take advantage of <>. + Alternatively, you can lower this value to something like 1.0 to reduce the background cost of writes, and use to limit the number of StoreFiles touched during reads. For most cases, the default value is appropriate. +| For minor compaction, this ratio is used to determine whether a given StoreFile which is larger than `hbase.hstore.compaction.min.size` is eligible for compaction. Its effect is to limit compaction of large StoreFile. The value of `hbase.hstore.compaction.ratio` is expressed as a floating-point decimal. + +* A large ratio, such as 10, will produce a single giant StoreFile. Conversely, a value of .25, will produce behavior similar to the BigTable compaction algorithm, producing four StoreFiles. +* A moderate value of between 1.0 and 1.4 is recommended. When tuning this value, you are balancing write costs with read costs. Raising the value (to something like 1.4) will have more write costs, because you will compact larger StoreFiles. However, during reads, HBase will need to seek through fewer StoreFiles to accomplish the read. Consider this approach if you cannot take advantage of <>. +* Alternatively, you can lower this value to something like 1.0 to reduce the background cost of writes, and use to limit the number of StoreFiles touched during reads. For most cases, the default value is appropriate. | `1.2F` - + |`hbase.hstore.compaction.ratio.offpeak` -| The compaction ratio used during off-peak compactions, if off-peak hours are also configured (see below). Expressed as a floating-point decimal. This allows for more aggressive (or less aggressive, if you set it lower than hbase.hstore.compaction.ratio) compaction during a set time period. Ignored if off-peak is disabled (default). This works the same as hbase.hstore.compaction.ratio. +| The compaction ratio used during off-peak compactions, if off-peak hours are also configured (see below). Expressed as a floating-point decimal. This allows for more aggressive (or less aggressive, if you set it lower than `hbase.hstore.compaction.ratio`) compaction during a set time period. Ignored if off-peak is disabled (default). This works the same as hbase.hstore.compaction.ratio. | `5.0F` | `hbase.offpeak.start.hour` @@ -1769,16 +1764,15 @@ For a full list of all configuration parameters available, see <> For information on the way that compactions work in HBase 0.96.x and later, see <>. +You can still use this behavior if you enable <>. For information on the way that compactions work in HBase 0.96.x and later, see <>. ==== -To understand the core algorithm for StoreFile selection, there is some ASCII-art in the link:http://hbase.apache.org/xref/org/apache/hadoop/hbase/regionserver/Store.html#836[Store - source code] that will serve as useful reference. -It has been copied below: +To understand the core algorithm for StoreFile selection, there is some ASCII-art in the link:http://hbase.apache.org/xref/org/apache/hadoop/hbase/regionserver/Store.html#836[Store source code] that will serve as useful reference. + +It has been copied below: [source] ---- /* normal skew: @@ -1808,92 +1802,92 @@ It has been copied below: * | | | | | | | | | | | | * | | | | | | | | | | | | */ ----- -.Important knobs: +---- +.Important knobs: * `hbase.hstore.compaction.ratio` Ratio used in compaction file selection algorithm (default 1.2f). -* `hbase.hstore.compaction.min` (.90 hbase.hstore.compactionThreshold) (files) Minimum number of StoreFiles per Store to be selected for a compaction to occur (default 2). +* `hbase.hstore.compaction.min` (in HBase v 0.90 this is called `hbase.hstore.compactionThreshold`) (files) Minimum number of StoreFiles per Store to be selected for a compaction to occur (default 2). * `hbase.hstore.compaction.max` (files) Maximum number of StoreFiles to compact per minor compaction (default 10). * `hbase.hstore.compaction.min.size` (bytes) Any StoreFile smaller than this setting with automatically be a candidate for compaction. - Defaults to `hbase.hregion.memstore.flush.size` (128 mb). -* `hbase.hstore.compaction.max.size` (.92) (bytes) Any StoreFile larger than this setting with automatically be excluded from compaction (default Long.MAX_VALUE). + Defaults to `hbase.hregion.memstore.flush.size` (128 mb). +* `hbase.hstore.compaction.max.size` (.92) (bytes) Any StoreFile larger than this setting with automatically be excluded from compaction (default Long.MAX_VALUE). -The minor compaction StoreFile selection logic is size based, and selects a file for compaction when the file <= sum(smaller_files) * `hbase.hstore.compaction.ratio`. +The minor compaction StoreFile selection logic is size based, and selects a file for compaction when the `file <= sum(smaller_files) * hbase.hstore.compaction.ratio`. [[compaction.file.selection.example1]] ====== Minor Compaction File Selection - Example #1 (Basic Example) This example mirrors an example from the unit test `TestCompactSelection`. -* `hbase.hstore.compaction.ratio` = 1.0f -* `hbase.hstore.compaction.min` = 3 (files) -* `hbase.hstore.compaction.max` = 5 (files) -* `hbase.hstore.compaction.min.size` = 10 (bytes) -* `hbase.hstore.compaction.max.size` = 1000 (bytes) +* `hbase.hstore.compaction.ratio` = 1.0f +* `hbase.hstore.compaction.min` = 3 (files) +* `hbase.hstore.compaction.max` = 5 (files) +* `hbase.hstore.compaction.min.size` = 10 (bytes) +* `hbase.hstore.compaction.max.size` = 1000 (bytes) -The following StoreFiles exist: 100, 50, 23, 12, and 12 bytes apiece (oldest to newest). With the above parameters, the files that would be selected for minor compaction are 23, 12, and 12. +The following StoreFiles exist: 100, 50, 23, 12, and 12 bytes apiece (oldest to newest). With the above parameters, the files that would be selected for minor compaction are 23, 12, and 12. -Why? +Why? -* 100 --> No, because sum(50, 23, 12, 12) * 1.0 = 97. -* 50 --> No, because sum(23, 12, 12) * 1.0 = 47. -* 23 --> Yes, because sum(12, 12) * 1.0 = 24. -* 12 --> Yes, because the previous file has been included, and because this does not exceed the the max-file limit of 5 -* 12 --> Yes, because the previous file had been included, and because this does not exceed the the max-file limit of 5. +* 100 -> No, because sum(50, 23, 12, 12) * 1.0 = 97. +* 50 -> No, because sum(23, 12, 12) * 1.0 = 47. +* 23 -> Yes, because sum(12, 12) * 1.0 = 24. +* 12 -> Yes, because the previous file has been included, and because this does not exceed the the max-file limit of 5 +* 12 -> Yes, because the previous file had been included, and because this does not exceed the the max-file limit of 5. [[compaction.file.selection.example2]] ====== Minor Compaction File Selection - Example #2 (Not Enough Files ToCompact) -This example mirrors an example from the unit test `TestCompactSelection`. +This example mirrors an example from the unit test `TestCompactSelection`. -* `hbase.hstore.compaction.ratio` = 1.0f -* `hbase.hstore.compaction.min` = 3 (files) +* `hbase.hstore.compaction.ratio` = 1.0f +* `hbase.hstore.compaction.min` = 3 (files) * `hbase.hstore.compaction.max` = 5 (files) -* `hbase.hstore.compaction.min.size` = 10 (bytes) -* `hbase.hstore.compaction.max.size` = 1000 (bytes) +* `hbase.hstore.compaction.min.size` = 10 (bytes) +* `hbase.hstore.compaction.max.size` = 1000 (bytes) -The following StoreFiles exist: 100, 25, 12, and 12 bytes apiece (oldest to newest). With the above parameters, no compaction will be started. +The following StoreFiles exist: 100, 25, 12, and 12 bytes apiece (oldest to newest). With the above parameters, no compaction will be started. -Why? +Why? -* 100 --> No, because sum(25, 12, 12) * 1.0 = 47 -* 25 --> No, because sum(12, 12) * 1.0 = 24 -* 12 --> No. - Candidate because sum(12) * 1.0 = 12, there are only 2 files to compact and that is less than the threshold of 3 -* 12 --> No. - Candidate because the previous StoreFile was, but there are not enough files to compact +* 100 -> No, because sum(25, 12, 12) * 1.0 = 47 +* 25 -> No, because sum(12, 12) * 1.0 = 24 +* 12 -> No. Candidate because sum(12) * 1.0 = 12, there are only 2 files to compact and that is less than the threshold of 3 +* 12 -> No. Candidate because the previous StoreFile was, but there are not enough files to compact [[compaction.file.selection.example3]] ====== Minor Compaction File Selection - Example #3 (Limiting Files To Compact) -This example mirrors an example from the unit test `TestCompactSelection`. +This example mirrors an example from the unit test `TestCompactSelection`. -* `hbase.hstore.compaction.ratio` = 1.0f -* `hbase.hstore.compaction.min` = 3 (files) +* `hbase.hstore.compaction.ratio` = 1.0f +* `hbase.hstore.compaction.min` = 3 (files) * `hbase.hstore.compaction.max` = 5 (files) -* `hbase.hstore.compaction.min.size` = 10 (bytes) -* `hbase.hstore.compaction.max.size` = 1000 (bytes) The following StoreFiles exist: 7, 6, 5, 4, 3, 2, and 1 bytes apiece (oldest to newest). With the above parameters, the files that would be selected for minor compaction are 7, 6, 5, 4, 3. +* `hbase.hstore.compaction.min.size` = 10 (bytes) +* `hbase.hstore.compaction.max.size` = 1000 (bytes) -Why? +The following StoreFiles exist: 7, 6, 5, 4, 3, 2, and 1 bytes apiece (oldest to newest). With the above parameters, the files that would be selected for minor compaction are 7, 6, 5, 4, 3. + +Why? * 7 -> Yes, because sum(6, 5, 4, 3, 2, 1) * 1.0 = 21. Also, 7 is less than the min-size * 6 -> Yes, because sum(5, 4, 3, 2, 1) * 1.0 = 15. - Also, 6 is less than the min-size. + Also, 6 is less than the min-size. * 5 -> Yes, because sum(4, 3, 2, 1) * 1.0 = 10. - Also, 5 is less than the min-size. + Also, 5 is less than the min-size. * 4 -> Yes, because sum(3, 2, 1) * 1.0 = 6. - Also, 4 is less than the min-size. + Also, 4 is less than the min-size. * 3 -> Yes, because sum(2, 1) * 1.0 = 3. - Also, 3 is less than the min-size. + Also, 3 is less than the min-size. * 2 -> No. - Candidate because previous file was selected and 2 is less than the min-size, but the max-number of files to compact has been reached. + Candidate because previous file was selected and 2 is less than the min-size, but the max-number of files to compact has been reached. * 1 -> No. - Candidate because previous file was selected and 1 is less than the min-size, but max-number of files to compact has been reached. + Candidate because previous file was selected and 1 is less than the min-size, but max-number of files to compact has been reached. [[compaction.config.impact]] .Impact of Key Configuration Options -NOTE: This information is now included in the configuration parameter table in <>. +NOTE: This information is now included in the configuration parameter table in <>. [[ops.stripe]] ===== Experimental: Stripe Compactions @@ -1906,8 +1900,8 @@ Stripe compactions change the HFile layout, creating sub-regions within regions. These sub-regions are easier to compact, and should result in fewer major compactions. This approach alleviates some of the challenges of larger regions. -Stripe compaction is fully compatible with <> and works in conjunction with either the ExploringCompactionPolicy or RatioBasedCompactionPolicy. -It can be enabled for existing tables, and the table will continue to operate normally if it is disabled later. +Stripe compaction is fully compatible with <> and works in conjunction with either the ExploringCompactionPolicy or RatioBasedCompactionPolicy. +It can be enabled for existing tables, and the table will continue to operate normally if it is disabled later. [[ops.stripe.when]] ===== When To Use Stripe Compactions @@ -1945,7 +1939,7 @@ create 'orders_table', 'blobs_cf', CONFIGURATION => {'hbase.hstore.engine.class' ---- . Configure other options if needed. - See <> for more information. + See <> for more information. . Enable the table. .Procedure: Disable Stripe Compaction @@ -1955,7 +1949,7 @@ create 'orders_table', 'blobs_cf', CONFIGURATION => {'hbase.hstore.engine.class' + [source,sql] ---- -alter 'orders_table', CONFIGURATION => {'hbase.hstore.engine.class' => ''} +alter 'orders_table', CONFIGURATION => {'hbase.hstore.engine.class' => 'rg.apache.hadoop.hbase.regionserver.DefaultStoreEngine'} ---- . Enable the table. @@ -1977,7 +1971,7 @@ alter 'orders_table', CONFIGURATION => {'key' => 'value', ..., 'key' => 'value'} [[ops.stripe.config.sizing]] .Region and stripe sizing -You can configure your stripe sizing bsaed upon your region sizing. +You can configure your stripe sizing based upon your region sizing. By default, your new regions will start with one stripe. On the next compaction after the stripe has grown too large (16 x MemStore flushes size), it is split into two stripes. Stripe splitting continues as the region grows, until the region is large enough to split. @@ -1987,38 +1981,42 @@ A good rule is to aim for a stripe size of at least 1 GB, and about 8-12 stripes For example, if your regions are 30 GB, 12 x 2.5 GB stripes might be a good starting point. .Stripe Sizing Settings -[cols="1,1", frame="all", options="header"] +[cols="1,1a", frame="all", options="header"] |=== | Setting | Notes -|`hbase.store.stripe.initialStripeCount` -|The number of stripes to create when stripe compaction is enabled.You can use it as follows: +|`hbase.store.stripe.initialStripeCount` +|The number of stripes to create when stripe compaction is enabled. You can use it as follows: + * For relatively uniform row keys, if you know the approximate target number of stripes from the above, you can avoid some splitting overhead by starting with several stripes (2, 5, 10...). If the early data is not representative of overall row key distribution, this will not be as efficient. + * For existing tables with a large amount of data, this setting will effectively pre-split your stripes. -* For keys such as hash-prefixed sequential keys, with more than - one hash prefix per region, pre-splitting may make sense. -| `hbase.store.stripe.sizeToSplit` +* For keys such as hash-prefixed sequential keys, with more than + one hash prefix per region, pre-splitting may make sense. + + +| `hbase.store.stripe.sizeToSplit` | The maximum size a stripe grows before splitting. Use this in conjunction with `hbase.store.stripe.splitPartCount` to control the target stripe size (`sizeToSplit = splitPartsCount * target -stripe size`), according to the above sizing considerations. +stripe size`), according to the above sizing considerations. | `hbase.store.stripe.splitPartCount` -| The number of new stripes to create when splitting a stripe. The default is 2, which is appropriate for most cases. For non-uniform row keys, you can experiment with increasing the number to 3 or 4, to isolate the arriving updates into narrower slice of the region without additional splits being required. +| The number of new stripes to create when splitting a stripe. The default is 2, which is appropriate for most cases. For non-uniform row keys, you can experiment with increasing the number to 3 or 4, to isolate the arriving updates into narrower slice of the region without additional splits being required. |=== [[ops.stripe.config.memstore]] .MemStore Size Settings By default, the flush creates several files from one MemStore, according to existing stripe boundaries and row keys to flush. -This approach minimizes write amplification, but can be undesirable if the MemStore is small and there are many stripes, because the files will be too small. +This approach minimizes write amplification, but can be undesirable if the MemStore is small and there are many stripes, because the files will be too small. In this type of situation, you can set `hbase.store.stripe.compaction.flushToL0` to `true`. This will cause a MemStore flush to create a single file instead. @@ -2027,9 +2025,9 @@ When at least `hbase.store.stripe.compaction.minFilesL0` such files (by default, [[ops.stripe.config.compact]] .Normal Compaction Configuration and Stripe Compaction -All the settings that apply to normal compactions (see <>) apply to stripe compactions. +All the settings that apply to normal compactions (see <>) apply to stripe compactions. The exceptions are the minimum and maximum number of files, which are set to higher values by default because the files in stripes are smaller. -To control these for stripe compactions, use `hbase.store.stripe.compaction.minFiles` and `hbase.store.stripe.compaction.maxFiles`, rather than `hbase.hstore.compaction.min` and `hbase.hstore.compaction.max`. +To control these for stripe compactions, use `hbase.store.stripe.compaction.minFiles` and `hbase.store.stripe.compaction.maxFiles`, rather than `hbase.hstore.compaction.min` and `hbase.hstore.compaction.max`. [[arch.bulk.load]] == Bulk Loading @@ -2038,96 +2036,87 @@ To control these for stripe compactions, use `hbase.store.stripe.compaction.minF === Overview HBase includes several methods of loading data into tables. -The most straightforward method is to either use the `TableOutputFormat` class from a MapReduce job, or use the normal client APIs; however, these are not always the most efficient methods. +The most straightforward method is to either use the `TableOutputFormat` class from a MapReduce job, or use the normal client APIs; however, these are not always the most efficient methods. The bulk load feature uses a MapReduce job to output table data in HBase's internal data format, and then directly loads the generated StoreFiles into a running cluster. -Using bulk load will use less CPU and network resources than simply using the HBase API. +Using bulk load will use less CPU and network resources than simply using the HBase API. [[arch.bulk.load.limitations]] === Bulk Load Limitations As bulk loading bypasses the write path, the WAL doesn't get written to as part of the process. -Replication works by reading the WAL files so it won't see the bulk loaded data – and the same goes for the edits that use Put.setWriteToWAL(true). One way to handle that is to ship the raw files or the HFiles to the other cluster and do the other processing there. +Replication works by reading the WAL files so it won't see the bulk loaded data – and the same goes for the edits that use `Put.setDurability(SKIP_WAL)`. One way to handle that is to ship the raw files or the HFiles to the other cluster and do the other processing there. [[arch.bulk.load.arch]] === Bulk Load Architecture -The HBase bulk load process consists of two main steps. +The HBase bulk load process consists of two main steps. [[arch.bulk.load.prep]] ==== Preparing data via a MapReduce job -The first step of a bulk load is to generate HBase data files (StoreFiles) from a MapReduce job using `HFileOutputFormat`. -This output format writes out data in HBase's internal storage format so that they can be later loaded very efficiently into the cluster. +The first step of a bulk load is to generate HBase data files (StoreFiles) from a MapReduce job using `HFileOutputFormat2`. +This output format writes out data in HBase's internal storage format so that they can be later loaded very efficiently into the cluster. -In order to function efficiently, `HFileOutputFormat` must be configured such that each output HFile fits within a single region. -In order to do this, jobs whose output will be bulk loaded into HBase use Hadoop's `TotalOrderPartitioner` class to partition the map output into disjoint ranges of the key space, corresponding to the key ranges of the regions in the table. +In order to function efficiently, `HFileOutputFormat2` must be configured such that each output HFile fits within a single region. +In order to do this, jobs whose output will be bulk loaded into HBase use Hadoop's `TotalOrderPartitioner` class to partition the map output into disjoint ranges of the key space, corresponding to the key ranges of the regions in the table. -`HFileOutputFormat` includes a convenience function, `configureIncrementalLoad()`, which automatically sets up a `TotalOrderPartitioner` based on the current region boundaries of a table. +`HFileOutputFormat2` includes a convenience function, `configureIncrementalLoad()`, which automatically sets up a `TotalOrderPartitioner` based on the current region boundaries of a table. [[arch.bulk.load.complete]] ==== Completing the data load -After the data has been prepared using `HFileOutputFormat`, it is loaded into the cluster using `completebulkload`. +After a data import has been prepared, either by using the `importtsv` tool with the "`importtsv.bulk.output`" option or by some other MapReduce job using the `HFileOutputFormat`, the `completebulkload` tool is used to import the data into the running cluster. This command line tool iterates through the prepared data files, and for each one determines the region the file belongs to. -It then contacts the appropriate Region Server which adopts the HFile, moving it into its storage directory and making the data available to clients. +It then contacts the appropriate RegionServer which adopts the HFile, moving it into its storage directory and making the data available to clients. -If the region boundaries have changed during the course of bulk load preparation, or between the preparation and completion steps, the `completebulkloads` utility will automatically split the data files into pieces corresponding to the new boundaries. -This process is not optimally efficient, so users should take care to minimize the delay between preparing a bulk load and importing it into the cluster, especially if other clients are simultaneously loading data through other means. - -[[arch.bulk.load.import]] -=== Importing the prepared data using the completebulkload tool - -After a data import has been prepared, either by using the `importtsv` tool with the "`importtsv.bulk.output`" option or by some other MapReduce job using the `HFileOutputFormat`, the `completebulkload` tool is used to import the data into the running cluster. - -The `completebulkload` tool simply takes the output path where `importtsv` or your MapReduce job put its results, and the table name to import into. -For example: +If the region boundaries have changed during the course of bulk load preparation, or between the preparation and completion steps, the `completebulkload` utility will automatically split the data files into pieces corresponding to the new boundaries. +This process is not optimally efficient, so users should take care to minimize the delay between preparing a bulk load and importing it into the cluster, especially if other clients are simultaneously loading data through other means. [source,bash] ---- $ hadoop jar hbase-server-VERSION.jar completebulkload [-c /path/to/hbase/config/hbase-site.xml] /user/todd/myoutput mytable ---- -The `-c config-file` option can be used to specify a file containing the appropriate hbase parameters (e.g., hbase-site.xml) if not supplied already on the CLASSPATH (In addition, the CLASSPATH must contain the directory that has the zookeeper configuration file if zookeeper is NOT managed by HBase). +The `-c config-file` option can be used to specify a file containing the appropriate hbase parameters (e.g., hbase-site.xml) if not supplied already on the CLASSPATH (In addition, the CLASSPATH must contain the directory that has the zookeeper configuration file if zookeeper is NOT managed by HBase). -Note: If the target table does not already exist in HBase, this tool will create the table automatically. +NOTE: If the target table does not already exist in HBase, this tool will create the table automatically. -This tool will run quickly, after which point the new data will be visible in the cluster. [[arch.bulk.load.also]] === See Also -For more information about the referenced utilities, see <> and <>. +For more information about the referenced utilities, see <> and <>. -See link:http://blog.cloudera.com/blog/2013/09/how-to-use-hbase-bulk-loading-and-why/[How-to: Use HBase Bulk Loading, and Why] for a recent blog on current state of bulk loading. +See link:http://blog.cloudera.com/blog/2013/09/how-to-use-hbase-bulk-loading-and-why/[How-to: Use HBase Bulk Loading, and Why] for a recent blog on current state of bulk loading. [[arch.bulk.load.adv]] === Advanced Usage Although the `importtsv` tool is useful in many cases, advanced users may want to generate data programatically, or import data from other formats. -To get started doing so, dig into `ImportTsv.java` and check the JavaDoc for HFileOutputFormat. +To get started doing so, dig into `ImportTsv.java` and check the JavaDoc for HFileOutputFormat. -The import step of the bulk load can also be done programatically. -See the `LoadIncrementalHFiles` class for more information. +The import step of the bulk load can also be done programmatically. +See the `LoadIncrementalHFiles` class for more information. [[arch.hdfs]] == HDFS -As HBase runs on HDFS (and each StoreFile is written as a file on HDFS), it is important to have an understanding of the HDFS Architecture especially in terms of how it stores files, handles failovers, and replicates blocks. +As HBase runs on HDFS (and each StoreFile is written as a file on HDFS), it is important to have an understanding of the HDFS Architecture especially in terms of how it stores files, handles failovers, and replicates blocks. -See the Hadoop documentation on link:http://hadoop.apache.org/common/docs/current/hdfs_design.html[HDFS Architecture] for more information. +See the Hadoop documentation on link:http://hadoop.apache.org/docs/current/hadoop-project-dist/hadoop-hdfs/HdfsDesign.html[HDFS Architecture] for more information. [[arch.hdfs.nn]] === NameNode The NameNode is responsible for maintaining the filesystem metadata. -See the above HDFS Architecture link for more information. +See the above HDFS Architecture link for more information. [[arch.hdfs.dn]] === DataNode The DataNodes are responsible for storing HDFS blocks. -See the above HDFS Architecture link for more information. +See the above HDFS Architecture link for more information. [[arch.timelineconsistent.reads]] == Timeline-consistent High Available Reads @@ -2137,53 +2126,53 @@ See the above HDFS Architecture link for more information. HBase, architecturally, always had the strong consistency guarantee from the start. All reads and writes are routed through a single region server, which guarantees that all writes happen in an order, and all reads are seeing the most recent committed data. - + However, because of this single homing of the reads to a single location, if the server becomes unavailable, the regions of the table that were hosted in the region server become unavailable for some time. There are three phases in the region recovery process - detection, assignment, and recovery. -Of these, the detection is usually the longest and is presently in the order of 20-30 seconds depending on the zookeeper session timeout. -During this time and before the recovery is complete, the clients will not be able to read the region data. +Of these, the detection is usually the longest and is presently in the order of 20-30 seconds depending on the ZooKeeper session timeout. +During this time and before the recovery is complete, the clients will not be able to read the region data. -However, for some use cases, either the data may be read-only, or doing reads againsts some stale data is acceptable. +However, for some use cases, either the data may be read-only, or doing reads against some stale data is acceptable. With timeline-consistent high available reads, HBase can be used for these kind of latency-sensitive use cases where the application can expect to have a time bound on the read completion. - -For achieving high availability for reads, HBase provides a feature called ``region replication''. In this model, for each region of a table, there will be multiple replicas that are opened in different region servers. + +For achieving high availability for reads, HBase provides a feature called _region replication_. In this model, for each region of a table, there will be multiple replicas that are opened in different RegionServers. By default, the region replication is set to 1, so only a single region replica is deployed and there will not be any changes from the original model. -If region replication is set to 2 or more, than the master will assign replicas of the regions of the table. -The Load Balancer ensures that the region replicas are not co-hosted in the same region servers and also in the same rack (if possible). +If region replication is set to 2 or more, then the master will assign replicas of the regions of the table. +The Load Balancer ensures that the region replicas are not co-hosted in the same region servers and also in the same rack (if possible). All of the replicas for a single region will have a unique replica_id, starting from 0. -The region replica having replica_id==0 is called the primary region, and the others ``secondary regions'' or secondaries. +The region replica having replica_id==0 is called the primary region, and the others _secondary regions_ or secondaries. Only the primary can accept writes from the client, and the primary will always contain the latest changes. -Since all writes still have to go through the primary region, the writes are not highly-available (meaning they might block for some time if the region becomes unavailable). +Since all writes still have to go through the primary region, the writes are not highly-available (meaning they might block for some time if the region becomes unavailable). -The writes are asynchronously sent to the secondary region replicas using an ``Async WAL replication'' feature. +The writes are asynchronously sent to the secondary region replicas using an _Async WAL replication_ feature. This works similarly to HBase's multi-datacenter replication, but instead the data from a region is replicated to the secondary regions. Each secondary replica always receives and observes the writes in the same order that the primary region committed them. This ensures that the secondaries won't diverge from the primary regions data, but since the log replication is asnyc, the data might be stale in secondary regions. -In some sense, this design can be thought of as ``in-cluster replication'', where instead of replicating to a different datacenter, the data goes to a secondary region to keep secondary region's in-memory state up to date. +In some sense, this design can be thought of as _in-cluster replication_, where instead of replicating to a different datacenter, the data goes to a secondary region to keep secondary region's in-memory state up to date. The data files are shared between the primary region and the other replicas, so that there is no extra storage overhead. -However, the secondary regions will have recent non-flushed data in their memstores, which increases the memory overhead. - +However, the secondary regions will have recent non-flushed data in their MemStores, which increases the memory overhead. + Async WAL replication feature is being implemented in Phase 2 of issue HBASE-10070. -Before this, region replicas will only be updated with flushed data files from the primary (see hbase.regionserver.storefile.refresh.period below). It is also possible to use this without setting storefile.refresh.period for read only tables. - +Before this, region replicas will only be updated with flushed data files from the primary (see `hbase.regionserver.storefile.refresh.period` below). It is also possible to use this without setting `storefile.refresh.period` for read only tables. -=== Timeline Consistency -With this feature, HBase introduces a Consistency definition, which can be provided per read operation (get or scan). +=== Timeline Consistency + +With this feature, HBase introduces a Consistency definition, which can be provided per read operation (get or scan). [source,java] ---- public enum Consistency { STRONG, TIMELINE } ----- +---- `Consistency.STRONG` is the default consistency model provided by HBase. In case the table has region replication = 1, or in a table with region replicas but the reads are done with this consistency, the read is always performed by the primary regions, so that there will not be any change from the previous behaviour, and the client always observes the latest data. - + In case a read is performed with `Consistency.TIMELINE`, then the read RPC will be sent to the primary region server first. After a short interval (`hbase.client.primaryCallTimeout.get`, 10ms by default), parallel RPC for secondary region replicas will also be sent if the primary does not respond back. @@ -2192,22 +2181,22 @@ If the response came back from the primary region replica, we can always know th For this Result.isStale() API has been added to inspect the staleness. If the result is from a secondary region, then Result.isStale() will be set to true. The user can then inspect this field to possibly reason about the data. - -In terms of semantics, TIMELINE consistency as implemented by HBase differs from pure eventual consistency in these respects: + +In terms of semantics, TIMELINE consistency as implemented by HBase differs from pure eventual consistency in these respects: * Single homed and ordered updates: Region replication or not, on the write side, there is still only 1 defined replica (primary) which can accept writes. This replica is responsible for ordering the edits and preventing conflicts. This guarantees that two different writes are not committed at the same time by different replicas and the data diverges. - With this, there is no need to do read-repair or last-timestamp-wins kind of conflict resolution. + With this, there is no need to do read-repair or last-timestamp-wins kind of conflict resolution. * The secondaries also apply the edits in the order that the primary committed them. This way the secondaries will contain a snapshot of the primaries data at any point in time. - This is similar to RDBMS replications and even HBase's own multi-datacenter replication, however in a single cluster. + This is similar to RDBMS replications and even HBase's own multi-datacenter replication, however in a single cluster. * On the read side, the client can detect whether the read is coming from up-to-date data or is stale data. - Also, the client can issue reads with different consistency requirements on a per-operation basis to ensure its own semantic guarantees. + Also, the client can issue reads with different consistency requirements on a per-operation basis to ensure its own semantic guarantees. * The client can still observe edits out-of-order, and can go back in time, if it observes reads from one secondary replica first, then another secondary replica. There is no stickiness to region replicas or a transaction-id based guarantee. - If required, this can be implemented later though. + If required, this can be implemented later though. .HFile Version 1 image::timeline_consistency.png[HFile Version 1] @@ -2216,50 +2205,52 @@ To better understand the TIMELINE semantics, lets look at the above diagram. Lets say that there are two clients, and the first one writes x=1 at first, then x=2 and x=3 later. As above, all writes are handled by the primary region replica. The writes are saved in the write ahead log (WAL), and replicated to the other replicas asynchronously. -In the above diagram, notice that replica_id=1 received 2 updates, and it's data shows that x=2, while the replica_id=2 only received a single update, and its data shows that x=1. - +In the above diagram, notice that replica_id=1 received 2 updates, and its data shows that x=2, while the replica_id=2 only received a single update, and its data shows that x=1. + If client1 reads with STRONG consistency, it will only talk with the replica_id=0, and thus is guaranteed to observe the latest value of x=3. In case of a client issuing TIMELINE consistency reads, the RPC will go to all replicas (after primary timeout) and the result from the first response will be returned back. Thus the client can see either 1, 2 or 3 as the value of x. Let's say that the primary region has failed and log replication cannot continue for some time. If the client does multiple reads with TIMELINE consistency, she can observe x=2 first, then x=1, and so on. - + === Tradeoffs Having secondary regions hosted for read availability comes with some tradeoffs which should be carefully evaluated per use case. Following are advantages and disadvantages. -* .AdvantagesHigh availability for read-only tables. +.Advantages +* High availability for read-only tables * High availability for stale reads * Ability to do very low latency reads with very high percentile (99.9%+) latencies for stale reads -* .DisadvantagesDouble / Triple memstore usage (depending on region replication count) for tables with region replication > 1 +.Disadvantages +* Double / Triple MemStore usage (depending on region replication count) for tables with region replication > 1 * Increased block cache usage -* Extra network traffic for log replication +* Extra network traffic for log replication * Extra backup RPCs for replicas To serve the region data from multiple replicas, HBase opens the regions in secondary mode in the region servers. -The regions opened in secondary mode will share the same data files with the primary region replica, however each secondary region replica will have its own memstore to keep the unflushed data (only primary region can do flushes). Also to serve reads from secondary regions, the blocks of data files may be also cached in the block caches for the secondary regions. +The regions opened in secondary mode will share the same data files with the primary region replica, however each secondary region replica will have its own MemStore to keep the unflushed data (only primary region can do flushes). Also to serve reads from secondary regions, the blocks of data files may be also cached in the block caches for the secondary regions. === Configuration properties To use highly available reads, you should set the following properties in hbase-site.xml file. There is no specific configuration to enable or disable region replicas. Instead you can change the number of region replicas per table to increase or decrease at the table creation or with alter table. - + ==== Server side properties [source,xml] ---- - hbase.regionserver.storefile.refresh.period - 0 - - The period (in milliseconds) for refreshing the store files for the secondary regions. 0 means this feature is disabled. Secondary regions sees new files (from flushes and compactions) from primary once the secondary region refreshes the list of files in the region. But too frequent refreshes might cause extra Namenode pressure. If the files cannot be refreshed for longer than HFile TTL (hbase.master.hfilecleaner.ttl) the requests are rejected. Configuring HFile TTL to a larger value is also recommended with this setting. - + hbase.regionserver.storefile.refresh.period + 0 + + The period (in milliseconds) for refreshing the store files for the secondary regions. 0 means this feature is disabled. Secondary regions sees new files (from flushes and compactions) from primary once the secondary region refreshes the list of files in the region. But too frequent refreshes might cause extra Namenode pressure. If the files cannot be refreshed for longer than HFile TTL (hbase.master.hfilecleaner.ttl) the requests are rejected. Configuring HFile TTL to a larger value is also recommended with this setting. + ---- @@ -2268,37 +2259,37 @@ If you are using a custom load balancer property in hbase-site.xml (`hbase.maste ==== Client side properties -Ensure to set the following for all clients (and servers) that will use region replicas. +Ensure to set the following for all clients (and servers) that will use region replicas. [source,xml] ---- - hbase.ipc.client.allowsInterrupt - true - - Whether to enable interruption of RPC threads at the client side. This is required for region replicas with fallback RPC’s to secondary regions. - + hbase.ipc.client.allowsInterrupt + true + + Whether to enable interruption of RPC threads at the client side. This is required for region replicas with fallback RPC’s to secondary regions. + - hbase.client.primaryCallTimeout.get - 10000 - - The timeout (in microseconds), before secondary fallback RPC’s are submitted for get requests with Consistency.TIMELINE to the secondary replicas of the regions. Defaults to 10ms. Setting this lower will increase the number of RPC’s, but will lower the p99 latencies. - + hbase.client.primaryCallTimeout.get + 10000 + + The timeout (in microseconds), before secondary fallback RPC’s are submitted for get requests with Consistency.TIMELINE to the secondary replicas of the regions. Defaults to 10ms. Setting this lower will increase the number of RPC’s, but will lower the p99 latencies. + - hbase.client.primaryCallTimeout.multiget - 10000 - - The timeout (in microseconds), before secondary fallback RPC’s are submitted for multi-get requests (HTable.get(List)) with Consistency.TIMELINE to the secondary replicas of the regions. Defaults to 10ms. Setting this lower will increase the number of RPC’s, but will lower the p99 latencies. - + hbase.client.primaryCallTimeout.multiget + 10000 + + The timeout (in microseconds), before secondary fallback RPC’s are submitted for multi-get requests (HTable.get(List)) with Consistency.TIMELINE to the secondary replicas of the regions. Defaults to 10ms. Setting this lower will increase the number of RPC’s, but will lower the p99 latencies. + - hbase.client.replicaCallTimeout.scan - 1000000 - - The timeout (in microseconds), before secondary fallback RPC’s are submitted for scan requests with Consistency.TIMELINE to the secondary replicas of the regions. Defaults to 1 sec. Setting this lower will increase the number of RPC’s, but will lower the p99 latencies. - + hbase.client.replicaCallTimeout.scan + 1000000 + + The timeout (in microseconds), before secondary fallback RPC’s are submitted for scan requests with Consistency.TIMELINE to the secondary replicas of the regions. Defaults to 1 sec. Setting this lower will increase the number of RPC’s, but will lower the p99 latencies. + ---- @@ -2307,7 +2298,7 @@ Ensure to set the following for all clients (and servers) that will use region r Region replication is a per-table property. All tables have REGION_REPLICATION = 1 by default, which means that there is only one replica per region. You can set and change the number of replicas per region of a table by supplying the REGION_REPLICATION property in the table descriptor. - + ==== Shell @@ -2326,7 +2317,7 @@ flush 't1' [source,java] ---- -HTableDescriptor htd = new HTableDesctiptor(TableName.valueOf(“test_table”)); +HTableDescriptor htd = new HTableDesctiptor(TableName.valueOf(“test_table”)); htd.setRegionReplication(2); ... admin.createTable(htd); @@ -2346,20 +2337,20 @@ To disable region splits you can use DisabledRegionSplitPolicy as the split poli In the masters user interface, the region replicas of a table are also shown together with the primary regions. You can notice that the replicas of a region will share the same start and end keys and the same region name prefix. The only difference would be the appended replica_id (which is encoded as hex), and the region encoded name will be different. -You can also see the replica ids shown explicitly in the UI. +You can also see the replica ids shown explicitly in the UI. === API and Usage ==== Shell -You can do reads in shell using a the Consistency.TIMELINE semantics as follows +You can do reads in shell using a the Consistency.TIMELINE semantics as follows [source] ---- hbase(main):001:0> get 't1','r6', {CONSISTENCY => "TIMELINE"} ---- -You can simulate a region server pausing or becoming unavailable and do a read from the secondary replica: +You can simulate a region server pausing or becoming unavailable and do a read from the secondary replica: [source,bash] ---- @@ -2368,7 +2359,7 @@ $ kill -STOP hbase(main):001:0> get 't1','r6', {CONSISTENCY => "TIMELINE"} ---- -Using scans is also similar +Using scans is also similar [source] ---- @@ -2387,7 +2378,7 @@ get.setConsistency(Consistency.TIMELINE); Result result = table.get(get); ---- -You can also pass multiple gets: +You can also pass multiple gets: [source,java] ---- @@ -2400,7 +2391,7 @@ gets.add(get1); Result[] results = table.get(gets); ---- -And Scans: +And Scans: [source,java] ---- @@ -2410,11 +2401,11 @@ scan.setConsistency(Consistency.TIMELINE); ResultScanner scanner = table.getScanner(scan); ---- -You can inspect whether the results are coming from primary region or not by calling the Result.isStale() method: +You can inspect whether the results are coming from primary region or not by calling the Result.isStale() method: [source,java] ---- -Result result = table.get(get); +Result result = table.get(get); if (result.isStale()) { ... } diff --git a/src/main/asciidoc/_chapters/case_studies.adoc b/src/main/asciidoc/_chapters/case_studies.adoc index 3746c2a3a68..992414c8d85 100644 --- a/src/main/asciidoc/_chapters/case_studies.adoc +++ b/src/main/asciidoc/_chapters/case_studies.adoc @@ -30,14 +30,14 @@ [[casestudies.overview]] == Overview -This chapter will describe a variety of performance and troubleshooting case studies that can provide a useful blueprint on diagnosing Apache HBase cluster issues. +This chapter will describe a variety of performance and troubleshooting case studies that can provide a useful blueprint on diagnosing Apache HBase cluster issues. -For more information on Performance and Troubleshooting, see <> and <>. +For more information on Performance and Troubleshooting, see <> and <>. [[casestudies.schema]] == Schema Design -See the schema design case studies here: <> +See the schema design case studies here: <> [[casestudies.perftroub]] == Performance/Troubleshooting @@ -49,16 +49,18 @@ See the schema design case studies here: <>. +See also <>. diff --git a/src/main/asciidoc/_chapters/configuration.adoc b/src/main/asciidoc/_chapters/configuration.adoc index a48281d2040..4a9835a6723 100644 --- a/src/main/asciidoc/_chapters/configuration.adoc +++ b/src/main/asciidoc/_chapters/configuration.adoc @@ -27,8 +27,8 @@ :icons: font :experimental: -This chapter expands upon the <> chapter to further explain configuration of Apache HBase. -Please read this chapter carefully, especially <> to ensure that your HBase testing and deployment goes smoothly, and prevent data loss. +This chapter expands upon the <> chapter to further explain configuration of Apache HBase. +Please read this chapter carefully, especially the <> to ensure that your HBase testing and deployment goes smoothly, and prevent data loss. == Configuration Files Apache HBase uses the same configuration system as Apache Hadoop. @@ -41,8 +41,7 @@ _backup-masters_:: _hadoop-metrics2-hbase.properties_:: Used to connect HBase Hadoop's Metrics2 framework. - See the link:http://wiki.apache.org/hadoop/HADOOP-6728-MetricsV2[Hadoop Wiki - entry] for more information on Metrics2. + See the link:http://wiki.apache.org/hadoop/HADOOP-6728-MetricsV2[Hadoop Wiki entry] for more information on Metrics2. Contains only commented-out examples by default. _hbase-env.cmd_ and _hbase-env.sh_:: @@ -51,7 +50,7 @@ _hbase-env.cmd_ and _hbase-env.sh_:: _hbase-policy.xml_:: The default policy configuration file used by RPC servers to make authorization decisions on client requests. - Only used if HBase security (<>) is enabled. + Only used if HBase <> is enabled. _hbase-site.xml_:: The main HBase configuration file. @@ -71,17 +70,16 @@ _regionservers_:: [TIP] ==== When you edit XML, it is a good idea to use an XML-aware editor to be sure that your syntax is correct and your XML is well-formed. -You can also use the +xmllint+ utility to check that your XML is well-formed. -By default, +xmllint+ re-flows and prints the XML to standard output. -To check for well-formedness and only print output if errors exist, use the command +xmllint -noout - filename.xml+. +You can also use the `xmllint` utility to check that your XML is well-formed. +By default, `xmllint` re-flows and prints the XML to standard output. +To check for well-formedness and only print output if errors exist, use the command `xmllint -noout filename.xml`. ==== .Keep Configuration In Sync Across the Cluster [WARNING] ==== When running in distributed mode, after you make an edit to an HBase configuration, make sure you copy the content of the _conf/_ directory to all nodes of the cluster. HBase will not do this for you. -Use +rsync+, +scp+, or another secure mechanism for copying the configuration files to your nodes. +Use `rsync`, `scp`, or another secure mechanism for copying the configuration files to your nodes. For most configuration, a restart is needed for servers to pick up changes An exception is dynamic configuration. to be described later below. ==== @@ -89,8 +87,9 @@ to be described later below. [[basic.prerequisites]] == Basic Prerequisites -This section lists required services and some required system configuration. +This section lists required services and some required system configuration. +[[java]] .Java [cols="1,1,1,4", options="header"] |=== @@ -107,9 +106,9 @@ This section lists required services and some required system configuration. |0.98 |yes |yes -|Running with JDK 8 works but is not well tested. Building with JDK 8 would require removal of the -deprecated `remove()` method of the `PoolMap` class and is under consideration. See -link:https://issues.apache.org/jira/browse/HBASE-7608[HBASE-7608] for more information about JDK 8 +|Running with JDK 8 works but is not well tested. Building with JDK 8 would require removal of the +deprecated `remove()` method of the `PoolMap` class and is under consideration. See +link:https://issues.apache.org/jira/browse/HBASE-7608[HBASE-7608] for more information about JDK 8 support. |0.96 @@ -127,27 +126,27 @@ NOTE: In HBase 0.98.5 and newer, you must set `JAVA_HOME` on each node of your c .Operating System Utilities ssh:: - HBase uses the Secure Shell (ssh) command and utilities extensively to communicate between cluster nodes. Each server in the cluster must be running +ssh+ so that the Hadoop and HBase daemons can be managed. You must be able to connect to all nodes via SSH, including the local node, from the Master as well as any backup Master, using a shared key rather than a password. You can see the basic methodology for such a set-up in Linux or Unix systems at <>. If your cluster nodes use OS X, see the section, link:http://wiki.apache.org/hadoop/Running_Hadoop_On_OS_X_10.5_64-bit_%28Single-Node_Cluster%29[SSH: Setting up Remote Desktop and Enabling Self-Login] on the Hadoop wiki. + HBase uses the Secure Shell (ssh) command and utilities extensively to communicate between cluster nodes. Each server in the cluster must be running `ssh` so that the Hadoop and HBase daemons can be managed. You must be able to connect to all nodes via SSH, including the local node, from the Master as well as any backup Master, using a shared key rather than a password. You can see the basic methodology for such a set-up in Linux or Unix systems at "<>". If your cluster nodes use OS X, see the section, link:http://wiki.apache.org/hadoop/Running_Hadoop_On_OS_X_10.5_64-bit_%28Single-Node_Cluster%29[SSH: Setting up Remote Desktop and Enabling Self-Login] on the Hadoop wiki. DNS:: - HBase uses the local hostname to self-report its IP address. Both forward and reverse DNS resolving must work in versions of HBase previous to 0.92.0. The link:https://github.com/sujee/hadoop-dns-checker[hadoop-dns-checker] tool can be used to verify DNS is working correctly on the cluster. The project README file provides detailed instructions on usage. + HBase uses the local hostname to self-report its IP address. Both forward and reverse DNS resolving must work in versions of HBase previous to 0.92.0. The link:https://github.com/sujee/hadoop-dns-checker[hadoop-dns-checker] tool can be used to verify DNS is working correctly on the cluster. The project `README` file provides detailed instructions on usage. Loopback IP:: - Prior to hbase-0.96.0, HBase only used the IP address [systemitem]+127.0.0.1+ to refer to `localhost`, and this could not be configured. - See <>. + Prior to hbase-0.96.0, HBase only used the IP address `127.0.0.1` to refer to `localhost`, and this could not be configured. + See <> for more details. NTP:: The clocks on cluster nodes should be synchronized. A small amount of variation is acceptable, but larger amounts of skew can cause erratic and unexpected behavior. Time synchronization is one of the first things to check if you see unexplained problems in your cluster. It is recommended that you run a Network Time Protocol (NTP) service, or another time-synchronization mechanism, on your cluster, and that all nodes look to the same service for time synchronization. See the link:http://www.tldp.org/LDP/sag/html/basic-ntp-config.html[Basic NTP Configuration] at [citetitle]_The Linux Documentation Project (TLDP)_ to set up NTP. Limits on Number of Files and Processes (ulimit):: - Apache HBase is a database. It requires the ability to open a large number of files at once. Many Linux distributions limit the number of files a single user is allowed to open to `1024` (or `256` on older versions of OS X). You can check this limit on your servers by running the command +ulimit -n+ when logged in as the user which runs HBase. See <> for some of the problems you may experience if the limit is too low. You may also notice errors such as the following: + Apache HBase is a database. It requires the ability to open a large number of files at once. Many Linux distributions limit the number of files a single user is allowed to open to `1024` (or `256` on older versions of OS X). You can check this limit on your servers by running the command `ulimit -n` when logged in as the user which runs HBase. See <> for some of the problems you may experience if the limit is too low. You may also notice errors such as the following: + ---- 2010-04-06 03:04:37,542 INFO org.apache.hadoop.hdfs.DFSClient: Exception increateBlockOutputStream java.io.EOFException 2010-04-06 03:04:37,542 INFO org.apache.hadoop.hdfs.DFSClient: Abandoning block blk_-6935524980745310745_1391901 ---- + -It is recommended to raise the ulimit to at least 10,000, but more likely 10,240, because the value is usually expressed in multiples of 1024. Each ColumnFamily has at least one StoreFile, and possibly more than 6 StoreFiles if the region is under load. The number of open files required depends upon the number of ColumnFamilies and the number of regions. The following is a rough formula for calculating the potential number of open files on a RegionServer. +It is recommended to raise the ulimit to at least 10,000, but more likely 10,240, because the value is usually expressed in multiples of 1024. Each ColumnFamily has at least one StoreFile, and possibly more than six StoreFiles if the region is under load. The number of open files required depends upon the number of ColumnFamilies and the number of regions. The following is a rough formula for calculating the potential number of open files on a RegionServer. + .Calculate the Potential Number of Open Files ---- @@ -156,18 +155,18 @@ It is recommended to raise the ulimit to at least 10,000, but more likely 10,240 + For example, assuming that a schema had 3 ColumnFamilies per region with an average of 3 StoreFiles per ColumnFamily, and there are 100 regions per RegionServer, the JVM will open `3 * 3 * 100 = 900` file descriptors, not counting open JAR files, configuration files, and others. Opening a file does not take many resources, and the risk of allowing a user to open too many files is minimal. + -Another related setting is the number of processes a user is allowed to run at once. In Linux and Unix, the number of processes is set using the ulimit -u command. This should not be confused with the nproc command, which controls the number of CPUs available to a given user. Under load, a nproc that is too low can cause OutOfMemoryError exceptions. See Jack Levin's major hdfs issues thread on the hbase-users mailing list, from 2011. +Another related setting is the number of processes a user is allowed to run at once. In Linux and Unix, the number of processes is set using the `ulimit -u` command. This should not be confused with the `nproc` command, which controls the number of CPUs available to a given user. Under load, a `ulimit -u` that is too low can cause OutOfMemoryError exceptions. See Jack Levin's major HDFS issues thread on the hbase-users mailing list, from 2011. + -Configuring the maximum number of ile descriptors and processes for the user who is running the HBase process is an operating system configuration, rather than an HBase configuration. It is also important to be sure that the settings are changed for the user that actually runs HBase. To see which user started HBase, and that user's ulimit configuration, look at the first line of the HBase log for that instance. A useful read setting config on you hadoop cluster is Aaron Kimballs' Configuration Parameters: What can you just ignore? -+ -.`ulimit` Settings on Ubuntu +Configuring the maximum number of file descriptors and processes for the user who is running the HBase process is an operating system configuration, rather than an HBase configuration. It is also important to be sure that the settings are changed for the user that actually runs HBase. To see which user started HBase, and that user's ulimit configuration, look at the first line of the HBase log for that instance. A useful read setting config on you hadoop cluster is Aaron Kimballs' Configuration Parameters: What can you just ignore? ++ +.`ulimit` Settings on Ubuntu ==== -To configure ulimit settings on Ubuntu, edit /etc/security/limits.conf, which is a space-delimited file with four columns. Refer to the man page for limits.conf for details about the format of this file. In the following example, the first line sets both soft and hard limits for the number of open files (nofile) to 32768 for the operating system user with the username hadoop. The second line sets the number of processes to 32000 for the same user. +To configure ulimit settings on Ubuntu, edit _/etc/security/limits.conf_, which is a space-delimited file with four columns. Refer to the man page for _limits.conf_ for details about the format of this file. In the following example, the first line sets both soft and hard limits for the number of open files (nofile) to 32768 for the operating system user with the username hadoop. The second line sets the number of processes to 32000 for the same user. ---- hadoop - nofile 32768 hadoop - nproc 32000 ---- -The settings are only applied if the Pluggable Authentication Module (PAM) environment is directed to use them. To configure PAM to use these limits, be sure that the /etc/pam.d/common-session file contains the following line: +The settings are only applied if the Pluggable Authentication Module (PAM) environment is directed to use them. To configure PAM to use these limits, be sure that the _/etc/pam.d/common-session_ file contains the following line: ---- session required pam_limits.so ---- @@ -185,7 +184,7 @@ The following table summarizes the versions of Hadoop supported with each versio Based on the version of HBase, you should select the most appropriate version of Hadoop. You can use Apache Hadoop, or a vendor's distribution of Hadoop. No distinction is made here. -See link:http://wiki.apache.org/hadoop/Distributions%20and%20Commercial%20Support for information about vendors of Hadoop. +See link:http://wiki.apache.org/hadoop/Distributions%20and%20Commercial%20Support[the Hadoop wiki] for information about vendors of Hadoop. .Hadoop 2.x is recommended. [TIP] @@ -198,9 +197,14 @@ HBase 0.98 drops support for Hadoop 1.0, deprecates use of Hadoop 1.1+, and HBas Use the following legend to interpret this table: .Hadoop version support matrix + +* "S" = supported +* "X" = not supported +* "NT" = Not tested + [cols="1,1,1,1,1,1", options="header"] |=== -| | HBase-0.92.x | HBase-0.94.x | HBase-0.96.x | HBase-0.98.x (Support for Hadoop 1.1+ is deprecated.) | HBase-1.0.x (Hadoop 1.x is NOT supported) +| | HBase-0.92.x | HBase-0.94.x | HBase-0.96.x | HBase-0.98.x (Support for Hadoop 1.1+ is deprecated.) | HBase-1.0.x (Hadoop 1.x is NOT supported) |Hadoop-0.20.205 | S | X | X | X | X |Hadoop-0.22.x | S | X | X | X | X |Hadoop-1.0.x |X | X | X | X | X @@ -222,13 +226,13 @@ The bundled jar is ONLY for use in standalone mode. In distributed mode, it is _critical_ that the version of Hadoop that is out on your cluster match what is under HBase. Replace the hadoop jar found in the HBase lib directory with the hadoop jar you are running on your cluster to avoid version mismatch issues. Make sure you replace the jar in HBase everywhere on your cluster. -Hadoop version mismatch issues have various manifestations but often all looks like its hung up. +Hadoop version mismatch issues have various manifestations but often all looks like its hung up. ==== [[hadoop2.hbase_0.94]] ==== Apache HBase 0.94 with Hadoop 2 -To get 0.94.x to run on hadoop 2.2.0, you need to change the hadoop 2 and protobuf versions in the _pom.xml_: Here is a diff with pom.xml changes: +To get 0.94.x to run on Hadoop 2.2.0, you need to change the hadoop 2 and protobuf versions in the _pom.xml_: Here is a diff with pom.xml changes: [source] ---- @@ -259,23 +263,23 @@ Index: pom.xml The next step is to regenerate Protobuf files and assuming that the Protobuf has been installed: -* Go to the hbase root folder, using the command line; +* Go to the HBase root folder, using the command line; * Type the following commands: + [source,bourne] ---- $ protoc -Isrc/main/protobuf --java_out=src/main/java src/main/protobuf/hbase.proto ----- +---- + [source,bourne] ---- $ protoc -Isrc/main/protobuf --java_out=src/main/java src/main/protobuf/ErrorHandling.proto ----- +---- -Building against the hadoop 2 profile by running something like the following command: +Building against the hadoop 2 profile by running something like the following command: ---- $ mvn clean install assembly:single -Dhadoop.profile=2.0 -DskipTests @@ -292,7 +296,7 @@ HBase-0.94 can additionally work with Hadoop-0.23.x and 2.x, but you may have to As of Apache HBase 0.96.x, Apache Hadoop 1.0.x at least is required. Hadoop 2 is strongly encouraged (faster but also has fixes that help MTTR). We will no longer run properly on older Hadoops such as 0.20.205 or branch-0.20-append. -Do not move to Apache HBase 0.96.x if you cannot upgrade your Hadoop.. See link:http://search-hadoop.com/m/7vFVx4EsUb2[HBase, mail # dev - DISCUSS: +Do not move to Apache HBase 0.96.x if you cannot upgrade your Hadoop. See link:http://search-hadoop.com/m/7vFVx4EsUb2[HBase, mail # dev - DISCUSS: Have hbase require at least hadoop 1.0.0 in hbase 0.96.0?] [[hadoop.older.versions]] @@ -303,13 +307,13 @@ DO NOT use Hadoop 0.20.2, Hadoop 0.20.203.0, and Hadoop 0.20.204.0 which DO NOT Currently only Hadoop versions 0.20.205.x or any release in excess of this version -- this includes hadoop-1.0.0 -- have a working, durable sync. The Cloudera blog post link:http://www.cloudera.com/blog/2012/01/an-update-on-apache-hadoop-1-0/[An update on Apache Hadoop 1.0] by Charles Zedlweski has a nice exposition on how all the Hadoop versions relate. -Its worth checking out if you are having trouble making sense of the Hadoop version morass. +It's worth checking out if you are having trouble making sense of the Hadoop version morass. Sync has to be explicitly enabled by setting `dfs.support.append` equal to true on both the client side -- in _hbase-site.xml_ -- and on the serverside in _hdfs-site.xml_ (The sync facility HBase needs is a subset of the append code path). [source,xml] ---- - + dfs.support.append true @@ -317,7 +321,7 @@ Sync has to be explicitly enabled by setting `dfs.support.append` equal to true ---- You will have to restart your cluster after making this edit. -Ignore the chicken-little comment you'll find in the _hdfs-default.xml_ in the description for the `dfs.support.append` configuration. +Ignore the chicken-little comment you'll find in the _hdfs-default.xml_ in the description for the `dfs.support.append` configuration. [[hadoop.security]] ==== Apache HBase on Secure Hadoop @@ -325,12 +329,12 @@ Ignore the chicken-little comment you'll find in the _hdfs-default.xml_ in the d Apache HBase will run on any Hadoop 0.20.x that incorporates Hadoop security features as long as you do as suggested above and replace the Hadoop jar that ships with HBase with the secure version. If you want to read more about how to setup Secure HBase, see <>. -`dfs.datanode.max.transfer.threads` -[[dfs.datanode.max.transfer.threads]] -==== (((dfs.datanode.max.transfer.threads))) -An HDFS datanode has an upper bound on the number of files that it will serve at any one time. -Before doing any loading, make sure you have configured Hadoop's _conf/hdfs-site.xml_, setting the `dfs.datanode.max.transfer.threads` value to at least the following: +[[dfs.datanode.max.transfer.threads]] +==== `dfs.datanode.max.transfer.threads` (((dfs.datanode.max.transfer.threads))) + +An HDFS DataNode has an upper bound on the number of files that it will serve at any one time. +Before doing any loading, make sure you have configured Hadoop's _conf/hdfs-site.xml_, setting the `dfs.datanode.max.transfer.threads` value to at least the following: [source,xml] ---- @@ -353,24 +357,24 @@ For example: contain current block. Will get new block locations from namenode and retry... ---- -See also <> and note that this property was previously known as `dfs.datanode.max.xcievers` (e.g. link:http://ccgtech.blogspot.com/2010/02/hadoop-hdfs-deceived-by-xciever.html[ - Hadoop HDFS: Deceived by Xciever]). +See also <> and note that this property was previously known as `dfs.datanode.max.xcievers` (e.g. link:http://ccgtech.blogspot.com/2010/02/hadoop-hdfs-deceived-by-xciever.html[Hadoop HDFS: Deceived by Xciever]). [[zookeeper.requirements]] === ZooKeeper Requirements ZooKeeper 3.4.x is required as of HBase 1.0.0. -HBase makes use of the [method]+multi+ functionality that is only available since 3.4.0 (The +useMulti+ is defaulted true in HBase 1.0.0). See link:[HBASE-12241 The crash of regionServer when taking deadserver's replication queue breaks replication] and link:[Use ZK.multi when available for HBASE-6710 0.92/0.94 compatibility fix] for background. +HBase makes use of the `multi` functionality that is only available since 3.4.0 (The `useMulti` configuration option defaults to `true` in HBase 1.0.0). +See link:https://issues.apache.org/jira/browse/HBASE-12241[HBASE-12241 (The crash of regionServer when taking deadserver's replication queue breaks replication)] and link:https://issues.apache.org/jira/browse/HBASE-6775[HBASE-6775 (Use ZK.multi when available for HBASE-6710 0.92/0.94 compatibility fix)] for background. [[standalone_dist]] == HBase run modes: Standalone and Distributed HBase has two run modes: <> and <>. Out of the box, HBase runs in standalone mode. -Whatever your mode, you will need to configure HBase by editing files in the HBase _conf_ directory. -At a minimum, you must edit `conf/hbase-env.sh` to tell HBase which +java+ to use. -In this file you set HBase environment variables such as the heapsize and other options for the +JVM+, the preferred location for log files, etc. -Set `JAVA_HOME` to point at the root of your +java+ install. +Whatever your mode, you will need to configure HBase by editing files in the HBase _conf_ directory. +At a minimum, you must edit [code]+conf/hbase-env.sh+ to tell HBase which +java+ to use. +In this file you set HBase environment variables such as the heapsize and other options for the `JVM`, the preferred location for log files, etc. +Set [var]+JAVA_HOME+ to point at the root of your +java+ install. [[standalone]] === Standalone HBase @@ -382,17 +386,12 @@ Zookeeper binds to a well known port so clients may talk to HBase. === Distributed -Distributed mode can be subdivided into distributed but all daemons run on a single node -- a.k.a _pseudo-distributed_-- and _fully-distributed_ where the daemons are spread across all nodes in the cluster. -The pseudo-distributed vs fully-distributed nomenclature comes from Hadoop. +Distributed mode can be subdivided into distributed but all daemons run on a single node -- a.k.a _pseudo-distributed_ -- and _fully-distributed_ where the daemons are spread across all nodes in the cluster. +The _pseudo-distributed_ vs. _fully-distributed_ nomenclature comes from Hadoop. Pseudo-distributed mode can run against the local filesystem or it can run against an instance of the _Hadoop Distributed File System_ (HDFS). Fully-distributed mode can ONLY run on HDFS. -See the Hadoop link:http://hadoop.apache.org/common/docs/r1.1.1/api/overview-summary.html#overview_description[ - requirements and instructions] for how to set up HDFS for Hadoop 1.x. -A good walk-through for setting up HDFS on Hadoop 2 is at link:http://www.alexjf.net/blog/distributed-systems/hadoop-yarn-installation-definitive-guide. - -Below we describe the different distributed setups. -Starting, verification and exploration of your install, whether a _pseudo-distributed_ or _fully-distributed_ configuration is described in a section that follows, <>. -The same verification script applies to both deploy types. +See the Hadoop link:http://hadoop.apache.org/docs/current/[documentation] for how to set up HDFS. +A good walk-through for setting up HDFS on Hadoop 2 can be found at http://www.alexjf.net/blog/distributed-systems/hadoop-yarn-installation-definitive-guide. [[pseudo]] ==== Pseudo-distributed @@ -418,7 +417,7 @@ For a production environment, distributed mode is appropriate. In distributed mode, multiple instances of HBase daemons run on multiple servers in the cluster. Just as in pseudo-distributed mode, a fully distributed configuration requires that you set the `hbase-cluster.distributed` property to `true`. -Typically, the `hbase.rootdir` is configured to point to a highly-available HDFS filesystem. +Typically, the `hbase.rootdir` is configured to point to a highly-available HDFS filesystem. In addition, the cluster is configured so that multiple cluster nodes enlist as RegionServers, ZooKeeper QuorumPeers, and backup HMaster servers. These configuration basics are all demonstrated in <>. @@ -430,14 +429,14 @@ Each host is on a separate line. All hosts listed in this file will have their RegionServer processes started and stopped when the master server starts or stops. .ZooKeeper and HBase -See section <> for ZooKeeper setup for HBase. +See the <> section for ZooKeeper setup instructions for HBase. .Example Distributed HBase Cluster ==== This is a bare-bones _conf/hbase-site.xml_ for a distributed HBase cluster. A cluster that is used for real-world work would contain more custom configuration parameters. Most HBase configuration directives have default values, which are used unless the value is overridden in the _hbase-site.xml_. -See <> for more information. +See "<>" for more information. [source,xml] ---- @@ -452,14 +451,14 @@ See <> for more information. true - hbase.zookeeper.quorum - node-a.example.com,node-b.example.com,node-c.example.com - + hbase.zookeeper.quorum + node-a.example.com,node-b.example.com,node-c.example.com + ---- -This is an example _conf/regionservers_ file, which contains a list of each node that should run a RegionServer in the cluster. -These nodes need HBase installed and they need to use the same contents of the _conf/_ directory as the Master server.. +This is an example _conf/regionservers_ file, which contains a list of nodes that should run a RegionServer in the cluster. +These nodes need HBase installed and they need to use the same contents of the _conf/_ directory as the Master server [source] ---- @@ -484,7 +483,7 @@ node-c.example.com See <> for a walk-through of a simple three-node cluster configuration with multiple ZooKeeper, backup HMaster, and RegionServer instances. .Procedure: HDFS Client Configuration -. Of note, if you have made HDFS client configuration on your Hadoop cluster, such as configuration directives for HDFS clients, as opposed to server-side configurations, you must use one of the following methods to enable HBase to see and use these configuration changes: +. Of note, if you have made HDFS client configuration changes on your Hadoop cluster, such as configuration directives for HDFS clients, as opposed to server-side configurations, you must use one of the following methods to enable HBase to see and use these configuration changes: + a. Add a pointer to your `HADOOP_CONF_DIR` to the `HBASE_CLASSPATH` environment variable in _hbase-env.sh_. b. Add a copy of _hdfs-site.xml_ (or _hadoop-site.xml_) or, better, symlinks, under _${HBASE_HOME}/conf_, or @@ -492,18 +491,17 @@ c. if only a small set of HDFS client configurations, add them to _hbase-site.xm An example of such an HDFS client configuration is `dfs.replication`. -If for example, you want to run with a replication factor of 5, hbase will create files with the default of 3 unless you do the above to make the configuration available to HBase. +If for example, you want to run with a replication factor of 5, HBase will create files with the default of 3 unless you do the above to make the configuration available to HBase. [[confirm]] == Running and Confirming Your Installation Make sure HDFS is running first. -Start and stop the Hadoop HDFS daemons by running _bin/start-hdfs.sh_ over in the `HADOOP_HOME` directory. -You can ensure it started properly by testing the +put+ and +get+ of files into the Hadoop filesystem. -HBase does not normally use the mapreduce daemons. -These do not need to be started. +Start and stop the Hadoop HDFS daemons by running _bin/start-hdfs.sh_ over in the `HADOOP_HOME` directory. +You can ensure it started properly by testing the `put` and `get` of files into the Hadoop filesystem. +HBase does not normally use the MapReduce or YARN daemons. These do not need to be started. -_If_ you are managing your own ZooKeeper, start it and confirm its running else, HBase will start up ZooKeeper for you as part of its start process. +_If_ you are managing your own ZooKeeper, start it and confirm it's running, else HBase will start up ZooKeeper for you as part of its start process. Start HBase with the following command: @@ -518,11 +516,11 @@ HBase logs can be found in the _logs_ subdirectory. Check them out especially if HBase had trouble starting. HBase also puts up a UI listing vital attributes. -By default its deployed on the Master host at port 16010 (HBase RegionServers listen on port 16020 by default and put up an informational http server at 16030). If the Master were running on a host named `master.example.org` on the default port, to see the Master's homepage you'd point your browser at _http://master.example.org:16010_. +By default it's deployed on the Master host at port 16010 (HBase RegionServers listen on port 16020 by default and put up an informational HTTP server at port 16030). If the Master is running on a host named `master.example.org` on the default port, point your browser at _http://master.example.org:16010_ to see the web interface. -Prior to HBase 0.98, the default ports the master ui was deployed on port 16010, and the HBase RegionServers would listen on port 16020 by default and put up an informational http server at 16030. +Prior to HBase 0.98 the master UI was deployed on port 60010, and the HBase RegionServers UI on port 60030. -Once HBase has started, see the <> for how to create tables, add data, scan your insertions, and finally disable and drop your tables. +Once HBase has started, see the <> section for how to create tables, add data, scan your insertions, and finally disable and drop your tables. To stop HBase after exiting the HBase shell enter @@ -545,11 +543,11 @@ Just as in Hadoop where you add site-specific HDFS configuration to the _hdfs-si For the list of configurable properties, see <> below or view the raw _hbase-default.xml_ source file in the HBase source code at _src/main/resources_. Not all configuration options make it out to _hbase-default.xml_. -Configuration that it is thought rare anyone would change can exist only in code; the only way to turn up such configurations is via a reading of the source code itself. +Configuration that it is thought rare anyone would change can exist only in code; the only way to turn up such configurations is via a reading of the source code itself. -Currently, changes here will require a cluster restart for HBase to notice the change. +Currently, changes here will require a cluster restart for HBase to notice the change. // hbase/src/main/asciidoc -// +// include::../../../../target/asciidoc/hbase-default.adoc[] @@ -563,14 +561,14 @@ Open the file at _conf/hbase-env.sh_ and peruse its content. Each option is fairly well documented. Add your own environment variables here if you want them read by HBase daemons on startup. -Changes here will require a cluster restart for HBase to notice the change. +Changes here will require a cluster restart for HBase to notice the change. [[log4j]] === _log4j.properties_ -Edit this file to change rate at which HBase files are rolled and to change the level at which HBase logs messages. +Edit this file to change rate at which HBase files are rolled and to change the level at which HBase logs messages. -Changes here will require a cluster restart for HBase to notice the change though log levels can be changed for particular daemons via the HBase UI. +Changes here will require a cluster restart for HBase to notice the change though log levels can be changed for particular daemons via the HBase UI. [[client_dependencies]] === Client configuration and dependencies connecting to an HBase cluster @@ -579,12 +577,12 @@ If you are running HBase in standalone mode, you don't need to configure anythin Since the HBase Master may move around, clients bootstrap by looking to ZooKeeper for current critical locations. ZooKeeper is where all these values are kept. -Thus clients require the location of the ZooKeeper ensemble information before they can do anything else. -Usually this the ensemble location is kept out in the _hbase-site.xml_ and is picked up by the client from the `CLASSPATH`. +Thus clients require the location of the ZooKeeper ensemble before they can do anything else. +Usually this the ensemble location is kept out in the _hbase-site.xml_ and is picked up by the client from the `CLASSPATH`. If you are configuring an IDE to run a HBase client, you should include the _conf/_ directory on your classpath so _hbase-site.xml_ settings can be found (or add _src/test/resources_ to pick up the hbase-site.xml used by tests). -Minimally, a client of HBase needs several libraries in its `CLASSPATH` when connecting to a cluster, including: +Minimally, a client of HBase needs several libraries in its `CLASSPATH` when connecting to a cluster, including: [source] ---- @@ -597,7 +595,7 @@ log4j (log4j-1.2.16.jar) slf4j-api (slf4j-api-1.5.8.jar) slf4j-log4j (slf4j-log4j12-1.5.8.jar) zookeeper (zookeeper-3.4.2.jar) ----- +---- An example basic _hbase-site.xml_ for client only might look as follows: [source,xml] @@ -612,36 +610,37 @@ An example basic _hbase-site.xml_ for client only might look as follows: ----- +---- [[java.client.config]] ==== Java client configuration -The configuration used by a Java client is kept in an link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/HBaseConfiguration[HBaseConfiguration] instance. +The configuration used by a Java client is kept in an link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/HBaseConfiguration[HBaseConfiguration] instance. -The factory method on HBaseConfiguration, `HBaseConfiguration.create();`, on invocation, will read in the content of the first _hbase-site.xml_ found on the client's `CLASSPATH`, if one is present (Invocation will also factor in any _hbase-default.xml_ found; an hbase-default.xml ships inside the _hbase.X.X.X.jar_). It is also possible to specify configuration directly without having to read from a _hbase-site.xml_. -For example, to set the ZooKeeper ensemble for the cluster programmatically do as follows: +The factory method on HBaseConfiguration, `HBaseConfiguration.create();`, on invocation, will read in the content of the first _hbase-site.xml_ found on the client's `CLASSPATH`, if one is present (Invocation will also factor in any _hbase-default.xml_ found; an _hbase-default.xml_ ships inside the _hbase.X.X.X.jar_). It is also possible to specify configuration directly without having to read from a _hbase-site.xml_. +For example, to set the ZooKeeper ensemble for the cluster programmatically do as follows: [source,java] ---- Configuration config = HBaseConfiguration.create(); config.set("hbase.zookeeper.quorum", "localhost"); // Here we are running zookeeper locally ----- +---- -If multiple ZooKeeper instances make up your ZooKeeper ensemble, they may be specified in a comma-separated list (just as in the _hbase-site.xml_ file). This populated `Configuration` instance can then be passed to an link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/HTable.html[HTable], and so on. +If multiple ZooKeeper instances make up your ZooKeeper ensemble, they may be specified in a comma-separated list (just as in the _hbase-site.xml_ file). This populated `Configuration` instance can then be passed to an link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/HTable.html[HTable], and so on. [[example_config]] == Example Configurations === Basic Distributed HBase Install -Here is an example basic configuration for a distributed ten node cluster. -The nodes are named `example0`, `example1`, etc., through node `example9` in this example. -The HBase Master and the HDFS namenode are running on the node `example0`. -RegionServers run on nodes `example1`-`example9`. -A 3-node ZooKeeper ensemble runs on `example1`, `example2`, and `example3` on the default ports. -ZooKeeper data is persisted to the directory _/export/zookeeper_. -Below we show what the main configuration files -- _hbase-site.xml_, _regionservers_, and _hbase-env.sh_ -- found in the HBase _conf_ directory might look like. +Here is an example basic configuration for a distributed ten node cluster: +* The nodes are named `example0`, `example1`, etc., through node `example9` in this example. +* The HBase Master and the HDFS NameNode are running on the node `example0`. +* RegionServers run on nodes `example1`-`example9`. +* A 3-node ZooKeeper ensemble runs on `example1`, `example2`, and `example3` on the default ports. +* ZooKeeper data is persisted to the directory _/export/zookeeper_. + +Below we show what the main configuration files -- _hbase-site.xml_, _regionservers_, and _hbase-env.sh_ -- found in the HBase _conf_ directory might look like. [[hbase_site]] ==== _hbase-site.xml_ @@ -685,7 +684,7 @@ Below we show what the main configuration files -- _hbase-site.xml_, _regionserv ==== _regionservers_ In this file you list the nodes that will run RegionServers. -In our case, these nodes are `example1`-`example9`. +In our case, these nodes are `example1`-`example9`. [source] ---- @@ -705,46 +704,43 @@ example9 The following lines in the _hbase-env.sh_ file show how to set the `JAVA_HOME` environment variable (required for HBase 0.98.5 and newer) and set the heap to 4 GB (rather than the default value of 1 GB). If you copy and paste this example, be sure to adjust the `JAVA_HOME` to suit your environment. -[source,bash] ---- # The java implementation to use. -export JAVA_HOME=/usr/java/jdk1.7.0/ +export JAVA_HOME=/usr/java/jdk1.7.0/ # The maximum amount of heap to use, in MB. Default is 1000. export HBASE_HEAPSIZE=4096 ---- -Use +rsync+ to copy the content of the _conf_ directory to all nodes of the cluster. +Use +rsync+ to copy the content of the _conf_ directory to all nodes of the cluster. [[important_configurations]] == The Important Configurations -Below we list what the _important_ Configurations. -We've divided this section into required configuration and worth-a-look recommended configs. +Below we list some _important_ configurations. +We've divided this section into required configuration and worth-a-look recommended configs. [[required_configuration]] === Required Configurations -Review the <> and <> sections. +Review the <> and <> sections. [[big.cluster.config]] ==== Big Cluster Configurations -If a cluster with a lot of regions, it is possible if an eager beaver regionserver checks in soon after master start while all the rest in the cluster are laggardly, this first server to checkin will be assigned all regions. -If lots of regions, this first server could buckle under the load. -To prevent the above scenario happening up the `hbase.master.wait.on.regionservers.mintostart` from its default value of 1. +If you have a cluster with a lot of regions, it is possible that a Regionserver checks in briefly after the Master starts while all the remaining RegionServers lag behind. This first server to check in will be assigned all regions which is not optimal. +To prevent the above scenario from happening, up the `hbase.master.wait.on.regionservers.mintostart` property from its default value of 1. See link:https://issues.apache.org/jira/browse/HBASE-6389[HBASE-6389 Modify the conditions to ensure that Master waits for sufficient number of Region Servers before - starting region assignments] for more detail. + starting region assignments] for more detail. [[backup.master.fail.fast]] -==== If a backup Master, making primary Master fail fast +==== If a backup Master exists, make the primary Master fail fast If the primary Master loses its connection with ZooKeeper, it will fall into a loop where it keeps trying to reconnect. -Disable this functionality if you are running more than one Master: i.e. -a backup Master. +Disable this functionality if you are running more than one Master: i.e. a backup Master. Failing to do so, the dying Master may continue to receive RPCs though another Master has assumed the role of primary. -See the configuration <>. +See the configuration <>. === Recommended Configurations @@ -760,15 +756,15 @@ Before changing this value, be sure you have your JVM garbage collection configu To change this configuration, edit _hbase-site.xml_, copy the changed file around the cluster and restart. -We set this value high to save our having to field noob questions up on the mailing lists asking why a RegionServer went down during a massive import. +We set this value high to save our having to field questions up on the mailing lists asking why a RegionServer went down during a massive import. The usual cause is that their JVM is untuned and they are running into long GC pauses. Our thinking is that while users are getting familiar with HBase, we'd save them having to know all of its intricacies. -Later when they've built some confidence, then they can play with configuration such as this. +Later when they've built some confidence, then they can play with configuration such as this. [[zookeeper.instances]] ===== Number of ZooKeeper Instances -See <>. +See <>. [[recommended.configurations.hdfs]] ==== HDFS Configurations @@ -776,35 +772,35 @@ See <>. [[dfs.datanode.failed.volumes.tolerated]] ===== dfs.datanode.failed.volumes.tolerated -This is the "...number of volumes that are allowed to fail before a datanode stops offering service. +This is the "...number of volumes that are allowed to fail before a DataNode stops offering service. By default any volume failure will cause a datanode to shutdown" from the _hdfs-default.xml_ description. -If you have > three or four disks, you might want to set this to 1 or if you have many disks, two or more. +You might want to set this to about half the amount of your available disks. [[hbase.regionserver.handler.count_description]] ==== `hbase.regionserver.handler.count` This setting defines the number of threads that are kept open to answer incoming requests to user tables. -The rule of thumb is to keep this number low when the payload per request approaches the MB (big puts, scans using a large cache) and high when the payload is small (gets, small puts, ICVs, deletes). The total size of the queries in progress is limited by the setting "hbase.ipc.server.max.callqueue.size". +The rule of thumb is to keep this number low when the payload per request approaches the MB (big puts, scans using a large cache) and high when the payload is small (gets, small puts, ICVs, deletes). The total size of the queries in progress is limited by the setting `hbase.ipc.server.max.callqueue.size`. -It is safe to set that number to the maximum number of incoming clients if their payload is small, the typical example being a cluster that serves a website since puts aren't typically buffered and most of the operations are gets. +It is safe to set that number to the maximum number of incoming clients if their payload is small, the typical example being a cluster that serves a website since puts aren't typically buffered and most of the operations are gets. The reason why it is dangerous to keep this setting high is that the aggregate size of all the puts that are currently happening in a region server may impose too much pressure on its memory, or even trigger an OutOfMemoryError. -A region server running on low memory will trigger its JVM's garbage collector to run more frequently up to a point where GC pauses become noticeable (the reason being that all the memory used to keep all the requests' payloads cannot be trashed, no matter how hard the garbage collector tries). After some time, the overall cluster throughput is affected since every request that hits that region server will take longer, which exacerbates the problem even more. +A RegionServer running on low memory will trigger its JVM's garbage collector to run more frequently up to a point where GC pauses become noticeable (the reason being that all the memory used to keep all the requests' payloads cannot be trashed, no matter how hard the garbage collector tries). After some time, the overall cluster throughput is affected since every request that hits that RegionServer will take longer, which exacerbates the problem even more. -You can get a sense of whether you have too little or too many handlers by <> on an individual RegionServer then tailing its logs (Queued requests consume memory). +You can get a sense of whether you have too little or too many handlers by <> on an individual RegionServer then tailing its logs (Queued requests consume memory). [[big_memory]] ==== Configuration for large memory machines HBase ships with a reasonable, conservative configuration that will work on nearly all machine types that people might want to test with. If you have larger machines -- HBase has 8G and larger heap -- you might the following configuration options helpful. -TODO. +TODO. [[config.compression]] ==== Compression You should consider enabling ColumnFamily compression. -There are several options that are near-frictionless and in most all cases boost performance by reducing the size of StoreFiles and thus reducing I/O. +There are several options that are near-frictionless and in most all cases boost performance by reducing the size of StoreFiles and thus reducing I/O. See <> for more information. @@ -812,11 +808,11 @@ See <> for more information. ==== Configuring the size and number of WAL files HBase uses <> to recover the memstore data that has not been flushed to disk in case of an RS failure. -These WAL files should be configured to be slightly smaller than HDFS block (by default, HDFS block is 64Mb and WAL file is ~60Mb). +These WAL files should be configured to be slightly smaller than HDFS block (by default a HDFS block is 64Mb and a WAL file is ~60Mb). -HBase also has a limit on number of WAL files, designed to ensure there's never too much data that needs to be replayed during recovery. +HBase also has a limit on the number of WAL files, designed to ensure there's never too much data that needs to be replayed during recovery. This limit needs to be set according to memstore configuration, so that all the necessary data would fit. -It is recommended to allocated enough WAL files to store at least that much data (when all memstores are close to full). For example, with 16Gb RS heap, default memstore settings (0.4), and default WAL file size (~60Mb), 16Gb*0.4/60, the starting point for WAL file count is ~109. +It is recommended to allocate enough WAL files to store at least that much data (when all memstores are close to full). For example, with 16Gb RS heap, default memstore settings (0.4), and default WAL file size (~60Mb), 16Gb*0.4/60, the starting point for WAL file count is ~109. However, as all memstores are not expected to be full all the time, less WAL files can be allocated. [[disable.splitting]] @@ -832,7 +828,7 @@ Instead of allowing HBase to split your regions automatically, you can choose to This feature was added in HBase 0.90.0. Manually managing splits works if you know your keyspace well, otherwise let HBase figure where to split for you. Manual splitting can mitigate region creation and movement under load. -It also makes it so region boundaries are known and invariant (if you disable region splitting). If you use manual splits, it is easier doing staggered, time-based major compactions spread out your network IO load. +It also makes it so region boundaries are known and invariant (if you disable region splitting). If you use manual splits, it is easier doing staggered, time-based major compactions to spread out your network IO load. .Disable Automatic Splitting To disable automatic splitting, set `hbase.hregion.max.filesize` to a very large value, such as `100 GB` It is not recommended to set it to its absolute maximum value of `Long.MAX_VALUE`. @@ -871,8 +867,7 @@ See the entry for `hbase.hregion.majorcompaction` in the <> @@ -881,7 +876,7 @@ For more information about compactions and the compaction file selection process ==== Speculative Execution Speculative Execution of MapReduce tasks is on by default, and for HBase clusters it is generally advised to turn off Speculative Execution at a system-level unless you need it for a specific case, where it can be configured per-job. -Set the properties `mapreduce.map.speculative` and `mapreduce.reduce.speculative` to false. +Set the properties `mapreduce.map.speculative` and `mapreduce.reduce.speculative` to false. [[other_configuration]] === Other Configurations @@ -890,98 +885,97 @@ Set the properties `mapreduce.map.speculative` and `mapreduce.reduce.speculative ==== Balancer The balancer is a periodic operation which is run on the master to redistribute regions on the cluster. -It is configured via `hbase.balancer.period` and defaults to 300000 (5 minutes). +It is configured via `hbase.balancer.period` and defaults to 300000 (5 minutes). -See <> for more information on the LoadBalancer. +See <> for more information on the LoadBalancer. [[disabling.blockcache]] ==== Disabling Blockcache -Do not turn off block cache (You'd do it by setting `hbase.block.cache.size` to zero). Currently we do not do well if you do this because the regionserver will spend all its time loading hfile indices over and over again. -If your working set it such that block cache does you no good, at least size the block cache such that hfile indices will stay up in the cache (you can get a rough idea on the size you need by surveying regionserver UIs; you'll see index block size accounted near the top of the webpage). +Do not turn off block cache (You'd do it by setting `hbase.block.cache.size` to zero). Currently we do not do well if you do this because the RegionServer will spend all its time loading HFile indices over and over again. +If your working set it such that block cache does you no good, at least size the block cache such that HFile indices will stay up in the cache (you can get a rough idea on the size you need by surveying RegionServer UIs; you'll see index block size accounted near the top of the webpage). [[nagles]] ==== link:http://en.wikipedia.org/wiki/Nagle's_algorithm[Nagle's] or the small package problem If a big 40ms or so occasional delay is seen in operations against HBase, try the Nagles' setting. -For example, see the user mailing list thread, link:http://search-hadoop.com/m/pduLg2fydtE/Inconsistent+scan+performance+with+caching+set+&subj=Re+Inconsistent+scan+performance+with+caching+set+to+1[Inconsistent scan performance with caching set to 1] and the issue cited therein where setting notcpdelay improved scan speeds. -You might also see the graphs on the tail of link:https://issues.apache.org/jira/browse/HBASE-7008[HBASE-7008 Set scanner caching to a better default] where our Lars Hofhansl tries various data sizes w/ Nagle's on and off measuring the effect. +For example, see the user mailing list thread, link:http://search-hadoop.com/m/pduLg2fydtE/Inconsistent+scan+performance+with+caching+set+&subj=Re+Inconsistent+scan+performance+with+caching+set+to+1[Inconsistent scan performance with caching set to 1] and the issue cited therein where setting `notcpdelay` improved scan speeds. +You might also see the graphs on the tail of link:https://issues.apache.org/jira/browse/HBASE-7008[HBASE-7008 Set scanner caching to a better default] where our Lars Hofhansl tries various data sizes w/ Nagle's on and off measuring the effect. [[mttr]] ==== Better Mean Time to Recover (MTTR) This section is about configurations that will make servers come back faster after a fail. -See the Deveraj Das an Nicolas Liochon blog post link:http://hortonworks.com/blog/introduction-to-hbase-mean-time-to-recover-mttr/[Introduction to HBase Mean Time to Recover (MTTR)] for a brief introduction. +See the Deveraj Das an Nicolas Liochon blog post link:http://hortonworks.com/blog/introduction-to-hbase-mean-time-to-recover-mttr/[Introduction to HBase Mean Time to Recover (MTTR)] for a brief introduction. -The issue link:https://issues.apache.org/jira/browse/HBASE-8389[HBASE-8354 forces Namenode into loop with lease recovery requests] is messy but has a bunch of good discussion toward the end on low timeouts and how to effect faster recovery including citation of fixes added to HDFS. -Read the Varun Sharma comments. +The issue link:https://issues.apache.org/jira/browse/HBASE-8389[HBASE-8354 forces Namenode into loop with lease recovery requests] is messy but has a bunch of good discussion toward the end on low timeouts and how to effect faster recovery including citation of fixes added to HDFS. Read the Varun Sharma comments. The below suggested configurations are Varun's suggestions distilled and tested. Make sure you are running on a late-version HDFS so you have the fixes he refers too and himself adds to HDFS that help HBase MTTR (e.g. -HDFS-3703, HDFS-3712, and HDFS-4791 -- hadoop 2 for sure has them and late hadoop 1 has some). Set the following in the RegionServer. +HDFS-3703, HDFS-3712, and HDFS-4791 -- Hadoop 2 for sure has them and late Hadoop 1 has some). Set the following in the RegionServer. [source,xml] ---- - hbase.lease.recovery.dfs.timeout - 23000 - How much time we allow elapse between calls to recover lease. - Should be larger than the dfs timeout. + hbase.lease.recovery.dfs.timeout + 23000 + How much time we allow elapse between calls to recover lease. + Should be larger than the dfs timeout. - dfs.client.socket-timeout - 10000 - Down the DFS timeout from 60 to 10 seconds. + dfs.client.socket-timeout + 10000 + Down the DFS timeout from 60 to 10 seconds. ---- -And on the namenode/datanode side, set the following to enable 'staleness' introduced in HDFS-3703, HDFS-3912. +And on the NameNode/DataNode side, set the following to enable 'staleness' introduced in HDFS-3703, HDFS-3912. [source,xml] ---- - dfs.client.socket-timeout - 10000 - Down the DFS timeout from 60 to 10 seconds. + dfs.client.socket-timeout + 10000 + Down the DFS timeout from 60 to 10 seconds. - dfs.datanode.socket.write.timeout - 10000 - Down the DFS timeout from 8 * 60 to 10 seconds. + dfs.datanode.socket.write.timeout + 10000 + Down the DFS timeout from 8 * 60 to 10 seconds. - ipc.client.connect.timeout - 3000 - Down from 60 seconds to 3. + ipc.client.connect.timeout + 3000 + Down from 60 seconds to 3. - ipc.client.connect.max.retries.on.timeouts - 2 - Down from 45 seconds to 3 (2 == 3 retries). + ipc.client.connect.max.retries.on.timeouts + 2 + Down from 45 seconds to 3 (2 == 3 retries). - dfs.namenode.avoid.read.stale.datanode - true - Enable stale state in hdfs + dfs.namenode.avoid.read.stale.datanode + true + Enable stale state in hdfs - dfs.namenode.stale.datanode.interval - 20000 - Down from default 30 seconds + dfs.namenode.stale.datanode.interval + 20000 + Down from default 30 seconds - dfs.namenode.avoid.write.stale.datanode - true - Enable stale state in hdfs + dfs.namenode.avoid.write.stale.datanode + true + Enable stale state in hdfs ---- [[jmx_config]] ==== JMX -JMX(Java Management Extensions) provides built-in instrumentation that enables you to monitor and manage the Java VM. -To enable monitoring and management from remote systems, you need to set system property com.sun.management.jmxremote.port(the port number through which you want to enable JMX RMI connections) when you start the Java VM. -See link:http://docs.oracle.com/javase/6/docs/technotes/guides/management/agent.html[official document] for more information. -Historically, besides above port mentioned, JMX opens 2 additional random TCP listening ports, which could lead to port conflict problem.(See link:https://issues.apache.org/jira/browse/HBASE-10289[HBASE-10289] for details) +JMX (Java Management Extensions) provides built-in instrumentation that enables you to monitor and manage the Java VM. +To enable monitoring and management from remote systems, you need to set system property `com.sun.management.jmxremote.port` (the port number through which you want to enable JMX RMI connections) when you start the Java VM. +See the link:http://docs.oracle.com/javase/6/docs/technotes/guides/management/agent.html[official documentation] for more information. +Historically, besides above port mentioned, JMX opens two additional random TCP listening ports, which could lead to port conflict problem. (See link:https://issues.apache.org/jira/browse/HBASE-10289[HBASE-10289] for details) As an alternative, You can use the coprocessor-based JMX implementation provided by HBase. To enable it in 0.99 or above, add below property in _hbase-site.xml_: @@ -989,31 +983,31 @@ To enable it in 0.99 or above, add below property in _hbase-site.xml_: [source,xml] ---- - hbase.coprocessor.regionserver.classes - org.apache.hadoop.hbase.JMXListener + hbase.coprocessor.regionserver.classes + org.apache.hadoop.hbase.JMXListener ----- +---- -NOTE: DO NOT set com.sun.management.jmxremote.port for Java VM at the same time. +NOTE: DO NOT set `com.sun.management.jmxremote.port` for Java VM at the same time. Currently it supports Master and RegionServer Java VM. The reason why you only configure coprocessor for 'regionserver' is that, starting from HBase 0.99, a Master IS also a RegionServer. -(See link:https://issues.apache.org/jira/browse/HBASE-10569[HBASE-10569] for more information.) By default, the JMX listens on TCP port 10102, you can further configure the port using below properties: +(See link:https://issues.apache.org/jira/browse/HBASE-10569[HBASE-10569] for more information.) By default, the JMX listens on TCP port 10102, you can further configure the port using below properties: [source,xml] ---- - regionserver.rmi.registry.port - 61130 + regionserver.rmi.registry.port + 61130 - regionserver.rmi.connector.port - 61140 + regionserver.rmi.connector.port + 61140 ----- +---- The registry port can be shared with connector port in most cases, so you only need to configure regionserver.rmi.registry.port. -However if you want to use SSL communication, the 2 ports must be configured to different values. +However if you want to use SSL communication, the 2 ports must be configured to different values. By default the password authentication and SSL communication is disabled. To enable password authentication, you need to update _hbase-env.sh_ like below: @@ -1025,11 +1019,11 @@ export HBASE_JMX_BASE="-Dcom.sun.management.jmxremote.authenticate=true export HBASE_MASTER_OPTS="$HBASE_MASTER_OPTS $HBASE_JMX_BASE " export HBASE_REGIONSERVER_OPTS="$HBASE_REGIONSERVER_OPTS $HBASE_JMX_BASE " ----- +---- -See example password/access file under $JRE_HOME/lib/management. +See example password/access file under _$JRE_HOME/lib/management_. -To enable SSL communication with password authentication, follow below steps: +To enable SSL communication with password authentication, follow below steps: [source,bash] ---- @@ -1041,7 +1035,7 @@ keytool -export -alias jconsole -keystore myKeyStore -file jconsole.cert #3. copy jconsole.cert to jconsole client machine, import it to jconsoleKeyStore keytool -import -alias jconsole -keystore jconsoleKeyStore -file jconsole.cert ----- +---- And then update _hbase-env.sh_ like below: @@ -1056,36 +1050,36 @@ export HBASE_JMX_BASE="-Dcom.sun.management.jmxremote.ssl=true export HBASE_MASTER_OPTS="$HBASE_MASTER_OPTS $HBASE_JMX_BASE " export HBASE_REGIONSERVER_OPTS="$HBASE_REGIONSERVER_OPTS $HBASE_JMX_BASE " ----- +---- -Finally start jconsole on client using the key store: +Finally start `jconsole` on the client using the key store: [source,bash] ---- jconsole -J-Djavax.net.ssl.trustStore=/home/tianq/jconsoleKeyStore ----- +---- NOTE: for HBase 0.98, To enable the HBase JMX implementation on Master, you also need to add below property in _hbase-site.xml_: [source,xml] ---- - hbase.coprocessor.master.classes - org.apache.hadoop.hbase.JMXListener + hbase.coprocessor.master.classes + org.apache.hadoop.hbase.JMXListener ----- +---- -The corresponding properties for port configuration are master.rmi.registry.port (by default 10101) and master.rmi.connector.port(by default the same as registry.port) +The corresponding properties for port configuration are `master.rmi.registry.port` (by default 10101) and `master.rmi.connector.port` (by default the same as registry.port) [[dyn_config]] == Dynamic Configuration Since HBase 1.0.0, it is possible to change a subset of the configuration without requiring a server restart. -In the hbase shell, there are new operators, +update_config+ and +update_all_config+ that will prompt a server or all servers to reload configuration. +In the HBase shell, there are new operators, `update_config` and `update_all_config` that will prompt a server or all servers to reload configuration. Only a subset of all configurations can currently be changed in the running server. -Here is an incomplete list: +hbase.regionserver.thread.compaction.large+, +hbase.regionserver.thread.compaction.small+, +hbase.regionserver.thread.split+, +hbase.regionserver.thread.merge+, as well as compaction policy and configurations and adjustment to offpeak hours. -For the full list consult the patch attached to link:https://issues.apache.org/jira/browse/HBASE-12147[HBASE-12147 Porting Online Config Change from 89-fb]. +Here is an incomplete list: `hbase.regionserver.thread.compaction.large`, `hbase.regionserver.thread.compaction.small`, `hbase.regionserver.thread.split`, `hbase.regionserver.thread.merge`, as well as compaction policy and configurations and adjustment to offpeak hours. +For the full list consult the patch attached to link:https://issues.apache.org/jira/browse/HBASE-12147[HBASE-12147 Porting Online Config Change from 89-fb]. ifdef::backend-docbook[] [index] diff --git a/src/main/asciidoc/_chapters/cp.adoc b/src/main/asciidoc/_chapters/cp.adoc index 96f1c2fd13f..a99e903c3ee 100644 --- a/src/main/asciidoc/_chapters/cp.adoc +++ b/src/main/asciidoc/_chapters/cp.adoc @@ -27,30 +27,32 @@ :icons: font :experimental: -HBase coprocessors are modeled after the coprocessors which are part of Google's BigTable (link:http://www.scribd.com/doc/21631448/Dean-Keynote-Ladis2009, pages 66-67.). Coprocessors function in a similar way to Linux kernel modules. +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. They provide a way to run server-level code against locally-stored data. 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. -The information in this chapter is primarily sourced and heavily reused from Mingjie Lai's blog post at link:https://blogs.apache.org/hbase/entry/coprocessor_introduction. +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. Coprocessors are not designed to be used by end users of HBase, but by HBase developers who need to add specialized functionality to HBase. -One example of the use of coprocessors is pluggable compaction and scan policies, which are provided as coprocessors in link:HBASE-6427. +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]. == Coprocessor Framework The implementation of HBase coprocessors diverges from the BigTable implementation. -The HBase framework provides a library and runtime environment for executing user code within the HBase region server and master processes. +The HBase framework provides a library and runtime environment for executing user code within the HBase region server and master processes. -The framework API is provided in the link:https://hbase.apache.org/apidocs/org/apache/hadoop/hbase/coprocessor/package-summary.html[coprocessor] package. +The framework API is provided in the link:https://hbase.apache.org/apidocs/org/apache/hadoop/hbase/coprocessor/package-summary.html[coprocessor] package. Two different types of coprocessors are provided by the framework, based on their scope. -.Types of CoprocessorsSystem Coprocessors:: +.Types of Coprocessors + +System Coprocessors:: System coprocessors are loaded globally on all tables and regions hosted by a region server. Table Coprocessors:: You can specify which coprocessors should be loaded on all regions for a table on a per-table basis. -The framework provides two different aspects of extensions as well: [firstterm]_observers_ and [firstterm]_endpoints_. +The framework provides two different aspects of extensions as well: _observers_ and _endpoints_. Observers:: Observers are analogous to triggers in conventional databases. @@ -80,7 +82,7 @@ You can load the coprocessor from your HBase configuration, so that the coproces === Load from Configuration -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: +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: * `hbase.coprocessor.region.classes`for RegionObservers and Endpoints * `hbase.coprocessor.wal.classes`for WALObservers @@ -90,12 +92,12 @@ To configure a coprocessor to be loaded when HBase starts, modify the RegionServ ==== In this example, one RegionObserver is configured for all the HBase tables. +[source,xml] ---- - - hbase.coprocessor.region.classes - org.apache.hadoop.hbase.coprocessor.AggregateImplementation - + hbase.coprocessor.region.classes + org.apache.hadoop.hbase.coprocessor.AggregateImplementation + ---- ==== @@ -106,7 +108,7 @@ Therefore, the jar file must reside on the server-side HBase classpath. Coprocessors which are loaded in this way will be active on all regions of all tables. These are the system coprocessor introduced earlier. The first listed coprocessors will be assigned the priority `Coprocessor.Priority.SYSTEM`. -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). +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). When calling out to registered observers, the framework executes their callbacks methods in the sorted order of their priority. Ties are broken arbitrarily. @@ -114,13 +116,12 @@ Ties are broken arbitrarily. === Load from the HBase Shell You can load a coprocessor on a specific table via a table attribute. -The following example will load the [systemitem]+FooRegionObserver+ observer when table [systemitem]+t1+ is read or re-read. +The following example will load the `FooRegionObserver` observer when table `t1` is read or re-read. .Load a Coprocessor On a Table Using HBase Shell ==== ---- - -hbase(main):005:0> alter 't1', METHOD => 'table_att', +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. @@ -128,18 +129,18 @@ Done. 0 row(s) in 1.0730 seconds 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'}]} +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 ---- ==== @@ -160,7 +161,7 @@ The value contains four pieces of information which are separated by the `|` cha ==== ---- -hbase(main):007:0> alter 't1', METHOD => 'table_att_unset', +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. @@ -168,27 +169,27 @@ 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'}]} +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. +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. +To check the status of a coprocessor after it has been configured, use the `status` HBase Shell command. ---- @@ -200,17 +201,17 @@ master coprocessors: [] 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, + 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, + 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, + 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 ---- @@ -218,16 +219,12 @@ coprocessors=[AggregateImplementation] == 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 <> or the Web UI for a given Region Server, via the [label]#Coprocessor Metrics# tab. +You can see these statistics via the HBase Metrics framework (see <> 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 metrics sampling rate as described in <>. +The metrics sampling rate as described in <>. .Coprocessor Metrics UI image::coprocessor_stats.png[] - -== Status of Coprocessors in HBase - -Coprocessors and the coprocessor framework are evolving rapidly and work is ongoing on several different JIRAs. diff --git a/src/main/asciidoc/_chapters/datamodel.adoc b/src/main/asciidoc/_chapters/datamodel.adoc index 854d78492cc..91e6be8856e 100644 --- a/src/main/asciidoc/_chapters/datamodel.adoc +++ b/src/main/asciidoc/_chapters/datamodel.adoc @@ -32,6 +32,7 @@ This is a terminology overlap with relational databases (RDBMSs), but this is no Instead, it can be helpful to think of an HBase table as a multi-dimensional map. .HBase Data Model Terminology + Table:: An HBase table consists of multiple rows. @@ -67,26 +68,24 @@ Timestamp:: == Conceptual View You can read a very understandable explanation of the HBase data model in the blog post link:http://jimbojw.com/wiki/index.php?title=Understanding_Hbase_and_BigTable[Understanding HBase and BigTable] by Jim R. Wilson. - -Another good explanation is available in the PDF link:http://0b4af6cdc2f0c5998459-c0245c5c937c5dedcca3f1764ecc9b2f.r43.cf2.rackcdn.com/9353-login1210_khurana.pdf[Introduction -to Basic Schema Design] by Amandeep Khurana. +Another good explanation is available in the PDF link:http://0b4af6cdc2f0c5998459-c0245c5c937c5dedcca3f1764ecc9b2f.r43.cf2.rackcdn.com/9353-login1210_khurana.pdf[Introduction to Basic Schema Design] by Amandeep Khurana. It may help to read different perspectives to get a solid understanding of HBase schema design. The linked articles cover the same ground as the information in this section. The following example is a slightly modified form of the one on page 2 of the link:http://research.google.com/archive/bigtable.html[BigTable] paper. -There is a table called `webtable` that contains two rows (`com.cnn.www` and `com.example.www`), three column families named `contents`, `anchor`, and `people`. +There is a table called `webtable` that contains two rows (`com.cnn.www` and `com.example.www`) and three column families named `contents`, `anchor`, and `people`. In this example, for the first row (`com.cnn.www`), `anchor` contains two columns (`anchor:cssnsi.com`, `anchor:my.look.ca`) and `contents` contains one column (`contents:html`). This example contains 5 versions of the row with the row key `com.cnn.www`, and one version of the row with the row key `com.example.www`. The `contents:html` column qualifier contains the entire HTML of a given website. Qualifiers of the `anchor` column family each contain the external site which links to the site represented by the row, along with the text it used in the anchor of its link. -The `people` column family represents people associated with the site. +The `people` column family represents people associated with the site. .Column Names [NOTE] ==== By convention, a column name is made of its column family prefix and a _qualifier_. For example, the column _contents:html_ is made up of the column family `contents` and the `html` qualifier. -The colon character (`:`) delimits the column family from the column family _qualifier_. +The colon character (`:`) delimits the column family from the column family _qualifier_. ==== .Table `webtable` @@ -109,27 +108,27 @@ This is only a mock-up for illustrative purposes and may not be strictly accurat [source,json] ---- { - "com.cnn.www": { - contents: { - t6: contents:html: "..." - t5: contents:html: "..." - t3: contents:html: "..." - } - anchor: { - t9: anchor:cnnsi.com = "CNN" - t8: anchor:my.look.ca = "CNN.com" - } - people: {} - } - "com.example.www": { - contents: { - t5: contents:html: "..." - } - anchor: {} - people: { - t5: people:author: "John Doe" - } - } + "com.cnn.www": { + contents: { + t6: contents:html: "..." + t5: contents:html: "..." + t3: contents:html: "..." + } + anchor: { + t9: anchor:cnnsi.com = "CNN" + t8: anchor:my.look.ca = "CNN.com" + } + people: {} + } + "com.example.www": { + contents: { + t5: contents:html: "..." + } + anchor: {} + people: { + t5: people:author: "John Doe" + } + } } ---- @@ -163,18 +162,18 @@ Thus a request for the value of the `contents:html` column at time stamp `t8` wo Similarly, a request for an `anchor:my.look.ca` value at time stamp `t9` would return no value. However, if no timestamp is supplied, the most recent value for a particular column would be returned. Given multiple versions, the most recent is also the first one found, since timestamps are stored in descending order. -Thus a request for the values of all columns in the row `com.cnn.www` if no timestamp is specified would be: the value of `contents:html` from timestamp `t6`, the value of `anchor:cnnsi.com` from timestamp `t9`, the value of `anchor:my.look.ca` from timestamp `t8`. +Thus a request for the values of all columns in the row `com.cnn.www` if no timestamp is specified would be: the value of `contents:html` from timestamp `t6`, the value of `anchor:cnnsi.com` from timestamp `t9`, the value of `anchor:my.look.ca` from timestamp `t8`. -For more information about the internals of how Apache HBase stores data, see <>. +For more information about the internals of how Apache HBase stores data, see <>. == Namespace A namespace is a logical grouping of tables analogous to a database in relation database systems. -This abstraction lays the groundwork for upcoming multi-tenancy related features: +This abstraction lays the groundwork for upcoming multi-tenancy related features: -* Quota Management (HBASE-8410) - Restrict the amount of resources (ie regions, tables) a namespace can consume. -* Namespace Security Administration (HBASE-9206) - provide another level of security administration for tenants. -* Region server groups (HBASE-6721) - A namespace/table can be pinned onto a subset of regionservers thus guaranteeing a course level of isolation. +* Quota Management (link:https://issues.apache.org/jira/browse/HBASE-8410[HBASE-8410]) - Restrict the amount of resources (ie regions, tables) a namespace can consume. +* Namespace Security Administration (link:https://issues.apache.org/jira/browse/HBASE-9206[HBASE-9206]) - Provide another level of security administration for tenants. +* Region server groups (link:https://issues.apache.org/jira/browse/HBASE-6721[HBASE-6721]) - A namespace/table can be pinned onto a subset of RegionServers thus guaranteeing a course level of isolation. [[namespace_creation]] === Namespace management @@ -221,10 +220,10 @@ alter_namespace 'my_ns', {METHOD => 'set', 'PROPERTY_NAME' => 'PROPERTY_VALUE'} [[namespace_special]] === Predefined namespaces -There are two predefined special namespaces: +There are two predefined special namespaces: -* hbase - system namespace, used to contain hbase internal tables -* default - tables with no explicit specified namespace will automatically fall into this namespace. +* hbase - system namespace, used to contain HBase internal tables +* default - tables with no explicit specified namespace will automatically fall into this namespace .Examples ==== @@ -241,11 +240,11 @@ create 'bar', 'fam' == Table -Tables are declared up front at schema definition time. +Tables are declared up front at schema definition time. == Row -Row keys are uninterrpreted bytes. +Row keys are uninterpreted bytes. Rows are lexicographically sorted with the lowest order appearing first in a table. The empty byte array is used to denote both the start and end of a tables' namespace. @@ -255,8 +254,7 @@ The empty byte array is used to denote both the start and end of a tables' names Columns in Apache HBase are grouped into _column families_. All column members of a column family have the same prefix. For example, the columns _courses:history_ and _courses:math_ are both members of the _courses_ column family. -The colon character (`:`) delimits the column family from the -column family qualifier. +The colon character (`:`) delimits the column family from the column family qualifier. The column family prefix must be composed of _printable_ characters. The qualifying tail, the column family _qualifier_, can be made of any arbitrary bytes. Column families must be declared up front at schema definition time whereas columns do not need to be defined at schema time but can be conjured on the fly while the table is up an running. @@ -267,29 +265,26 @@ Because tunings and storage specifications are done at the column family level, == Cells A _{row, column, version}_ tuple exactly specifies a `cell` in HBase. -Cell content is uninterrpreted bytes +Cell content is uninterpreted bytes == Data Model Operations The four primary data model operations are Get, Put, Scan, and Delete. -Operations are applied via link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Table.html[Table] instances. +Operations are applied via link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Table.html[Table] instances. === Get -link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Get.html[Get] returns attributes for a specified row. -Gets are executed via link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Table.html#get(org.apache.hadoop.hbase.client.Get)[ - Table.get]. +link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Get.html[Get] returns attributes for a specified row. +Gets are executed via link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Table.html#get(org.apache.hadoop.hbase.client.Get)[Table.get]. === Put -link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Put.html[Put] either adds new rows to a table (if the key is new) or can update existing rows (if the key already exists). Puts are executed via link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Table.html#put(org.apache.hadoop.hbase.client.Put)[ - Table.put] (writeBuffer) or link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Table.html#batch(java.util.List, java.lang.Object[])[ - Table.batch] (non-writeBuffer). +link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Put.html[Put] either adds new rows to a table (if the key is new) or can update existing rows (if the key already exists). Puts are executed via link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Table.html#put(org.apache.hadoop.hbase.client.Put)[Table.put] (writeBuffer) or link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Table.html#batch(java.util.List, java.lang.Object[])[Table.batch] (non-writeBuffer). [[scan]] === Scans -link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Scan.html[Scan] allow iteration over multiple rows for specified attributes. +link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Scan.html[Scan] allow iteration over multiple rows for specified attributes. The following is an example of a Scan on a Table instance. Assume that a table is populated with rows with keys "row1", "row2", "row3", and then another set of rows with the keys "abc1", "abc2", and "abc3". The following example shows how to set a Scan instance to return the rows beginning with "row". @@ -309,23 +304,24 @@ scan.setRowPrefixFilter(Bytes.toBytes("row")); ResultScanner rs = table.getScanner(scan); try { for (Result r = rs.next(); r != null; r = rs.next()) { - // process result... + // process result... + } } finally { rs.close(); // always close the ResultScanner! +} ---- -Note that generally the easiest way to specify a specific stop point for a scan is by using the link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/filter/InclusiveStopFilter.html[InclusiveStopFilter] class. +Note that generally the easiest way to specify a specific stop point for a scan is by using the link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/filter/InclusiveStopFilter.html[InclusiveStopFilter] class. === Delete -link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Delete.html[Delete] removes a row from a table. -Deletes are executed via link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Table.html#delete(org.apache.hadoop.hbase.client.Delete)[ - HTable.delete]. +link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Delete.html[Delete] removes a row from a table. +Deletes are executed via link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Table.html#delete(org.apache.hadoop.hbase.client.Delete)[HTable.delete]. HBase does not modify data in place, and so deletes are handled by creating new markers called _tombstones_. -These tombstones, along with the dead values, are cleaned up on major compactions. +These tombstones, along with the dead values, are cleaned up on major compactions. -See <> for more information on deleting versions of columns, and see <> for more information on compactions. +See <> for more information on deleting versions of columns, and see <> for more information on compactions. [[versions]] == Versions @@ -345,20 +341,20 @@ In particular: * It is OK to write cells in a non-increasing version order. Below we describe how the version dimension in HBase currently works. -See link:https://issues.apache.org/jira/browse/HBASE-2406[HBASE-2406] for discussion of HBase versions. link:http://outerthought.org/blog/417-ot.html[Bending time in HBase] makes for a good read on the version, or time, dimension in HBase. +See link:https://issues.apache.org/jira/browse/HBASE-2406[HBASE-2406] for discussion of HBase versions. link:http://outerthought.org/blog/417-ot.html[Bending time in HBase] makes for a good read on the version, or time, dimension in HBase. It has more detail on versioning than is provided here. -As of this writing, the limiitation _Overwriting values at existing timestamps_ mentioned in the article no longer holds in HBase. +As of this writing, the limitation _Overwriting values at existing timestamps_ mentioned in the article no longer holds in HBase. This section is basically a synopsis of this article by Bruno Dumon. [[specify.number.of.versions]] === Specifying the Number of Versions to Store -The maximum number of versions to store for a given column is part of the column schema and is specified at table creation, or via an +alter+ command, via `HColumnDescriptor.DEFAULT_VERSIONS`. +The maximum number of versions to store for a given column is part of the column schema and is specified at table creation, or via an `alter` command, via `HColumnDescriptor.DEFAULT_VERSIONS`. Prior to HBase 0.96, the default number of versions kept was `3`, but in 0.96 and newer has been changed to `1`. -.Modify the Maximum Number of Versions for a Column +.Modify the Maximum Number of Versions for a Column Family ==== -This example uses HBase Shell to keep a maximum of 5 versions of column `f1`. +This example uses HBase Shell to keep a maximum of 5 versions of all columns in column family `f1`. You could also use link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/HColumnDescriptor.html[HColumnDescriptor]. ---- @@ -366,11 +362,11 @@ hbase> alter ‘t1′, NAME => ‘f1′, VERSIONS => 5 ---- ==== -.Modify the Minimum Number of Versions for a Column +.Modify the Minimum Number of Versions for a Column Family ==== -You can also specify the minimum number of versions to store. +You can also specify the minimum number of versions to store per column family. By default, this is set to 0, which means the feature is disabled. -The following example sets the minimum number of versions on field `f1` to `2`, via HBase Shell. +The following example sets the minimum number of versions on all columns in column family `f1` to `2`, via HBase Shell. You could also use link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/HColumnDescriptor.html[HColumnDescriptor]. ---- @@ -378,7 +374,7 @@ hbase> alter ‘t1′, NAME => ‘f1′, MIN_VERSIONS => 2 ---- ==== -Starting with HBase 0.98.2, you can specify a global default for the maximum number of versions kept for all newly-created columns, by setting +hbase.column.max.version+ in _hbase-site.xml_. +Starting with HBase 0.98.2, you can specify a global default for the maximum number of versions kept for all newly-created columns, by setting `hbase.column.max.version` in _hbase-site.xml_. See <>. [[versions.ops]] @@ -389,13 +385,12 @@ In this section we look at the behavior of the version dimension for each of the ==== Get/Scan Gets are implemented on top of Scans. -The below discussion of link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Get.html[Get] applies equally to link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Scan.html[Scans]. +The below discussion of link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Get.html[Get] applies equally to link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Scan.html[Scans]. -By default, i.e. -if you specify no explicit version, when doing a `get`, the cell whose version has the largest value is returned (which may or may not be the latest one written, see later). The default behavior can be modified in the following ways: +By default, i.e. if you specify no explicit version, when doing a `get`, the cell whose version has the largest value is returned (which may or may not be the latest one written, see later). The default behavior can be modified in the following ways: * to return more than one version, see link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Get.html#setMaxVersions()[Get.setMaxVersions()] -* to return versions other than the latest, see link:???[Get.setTimeRange()] +* to return versions other than the latest, see link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Get.html#setTimeRange(long,%20long)[Get.setTimeRange()] + To retrieve the latest version that is less than or equal to a given value, thus giving the 'latest' state of the record at a certain point in time, just use a range from 0 to the desired version and set the max versions to 1. @@ -438,7 +433,7 @@ Doing a put always creates a new version of a `cell`, at a certain timestamp. By default the system uses the server's `currentTimeMillis`, but you can specify the version (= the long integer) yourself, on a per-column level. This means you could assign a time in the past or the future, or use the long value for non-time purposes. -To overwrite an existing value, do a put at exactly the same row, column, and version as that of the cell you would overshadow. +To overwrite an existing value, do a put at exactly the same row, column, and version as that of the cell you want to overwrite. ===== Implicit Version Example @@ -471,42 +466,39 @@ put.add(CF, ATTR, explicitTimeInMs, Bytes.toBytes(data)); table.put(put); ---- -Caution: the version timestamp is internally by HBase for things like time-to-live calculations. +Caution: the version timestamp is used internally by HBase for things like time-to-live calculations. It's usually best to avoid setting this timestamp yourself. -Prefer using a separate timestamp attribute of the row, or have the timestamp a part of the rowkey, or both. +Prefer using a separate timestamp attribute of the row, or have the timestamp as a part of the row key, or both. [[version.delete]] ==== Delete There are three different types of internal delete markers. -See Lars Hofhansl's blog for discussion of his attempt adding another, link:http://hadoop-hbase.blogspot.com/2012/01/scanning-in-hbase.html[Scanning - in HBase: Prefix Delete Marker]. +See Lars Hofhansl's blog for discussion of his attempt adding another, link:http://hadoop-hbase.blogspot.com/2012/01/scanning-in-hbase.html[Scanning in HBase: Prefix Delete Marker]. * Delete: for a specific version of a column. * Delete column: for all versions of a column. * Delete family: for all columns of a particular ColumnFamily -When deleting an entire row, HBase will internally create a tombstone for each ColumnFamily (i.e., not each individual column). +When deleting an entire row, HBase will internally create a tombstone for each ColumnFamily (i.e., not each individual column). Deletes work by creating _tombstone_ markers. For example, let's suppose we want to delete a row. For this you can specify a version, or else by default the `currentTimeMillis` is used. -What this means is [quote]_delete all - cells where the version is less than or equal to this version_. +What this means is _delete all cells where the version is less than or equal to this version_. HBase never modifies data in place, so for example a delete will not immediately delete (or mark as deleted) the entries in the storage file that correspond to the delete condition. Rather, a so-called _tombstone_ is written, which will mask the deleted values. When HBase does a major compaction, the tombstones are processed to actually remove the dead values, together with the tombstones themselves. If the version you specified when deleting a row is larger than the version of any value in the row, then you can consider the complete row to be deleted. -For an informative discussion on how deletes and versioning interact, see the thread link:http://comments.gmane.org/gmane.comp.java.hadoop.hbase.user/28421[Put w/ - timestamp -> Deleteall -> Put w/ timestamp fails] up on the user mailing list. +For an informative discussion on how deletes and versioning interact, see the thread link:http://comments.gmane.org/gmane.comp.java.hadoop.hbase.user/28421[Put w/timestamp -> Deleteall -> Put w/ timestamp fails] up on the user mailing list. -Also see <> for more information on the internal KeyValue format. +Also see <> for more information on the internal KeyValue format. -Delete markers are purged during the next major compaction of the store, unless the +KEEP_DELETED_CELLS+ option is set in the column family. +Delete markers are purged during the next major compaction of the store, unless the `KEEP_DELETED_CELLS` option is set in the column family. To keep the deletes for a configurable amount of time, you can set the delete TTL via the +hbase.hstore.time.to.purge.deletes+ property in _hbase-site.xml_. -If +hbase.hstore.time.to.purge.deletes+ is not set, or set to 0, all delete markers, including those with timestamps in the future, are purged during the next major compaction. -Otherwise, a delete marker with a timestamp in the future is kept until the major compaction which occurs after the time represented by the marker's timestamp plus the value of +hbase.hstore.time.to.purge.deletes+, in milliseconds. +If `hbase.hstore.time.to.purge.deletes` is not set, or set to 0, all delete markers, including those with timestamps in the future, are purged during the next major compaction. +Otherwise, a delete marker with a timestamp in the future is kept until the major compaction which occurs after the time represented by the marker's timestamp plus the value of `hbase.hstore.time.to.purge.deletes`, in milliseconds. NOTE: This behavior represents a fix for an unexpected change that was introduced in HBase 0.94, and was fixed in link:https://issues.apache.org/jira/browse/HBASE-10118[HBASE-10118]. The change has been backported to HBase 0.94 and newer branches. @@ -529,35 +521,34 @@ But they can occur even if you do not care about time: just do delete and put im [[major.compactions.change.query.results]] ==== Major compactions change query results -[quote]_...create three cell versions at t1, t2 and t3, with a maximum-versions - setting of 2. So when getting all versions, only the values at t2 and t3 will be - returned. But if you delete the version at t2 or t3, the one at t1 will appear again. - Obviously, once a major compaction has run, such behavior will not be the case - anymore..._ (See _Garbage Collection_ in link:http://outerthought.org/blog/417-ot.html[Bending time in - HBase].) +_...create three cell versions at t1, t2 and t3, with a maximum-versions + setting of 2. So when getting all versions, only the values at t2 and t3 will be + returned. But if you delete the version at t2 or t3, the one at t1 will appear again. + Obviously, once a major compaction has run, such behavior will not be the case + anymore..._ (See _Garbage Collection_ in link:http://outerthought.org/blog/417-ot.html[Bending time in HBase].) [[dm.sort]] == Sort Order All data model operations HBase return data in sorted order. -First by row, then by ColumnFamily, followed by column qualifier, and finally timestamp (sorted in reverse, so newest records are returned first). +First by row, then by ColumnFamily, followed by column qualifier, and finally timestamp (sorted in reverse, so newest records are returned first). [[dm.column.metadata]] == Column Metadata There is no store of column metadata outside of the internal KeyValue instances for a ColumnFamily. -Thus, while HBase can support not only a wide number of columns per row, but a heterogenous set of columns between rows as well, it is your responsibility to keep track of the column names. +Thus, while HBase can support not only a wide number of columns per row, but a heterogeneous set of columns between rows as well, it is your responsibility to keep track of the column names. The only way to get a complete set of columns that exist for a ColumnFamily is to process all the rows. -For more information about how HBase stores data internally, see <>. +For more information about how HBase stores data internally, see <>. == Joins -Whether HBase supports joins is a common question on the dist-list, and there is a simple answer: it doesn't, at not least in the way that RDBMS' support them (e.g., with equi-joins or outer-joins in SQL). As has been illustrated in this chapter, the read data model operations in HBase are Get and Scan. +Whether HBase supports joins is a common question on the dist-list, and there is a simple answer: it doesn't, at not least in the way that RDBMS' support them (e.g., with equi-joins or outer-joins in SQL). As has been illustrated in this chapter, the read data model operations in HBase are Get and Scan. However, that doesn't mean that equivalent join functionality can't be supported in your application, but you have to do it yourself. The two primary strategies are either denormalizing the data upon writing to HBase, or to have lookup tables and do the join between HBase tables in your application or MapReduce code (and as RDBMS' demonstrate, there are several strategies for this depending on the size of the tables, e.g., nested loops vs. -hash-joins). So which is the best approach? It depends on what you are trying to do, and as such there isn't a single answer that works for every use case. +hash-joins). So which is the best approach? It depends on what you are trying to do, and as such there isn't a single answer that works for every use case. == ACID diff --git a/src/main/asciidoc/_chapters/external_apis.adoc b/src/main/asciidoc/_chapters/external_apis.adoc index dfc64e33d18..37156ca035f 100644 --- a/src/main/asciidoc/_chapters/external_apis.adoc +++ b/src/main/asciidoc/_chapters/external_apis.adoc @@ -28,39 +28,39 @@ :experimental: This chapter will cover access to Apache HBase either through non-Java languages, or through custom protocols. -For information on using the native HBase APIs, refer to link:http://hbase.apache.org/apidocs/index.html[User API Reference] and the new <> chapter. +For information on using the native HBase APIs, refer to link:http://hbase.apache.org/apidocs/index.html[User API Reference] and the new <> chapter. [[nonjava.jvm]] == Non-Java Languages Talking to the JVM -Currently the documentation on this topic in the link:http://wiki.apache.org/hadoop/Hbase[Apache HBase Wiki]. -See also the link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/thrift/package-summary.html#package_description[Thrift API Javadoc]. +Currently the documentation on this topic is in the link:http://wiki.apache.org/hadoop/Hbase[Apache HBase Wiki]. +See also the link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/thrift/package-summary.html#package_description[Thrift API Javadoc]. == REST -Currently most of the documentation on REST exists in the link:http://wiki.apache.org/hadoop/Hbase/Stargate[Apache HBase Wiki on REST] (The REST gateway used to be called 'Stargate'). There are also a nice set of blogs on link:http://blog.cloudera.com/blog/2013/03/how-to-use-the-apache-hbase-rest-interface-part-1/[How-to: Use the Apache HBase REST Interface] by Jesse Anderson. +Currently most of the documentation on REST exists in the link:http://wiki.apache.org/hadoop/Hbase/Stargate[Apache HBase Wiki on REST] (The REST gateway used to be called 'Stargate'). There are also a nice set of blogs on link:http://blog.cloudera.com/blog/2013/03/how-to-use-the-apache-hbase-rest-interface-part-1/[How-to: Use the Apache HBase REST Interface] by Jesse Anderson. + +To run your REST server under SSL, set `hbase.rest.ssl.enabled` to `true` and also set the following configs when you launch the REST server: (See example commands in <>) -To run your REST server under SSL, set hbase.rest.ssl.enabled to true and also set the following configs when you launch the REST server:(See example commands in <>) [source] ---- - hbase.rest.ssl.keystore.store hbase.rest.ssl.keystore.password hbase.rest.ssl.keystore.keypassword ----- +---- HBase ships a simple REST client, see link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/rest/client/package-summary.html[REST client] package for details. -To enable SSL support for it, please also import your certificate into local java cacerts keystore: +To enable SSL support for it, please also import your certificate into local java cacerts keystore: ---- keytool -import -trustcacerts -file /home/user/restserver.cert -keystore $JAVA_HOME/jre/lib/security/cacerts ----- +---- == Thrift -Documentation about Thrift has moved to <>. +Documentation about Thrift has moved to <>. [[c]] == C/C++ Apache HBase Client FB's Chip Turner wrote a pure C/C++ client. - link:https://github.com/facebook/native-cpp-hbase-client[Check it out]. +link:https://github.com/facebook/native-cpp-hbase-client[Check it out]. diff --git a/src/main/asciidoc/_chapters/getting_started.adoc b/src/main/asciidoc/_chapters/getting_started.adoc index 9e0b5a116d3..d20ddd7a44e 100644 --- a/src/main/asciidoc/_chapters/getting_started.adoc +++ b/src/main/asciidoc/_chapters/getting_started.adoc @@ -28,30 +28,31 @@ == Introduction -<> will get you up and running on a single-node, standalone instance of HBase, followed by a pseudo-distributed single-machine instance, and finally a fully-distributed cluster. +<> will get you up and running on a single-node, standalone instance of HBase, followed by a pseudo-distributed single-machine instance, and finally a fully-distributed cluster. [[quickstart]] -== Quick Start +== Quick Start - Standalone HBase -This guide describes setup of a standalone HBase instance running against the local filesystem. +This guide describes the setup of a standalone HBase instance running against the local filesystem. This is not an appropriate configuration for a production instance of HBase, but will allow you to experiment with HBase. -This section shows you how to create a table in HBase using the +hbase shell+ CLI, insert rows into the table, perform put and scan operations against the table, enable or disable the table, and start and stop HBase. +This section shows you how to create a table in HBase using the `hbase shell` CLI, insert rows into the table, perform put and scan operations against the table, enable or disable the table, and start and stop HBase. Apart from downloading HBase, this procedure should take less than 10 minutes. -WARNING: Local Filesystem and Durability This is fixed in HBase 0.98.3 and beyond. See link:https://issues.apache.org/jira/browse/HBASE-11272[HBASE-11272] and link:https://issues.apache.org/jira/browse/HBASE-11218[HBASE-11218]._ +.Local Filesystem and Durability +WARNING: _The following is fixed in HBase 0.98.3 and beyond. See link:https://issues.apache.org/jira/browse/HBASE-11272[HBASE-11272] and link:https://issues.apache.org/jira/browse/HBASE-11218[HBASE-11218]._ Using HBase with a local filesystem does not guarantee durability. The HDFS local filesystem implementation will lose edits if files are not properly closed. This is very likely to happen when you are experimenting with new software, starting and stopping the daemons often and not always cleanly. You need to run HBase on HDFS to ensure all writes are preserved. Running against the local filesystem is intended as a shortcut to get you familiar with how the general system works, as the very first phase of evaluation. -See link:https://issues.apache.org/jira/browse/HBASE-3696 and its associated issues for more details about the issues of running on the local filesystem. +See link:https://issues.apache.org/jira/browse/HBASE-3696[HBASE-3696] and its associated issues for more details about the issues of running on the local filesystem. +[[loopback.ip]] .Loopback IP - HBase 0.94.x and earlier - NOTE: _The below advice is for hbase-0.94.x and older versions only. This is fixed in hbase-0.96.0 and beyond._ -Prior to HBase 0.94.x, HBase expected the loopback IP address to be 127.0.0.1. Ubuntu and some other distributions default to 127.0.1.1 and this will cause problems for you . See link:http://blog.devving.com/why-does-hbase-care-about-etchosts/[Why does HBase care about /etc/hosts?] for detail. +Prior to HBase 0.94.x, HBase expected the loopback IP address to be 127.0.0.1. Ubuntu and some other distributions default to 127.0.1.1 and this will cause problems for you. .Example /etc/hosts File for Ubuntu @@ -69,7 +70,7 @@ The following _/etc/hosts_ file works correctly for HBase 0.94.x and earlier, on === JDK Version Requirements HBase requires that a JDK be installed. -See <> for information about supported JDK versions. +See <> for information about supported JDK versions. === Get Started with HBase @@ -86,11 +87,11 @@ See <> for information about supported JDK versions. + ---- -$ tar xzvf hbase--hadoop2-bin.tar.gz +$ tar xzvf hbase--hadoop2-bin.tar.gz $ cd hbase--hadoop2/ ---- -. For HBase 0.98.5 and later, you are required to set the `JAVA_HOME` environment variable before starting HBase. +. For HBase 0.98.5 and later, you are required to set the `JAVA_HOME` environment variable before starting HBase. Prior to 0.98.5, HBase attempted to detect the location of Java if the variables was not set. You can set the variable via your operating system's usual mechanism, but HBase provides a central mechanism, _conf/hbase-env.sh_. Edit this file, uncomment the line starting with `JAVA_HOME`, and set it to the appropriate location for your operating system. @@ -103,14 +104,14 @@ JAVA_HOME=/usr ---- + NOTE: These instructions assume that each node of your cluster uses the same configuration. -If this is not the case, you may need to set `JAVA_HOME` separately for each node. +If this is not the case, you may need to set `JAVA_HOME` separately for each node. . Edit _conf/hbase-site.xml_, which is the main HBase configuration file. - At this time, you only need to specify the directory on the local filesystem where HBase and Zookeeper write data. + At this time, you only need to specify the directory on the local filesystem where HBase and ZooKeeper write data. By default, a new directory is created under /tmp. - Many servers are configured to delete the contents of /tmp upon reboot, so you should store the data elsewhere. - The following configuration will store HBase's data in the _hbase_ directory, in the home directory of the user called [systemitem]+testuser+. - Paste the [markup]++ tags beneath the [markup]++ tags, which should be empty in a new HBase install. + Many servers are configured to delete the contents of _/tmp_ upon reboot, so you should store the data elsewhere. + The following configuration will store HBase's data in the _hbase_ directory, in the home directory of the user called `testuser`. + Paste the `` tags beneath the `` tags, which should be empty in a new HBase install. + .Example _hbase-site.xml_ for Standalone HBase ==== @@ -136,7 +137,7 @@ If you create the directory, HBase will attempt to do a migration, which is not . The _bin/start-hbase.sh_ script is provided as a convenient way to start HBase. Issue the command, and if all goes well, a message is logged to standard output showing that HBase started successfully. - You can use the +jps+ command to verify that you have one running process called `HMaster`. + You can use the `jps` command to verify that you have one running process called `HMaster`. In standalone mode HBase runs all daemons within this single JVM, i.e. the HMaster, a single HRegionServer, and the ZooKeeper daemon. + @@ -144,10 +145,11 @@ NOTE: Java needs to be installed and available. If you get an error indicating that Java is not installed, but it is on your system, perhaps in a non-standard location, edit the _conf/hbase-env.sh_ file and modify the `JAVA_HOME` setting to point to the directory that contains _bin/java_ your system. +[[shell_exercises]] .Procedure: Use HBase For the First Time . Connect to HBase. + -Connect to your running instance of HBase using the +hbase shell+ command, located in the _bin/_ directory of your HBase install. +Connect to your running instance of HBase using the `hbase shell` command, located in the [path]_bin/_ directory of your HBase install. In this example, some usage and version information that is printed when you start HBase Shell has been omitted. The HBase Shell prompt ends with a `>` character. + @@ -168,21 +170,21 @@ Use the `create` command to create a new table. You must specify the table name and the ColumnFamily name. + ---- +hbase(main):001:0> create 'test', 'cf' +0 row(s) in 0.4170 seconds -hbase> create 'test', 'cf' -0 row(s) in 1.2200 seconds +=> Hbase::Table - test ---- . List Information About your Table + -Use the `list` command to +Use the `list` command to + ---- - -hbase> list 'test' +hbase(main):002:0> list 'test' TABLE test -1 row(s) in 0.0350 seconds +1 row(s) in 0.0180 seconds => ["test"] ---- @@ -192,15 +194,14 @@ test To put data into your table, use the `put` command. + ---- +hbase(main):003:0> put 'test', 'row1', 'cf:a', 'value1' +0 row(s) in 0.0850 seconds -hbase> put 'test', 'row1', 'cf:a', 'value1' -0 row(s) in 0.1770 seconds +hbase(main):004:0> put 'test', 'row2', 'cf:b', 'value2' +0 row(s) in 0.0110 seconds -hbase> put 'test', 'row2', 'cf:b', 'value2' -0 row(s) in 0.0160 seconds - -hbase> put 'test', 'row3', 'cf:c', 'value3' -0 row(s) in 0.0260 seconds +hbase(main):005:0> put 'test', 'row3', 'cf:c', 'value3' +0 row(s) in 0.0100 seconds ---- + Here, we insert three values, one at a time. @@ -210,51 +211,47 @@ Columns in HBase are comprised of a column family prefix, `cf` in this example, . Scan the table for all data at once. + One of the ways to get data from HBase is to scan. -Use the +scan+ command to scan the table for data. +Use the `scan` command to scan the table for data. You can limit your scan, but for now, all data is fetched. + ---- - -hbase> scan 'test' -ROW COLUMN+CELL - row1 column=cf:a, timestamp=1403759475114, value=value1 - row2 column=cf:b, timestamp=1403759492807, value=value2 - row3 column=cf:c, timestamp=1403759503155, value=value3 -3 row(s) in 0.0440 seconds +hbase(main):006:0> scan 'test' +ROW COLUMN+CELL + row1 column=cf:a, timestamp=1421762485768, value=value1 + row2 column=cf:b, timestamp=1421762491785, value=value2 + row3 column=cf:c, timestamp=1421762496210, value=value3 +3 row(s) in 0.0230 seconds ---- . Get a single row of data. + -To get a single row of data at a time, use the +get+ command. +To get a single row of data at a time, use the `get` command. + ---- - -hbase> get 'test', 'row1' -COLUMN CELL - cf:a timestamp=1403759475114, value=value1 -1 row(s) in 0.0230 seconds +hbase(main):007:0> get 'test', 'row1' +COLUMN CELL + cf:a timestamp=1421762485768, value=value1 +1 row(s) in 0.0350 seconds ---- . Disable a table. + -If you want to delete a table or change its settings, as well as in some other situations, you need to disable the table first, using the `disable` command. +If you want to delete a table or change its settings, as well as in some other situations, you need to disable the table first, using the `disable` command. You can re-enable it using the `enable` command. + ---- +hbase(main):008:0> disable 'test' +0 row(s) in 1.1820 seconds -hbase> disable 'test' -0 row(s) in 1.6270 seconds - -hbase> enable 'test' -0 row(s) in 0.4500 seconds +hbase(main):009:0> enable 'test' +0 row(s) in 0.1770 seconds ---- + -Disable the table again if you tested the +enable+ command above: +Disable the table again if you tested the `enable` command above: + ---- - -hbase> disable 'test' -0 row(s) in 1.6270 seconds +hbase(main):010:0> disable 'test' +0 row(s) in 1.1820 seconds ---- . Drop the table. @@ -262,14 +259,13 @@ hbase> disable 'test' To drop (delete) a table, use the `drop` command. + ---- - -hbase> drop 'test' -0 row(s) in 0.2900 seconds +hbase(main):011:0> drop 'test' +0 row(s) in 0.1370 seconds ---- . Exit the HBase Shell. + -To exit the HBase Shell and disconnect from your cluster, use the +quit+ command. +To exit the HBase Shell and disconnect from your cluster, use the `quit` command. HBase is still running in the background. @@ -284,7 +280,7 @@ $ ---- . After issuing the command, it can take several minutes for the processes to shut down. - Use the +jps+ to be sure that the HMaster and HRegionServer processes are shut down. + Use the `jps` to be sure that the HMaster and HRegionServer processes are shut down. [[quickstart_pseudo]] === Intermediate - Pseudo-Distributed Local Install @@ -313,7 +309,7 @@ This procedure will create a totally new directory where HBase will store its da + Edit the _hbase-site.xml_ configuration. First, add the following property. -which directs HBase to run in distributed mode, with one JVM instance per daemon. +which directs HBase to run in distributed mode, with one JVM instance per daemon. + [source,xml] ---- @@ -343,13 +339,13 @@ If you create the directory, HBase will attempt to do a migration, which is not . Start HBase. + Use the _bin/start-hbase.sh_ command to start HBase. -If your system is configured correctly, the +jps+ command should show the HMaster and HRegionServer processes running. +If your system is configured correctly, the `jps` command should show the HMaster and HRegionServer processes running. . Check the HBase directory in HDFS. + If everything worked correctly, HBase created its directory in HDFS. In the configuration above, it is stored in _/hbase/_ on HDFS. -You can use the +hadoop fs+ command in Hadoop's _bin/_ directory to list this directory. +You can use the `hadoop fs` command in Hadoop's _bin/_ directory to list this directory. + ---- @@ -375,7 +371,7 @@ This step is offered for testing and learning purposes only. + The HMaster server controls the HBase cluster. You can start up to 9 backup HMaster servers, which makes 10 total HMasters, counting the primary. -To start a backup HMaster, use the +local-master-backup.sh+. +To start a backup HMaster, use the `local-master-backup.sh`. For each backup master you want to start, add a parameter representing the port offset for that master. Each HMaster uses three ports (16010, 16020, and 16030 by default). The port offset is added to these ports, so using an offset of 2, the backup HMaster would use ports 16012, 16022, and 16032. The following command starts 3 backup servers using ports 16012/16022/16032, 16013/16023/16033, and 16015/16025/16035. @@ -386,8 +382,8 @@ $ ./bin/local-master-backup.sh 2 3 5 ---- + To kill a backup master without killing the entire cluster, you need to find its process ID (PID). The PID is stored in a file with a name like _/tmp/hbase-USER-X-master.pid_. -The only contents of the file are the PID. -You can use the +kill -9+ command to kill that PID. +The only contents of the file is the PID. +You can use the `kill -9` command to kill that PID. The following command will kill the master with port offset 1, but leave the cluster running: + ---- @@ -400,8 +396,8 @@ $ cat /tmp/hbase-testuser-1-master.pid |xargs kill -9 The HRegionServer manages the data in its StoreFiles as directed by the HMaster. Generally, one HRegionServer runs per node in the cluster. Running multiple HRegionServers on the same system can be useful for testing in pseudo-distributed mode. -The +local-regionservers.sh+ command allows you to run multiple RegionServers. -It works in a similar way to the +local-master-backup.sh+ command, in that each parameter you provide represents the port offset for an instance. +The `local-regionservers.sh` command allows you to run multiple RegionServers. +It works in a similar way to the `local-master-backup.sh` command, in that each parameter you provide represents the port offset for an instance. Each RegionServer requires two ports, and the default ports are 16020 and 16030. However, the base ports for additional RegionServers are not the default ports since the default ports are used by the HMaster, which is also a RegionServer since HBase version 1.0.0. The base ports are 16200 and 16300 instead. @@ -413,7 +409,7 @@ The following command starts four additional RegionServers, running on sequentia $ .bin/local-regionservers.sh start 2 3 4 5 ---- + -To stop a RegionServer manually, use the +local-regionservers.sh+ command with the `stop` parameter and the offset of the server to stop. +To stop a RegionServer manually, use the `local-regionservers.sh` command with the `stop` parameter and the offset of the server to stop. + ---- $ .bin/local-regionservers.sh stop 3 @@ -444,20 +440,21 @@ The architecture will be as follows: |=== This quickstart assumes that each node is a virtual machine and that they are all on the same network. -It builds upon the previous quickstart, <>, assuming that the system you configured in that procedure is now `node-a`. -Stop HBase on `node-a` before continuing. +It builds upon the previous quickstart, <>, assuming that the system you configured in that procedure is now `node-a`. +Stop HBase on `node-a` before continuing. NOTE: Be sure that all the nodes have full access to communicate, and that no firewall rules are in place which could prevent them from talking to each other. If you see any errors like `no route to host`, check your firewall. -.Procedure: Configure Password-Less SSH Access +[[passwordless.ssh.quickstart]] +.Procedure: Configure Passwordless SSH Access `node-a` needs to be able to log into `node-b` and `node-c` (and to itself) in order to start the daemons. -The easiest way to accomplish this is to use the same username on all hosts, and configure password-less SSH login from `node-a` to each of the others. +The easiest way to accomplish this is to use the same username on all hosts, and configure password-less SSH login from `node-a` to each of the others. . On `node-a`, generate a key pair. + -While logged in as the user who will run HBase, generate a SSH key pair, using the following command: +While logged in as the user who will run HBase, generate a SSH key pair, using the following command: + [source,bash] ---- @@ -474,9 +471,9 @@ If it already exists, be aware that it may already contain other keys. . Copy the public key to the other nodes. + -Securely copy the public key from `node-a` to each of the nodes, by using the +scp+ or some other secure means. +Securely copy the public key from `node-a` to each of the nodes, by using the `scp` or some other secure means. On each of the other nodes, create a new file called _.ssh/authorized_keys_ _if it does - not already exist_, and append the contents of the _id_rsa.pub_ file to the end of it. +not already exist_, and append the contents of the _id_rsa.pub_ file to the end of it. Note that you also need to do this for `node-a` itself. + ---- @@ -485,7 +482,7 @@ $ cat id_rsa.pub >> ~/.ssh/authorized_keys . Test password-less login. + -If you performed the procedure correctly, if you SSH from `node-a` to either of the other nodes, using the same username, you should not be prompted for a password. +If you performed the procedure correctly, if you SSH from `node-a` to either of the other nodes, using the same username, you should not be prompted for a password. . Since `node-b` will run a backup Master, repeat the procedure above, substituting `node-b` everywhere you see `node-a`. Be sure not to overwrite your existing _.ssh/authorized_keys_ files, but concatenate the new key onto the existing file using the `>>` operator rather than the `>` operator. @@ -515,7 +512,7 @@ This configuration will direct HBase to start and manage a ZooKeeper instance on + On `node-a`, edit _conf/hbase-site.xml_ and add the following properties. + -[source,bourne] +[source,xml] ---- hbase.zookeeper.quorum @@ -538,24 +535,23 @@ On `node-a`, edit _conf/hbase-site.xml_ and add the following properties. + Download and unpack HBase to `node-b`, just as you did for the standalone and pseudo-distributed quickstarts. -. Copy the configuration files from `node-a` to `node-b`.and - `node-c`. +. Copy the configuration files from `node-a` to `node-b`.and `node-c`. + Each node of your cluster needs to have the same configuration information. -Copy the contents of the _conf/_ directory to the _conf/_ directory on `node-b` and `node-c`. +Copy the contents of the _conf/_ directory to the _conf/_ directory on `node-b` and `node-c`. .Procedure: Start and Test Your Cluster . Be sure HBase is not running on any node. + If you forgot to stop HBase from previous testing, you will have errors. -Check to see whether HBase is running on any of your nodes by using the +jps+ command. +Check to see whether HBase is running on any of your nodes by using the `jps` command. Look for the processes `HMaster`, `HRegionServer`, and `HQuorumPeer`. If they exist, kill them. . Start the cluster. + -On `node-a`, issue the +start-hbase.sh+ command. +On `node-a`, issue the `start-hbase.sh` command. Your output will be similar to that below. + ---- @@ -566,15 +562,15 @@ node-a.example.com: starting zookeeper, logging to /home/hbuser/hbase-0.98.3-had node-b.example.com: starting zookeeper, logging to /home/hbuser/hbase-0.98.3-hadoop2/bin/../logs/hbase-hbuser-zookeeper-node-b.example.com.out starting master, logging to /home/hbuser/hbase-0.98.3-hadoop2/bin/../logs/hbase-hbuser-master-node-a.example.com.out node-c.example.com: starting regionserver, logging to /home/hbuser/hbase-0.98.3-hadoop2/bin/../logs/hbase-hbuser-regionserver-node-c.example.com.out -node-b.example.com: starting regionserver, logging to /home/hbuser/hbase-0.98.3-hadoop2/bin/../logs/hbase-hbuser-regionserver-node-b.example.com.out +node-b.example.com: starting regionserver, logging to /home/hbuser/hbase-0.98.3-hadoop2/bin/../logs/hbase-hbuser-regionserver-node-b.example.com.out node-b.example.com: starting master, logging to /home/hbuser/hbase-0.98.3-hadoop2/bin/../logs/hbase-hbuser-master-nodeb.example.com.out ---- + -ZooKeeper starts first, followed by the master, then the RegionServers, and finally the backup masters. +ZooKeeper starts first, followed by the master, then the RegionServers, and finally the backup masters. . Verify that the processes are running. + -On each node of the cluster, run the +jps+ command and verify that the correct processes are running on each server. +On each node of the cluster, run the `jps` command and verify that the correct processes are running on each server. You may see additional Java processes running on your servers as well, if they are used for other purposes. + .`node-a` `jps` Output @@ -602,7 +598,7 @@ $ jps .`node-a` `jps` Output ==== ---- -$ jps +$ jps 13901 Jps 13639 HQuorumPeer 13737 HRegionServer diff --git a/src/main/asciidoc/_chapters/hbase_apis.adoc b/src/main/asciidoc/_chapters/hbase_apis.adoc index 1fed94685c8..7fe0d3e3b61 100644 --- a/src/main/asciidoc/_chapters/hbase_apis.adoc +++ b/src/main/asciidoc/_chapters/hbase_apis.adoc @@ -28,12 +28,11 @@ :experimental: This chapter provides information about performing operations using HBase native APIs. -This information is not exhaustive, and provides a quick reference in addition to the link:http://hbase.apache.org/apidocs/index.html[User API - Reference]. +This information is not exhaustive, and provides a quick reference in addition to the link:http://hbase.apache.org/apidocs/index.html[User API Reference]. The examples here are not comprehensive or complete, and should be used for purposes of illustration only. Apache HBase also works with multiple external APIs. -See <> for more information. +See <> for more information. == Examples @@ -60,7 +59,7 @@ import static com.example.hbase.Constants.*; public class CreateSchema { - public static void createOrOverwrite(HBaseAdmin admin, HTableDescriptor table) throws IOException { + public static void createOrOverwrite(HBaseAdmin admin, HTableDescriptor table) throws IOException { if (admin.tableExists(table.getName())) { admin.disableTable(table.getName()); admin.deleteTable(table.getName()); @@ -85,7 +84,6 @@ public class CreateSchema { } } - } ---- ==== @@ -96,42 +94,41 @@ This example has been tested on HBase 0.96.1.1. [source,java] ---- - public static void upgradeFrom0 (Configuration config) { - try { - final HBaseAdmin admin = new HBaseAdmin(config); - TableName tableName = TableName.valueOf(TABLE_ASSETMETA); - HTableDescriptor table_assetmeta = new HTableDescriptor(tableName); - table_assetmeta.addFamily(new HColumnDescriptor(CF_DEFAULT).setCompressionType(Algorithm.SNAPPY)); + try { + final HBaseAdmin admin = new HBaseAdmin(config); + TableName tableName = TableName.valueOf(TABLE_ASSETMETA); + HTableDescriptor table_assetmeta = new HTableDescriptor(tableName); + table_assetmeta.addFamily(new HColumnDescriptor(CF_DEFAULT).setCompressionType(Algorithm.SNAPPY)); - // Create a new table. + // Create a new table. - System.out.print("Creating table_assetmeta. "); - admin.createTable(table_assetmeta); - System.out.println(" Done."); + System.out.print("Creating table_assetmeta. "); + admin.createTable(table_assetmeta); + System.out.println(" Done."); - // Update existing table - HColumnDescriptor newColumn = new HColumnDescriptor("NEWCF"); - newColumn.setCompactionCompressionType(Algorithm.GZ); - newColumn.setMaxVersions(HConstants.ALL_VERSIONS); - admin.addColumn(tableName, newColumn); + // Update existing table + HColumnDescriptor newColumn = new HColumnDescriptor("NEWCF"); + newColumn.setCompactionCompressionType(Algorithm.GZ); + newColumn.setMaxVersions(HConstants.ALL_VERSIONS); + admin.addColumn(tableName, newColumn); - // Disable an existing table - admin.disableTable(tableName); + // Disable an existing table + admin.disableTable(tableName); - // Delete an existing column family - admin.deleteColumn(tableName, CF_DEFAULT); + // Delete an existing column family + admin.deleteColumn(tableName, CF_DEFAULT); - // Delete a table (Need to be disabled first) - admin.deleteTable(tableName); + // Delete a table (Need to be disabled first) + admin.deleteTable(tableName); - admin.close(); - } catch (Exception e) { - e.printStackTrace(); - System.exit(-1); - } + admin.close(); + } catch (Exception e) { + e.printStackTrace(); + System.exit(-1); } +} ---- ==== diff --git a/src/main/asciidoc/_chapters/mapreduce.adoc b/src/main/asciidoc/_chapters/mapreduce.adoc index 1228f57376c..a008a4fe41f 100644 --- a/src/main/asciidoc/_chapters/mapreduce.adoc +++ b/src/main/asciidoc/_chapters/mapreduce.adoc @@ -29,48 +29,48 @@ Apache MapReduce is a software framework used to analyze large amounts of data, and is the framework used most often with link:http://hadoop.apache.org/[Apache Hadoop]. MapReduce itself is out of the scope of this document. -A good place to get started with MapReduce is link:http://hadoop.apache.org/docs/r1.2.1/mapred_tutorial.html. -MapReduce version 2 (MR2)is now part of link:http://hadoop.apache.org/docs/r2.3.0/hadoop-yarn/hadoop-yarn-site/[YARN]. +A good place to get started with MapReduce is http://hadoop.apache.org/docs/r2.6.0/hadoop-mapreduce-client/hadoop-mapreduce-client-core/MapReduceTutorial.html. +MapReduce version 2 (MR2)is now part of link:http://hadoop.apache.org/docs/r2.3.0/hadoop-yarn/hadoop-yarn-site/[YARN]. This chapter discusses specific configuration steps you need to take to use MapReduce on data within HBase. -In addition, it discusses other interactions and issues between HBase and MapReduce jobs. +In addition, it discusses other interactions and issues between HBase and MapReduce jobs. -.mapred and mapreduce +.`mapred` and `mapreduce` [NOTE] ==== There are two mapreduce packages in HBase as in MapReduce itself: _org.apache.hadoop.hbase.mapred_ and _org.apache.hadoop.hbase.mapreduce_. The former does old-style API and the latter the new style. The latter has more facility though you can usually find an equivalent in the older package. -Pick the package that goes with your mapreduce deploy. +Pick the package that goes with your MapReduce deploy. When in doubt or starting over, pick the _org.apache.hadoop.hbase.mapreduce_. -In the notes below, we refer to o.a.h.h.mapreduce but replace with the o.a.h.h.mapred if that is what you are using. -==== +In the notes below, we refer to o.a.h.h.mapreduce but replace with the o.a.h.h.mapred if that is what you are using. +==== [[hbase.mapreduce.classpath]] == HBase, MapReduce, and the CLASSPATH By default, MapReduce jobs deployed to a MapReduce cluster do not have access to either the HBase configuration under `$HBASE_CONF_DIR` or the HBase classes. -To give the MapReduce jobs the access they need, you could add _hbase-site.xml_ to the _$HADOOP_HOME/conf/_ directory and add the HBase JARs to the _`$HADOOP_HOME`/conf/_ directory, then copy these changes across your cluster. -You could add hbase-site.xml to `$HADOOP_HOME`/conf and add HBase jars to the $HADOOP_HOME/lib. -You would then need to copy these changes across your cluster or edit _`$HADOOP_HOME`/conf/hadoop-env.sh_ and add them to the `HADOOP_CLASSPATH` variable. +To give the MapReduce jobs the access they need, you could add _hbase-site.xml_ to the _$HADOOP_HOME/conf/_ directory and add the HBase JARs to the _HADOOP_HOME/conf/_ directory, then copy these changes across your cluster. +You could add _hbase-site.xml_ to _$HADOOP_HOME/conf_ and add HBase jars to the _$HADOOP_HOME/lib_ directory. +You would then need to copy these changes across your cluster or edit _$HADOOP_HOMEconf/hadoop-env.sh_ and add them to the `HADOOP_CLASSPATH` variable. However, this approach is not recommended because it will pollute your Hadoop install with HBase references. It also requires you to restart the Hadoop cluster before Hadoop can use the HBase data. Since HBase 0.90.x, HBase adds its dependency JARs to the job configuration itself. The dependencies only need to be available on the local `CLASSPATH`. -The following example runs the bundled HBase link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/mapreduce/RowCounter.html[RowCounter] MapReduce job against a table named [systemitem]+usertable+ If you have not set the environment variables expected in the command (the parts prefixed by a `$` sign and curly braces), you can use the actual system paths instead. +The following example runs the bundled HBase link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/mapreduce/RowCounter.html[RowCounter] MapReduce job against a table named `usertable` If you have not set the environment variables expected in the command (the parts prefixed by a `$` sign and curly braces), you can use the actual system paths instead. Be sure to use the correct version of the HBase JAR for your system. -The backticks (``` symbols) cause ths shell to execute the sub-commands, setting the CLASSPATH as part of the command. -This example assumes you use a BASH-compatible shell. +The backticks (``` symbols) cause ths shell to execute the sub-commands, setting the `CLASSPATH` as part of the command. +This example assumes you use a BASH-compatible shell. [source,bash] ---- $ HADOOP_CLASSPATH=`${HBASE_HOME}/bin/hbase classpath` ${HADOOP_HOME}/bin/hadoop jar ${HBASE_HOME}/hbase-server-VERSION.jar rowcounter usertable ---- -When the command runs, internally, the HBase JAR finds the dependencies it needs for zookeeper, guava, and its other dependencies on the passed `HADOOP_CLASSPATH` and adds the JARs to the MapReduce job configuration. -See the source at TableMapReduceUtil#addDependencyJars(org.apache.hadoop.mapreduce.Job) for how this is done. +When the command runs, internally, the HBase JAR finds the dependencies it needs for ZooKeeper, Guava, and its other dependencies on the passed `HADOOP_CLASSPATH` and adds the JARs to the MapReduce job configuration. +See the source at `TableMapReduceUtil#addDependencyJars(org.apache.hadoop.mapreduce.Job)` for how this is done. [NOTE] ==== @@ -89,10 +89,10 @@ $ HADOOP_CLASSPATH=${HBASE_HOME}/hbase-server/target/hbase-server-VERSION-SNAPSH ---- ==== -.Notice to Mapreduce users of HBase 0.96.1 and above +.Notice to MapReduce users of HBase 0.96.1 and above [CAUTION] ==== -Some mapreduce jobs that use HBase fail to launch. +Some MapReduce jobs that use HBase fail to launch. The symptom is an exception similar to the following: ---- @@ -125,15 +125,15 @@ Exception in thread "main" java.lang.IllegalAccessError: class ... ---- -This is caused by an optimization introduced in link:https://issues.apache.org/jira/browse/HBASE-9867[HBASE-9867] that inadvertently introduced a classloader dependency. +This is caused by an optimization introduced in link:https://issues.apache.org/jira/browse/HBASE-9867[HBASE-9867] that inadvertently introduced a classloader dependency. This affects both jobs using the `-libjars` option and "fat jar," those which package their runtime dependencies in a nested `lib` folder. -In order to satisfy the new classloader requirements, hbase-protocol.jar must be included in Hadoop's classpath. -See <> for current recommendations for resolving classpath errors. +In order to satisfy the new classloader requirements, `hbase-protocol.jar` must be included in Hadoop's classpath. +See <> for current recommendations for resolving classpath errors. The following is included for historical purposes. -This can be resolved system-wide by including a reference to the hbase-protocol.jar in hadoop's lib directory, via a symlink or by copying the jar into the new location. +This can be resolved system-wide by including a reference to the `hbase-protocol.jar` in Hadoop's lib directory, via a symlink or by copying the jar into the new location. This can also be achieved on a per-job launch basis by including it in the `HADOOP_CLASSPATH` environment variable at job submission time. When launching jobs that package their dependencies, all three of the following job launching commands satisfy this requirement: @@ -162,7 +162,7 @@ This functionality was lost due to a bug in HBase 0.95 (link:https://issues.apac The priority order for choosing the scanner caching is as follows: . Caching settings which are set on the scan object. -. Caching settings which are specified via the configuration option +hbase.client.scanner.caching+, which can either be set manually in _hbase-site.xml_ or via the helper method `TableMapReduceUtil.setScannerCaching()`. +. Caching settings which are specified via the configuration option `hbase.client.scanner.caching`, which can either be set manually in _hbase-site.xml_ or via the helper method `TableMapReduceUtil.setScannerCaching()`. . The default value `HConstants.DEFAULT_HBASE_CLIENT_SCANNER_CACHING`, which is set to `100`. Optimizing the caching settings is a balance between the time the client waits for a result and the number of sets of results the client needs to receive. @@ -176,7 +176,7 @@ See the API documentation for link:https://hbase.apache.org/apidocs/org/apache/h == Bundled HBase MapReduce Jobs -The HBase JAR also serves as a Driver for some bundled mapreduce jobs. +The HBase JAR also serves as a Driver for some bundled MapReduce jobs. To learn about the bundled MapReduce jobs, run the following command. [source,bash] @@ -202,35 +202,35 @@ $ ${HADOOP_HOME}/bin/hadoop jar ${HBASE_HOME}/hbase-server-VERSION.jar rowcounte == HBase as a MapReduce Job Data Source and Data Sink -HBase can be used as a data source, link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/mapreduce/TableInputFormat.html[TableInputFormat], and data sink, link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/mapreduce/TableOutputFormat.html[TableOutputFormat] or link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/mapreduce/MultiTableOutputFormat.html[MultiTableOutputFormat], for MapReduce jobs. +HBase can be used as a data source, link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/mapreduce/TableInputFormat.html[TableInputFormat], and data sink, link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/mapreduce/TableOutputFormat.html[TableOutputFormat] or link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/mapreduce/MultiTableOutputFormat.html[MultiTableOutputFormat], for MapReduce jobs. Writing MapReduce jobs that read or write HBase, it is advisable to subclass link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/mapreduce/TableMapper.html[TableMapper] and/or link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/mapreduce/TableReducer.html[TableReducer]. -See the do-nothing pass-through classes link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/mapreduce/IdentityTableMapper.html[IdentityTableMapper] and link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/mapreduce/IdentityTableReducer.html[IdentityTableReducer] for basic usage. -For a more involved example, see link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/mapreduce/RowCounter.html[RowCounter] or review the `org.apache.hadoop.hbase.mapreduce.TestTableMapReduce` unit test. +See the do-nothing pass-through classes link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/mapreduce/IdentityTableMapper.html[IdentityTableMapper] and link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/mapreduce/IdentityTableReducer.html[IdentityTableReducer] for basic usage. +For a more involved example, see link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/mapreduce/RowCounter.html[RowCounter] or review the `org.apache.hadoop.hbase.mapreduce.TestTableMapReduce` unit test. If you run MapReduce jobs that use HBase as source or sink, need to specify source and sink table and column names in your configuration. When you read from HBase, the `TableInputFormat` requests the list of regions from HBase and makes a map, which is either a `map-per-region` or `mapreduce.job.maps` map, whichever is smaller. If your job only has two maps, raise `mapreduce.job.maps` to a number greater than the number of regions. -Maps will run on the adjacent TaskTracker if you are running a TaskTracer and RegionServer per node. +Maps will run on the adjacent TaskTracker/NodeManager if you are running a TaskTracer/NodeManager and RegionServer per node. When writing to HBase, it may make sense to avoid the Reduce step and write back into HBase from within your map. This approach works when your job does not need the sort and collation that MapReduce does on the map-emitted data. On insert, HBase 'sorts' so there is no point double-sorting (and shuffling data around your MapReduce cluster) unless you need to. -If you do not need the Reduce, you myour map might emit counts of records processed for reporting at the end of the jobj, or set the number of Reduces to zero and use TableOutputFormat. +If you do not need the Reduce, your map might emit counts of records processed for reporting at the end of the job, or set the number of Reduces to zero and use TableOutputFormat. If running the Reduce step makes sense in your case, you should typically use multiple reducers so that load is spread across the HBase cluster. A new HBase partitioner, the link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/mapreduce/HRegionPartitioner.html[HRegionPartitioner], can run as many reducers the number of existing regions. The HRegionPartitioner is suitable when your table is large and your upload will not greatly alter the number of existing regions upon completion. -Otherwise use the default partitioner. +Otherwise use the default partitioner. == Writing HFiles Directly During Bulk Import If you are importing into a new table, you can bypass the HBase API and write your content directly to the filesystem, formatted into HBase data files (HFiles). Your import will run faster, perhaps an order of magnitude faster. -For more on how this mechanism works, see <>. +For more on how this mechanism works, see <>. == RowCounter Example -The included link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/mapreduce/RowCounter.html[RowCounter] MapReduce job uses `TableInputFormat` and does a count of all rows in the specified table. -To run it, use the following command: +The included link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/mapreduce/RowCounter.html[RowCounter] MapReduce job uses `TableInputFormat` and does a count of all rows in the specified table. +To run it, use the following command: [source,bash] ---- @@ -239,9 +239,9 @@ $ ./bin/hadoop jar hbase-X.X.X.jar This will invoke the HBase MapReduce Driver class. Select `rowcounter` from the choice of jobs offered. -This will print rowcouner usage advice to standard output. +This will print rowcounter usage advice to standard output. Specify the tablename, column to count, and output directory. -If you have classpath errors, see <>. +If you have classpath errors, see <>. [[splitter]] == Map-Task Splitting @@ -249,14 +249,14 @@ If you have classpath errors, see < { - public void map(ImmutableBytesWritable row, Result value, Context context) throws IOException, InterruptedException { - // this example is just copying the data from the source table... - context.write(row, resultToPut(row,value)); - } + public void map(ImmutableBytesWritable row, Result value, Context context) throws IOException, InterruptedException { + // this example is just copying the data from the source table... + context.write(row, resultToPut(row,value)); + } - private static Put resultToPut(ImmutableBytesWritable key, Result result) throws IOException { - Put put = new Put(key.get()); - for (KeyValue kv : result.raw()) { - put.add(kv); - } - return put; - } + private static Put resultToPut(ImmutableBytesWritable key, Result result) throws IOException { + Put put = new Put(key.get()); + for (KeyValue kv : result.raw()) { + put.add(kv); + } + return put; + } } ---- -There isn't actually a reducer step, so `TableOutputFormat` takes care of sending the `Put` to the target table. +There isn't actually a reducer step, so `TableOutputFormat` takes care of sending the `Put` to the target table. -This is just an example, developers could choose not to use `TableOutputFormat` and connect to the target table themselves. +This is just an example, developers could choose not to use `TableOutputFormat` and connect to the target table themselves. [[mapreduce.example.readwrite.multi]] === HBase MapReduce Read/Write Example With Multi-Table Output -TODO: example for `MultiTableOutputFormat`. +TODO: example for `MultiTableOutputFormat`. [[mapreduce.example.summary]] === HBase MapReduce Summary to HBase Example The following example uses HBase as a MapReduce source and sink with a summarization step. -This example will count the number of distinct instances of a value in a table and write those summarized counts in another table. +This example will count the number of distinct instances of a value in a table and write those summarized counts in another table. [source,java] ---- @@ -395,72 +395,71 @@ scan.setCacheBlocks(false); // don't set to true for MR jobs // set other scan attrs TableMapReduceUtil.initTableMapperJob( - sourceTable, // input table - scan, // Scan instance to control CF and attribute selection - MyMapper.class, // mapper class - Text.class, // mapper output key - IntWritable.class, // mapper output value - job); + sourceTable, // input table + scan, // Scan instance to control CF and attribute selection + MyMapper.class, // mapper class + Text.class, // mapper output key + IntWritable.class, // mapper output value + job); TableMapReduceUtil.initTableReducerJob( - targetTable, // output table - MyTableReducer.class, // reducer class - job); + targetTable, // output table + MyTableReducer.class, // reducer class + job); job.setNumReduceTasks(1); // at least one, adjust as required boolean b = job.waitForCompletion(true); if (!b) { - throw new IOException("error with job!"); + throw new IOException("error with job!"); } ----- +---- In this example mapper a column with a String-value is chosen as the value to summarize upon. -This value is used as the key to emit from the mapper, and an `IntWritable` represents an instance counter. +This value is used as the key to emit from the mapper, and an `IntWritable` represents an instance counter. [source,java] ---- public static class MyMapper extends TableMapper { - public static final byte[] CF = "cf".getBytes(); - public static final byte[] ATTR1 = "attr1".getBytes(); + public static final byte[] CF = "cf".getBytes(); + public static final byte[] ATTR1 = "attr1".getBytes(); - private final IntWritable ONE = new IntWritable(1); - private Text text = new Text(); + private final IntWritable ONE = new IntWritable(1); + private Text text = new Text(); - public void map(ImmutableBytesWritable row, Result value, Context context) throws IOException, InterruptedException { - String val = new String(value.getValue(CF, ATTR1)); - text.set(val); // we can only emit Writables... - - context.write(text, ONE); - } + public void map(ImmutableBytesWritable row, Result value, Context context) throws IOException, InterruptedException { + String val = new String(value.getValue(CF, ATTR1)); + text.set(val); // we can only emit Writables... + context.write(text, ONE); + } } ----- +---- -In the reducer, the "ones" are counted (just like any other MR example that does this), and then emits a `Put`. +In the reducer, the "ones" are counted (just like any other MR example that does this), and then emits a `Put`. [source,java] ---- public static class MyTableReducer extends TableReducer { - public static final byte[] CF = "cf".getBytes(); - public static final byte[] COUNT = "count".getBytes(); + public static final byte[] CF = "cf".getBytes(); + public static final byte[] COUNT = "count".getBytes(); - public void reduce(Text key, Iterable values, Context context) throws IOException, InterruptedException { - int i = 0; - for (IntWritable val : values) { - i += val.get(); - } - Put put = new Put(Bytes.toBytes(key.toString())); - put.add(CF, COUNT, Bytes.toBytes(i)); + public void reduce(Text key, Iterable values, Context context) throws IOException, InterruptedException { + int i = 0; + for (IntWritable val : values) { + i += val.get(); + } + Put put = new Put(Bytes.toBytes(key.toString())); + put.add(CF, COUNT, Bytes.toBytes(i)); - context.write(null, put); - } + context.write(null, put); + } } ----- +---- [[mapreduce.example.summary.file]] === HBase MapReduce Summary to File Example This very similar to the summary example above, with exception that this is using HBase as a MapReduce source but HDFS as the sink. The differences are in the job setup and in the reducer. -The mapper remains the same. +The mapper remains the same. [source,java] ---- @@ -474,19 +473,19 @@ scan.setCacheBlocks(false); // don't set to true for MR jobs // set other scan attrs TableMapReduceUtil.initTableMapperJob( - sourceTable, // input table - scan, // Scan instance to control CF and attribute selection - MyMapper.class, // mapper class - Text.class, // mapper output key - IntWritable.class, // mapper output value - job); + sourceTable, // input table + scan, // Scan instance to control CF and attribute selection + MyMapper.class, // mapper class + Text.class, // mapper output key + IntWritable.class, // mapper output value + job); job.setReducerClass(MyReducer.class); // reducer class job.setNumReduceTasks(1); // at least one, adjust as required FileOutputFormat.setOutputPath(job, new Path("/tmp/mr/mySummaryFile")); // adjust directories as required boolean b = job.waitForCompletion(true); if (!b) { - throw new IOException("error with job!"); + throw new IOException("error with job!"); } ---- @@ -497,68 +496,68 @@ As for the Reducer, it is a "generic" Reducer instead of extending TableMapper a ---- public static class MyReducer extends Reducer { - public void reduce(Text key, Iterable values, Context context) throws IOException, InterruptedException { - int i = 0; - for (IntWritable val : values) { - i += val.get(); - } - context.write(key, new IntWritable(i)); - } + public void reduce(Text key, Iterable values, Context context) throws IOException, InterruptedException { + int i = 0; + for (IntWritable val : values) { + i += val.get(); + } + context.write(key, new IntWritable(i)); + } } ---- [[mapreduce.example.summary.noreducer]] === HBase MapReduce Summary to HBase Without Reducer -It is also possible to perform summaries without a reducer - if you use HBase as the reducer. +It is also possible to perform summaries without a reducer - if you use HBase as the reducer. An HBase target table would need to exist for the job summary. The Table method `incrementColumnValue` would be used to atomically increment values. -From a performance perspective, it might make sense to keep a Map of values with their values to be incremeneted for each map-task, and make one update per key at during the `cleanup` method of the mapper. -However, your milage may vary depending on the number of rows to be processed and unique keys. +From a performance perspective, it might make sense to keep a Map of values with their values to be incremented for each map-task, and make one update per key at during the `cleanup` method of the mapper. +However, your mileage may vary depending on the number of rows to be processed and unique keys. -In the end, the summary results are in HBase. +In the end, the summary results are in HBase. [[mapreduce.example.summary.rdbms]] === HBase MapReduce Summary to RDBMS Sometimes it is more appropriate to generate summaries to an RDBMS. For these cases, it is possible to generate summaries directly to an RDBMS via a custom reducer. -The `setup` method can connect to an RDBMS (the connection information can be passed via custom parameters in the context) and the cleanup method can close the connection. +The `setup` method can connect to an RDBMS (the connection information can be passed via custom parameters in the context) and the cleanup method can close the connection. It is critical to understand that number of reducers for the job affects the summarization implementation, and you'll have to design this into your reducer. Specifically, whether it is designed to run as a singleton (one reducer) or multiple reducers. Neither is right or wrong, it depends on your use-case. -Recognize that the more reducers that are assigned to the job, the more simultaneous connections to the RDBMS will be created - this will scale, but only to a point. +Recognize that the more reducers that are assigned to the job, the more simultaneous connections to the RDBMS will be created - this will scale, but only to a point. [source,java] ---- - public static class MyRdbmsReducer extends Reducer { +public static class MyRdbmsReducer extends Reducer { - private Connection c = null; + private Connection c = null; - public void setup(Context context) { - // create DB connection... - } + public void setup(Context context) { + // create DB connection... + } - public void reduce(Text key, Iterable values, Context context) throws IOException, InterruptedException { - // do summarization - // in this example the keys are Text, but this is just an example - } + public void reduce(Text key, Iterable values, Context context) throws IOException, InterruptedException { + // do summarization + // in this example the keys are Text, but this is just an example + } - public void cleanup(Context context) { - // close db connection - } + public void cleanup(Context context) { + // close db connection + } } ---- -In the end, the summary results are written to your RDBMS table/s. +In the end, the summary results are written to your RDBMS table/s. [[mapreduce.htable.access]] == Accessing Other HBase Tables in a MapReduce Job -Although the framework currently allows one HBase table as input to a MapReduce job, other HBase tables can be accessed as lookup tables, etc., in a MapReduce job via creating an Table instance in the setup method of the Mapper. +Although the framework currently allows one HBase table as input to a MapReduce job, other HBase tables can be accessed as lookup tables, etc., in a MapReduce job via creating an Table instance in the setup method of the Mapper. [source,java] ---- public class MyMapper extends TableMapper { @@ -571,16 +570,16 @@ public class MyMapper extends TableMapper { } public void map(ImmutableBytesWritable row, Result value, Context context) throws IOException, InterruptedException { - // process Result... - // use 'myOtherTable' for lookups + // process Result... + // use 'myOtherTable' for lookups } ----- +---- [[mapreduce.specex]] == Speculative Execution It is generally advisable to turn off speculative execution for MapReduce jobs that use HBase as a source. This can either be done on a per-Job basis through properties, on on the entire cluster. -Especially for longer running jobs, speculative execution will create duplicate map-tasks which will double-write your data to HBase; this is probably not what you want. +Especially for longer running jobs, speculative execution will create duplicate map-tasks which will double-write your data to HBase; this is probably not what you want. -See <> for more information. +See <> for more information. diff --git a/src/main/asciidoc/_chapters/ops_mgt.adoc b/src/main/asciidoc/_chapters/ops_mgt.adoc index b0b496a8507..852e76b2821 100644 --- a/src/main/asciidoc/_chapters/ops_mgt.adoc +++ b/src/main/asciidoc/_chapters/ops_mgt.adoc @@ -28,7 +28,7 @@ :experimental: This chapter will cover operational tools and practices required of a running Apache HBase cluster. -The subject of operations is related to the topics of <>, <>, and <> but is a distinct topic in itself. +The subject of operations is related to the topics of <>, <>, and <> but is a distinct topic in itself. [[tools]] == HBase Tools and Utilities @@ -36,9 +36,9 @@ The subject of operations is related to the topics of <>, <>), +hbase upgrade+ (<>), and +hbase - thrift+ (<>), are documented elsewhere in this guide. +Others, such as `hbase shell` (<>), `hbase upgrade` (<>), and `hbase thrift` (<>), are documented elsewhere in this guide. === Canary -There is a Canary class can help users to canary-test the HBase cluster status, with every column-family for every regions or regionservers granularity. -To see the usage, use the `--help` parameter. +There is a Canary class can help users to canary-test the HBase cluster status, with every column-family for every regions or RegionServer's granularity. +To see the usage, use the `--help` parameter. ---- $ ${HBASE_HOME}/bin/hbase org.apache.hadoop.hbase.tool.Canary -help @@ -96,7 +95,7 @@ Usage: bin/hbase org.apache.hadoop.hbase.tool.Canary [opts] [table1 [table2]...] ---- This tool will return non zero error codes to user for collaborating with other monitoring tools, such as Nagios. -The error code definitions are: +The error code definitions are: [source,java] ---- @@ -107,26 +106,26 @@ private static final int ERROR_EXIT_CODE = 4; ---- Here are some examples based on the following given case. -There are two HTable called test-01 and test-02, they have two column family cf1 and cf2 respectively, and deployed on the 3 regionservers. -see following table. +There are two HTable called test-01 and test-02, they have two column family cf1 and cf2 respectively, and deployed on the 3 RegionServers. +see following table. [cols="1,1,1", options="header"] |=== | RegionServer | test-01 | test-02 -|rs1| r1| r2 -|rs2 |r2 | -|rs3 |r2 |r1 +| rs1 | r1 | r2 +| rs2 | r2 | +| rs3 | r2 | r1 |=== -Following are some examples based on the previous given case. +Following are some examples based on the previous given case. ==== Canary test for every column family (store) of every region of every table ---- $ ${HBASE_HOME}/bin/hbase org.apache.hadoop.hbase.tool.Canary - + 3/12/09 03:26:32 INFO tool.Canary: read from region test-01,,1386230156732.0e3c7d77ffb6361ea1b996ac1042ca9a. column family cf1 in 2ms 13/12/09 03:26:32 INFO tool.Canary: read from region test-01,,1386230156732.0e3c7d77ffb6361ea1b996ac1042ca9a. column family cf2 in 2ms 13/12/09 03:26:32 INFO tool.Canary: read from region test-01,0004883,1386230156732.87b55e03dfeade00f441125159f8ca87. column family cf1 in 4ms @@ -139,23 +138,23 @@ $ ${HBASE_HOME}/bin/hbase org.apache.hadoop.hbase.tool.Canary ---- So you can see, table test-01 has two regions and two column families, so the Canary tool will pick 4 small piece of data from 4 (2 region * 2 store) different stores. -This is a default behavior of the this tool does. +This is a default behavior of the this tool does. -==== Canary test for every column family (store) of every region of specifictable(s) +==== Canary test for every column family (store) of every region of specific table(s) You can also test one or more specific tables. ---- -$ ${HBASE_HOME}/bin/hbase orghapache.hadoop.hbase.tool.Canary test-01 test-02 +$ ${HBASE_HOME}/bin/hbase org.apache.hadoop.hbase.tool.Canary test-01 test-02 ---- -==== Canary test with regionserver granularity +==== Canary test with RegionServer granularity -This will pick one small piece of data from each regionserver, and can also put your resionserver name as input options for canary-test specific regionservers. +This will pick one small piece of data from each RegionServer, and can also put your RegionServer name as input options for canary-test specific RegionServer. ---- $ ${HBASE_HOME}/bin/hbase org.apache.hadoop.hbase.tool.Canary -regionserver - + 13/12/09 06:05:17 INFO tool.Canary: Read from table:test-01 on region server:rs2 in 72ms 13/12/09 06:05:17 INFO tool.Canary: Read from table:test-02 on region server:rs3 in 34ms 13/12/09 06:05:17 INFO tool.Canary: Read from table:test-01 on region server:rs1 in 56ms @@ -166,33 +165,32 @@ $ ${HBASE_HOME}/bin/hbase org.apache.hadoop.hbase.tool.Canary -regionserver This will test both table test-01 and test-02. ---- -$ ${HBASE_HOME}/bin/hbase orghapache.hadoop.hbase.tool.Canary -e test-0[1-2] +$ ${HBASE_HOME}/bin/hbase org.apache.hadoop.hbase.tool.Canary -e test-0[1-2] ---- ==== Run canary test as daemon mode -Run repeatedly with interval defined in option -interval whose default value is 6 seconds. +Run repeatedly with interval defined in option `-interval` whose default value is 6 seconds. This daemon will stop itself and return non-zero error code if any error occurs, due to the default value of option -f is true. ---- -$ ${HBASE_HOME}/bin/hbase orghapache.hadoop.hbase.tool.Canary -daemon +$ ${HBASE_HOME}/bin/hbase org.apache.hadoop.hbase.tool.Canary -daemon ---- -Run repeatedly with internal 5 seconds and will not stop itself even error occurs in the test. +Run repeatedly with internal 5 seconds and will not stop itself even if errors occur in the test. ---- -$ ${HBASE_HOME}/bin/hbase orghapache.hadoop.hbase.tool.Canary -daemon -interval 50000 -f false +$ ${HBASE_HOME}/bin/hbase org.apache.hadoop.hbase.tool.Canary -daemon -interval 50000 -f false ---- ==== Force timeout if canary test stuck -In some cases, we suffered the request stucked on the regionserver and not response back to the client. -The regionserver in problem, would also not indicated to be dead by Master, which would bring the clients hung. -So we provide the timeout option to kill the canary test forcefully and return non-zero error code as well. +In some cases the request is stuck and no response is sent back to the client. This can happen with dead RegionServers which the master has not yet noticed. +Because of this we provide a timeout option to kill the canary test and return a non-zero error code. This run sets the timeout value to 60 seconds, the default value is 600 seconds. ---- -$ ${HBASE_HOME}/bin/hbase orghapache.hadoop.hbase.tool.Canary -t 600000 +$ ${HBASE_HOME}/bin/hbase org.apache.hadoop.hbase.tool.Canary -t 600000 ---- ==== Running Canary in a Kerberos-enabled Cluster @@ -215,7 +213,6 @@ This example shows each of the properties with valid values. [source,xml] ---- - hbase.client.kerberos.principal hbase/_HOST@YOUR-REALM.COM @@ -239,14 +236,14 @@ property> [[health.check]] === Health Checker -You can configure HBase to run a script on a period and if it fails N times (configurable), have the server exit. -See link:[HBASE-7351 Periodic health check script] for configurations and detail. +You can configure HBase to run a script periodically and if it fails N times (configurable), have the server exit. +See _HBASE-7351 Periodic health check script_ for configurations and detail. === Driver Several frequently-accessed utilities are provided as `Driver` classes, and executed by the _bin/hbase_ command. These utilities represent MapReduce jobs which run on your cluster. -They are run in the following way, replacing [replaceable]_UtilityName_ with the utility you want to run. +They are run in the following way, replacing _UtilityName_ with the utility you want to run. This command assumes you have set the environment variable `HBASE_HOME` to the directory where HBase is unpacked on your server. ---- @@ -256,45 +253,45 @@ ${HBASE_HOME}/bin/hbase org.apache.hadoop.hbase.mapreduce.UtilityName The following utilities are available: -+LoadIncrementalHFiles+:: +`LoadIncrementalHFiles`:: Complete a bulk data load. -+CopyTable+:: +`CopyTable`:: Export a table from the local cluster to a peer cluster. -+Export+:: +`Export`:: Write table data to HDFS. -+Import+:: - Import data written by a previous +Export+ operation. +`Import`:: + Import data written by a previous `Export` operation. -+ImportTsv+:: +`ImportTsv`:: Import data in TSV format. -+RowCounter+:: +`RowCounter`:: Count rows in an HBase table. -+replication.VerifyReplication+:: +`replication.VerifyReplication`:: Compare the data from tables in two different clusters. WARNING: It doesn't work for incrementColumnValues'd cells since the timestamp is changed. Note that this command is in a different package than the others. -Each command except +RowCounter+ accepts a single `--help` argument to print usage instructions. +Each command except `RowCounter` accepts a single `--help` argument to print usage instructions. [[hbck]] -=== HBase +hbck+ +=== HBase `hbck` -To run +hbck+ against your HBase cluster run `$./bin/hbase hbck`. At the end of the command's output it prints `OK` or `INCONSISTENCY`. +To run `hbck` against your HBase cluster run `$./bin/hbase hbck`. At the end of the command's output it prints `OK` or `INCONSISTENCY`. If your cluster reports inconsistencies, pass `-details` to see more detail emitted. -If inconsistencies, run `hbck` a few times because the inconsistency may be transient (e.g. -cluster is starting up or a region is splitting). Passing `-fix` may correct the inconsistency (This latter is an experimental feature). +If inconsistencies, run `hbck` a few times because the inconsistency may be transient (e.g. cluster is starting up or a region is splitting). + Passing `-fix` may correct the inconsistency (This is an experimental feature). -For more information, see <>. +For more information, see <>. [[hfile_tool2]] === HFile Tool -See <>. +See <>. === WAL Tools @@ -311,7 +308,7 @@ You can get a textual dump of a WAL file content by doing the following: $ ./bin/hbase org.apache.hadoop.hbase.regionserver.wal.FSHLog --dump hdfs://example.org:8020/hbase/.logs/example.org,60020,1283516293161/10.10.21.10%3A60020.1283973724012 ---- -The return code will be non-zero if issues with the file so you can test wholesomeness of file by redirecting `STDOUT` to `/dev/null` and testing the program return. +The return code will be non-zero if there are any issues with the file so you can test wholesomeness of file by redirecting `STDOUT` to `/dev/null` and testing the program return. Similarly you can force a split of a log file directory by doing: @@ -323,7 +320,7 @@ Similarly you can force a split of a log file directory by doing: ===== WAL Pretty Printer The WAL Pretty Printer is a tool with configurable options to print the contents of a WAL. -You can invoke it via the hbase cli with the 'wal' command. +You can invoke it via the HBase cli with the 'wal' command. ---- $ ./bin/hbase wal hdfs://example.org:8020/hbase/.logs/example.org,60020,1283516293161/10.10.21.10%3A60020.1283973724012 @@ -333,7 +330,7 @@ You can invoke it via the hbase cli with the 'wal' command. [NOTE] ==== Prior to version 2.0, the WAL Pretty Printer was called the `HLogPrettyPrinter`, after an internal name for HBase's write ahead log. -In those versions, you can pring the contents of a WAL using the same configuration as above, but with the 'hlog' command. +In those versions, you can pring the contents of a WAL using the same configuration as above, but with the 'hlog' command. ---- $ ./bin/hbase hlog hdfs://example.org:8020/hbase/.logs/example.org,60020,1283516293161/10.10.21.10%3A60020.1283973724012 @@ -353,12 +350,12 @@ The usage is as follows: ---- -$ ./bin/hbase org.apache.hadoop.hbase.mapreduce.CopyTable --help +$ ./bin/hbase org.apache.hadoop.hbase.mapreduce.CopyTable --help /bin/hbase org.apache.hadoop.hbase.mapreduce.CopyTable --help Usage: CopyTable [general options] [--starttime=X] [--endtime=Y] [--new.name=NEW] [--peer.adr=ADR] Options: - rs.class hbase.regionserver.class of the peer cluster, + rs.class hbase.regionserver.class of the peer cluster, specify if different from current cluster rs.impl hbase.regionserver.impl of the peer cluster, startrow the start row @@ -394,17 +391,17 @@ For performance consider the following general options: .Scanner Caching [NOTE] ==== -Caching for the input Scan is configured via `hbase.client.scanner.caching` in the job configuration. +Caching for the input Scan is configured via `hbase.client.scanner.caching` in the job configuration. ==== .Versions [NOTE] ==== -By default, CopyTable utility only copies the latest version of row cells unless `--versions=n` is explicitly specified in the command. +By default, CopyTable utility only copies the latest version of row cells unless `--versions=n` is explicitly specified in the command. ==== See Jonathan Hsieh's link:http://www.cloudera.com/blog/2012/06/online-hbase-backups-with-copytable-2/[Online - HBase Backups with CopyTable] blog post for more on +CopyTable+. + HBase Backups with CopyTable] blog post for more on `CopyTable`. === Export @@ -415,7 +412,7 @@ Invoke via: $ bin/hbase org.apache.hadoop.hbase.mapreduce.Export [ [ []]] ---- -Note: caching for the input Scan is configured via `hbase.client.scanner.caching` in the job configuration. +Note: caching for the input Scan is configured via `hbase.client.scanner.caching` in the job configuration. === Import @@ -435,7 +432,7 @@ $ bin/hbase -Dhbase.import.version=0.94 org.apache.hadoop.hbase.mapreduce.Import === ImportTsv ImportTsv is a utility that will load data in TSV format into HBase. -It has two distinct usages: loading data from TSV format in HDFS into HBase via Puts, and preparing StoreFiles to be loaded via the `completebulkload`. +It has two distinct usages: loading data from TSV format in HDFS into HBase via Puts, and preparing StoreFiles to be loaded via the `completebulkload`. To load data via Puts (i.e., non-bulk loading): @@ -450,12 +447,12 @@ To generate StoreFiles for bulk-loading: $ bin/hbase org.apache.hadoop.hbase.mapreduce.ImportTsv -Dimporttsv.columns=a,b,c -Dimporttsv.bulk.output=hdfs://storefile-outputdir ---- -These generated StoreFiles can be loaded into HBase via <>. +These generated StoreFiles can be loaded into HBase via <>. [[importtsv.options]] ==== ImportTsv Options -Running +ImportTsv+ with no arguments prints brief usage information: +Running `ImportTsv` with no arguments prints brief usage information: ---- @@ -486,9 +483,9 @@ Other options that may be specified with -D include: [[importtsv.example]] ==== ImportTsv Example -For example, assume that we are loading data into a table called 'datatsv' with a ColumnFamily called 'd' with two columns "c1" and "c2". +For example, assume that we are loading data into a table called 'datatsv' with a ColumnFamily called 'd' with two columns "c1" and "c2". -Assume that an input file exists as follows: +Assume that an input file exists as follows: ---- row1 c1 c2 @@ -501,7 +498,7 @@ row7 c1 c2 row8 c1 c2 row9 c1 c2 row10 c1 c2 ----- +---- For ImportTsv to use this imput file, the command line needs to look like this: @@ -511,12 +508,12 @@ For ImportTsv to use this imput file, the command line needs to look like this: ---- \... and in this example the first column is the rowkey, which is why the HBASE_ROW_KEY is used. -The second and third columns in the file will be imported as "d:c1" and "d:c2", respectively. +The second and third columns in the file will be imported as "d:c1" and "d:c2", respectively. [[importtsv.warning]] ==== ImportTsv Warning -If you have preparing a lot of data for bulk loading, make sure the target HBase table is pre-split appropriately. +If you have preparing a lot of data for bulk loading, make sure the target HBase table is pre-split appropriately. [[importtsv.also]] ==== See Also @@ -526,7 +523,7 @@ For more information about bulk-loading HFiles into HBase, see <>. +This utility is often used in conjunction with output from <>. There are two ways to invoke this utility, with explicit classname and via the driver: @@ -546,16 +543,16 @@ HADOOP_CLASSPATH=`${HBASE_HOME}/bin/hbase classpath` ${HADOOP_HOME}/bin/hadoop j Data generated via MapReduce is often created with file permissions that are not compatible with the running HBase process. Assuming you're running HDFS with permissions enabled, those permissions will need to be updated before you run CompleteBulkLoad. -For more information about bulk-loading HFiles into HBase, see <>. +For more information about bulk-loading HFiles into HBase, see <>. === WALPlayer -WALPlayer is a utility to replay WAL files into HBase. +WALPlayer is a utility to replay WAL files into HBase. The WAL can be replayed for a set of tables or all tables, and a timerange can be provided (in milliseconds). The WAL is filtered to this set of tables. -The output can optionally be mapped to another set of tables. +The output can optionally be mapped to another set of tables. -WALPlayer can also generate HFiles for later bulk importing, in that case only a single table and no mapping can be specified. +WALPlayer can also generate HFiles for later bulk importing, in that case only a single table and no mapping can be specified. Invoke via: @@ -570,7 +567,7 @@ $ bin/hbase org.apache.hadoop.hbase.mapreduce.WALPlayer /backuplogdir oldTable1, ---- WALPlayer, by default, runs as a mapreduce job. -To NOT run WALPlayer as a mapreduce job on your cluster, force it to run all in the local process by adding the flags `-Dmapreduce.jobtracker.address=local` on the command line. +To NOT run WALPlayer as a mapreduce job on your cluster, force it to run all in the local process by adding the flags `-Dmapreduce.jobtracker.address=local` on the command line. [[rowcounter]] === RowCounter and CellCounter @@ -583,11 +580,11 @@ It will run the mapreduce all in a single process but it will run faster if you $ bin/hbase org.apache.hadoop.hbase.mapreduce.RowCounter [ ...] ---- -Note: caching for the input Scan is configured via `hbase.client.scanner.caching` in the job configuration. +Note: caching for the input Scan is configured via `hbase.client.scanner.caching` in the job configuration. HBase ships another diagnostic mapreduce job called link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/mapreduce/CellCounter.html[CellCounter]. Like RowCounter, it gathers more fine-grained statistics about your table. -The statistics gathered by RowCounter are more fine-grained and include: +The statistics gathered by RowCounter are more fine-grained and include: * Total number of rows in the table. * Total number of CFs across all rows. @@ -604,13 +601,13 @@ Use `hbase.mapreduce.scan.column.family` to specify scanning a single column fam $ bin/hbase org.apache.hadoop.hbase.mapreduce.CellCounter [regex or prefix] ---- -Note: just like RowCounter, caching for the input Scan is configured via `hbase.client.scanner.caching` in the job configuration. +Note: just like RowCounter, caching for the input Scan is configured via `hbase.client.scanner.caching` in the job configuration. === mlockall It is possible to optionally pin your servers in physical memory making them less likely to be swapped out in oversubscribed environments by having the servers call link:http://linux.die.net/man/2/mlockall[mlockall] on startup. See link:https://issues.apache.org/jira/browse/HBASE-4391[HBASE-4391 Add ability to - start RS as root and call mlockall] for how to build the optional library and have it run on startup. + start RS as root and call mlockall] for how to build the optional library and have it run on startup. [[compaction.tool]] === Offline Compaction Tool @@ -618,14 +615,14 @@ See link:https://issues.apache.org/jira/browse/HBASE-4391[HBASE-4391 Add ability See the usage for the link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/regionserver/CompactionTool.html[Compaction Tool]. Run it like this +./bin/hbase - org.apache.hadoop.hbase.regionserver.CompactionTool+ + org.apache.hadoop.hbase.regionserver.CompactionTool+ -=== +hbase clean+ +=== `hbase clean` -The +hbase clean+ command cleans HBase data from ZooKeeper, HDFS, or both. +The `hbase clean` command cleans HBase data from ZooKeeper, HDFS, or both. It is appropriate to use for testing. Run it with no options for usage instructions. -The +hbase clean+ command was introduced in HBase 0.98. +The `hbase clean` command was introduced in HBase 0.98. ---- @@ -637,25 +634,25 @@ Options: --cleanAll cleans hbase related data from both zookeeper and hdfs. ---- -=== +hbase pe+ +=== `hbase pe` -The +hbase pe+ command is a shortcut provided to run the `org.apache.hadoop.hbase.PerformanceEvaluation` tool, which is used for testing. -The +hbase pe+ command was introduced in HBase 0.98.4. +The `hbase pe` command is a shortcut provided to run the `org.apache.hadoop.hbase.PerformanceEvaluation` tool, which is used for testing. +The `hbase pe` command was introduced in HBase 0.98.4. The PerformanceEvaluation tool accepts many different options and commands. For usage instructions, run the command with no options. -To run PerformanceEvaluation prior to HBase 0.98.4, issue the command +hbase org.apache.hadoop.hbase.PerformanceEvaluation+. +To run PerformanceEvaluation prior to HBase 0.98.4, issue the command `hbase org.apache.hadoop.hbase.PerformanceEvaluation`. The PerformanceEvaluation tool has received many updates in recent HBase releases, including support for namespaces, support for tags, cell-level ACLs and visibility labels, multiget support for RPC calls, increased sampling sizes, an option to randomly sleep during testing, and ability to "warm up" the cluster before testing starts. -=== +hbase ltt+ +=== `hbase ltt` -The +hbase ltt+ command is a shortcut provided to run the `org.apache.hadoop.hbase.util.LoadTestTool` utility, which is used for testing. -The +hbase ltt+ command was introduced in HBase 0.98.4. +The `hbase ltt` command is a shortcut provided to run the `org.apache.hadoop.hbase.util.LoadTestTool` utility, which is used for testing. +The `hbase ltt` command was introduced in HBase 0.98.4. -You must specify either +-write+ or +-update-read+ as the first option. -For general usage instructions, pass the +-h+ option. +You must specify either `-write` or `-update-read` as the first option. +For general usage instructions, pass the `-h` option. To run LoadTestTool prior to HBase 0.98.4, issue the command +hbase org.apache.hadoop.hbase.util.LoadTestTool+. @@ -668,10 +665,10 @@ The LoadTestTool has received many updates in recent HBase releases, including s [[ops.regionmgt.majorcompact]] === Major Compaction -Major compactions can be requested via the HBase shell or link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/HBaseAdmin.html#majorCompact%28java.lang.String%29[HBaseAdmin.majorCompact]. +Major compactions can be requested via the HBase shell or link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/HBaseAdmin.html#majorCompact%28java.lang.String%29[HBaseAdmin.majorCompact]. Note: major compactions do NOT do region merges. -See <> for more information about compactions. +See <> for more information about compactions. [[ops.regionmgt.merge]] === Merge @@ -686,13 +683,13 @@ $ bin/hbase org.apache.hadoop.hbase.util.Merge If you feel you have too many regions and want to consolidate them, Merge is the utility you need. Merge must run be done when the cluster is down. See the link:http://ofps.oreilly.com/titles/9781449396107/performance.html[O'Reilly HBase - Book] for an example of usage. + Book] for an example of usage. You will need to pass 3 parameters to this application. The first one is the table name. -The second one is the fully qualified name of the first region to merge, like "table_name,\x0A,1342956111995.7cef47f192318ba7ccc75b1bbf27a82b.". The third one is the fully qualified name for the second region to merge. +The second one is the fully qualified name of the first region to merge, like "table_name,\x0A,1342956111995.7cef47f192318ba7ccc75b1bbf27a82b.". The third one is the fully qualified name for the second region to merge. -Additionally, there is a Ruby script attached to link:https://issues.apache.org/jira/browse/HBASE-1621[HBASE-1621] for region merging. +Additionally, there is a Ruby script attached to link:https://issues.apache.org/jira/browse/HBASE-1621[HBASE-1621] for region merging. [[node.management]] == Node Management @@ -708,14 +705,14 @@ $ ./bin/hbase-daemon.sh stop regionserver The RegionServer will first close all regions and then shut itself down. On shutdown, the RegionServer's ephemeral node in ZooKeeper will expire. -The master will notice the RegionServer gone and will treat it as a 'crashed' server; it will reassign the nodes the RegionServer was carrying. +The master will notice the RegionServer gone and will treat it as a 'crashed' server; it will reassign the nodes the RegionServer was carrying. .Disable the Load Balancer before Decommissioning a node [NOTE] ==== If the load balancer runs while a node is shutting down, then there could be contention between the Load Balancer and the Master's recovery of the just decommissioned RegionServer. Avoid any problems by disabling the balancer first. -See <> below. +See <> below. ==== .Kill Node Tool @@ -726,7 +723,7 @@ Hardware issues could be detected by specialized monitoring tools before the zo It deletes all the znodes of the server, starting the recovery process. Plug in the script into your monitoring/fault detection tools to initiate faster failover. Be careful how you use this disruptive tool. -Copy the script if you need to make use of it in a version of hbase previous to hbase-2.0. +Copy the script if you need to make use of it in a version of hbase previous to hbase-2.0. ==== A downside to the above stop of a RegionServer is that regions could be offline for a good period of time. @@ -748,7 +745,7 @@ Usage: graceful_stop.sh [--config &conf-dir>] [--restart] [--reload] [--thrift] ---- To decommission a loaded RegionServer, run the following: +$ - ./bin/graceful_stop.sh HOSTNAME+ where `HOSTNAME` is the host carrying the RegionServer you would decommission. + ./bin/graceful_stop.sh HOSTNAME+ where `HOSTNAME` is the host carrying the RegionServer you would decommission. .On `HOSTNAME` [NOTE] @@ -757,18 +754,18 @@ The `HOSTNAME` passed to _graceful_stop.sh_ must match the hostname that hbase i Check the list of RegionServers in the master UI for how HBase is referring to servers. Its usually hostname but can also be FQDN. Whatever HBase is using, this is what you should pass the _graceful_stop.sh_ decommission script. -If you pass IPs, the script is not yet smart enough to make a hostname (or FQDN) of it and so it will fail when it checks if server is currently running; the graceful unloading of regions will not run. +If you pass IPs, the script is not yet smart enough to make a hostname (or FQDN) of it and so it will fail when it checks if server is currently running; the graceful unloading of regions will not run. ==== The _graceful_stop.sh_ script will move the regions off the decommissioned RegionServer one at a time to minimize region churn. It will verify the region deployed in the new location before it will moves the next region and so on until the decommissioned server is carrying zero regions. -At this point, the _graceful_stop.sh_ tells the RegionServer +stop+. -The master will at this point notice the RegionServer gone but all regions will have already been redeployed and because the RegionServer went down cleanly, there will be no WAL logs to split. +At this point, the _graceful_stop.sh_ tells the RegionServer `stop`. +The master will at this point notice the RegionServer gone but all regions will have already been redeployed and because the RegionServer went down cleanly, there will be no WAL logs to split. .Load Balancer [NOTE] ==== -It is assumed that the Region Load Balancer is disabled while the +graceful_stop+ script runs (otherwise the balancer and the decommission script will end up fighting over region deployments). Use the shell to disable the balancer: +It is assumed that the Region Load Balancer is disabled while the `graceful_stop` script runs (otherwise the balancer and the decommission script will end up fighting over region deployments). Use the shell to disable the balancer: [source] ---- @@ -787,9 +784,9 @@ false 0 row(s) in 0.3590 seconds ---- -The +graceful_stop+ will check the balancer and if enabled, will turn it off before it goes to work. +The `graceful_stop` will check the balancer and if enabled, will turn it off before it goes to work. If it exits prematurely because of error, it will not have reset the balancer. -Hence, it is better to manage the balancer apart from +graceful_stop+ reenabling it after you are done w/ graceful_stop. +Hence, it is better to manage the balancer apart from `graceful_stop` reenabling it after you are done w/ graceful_stop. ==== [[draining.servers]] @@ -798,7 +795,7 @@ Hence, it is better to manage the balancer apart from +graceful_stop+ reenabling If you have a large cluster, you may want to decommission more than one machine at a time by gracefully stopping mutiple RegionServers concurrently. To gracefully drain multiple regionservers at the same time, RegionServers can be put into a "draining" state. This is done by marking a RegionServer as a draining node by creating an entry in ZooKeeper under the _hbase_root/draining_ znode. -This znode has format `name,port,startcode` just like the regionserver entries under _hbase_root/rs_ znode. +This znode has format `name,port,startcode` just like the regionserver entries under _hbase_root/rs_ znode. Without this facility, decommissioning mulitple nodes may be non-optimal because regions that are being drained from one region server may be moved to other regionservers that are also draining. Marking RegionServers to be in the draining state prevents this from happening. @@ -814,7 +811,7 @@ take a while to go down spewing errors in _dmesg_ -- or for some reason, run muc In this case you want to decommission the disk. You have two options. You can link:http://wiki.apache.org/hadoop/FAQ#I_want_to_make_a_large_cluster_smaller_by_taking_out_a_bunch_of_nodes_simultaneously._How_can_this_be_done.3F[decommission - the datanode] or, less disruptive in that only the bad disks data will be rereplicated, can stop the datanode, unmount the bad volume (You can't umount a volume while the datanode is using it), and then restart the datanode (presuming you have set dfs.datanode.failed.volumes.tolerated > 0). The regionserver will throw some errors in its logs as it recalibrates where to get its data from -- it will likely roll its WAL log too -- but in general but for some latency spikes, it should keep on chugging. + the datanode] or, less disruptive in that only the bad disks data will be rereplicated, can stop the datanode, unmount the bad volume (You can't umount a volume while the datanode is using it), and then restart the datanode (presuming you have set dfs.datanode.failed.volumes.tolerated > 0). The regionserver will throw some errors in its logs as it recalibrates where to get its data from -- it will likely roll its WAL log too -- but in general but for some latency spikes, it should keep on chugging. .Short Circuit Reads [NOTE] @@ -833,7 +830,7 @@ See the release notes for release you want to upgrade to, to find out about limi There are multiple ways to restart your cluster nodes, depending on your situation. These methods are detailed below. -==== Using the +rolling-restart.sh+ Script +==== Using the `rolling-restart.sh` Script HBase ships with a script, _bin/rolling-restart.sh_, that allows you to perform rolling restarts on the entire cluster, the master only, or the RegionServers only. The script is provided as a template for your own script, and is not explicitly tested. @@ -869,7 +866,7 @@ Limiting the Number of Threads:: ==== Manual Rolling Restart To retain more control over the process, you may wish to manually do a rolling restart across your cluster. -This uses the +graceful-stop.sh+ command <>. +This uses the `graceful-stop.sh` command <>. In this method, you can restart each RegionServer individually and then move its old regions back into place, retaining locality. If you also need to restart the Master, you need to do it separately, and restart the Master before restarting the RegionServers using this method. The following is an example of such a command. @@ -882,13 +879,13 @@ It disables the load balancer before moving the regions. $ for i in `cat conf/regionservers|sort`; do ./bin/graceful_stop.sh --restart --reload --debug $i; done &> /tmp/log.txt &; ---- -Monitor the output of the _/tmp/log.txt_ file to follow the progress of the script. +Monitor the output of the _/tmp/log.txt_ file to follow the progress of the script. ==== Logic for Crafting Your Own Rolling Restart Script Use the following guidelines if you want to create your own rolling restart script. -. Extract the new release, verify its configuration, and synchronize it to all nodes of your cluster using +rsync+, +scp+, or another secure synchronization mechanism. +. Extract the new release, verify its configuration, and synchronize it to all nodes of your cluster using `rsync`, `scp`, or another secure synchronization mechanism. . Use the hbck utility to ensure that the cluster is consistent. + ---- @@ -915,12 +912,12 @@ $ for i in `cat conf/regionservers|sort`; do ./bin/graceful_stop.sh --restart -- ---- + If you are running Thrift or REST servers, pass the --thrift or --rest options. -For other available options, run the +bin/graceful-stop.sh --help+ command. +For other available options, run the `bin/graceful-stop.sh --help` command. + It is important to drain HBase regions slowly when restarting multiple RegionServers. Otherwise, multiple regions go offline simultaneously and must be reassigned to other nodes, which may also go offline soon. This can negatively affect performance. -You can inject delays into the script above, for instance, by adding a Shell command such as +sleep+. +You can inject delays into the script above, for instance, by adding a Shell command such as `sleep`. To wait for 5 minutes between each RegionServer restart, modify the above script to the following: + ---- @@ -929,24 +926,24 @@ $ for i in `cat conf/regionservers|sort`; do ./bin/graceful_stop.sh --restart -- ---- . Restart the Master again, to clear out the dead servers list and re-enable the load balancer. -. Run the +hbck+ utility again, to be sure the cluster is consistent. +. Run the `hbck` utility again, to be sure the cluster is consistent. [[adding.new.node]] === Adding a New Node -Adding a new regionserver in HBase is essentially free, you simply start it like this: +$ ./bin/hbase-daemon.sh start regionserver+ and it will register itself with the master. +Adding a new regionserver in HBase is essentially free, you simply start it like this: `$ ./bin/hbase-daemon.sh start regionserver` and it will register itself with the master. Ideally you also started a DataNode on the same machine so that the RS can eventually start to have local files. -If you rely on ssh to start your daemons, don't forget to add the new hostname in _conf/regionservers_ on the master. +If you rely on ssh to start your daemons, don't forget to add the new hostname in _conf/regionservers_ on the master. At this point the region server isn't serving data because no regions have moved to it yet. If the balancer is enabled, it will start moving regions to the new RS. On a small/medium cluster this can have a very adverse effect on latency as a lot of regions will be offline at the same time. -It is thus recommended to disable the balancer the same way it's done when decommissioning a node and move the regions manually (or even better, using a script that moves them one by one). +It is thus recommended to disable the balancer the same way it's done when decommissioning a node and move the regions manually (or even better, using a script that moves them one by one). The moved regions will all have 0% locality and won't have any blocks in cache so the region server will have to use the network to serve requests. Apart from resulting in higher latency, it may also be able to use all of your network card's capacity. For practical purposes, consider that a standard 1GigE NIC won't be able to read much more than _100MB/s_. -In this case, or if you are in a OLAP environment and require having locality, then it is recommended to major compact the moved regions. +In this case, or if you are in a OLAP environment and require having locality, then it is recommended to major compact the moved regions. == HBase Metrics @@ -965,7 +962,7 @@ To configure metrics for a given region server, edit the _conf/hadoop-metrics2-h Restart the region server for the changes to take effect. To change the sampling rate for the default sink, edit the line beginning with `*.period`. -To filter which metrics are emitted or to extend the metrics framework, see link:http://hadoop.apache.org/docs/current/api/org/apache/hadoop/metrics2/package-summary.html +To filter which metrics are emitted or to extend the metrics framework, see link:http://hadoop.apache.org/docs/current/api/org/apache/hadoop/metrics2/package-summary.html .HBase Metrics and Ganglia [NOTE] @@ -993,19 +990,19 @@ Different metrics are exposed for the Master process and each region server proc The metrics for the region server are presented as a dump of the JMX bean in JSON format. This will dump out all metrics names and their values. To include metrics descriptions in the listing -- this can be useful when you are exploring what is available -- add a query string of `?description=true` so your URL becomes `http://REGIONSERVER_HOSTNAME:60030/jmx?description=true`. - Not all beans and attributes have descriptions. + Not all beans and attributes have descriptions. . To view metrics for the Master, connect to the Master's web UI instead (defaults to `http://localhost:60010` or port 16010 in HBase 1.0+) and click its [label]#Metrics Dump# link. To include metrics descriptions in the listing -- this can be useful when you are exploring what is available -- add a query string of `?description=true` so your URL becomes `http://REGIONSERVER_HOSTNAME:60010/jmx?description=true`. - Not all beans and attributes have descriptions. + Not all beans and attributes have descriptions. You can use many different tools to view JMX content by browsing MBeans. -This procedure uses +jvisualvm+, which is an application usually available in the JDK. +This procedure uses `jvisualvm`, which is an application usually available in the JDK. .Procedure: Browse the JMX Output of Available Metrics . Start HBase, if it is not already running. -. Run the command +jvisualvm+ command on a host with a GUI display. +. Run the command `jvisualvm` command on a host with a GUI display. You can launch it from the command line or another method appropriate for your operating system. . Be sure the [label]#VisualVM-MBeans# plugin is installed. Browse to *Tools -> Plugins*. Click [label]#Installed# and check whether the plugin is listed. If not, click [label]#Available Plugins#, select it, and click btn:[Install]. @@ -1014,8 +1011,8 @@ This procedure uses +jvisualvm+, which is an application usually available in th A detailed view opens in the right-hand panel. Click the [label]#MBeans# tab which appears as a tab in the top of the right-hand panel. . To access the HBase metrics, navigate to the appropriate sub-bean: -.* Master: -.* RegionServer: +.* Master: +.* RegionServer: . The name of each metric and its current value is displayed in the [label]#Attributes# tab. For a view which includes more details, including the description of each attribute, click the [label]#Metadata# tab. @@ -1051,7 +1048,7 @@ hbase.master.ritCountOverThreshold:: The number of regions that have been in transition longer than a threshold time (default: 60 seconds) hbase.master.ritOldestAge:: - The age of the longest region in transition, in milliseconds + The age of the longest region in transition, in milliseconds [[rs_metrics]] === Most Important RegionServer Metrics @@ -1148,7 +1145,7 @@ hbase.regionserver.mutationsWithoutWALCount :: === Overview The following metrics are arguably the most important to monitor for each RegionServer for "macro monitoring", preferably with a system like link:http://opentsdb.net/[OpenTSDB]. -If your cluster is having performance issues it's likely that you'll see something unusual with this group. +If your cluster is having performance issues it's likely that you'll see something unusual with this group. HBase:: * See <> @@ -1160,7 +1157,7 @@ OS:: Java:: * GC -For more information on HBase metrics, see <>. +For more information on HBase metrics, see <>. [[ops.slow.query]] === Slow Query Log @@ -1168,18 +1165,18 @@ For more information on HBase metrics, see <>. The HBase slow query log consists of parseable JSON structures describing the properties of those client operations (Gets, Puts, Deletes, etc.) that either took too long to run, or produced too much output. The thresholds for "too long to run" and "too much output" are configurable, as described below. The output is produced inline in the main region server logs so that it is easy to discover further details from context with other logged events. -It is also prepended with identifying tags [constant]+(responseTooSlow)+, [constant]+(responseTooLarge)+, [constant]+(operationTooSlow)+, and [constant]+(operationTooLarge)+ in order to enable easy filtering with grep, in case the user desires to see only slow queries. +It is also prepended with identifying tags `(responseTooSlow)`, `(responseTooLarge)`, `(operationTooSlow)`, and `(operationTooLarge)` in order to enable easy filtering with grep, in case the user desires to see only slow queries. ==== Configuration -There are two configuration knobs that can be used to adjust the thresholds for when queries are logged. +There are two configuration knobs that can be used to adjust the thresholds for when queries are logged. * `hbase.ipc.warn.response.time` Maximum number of milliseconds that a query can be run without being logged. Defaults to 10000, or 10 seconds. - Can be set to -1 to disable logging by time. + Can be set to -1 to disable logging by time. * `hbase.ipc.warn.response.size` Maximum byte size of response that a query can return without being logged. Defaults to 100 megabytes. - Can be set to -1 to disable logging by size. + Can be set to -1 to disable logging by size. ==== Metrics @@ -1190,8 +1187,8 @@ The slow query log exposes to metrics to JMX. ==== Output -The output is tagged with operation e.g. [constant]+(operationTooSlow)+ if the call was a client operation, such as a Put, Get, or Delete, which we expose detailed fingerprint information for. -If not, it is tagged [constant]+(responseTooSlow)+ and still produces parseable JSON output, but with less verbose information solely regarding its duration and size in the RPC itself. [constant]+TooLarge+ is substituted for [constant]+TooSlow+ if the response size triggered the logging, with [constant]+TooLarge+ appearing even in the case that both size and duration triggered logging. +The output is tagged with operation e.g. `(operationTooSlow)` if the call was a client operation, such as a Put, Get, or Delete, which we expose detailed fingerprint information for. +If not, it is tagged `(responseTooSlow)` and still produces parseable JSON output, but with less verbose information solely regarding its duration and size in the RPC itself. `TooLarge` is substituted for `TooSlow` if the response size triggered the logging, with `TooLarge` appearing even in the case that both size and duration triggered logging. ==== Example @@ -1199,13 +1196,13 @@ If not, it is tagged [constant]+(responseTooSlow)+ and still produces p [source] ---- 2011-09-08 10:01:25,824 WARN org.apache.hadoop.ipc.HBaseServer: (operationTooSlow): {"tables":{"riley2":{"puts":[{"totalColumns":11,"families":{"actions":[{"timestamp":1315501284459,"qualifier":"0","vlen":9667580},{"timestamp":1315501284459,"qualifier":"1","vlen":10122412},{"timestamp":1315501284459,"qualifier":"2","vlen":11104617},{"timestamp":1315501284459,"qualifier":"3","vlen":13430635}]},"row":"cfcd208495d565ef66e7dff9f98764da:0"}],"families":["actions"]}},"processingtimems":956,"client":"10.47.34.63:33623","starttimems":1315501284456,"queuetimems":0,"totalPuts":1,"class":"HRegionServer","responsesize":0,"method":"multiPut"} ----- +---- Note that everything inside the "tables" structure is output produced by MultiPut's fingerprint, while the rest of the information is RPC-specific, such as processing time and client IP/port. Other client operations follow the same pattern and the same general structure, with necessary differences due to the nature of the individual operations. -In the case that the call is not a client operation, that detailed fingerprint information will be completely absent. +In the case that the call is not a client operation, that detailed fingerprint information will be completely absent. -This particular example, for example, would indicate that the likely cause of slowness is simply a very large (on the order of 100MB) multiput, as we can tell by the "vlen," or value length, fields of each put in the multiPut. +This particular example, for example, would indicate that the likely cause of slowness is simply a very large (on the order of 100MB) multiput, as we can tell by the "vlen," or value length, fields of each put in the multiPut. === Block Cache Monitoring @@ -1230,7 +1227,7 @@ Have a look in the Web UI. == Cluster Replication -NOTE: This information was previously available at link:http://hbase.apache.org/replication.html[Cluster Replication]. +NOTE: This information was previously available at link:http://hbase.apache.org/replication.html[Cluster Replication]. HBase provides a cluster replication mechanism which allows you to keep one cluster's state synchronized with that of another cluster, using the write-ahead log (WAL) of the source cluster to propagate the changes. Some use cases for cluster replication include: @@ -1282,7 +1279,7 @@ Use the arrows to follow the data paths. image::hbase_replication_diagram.jpg[] HBase replication borrows many concepts from the [firstterm]_statement-based replication_ design used by MySQL. -Instead of SQL statements, entire WALEdits (consisting of multiple cell inserts coming from Put and Delete operations on the clients) are replicated in order to maintain atomicity. +Instead of SQL statements, entire WALEdits (consisting of multiple cell inserts coming from Put and Delete operations on the clients) are replicated in order to maintain atomicity. === Configuring Cluster Replication @@ -1312,8 +1309,8 @@ If both clusters use the same ZooKeeper cluster, you must use a different `zooke . On the source cluster, configure each column family to be replicated by setting its REPLICATION_SCOPE to 1, using commands such as the following in HBase Shell. + ---- -hbase> disable 'example_table' -hbase> alter 'example_table', {NAME => 'example_family', REPLICATION_SCOPE => '1'} +hbase> disable 'example_table' +hbase> alter 'example_table', {NAME => 'example_family', REPLICATION_SCOPE => '1'} hbase> enable 'example_table' ---- @@ -1321,7 +1318,7 @@ hbase> enable 'example_table' + ---- Considering 1 rs, with ratio 0.1 -Getting 1 rs from peer cluster # 0 +Getting 1 rs from peer cluster # 0 Choosing peer 10.10.1.49:62020 ---- @@ -1334,7 +1331,7 @@ The command has the following form: hbase org.apache.hadoop.hbase.mapreduce.replication.VerifyReplication [--starttime=timestamp1] [--stoptime=timestamp [--families=comma separated list of families] ---- + -The `VerifyReplication` command prints out `GOODROWS` and `BADROWS` counters to indicate rows that did and did not replicate correctly. +The `VerifyReplication` command prints out `GOODROWS` and `BADROWS` counters to indicate rows that did and did not replicate correctly. === Detailed Information About Cluster Replication @@ -1613,10 +1610,10 @@ The following metrics are exposed at the global region server level and (since H == HBase Backup There are two broad strategies for performing HBase backups: backing up with a full cluster shutdown, and backing up on a live cluster. -Each approach has pros and cons. +Each approach has pros and cons. For additional information, see link:http://blog.sematext.com/2011/03/11/hbase-backup-options/[HBase Backup - Options] over on the Sematext Blog. + Options] over on the Sematext Blog. [[ops.backup.fullshutdown]] === Full Shutdown Backup @@ -1624,7 +1621,7 @@ For additional information, see link:http://blog.sematext.com/2011/03/11/hbase-b Some environments can tolerate a periodic full shutdown of their HBase cluster, for example if it is being used a back-end analytic capacity and not serving front-end web-pages. The benefits are that the NameNode/Master are RegionServers are down, so there is no chance of missing any in-flight changes to either StoreFiles or metadata. The obvious con is that the cluster is down. -The steps include: +The steps include: [[ops.backup.fullshutdown.stop]] ==== Stop HBase @@ -1634,47 +1631,47 @@ The steps include: [[ops.backup.fullshutdown.distcp]] ==== Distcp -Distcp could be used to either copy the contents of the HBase directory in HDFS to either the same cluster in another directory, or to a different cluster. +Distcp could be used to either copy the contents of the HBase directory in HDFS to either the same cluster in another directory, or to a different cluster. Note: Distcp works in this situation because the cluster is down and there are no in-flight edits to files. -Distcp-ing of files in the HBase directory is not generally recommended on a live cluster. +Distcp-ing of files in the HBase directory is not generally recommended on a live cluster. [[ops.backup.fullshutdown.restore]] ==== Restore (if needed) The backup of the hbase directory from HDFS is copied onto the 'real' hbase directory via distcp. -The act of copying these files creates new HDFS metadata, which is why a restore of the NameNode edits from the time of the HBase backup isn't required for this kind of restore, because it's a restore (via distcp) of a specific HDFS directory (i.e., the HBase part) not the entire HDFS file-system. +The act of copying these files creates new HDFS metadata, which is why a restore of the NameNode edits from the time of the HBase backup isn't required for this kind of restore, because it's a restore (via distcp) of a specific HDFS directory (i.e., the HBase part) not the entire HDFS file-system. [[ops.backup.live.replication]] === Live Cluster Backup - Replication This approach assumes that there is a second cluster. -See the HBase page on link:http://hbase.apache.org/replication.html[replication] for more information. +See the HBase page on link:http://hbase.apache.org/replication.html[replication] for more information. [[ops.backup.live.copytable]] === Live Cluster Backup - CopyTable -The <> utility could either be used to copy data from one table to another on the same cluster, or to copy data to another table on another cluster. +The <> utility could either be used to copy data from one table to another on the same cluster, or to copy data to another table on another cluster. -Since the cluster is up, there is a risk that edits could be missed in the copy process. +Since the cluster is up, there is a risk that edits could be missed in the copy process. [[ops.backup.live.export]] === Live Cluster Backup - Export The <> approach dumps the content of a table to HDFS on the same cluster. -To restore the data, the <> utility would be used. +To restore the data, the <> utility would be used. -Since the cluster is up, there is a risk that edits could be missed in the export process. +Since the cluster is up, there is a risk that edits could be missed in the export process. [[ops.snapshots]] == HBase Snapshots HBase Snapshots allow you to take a snapshot of a table without too much impact on Region Servers. Snapshot, Clone and restore operations don't involve data copying. -Also, Exporting the snapshot to another cluster doesn't have impact on the Region Servers. +Also, Exporting the snapshot to another cluster doesn't have impact on the Region Servers. Prior to version 0.94.6, the only way to backup or to clone a table is to use CopyTable/ExportTable, or to copy all the hfiles in HDFS after disabling the table. -The disadvantages of these methods are that you can degrade region server performance (Copy/Export Table) or you need to disable the table, that means no reads or writes; and this is usually unacceptable. +The disadvantages of these methods are that you can degrade region server performance (Copy/Export Table) or you need to disable the table, that means no reads or writes; and this is usually unacceptable. [[ops.snapshots.configuration]] === Configuration @@ -1707,7 +1704,7 @@ hbase> snapshot 'myTable', 'myTableSnapshot-122112' The default behavior is to perform a flush of data in memory before the snapshot is taken. This means that data in memory is included in the snapshot. In most cases, this is the desired behavior. -However, if your set-up can tolerate data in memory being excluded from the snapshot, you can use the +SKIP_FLUSH+ option of the +snapshot+ command to disable and flushing while taking the snapshot. +However, if your set-up can tolerate data in memory being excluded from the snapshot, you can use the `SKIP_FLUSH` option of the `snapshot` command to disable and flushing while taking the snapshot. ---- hbase> snapshot 'mytable', 'snapshot123', {SKIP_FLUSH => true} @@ -1765,9 +1762,9 @@ hbase> restore_snapshot 'myTableSnapshot-122112' ---- NOTE: Since Replication works at log level and snapshots at file-system level, after a restore, the replicas will be in a different state from the master. -If you want to use restore, you need to stop replication and redo the bootstrap. +If you want to use restore, you need to stop replication and redo the bootstrap. -In case of partial data-loss due to misbehaving client, instead of a full restore that requires the table to be disabled, you can clone the table from the snapshot and use a Map-Reduce job to copy the data that you need, from the clone to the main one. +In case of partial data-loss due to misbehaving client, instead of a full restore that requires the table to be disabled, you can clone the table from the snapshot and use a Map-Reduce job to copy the data that you need, from the clone to the main one. [[ops.snapshots.acls]] === Snapshots operations and ACLs @@ -1809,7 +1806,7 @@ Start with a solid understanding of how HBase handles data internally. [[ops.capacity.nodes.datasize]] ==== Physical data size -Physical data size on disk is distinct from logical size of your data and is affected by the following: +Physical data size on disk is distinct from logical size of your data and is affected by the following: * Increased by HBase overhead + @@ -1868,7 +1865,7 @@ HDFS replication factor only affects your disk usage and is invisible to most HB You can view the current number of regions for a given table using the HMaster UI. In the [label]#Tables# section, the number of online regions for each table is listed in the [label]#Online Regions# column. This total only includes the in-memory state and does not include disabled or offline regions. -If you do not want to use the HMaster UI, you can determine the number of regions by counting the number of subdirectories of the /hbase// subdirectories in HDFS, or by running the +bin/hbase hbck+ command. +If you do not want to use the HMaster UI, you can determine the number of regions by counting the number of subdirectories of the /hbase/
/ subdirectories in HDFS, or by running the `bin/hbase hbck` command. Each of these methods may return a slightly different number, depending on the status of each region. [[ops.capacity.regions.count]] @@ -1979,8 +1976,8 @@ For pre-splitting howto, see <>. +Are all the network interfaces functioning correctly? Are you sure? See the Troubleshooting Case Study in <>. [[jvm]] == Java @@ -109,35 +109,33 @@ Are all the network interfaces functioning correctly? Are you sure? See the Trou [[gcpause]] ==== Long GC pauses -In his presentation, link:http://www.slideshare.net/cloudera/hbase-hug-presentation[Avoiding Full GCs - with MemStore-Local Allocation Buffers], Todd Lipcon describes two cases of stop-the-world garbage collections common in HBase, especially during loading; CMS failure modes and old generation heap fragmentation brought. +In his presentation, link:http://www.slideshare.net/cloudera/hbase-hug-presentation[Avoiding Full GCs with MemStore-Local Allocation Buffers], Todd Lipcon describes two cases of stop-the-world garbage collections common in HBase, especially during loading; CMS failure modes and old generation heap fragmentation brought. + To address the first, start the CMS earlier than default by adding `-XX:CMSInitiatingOccupancyFraction` and setting it down from defaults. -Start at 60 or 70 percent (The lower you bring down the threshold, the more GCing is done, the more CPU used). To address the second fragmentation issue, Todd added an experimental facility, -(((MSLAB))), that must be explicitly enabled in Apache HBase 0.90.x (Its defaulted to be on in Apache 0.92.x HBase). See `hbase.hregion.memstore.mslab.enabled` to true in your `Configuration`. +Start at 60 or 70 percent (The lower you bring down the threshold, the more GCing is done, the more CPU used). To address the second fragmentation issue, Todd added an experimental facility, +(MSLAB), that must be explicitly enabled in Apache HBase 0.90.x (It's defaulted to be _on_ in Apache 0.92.x HBase). Set `hbase.hregion.memstore.mslab.enabled` to true in your `Configuration`. See the cited slides for background and detail. -The latest jvms do better regards fragmentation so make sure you are running a recent release. -Read down in the message, link:http://osdir.com/ml/hotspot-gc-use/2011-11/msg00002.html[Identifying - concurrent mode failures caused by fragmentation]. +The latest JVMs do better regards fragmentation so make sure you are running a recent release. +Read down in the message, link:http://osdir.com/ml/hotspot-gc-use/2011-11/msg00002.html[Identifying concurrent mode failures caused by fragmentation]. Be aware that when enabled, each MemStore instance will occupy at least an MSLAB instance of memory. If you have thousands of regions or lots of regions each with many column families, this allocation of MSLAB may be responsible for a good portion of your heap allocation and in an extreme case cause you to OOME. -Disable MSLAB in this case, or lower the amount of memory it uses or float less regions per server. +Disable MSLAB in this case, or lower the amount of memory it uses or float less regions per server. -If you have a write-heavy workload, check out link:https://issues.apache.org/jira/browse/HBASE-8163[HBASE-8163 - MemStoreChunkPool: An improvement for JAVA GC when using MSLAB]. +If you have a write-heavy workload, check out link:https://issues.apache.org/jira/browse/HBASE-8163[HBASE-8163 MemStoreChunkPool: An improvement for JAVA GC when using MSLAB]. It describes configurations to lower the amount of young GC during write-heavy loadings. If you do not have HBASE-8163 installed, and you are trying to improve your young GC times, one trick to consider -- courtesy of our Liang Xie -- is to set the GC config `-XX:PretenureSizeThreshold` in _hbase-env.sh_ to be just smaller than the size of `hbase.hregion.memstore.mslab.chunksize` so MSLAB allocations happen in the tenured space directly rather than first in the young gen. -You'd do this because these MSLAB allocations are going to likely make it to the old gen anyways and rather than pay the price of a copies between s0 and s1 in eden space followed by the copy up from young to old gen after the MSLABs have achieved sufficient tenure, save a bit of YGC churn and allocate in the old gen directly. +You'd do this because these MSLAB allocations are going to likely make it to the old gen anyways and rather than pay the price of a copies between s0 and s1 in eden space followed by the copy up from young to old gen after the MSLABs have achieved sufficient tenure, save a bit of YGC churn and allocate in the old gen directly. -For more information about GC logs, see <>. +For more information about GC logs, see <>. -Consider also enabling the offheap Block Cache. +Consider also enabling the off-heap Block Cache. This has been shown to mitigate GC pause times. -See <> +See <> [[perf.configurations]] == HBase Configurations -See <>. +See <>. [[perf.compactions.and.splits]] === Managing Compactions @@ -147,22 +145,22 @@ For larger systems, managing link:[compactions and splits] may be something you [[perf.handlers]] === `hbase.regionserver.handler.count` -See <>. +See <>. [[perf.hfile.block.cache.size]] === `hfile.block.cache.size` -See <>. -A memory setting for the RegionServer process. +See <>. +A memory setting for the RegionServer process. [[blockcache.prefetch]] === Prefetch Option for Blockcache -link:https://issues.apache.org/jira/browse/HBASE-9857[HBASE-9857] adds a new option to prefetch HFile contents when opening the blockcache, if a columnfamily or regionserver property is set. +link:https://issues.apache.org/jira/browse/HBASE-9857[HBASE-9857] adds a new option to prefetch HFile contents when opening the BlockCache, if a Column family or RegionServer property is set. This option is available for HBase 0.98.3 and later. -The purpose is to warm the blockcache as rapidly as possible after the cache is opened, using in-memory table data, and not counting the prefetching as cache misses. -This is great for fast reads, but is not a good idea if the data to be preloaded will not fit into the blockcache. -It is useful for tuning the IO impact of prefetching versus the time before all data blocks are in cache. +The purpose is to warm the BlockCache as rapidly as possible after the cache is opened, using in-memory table data, and not counting the prefetching as cache misses. +This is great for fast reads, but is not a good idea if the data to be preloaded will not fit into the BlockCache. +It is useful for tuning the IO impact of prefetching versus the time before all data blocks are in cache. To enable prefetching on a given column family, you can use HBase Shell or use the API. @@ -192,73 +190,73 @@ See the API documentation for link:https://hbase.apache.org/apidocs/org/apache/h [[perf.rs.memstore.size]] === `hbase.regionserver.global.memstore.size` -See <>. -This memory setting is often adjusted for the RegionServer process depending on needs. +See <>. +This memory setting is often adjusted for the RegionServer process depending on needs. [[perf.rs.memstore.size.lower.limit]] === `hbase.regionserver.global.memstore.size.lower.limit` -See <>. -This memory setting is often adjusted for the RegionServer process depending on needs. +See <>. +This memory setting is often adjusted for the RegionServer process depending on needs. [[perf.hstore.blockingstorefiles]] === `hbase.hstore.blockingStoreFiles` -See <>. -If there is blocking in the RegionServer logs, increasing this can help. +See <>. +If there is blocking in the RegionServer logs, increasing this can help. [[perf.hregion.memstore.block.multiplier]] === `hbase.hregion.memstore.block.multiplier` -See <>. -If there is enough RAM, increasing this can help. +See <>. +If there is enough RAM, increasing this can help. [[hbase.regionserver.checksum.verify.performance]] === `hbase.regionserver.checksum.verify` Have HBase write the checksum into the datablock and save having to do the checksum seek whenever you read. -See <>, <> and <> For more information see the release note on link:https://issues.apache.org/jira/browse/HBASE-5074[HBASE-5074 support checksums in HBase block cache]. +See <>, <> and <>. For more information see the release note on link:https://issues.apache.org/jira/browse/HBASE-5074[HBASE-5074 support checksums in HBase block cache]. === Tuning `callQueue` Options -link:https://issues.apache.org/jira/browse/HBASE-11355[HBASE-11355] introduces several callQueue tuning mechanisms which can increase performance. +link:https://issues.apache.org/jira/browse/HBASE-11355[HBASE-11355] introduces several callQueue tuning mechanisms which can increase performance. See the JIRA for some benchmarking information. -* To increase the number of callqueues, set +hbase.ipc.server.num.callqueue+ to a value greater than `1`. -* To split the callqueue into separate read and write queues, set `hbase.ipc.server.callqueue.read.ratio` to a value between `0` and `1`. - This factor weights the queues toward writes (if below .5) or reads (if above .5). Another way to say this is that the factor determines what percentage of the split queues are used for reads. - The following examples illustrate some of the possibilities. - Note that you always have at least one write queue, no matter what setting you use. -+ +To increase the number of callqueues, set `hbase.ipc.server.num.callqueue` to a value greater than `1`. +To split the callqueue into separate read and write queues, set `hbase.ipc.server.callqueue.read.ratio` to a value between `0` and `1`. +This factor weights the queues toward writes (if below .5) or reads (if above .5). Another way to say this is that the factor determines what percentage of the split queues are used for reads. +The following examples illustrate some of the possibilities. +Note that you always have at least one write queue, no matter what setting you use. + * The default value of `0` does not split the queue. * A value of `.3` uses 30% of the queues for reading and 60% for writing. - Given a value of `10` for +hbase.ipc.server.num.callqueue+, 3 queues would be used for reads and 7 for writes. + Given a value of `10` for `hbase.ipc.server.num.callqueue`, 3 queues would be used for reads and 7 for writes. * A value of `.5` uses the same number of read queues and write queues. - Given a value of `10` for +hbase.ipc.server.num.callqueue+, 5 queues would be used for reads and 5 for writes. + Given a value of `10` for `hbase.ipc.server.num.callqueue`, 5 queues would be used for reads and 5 for writes. * A value of `.6` uses 60% of the queues for reading and 30% for reading. - Given a value of `10` for +hbase.ipc.server.num.callqueue+, 7 queues would be used for reads and 3 for writes. + Given a value of `10` for `hbase.ipc.server.num.callqueue`, 7 queues would be used for reads and 3 for writes. * A value of `1.0` uses one queue to process write requests, and all other queues process read requests. - A value higher than `1.0` has the same effect as a value of `1.0`. - Given a value of `10` for +hbase.ipc.server.num.callqueue+, 9 queues would be used for reads and 1 for writes. + A value higher than `1.0` has the same effect as a value of `1.0`. + Given a value of `10` for `hbase.ipc.server.num.callqueue`, 9 queues would be used for reads and 1 for writes. + +You can also split the read queues so that separate queues are used for short reads (from Get operations) and long reads (from Scan operations), by setting the `hbase.ipc.server.callqueue.scan.ratio` option. +This option is a factor between 0 and 1, which determine the ratio of read queues used for Gets and Scans. +More queues are used for Gets if the value is below `.5` and more are used for scans if the value is above `.5`. +No matter what setting you use, at least one read queue is used for Get operations. -* You can also split the read queues so that separate queues are used for short reads (from Get operations) and long reads (from Scan operations), by setting the +hbase.ipc.server.callqueue.scan.ratio+ option. - This option is a factor between 0 and 1, which determine the ratio of read queues used for Gets and Scans. - More queues are used for Gets if the value is below `.5` and more are used for scans if the value is above `.5`. - No matter what setting you use, at least one read queue is used for Get operations. -+ * A value of `0` does not split the read queue. * A value of `.3` uses 60% of the read queues for Gets and 30% for Scans. - Given a value of `20` for +hbase.ipc.server.num.callqueue+ and a value of `.5` for `hbase.ipc.server.callqueue.read.ratio`, 10 queues would be used for reads, out of those 10, 7 would be used for Gets and 3 for Scans. + Given a value of `20` for `hbase.ipc.server.num.callqueue` and a value of `.5` for `hbase.ipc.server.callqueue.read.ratio`, 10 queues would be used for reads, out of those 10, 7 would be used for Gets and 3 for Scans. * A value of `.5` uses half the read queues for Gets and half for Scans. - Given a value of `20` for +hbase.ipc.server.num.callqueue+ and a value of `.5` for `hbase.ipc.server.callqueue.read.ratio`, 10 queues would be used for reads, out of those 10, 5 would be used for Gets and 5 for Scans. + Given a value of `20` for `hbase.ipc.server.num.callqueue` and a value of `.5` for `hbase.ipc.server.callqueue.read.ratio`, 10 queues would be used for reads, out of those 10, 5 would be used for Gets and 5 for Scans. * A value of `.6` uses 30% of the read queues for Gets and 60% for Scans. - Given a value of `20` for +hbase.ipc.server.num.callqueue+ and a value of `.5` for `hbase.ipc.server.callqueue.read.ratio`, 10 queues would be used for reads, out of those 10, 3 would be used for Gets and 7 for Scans. + Given a value of `20` for `hbase.ipc.server.num.callqueue` and a value of `.5` for `hbase.ipc.server.callqueue.read.ratio`, 10 queues would be used for reads, out of those 10, 3 would be used for Gets and 7 for Scans. * A value of `1.0` uses all but one of the read queues for Scans. - Given a value of `20` for +hbase.ipc.server.num.callqueue+ and a value of`.5` for `hbase.ipc.server.callqueue.read.ratio`, 10 queues would be used for reads, out of those 10, 1 would be used for Gets and 9 for Scans. + Given a value of `20` for `hbase.ipc.server.num.callqueue` and a value of`.5` for `hbase.ipc.server.callqueue.read.ratio`, 10 queues would be used for reads, out of those 10, 1 would be used for Gets and 9 for Scans. + +You can use the new option `hbase.ipc.server.callqueue.handler.factor` to programmatically tune the number of queues: -* You can use the new option `hbase.ipc.server.callqueue.handler.factor` to programmatically tune the number of queues: -+ * A value of `0` uses a single shared queue between all the handlers. * A value of `1` uses a separate queue for each handler. * A value between `0` and `1` tunes the number of queues against the number of handlers. @@ -268,13 +266,13 @@ Having more queues, such as in a situation where you have one queue per handler, The trade-off is that if you have some queues with long-running tasks, a handler may end up waiting to execute from that queue rather than processing another queue which has waiting tasks. -For these values to take effect on a given Region Server, the Region Server must be restarted. +For these values to take effect on a given RegionServer, the RegionServer must be restarted. These parameters are intended for testing purposes and should be used carefully. [[perf.zookeeper]] == ZooKeeper -See <> for information on configuring ZooKeeper, and see the part about having a dedicated disk. +See <> for information on configuring ZooKeeper, and see the part about having a dedicated disk. [[perf.schema]] == Schema Design @@ -282,20 +280,20 @@ See <> for information on configuring ZooKeeper, and see th [[perf.number.of.cfs]] === Number of Column Families -See <>. +See <>. [[perf.schema.keys]] === Key and Attribute Lengths -See <>. -See also <> for compression caveats. +See <>. +See also <> for compression caveats. [[schema.regionsize]] === Table RegionSize -The regionsize can be set on a per-table basis via `setFileSize` on link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/HTableDescriptor.html[HTableDescriptor] in the event where certain tables require different regionsizes than the configured default regionsize. +The regionsize can be set on a per-table basis via `setFileSize` on link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/HTableDescriptor.html[HTableDescriptor] in the event where certain tables require different regionsizes than the configured default regionsize. -See <> for more information. +See <> for more information. [[schema.bloom]] === Bloom Filters @@ -303,13 +301,13 @@ See <> for more information. A Bloom filter, named for its creator, Burton Howard Bloom, is a data structure which is designed to predict whether a given element is a member of a set of data. A positive result from a Bloom filter is not always accurate, but a negative result is guaranteed to be accurate. Bloom filters are designed to be "accurate enough" for sets of data which are so large that conventional hashing mechanisms would be impractical. -For more information about Bloom filters in general, refer to link:http://en.wikipedia.org/wiki/Bloom_filter. +For more information about Bloom filters in general, refer to http://en.wikipedia.org/wiki/Bloom_filter. In terms of HBase, Bloom filters provide a lightweight in-memory structure to reduce the number of disk reads for a given Get operation (Bloom filters do not work with Scans) to only the StoreFiles likely to contain the desired Row. -The potential performance gain increases with the number of parallel reads. +The potential performance gain increases with the number of parallel reads. The Bloom filters themselves are stored in the metadata of each HFile and never need to be updated. -When an HFile is opened because a region is deployed to a RegionServer, the Bloom filter is loaded into memory. +When an HFile is opened because a region is deployed to a RegionServer, the Bloom filter is loaded into memory. HBase includes some tuning mechanisms for folding the Bloom filter to reduce the size and keep the false positive rate within a desired range. @@ -317,8 +315,7 @@ Bloom filters were introduced in link:https://issues.apache.org/jira/browse/HBAS Since HBase 0.96, row-based Bloom filters are enabled by default. (link:https://issues.apache.org/jira/browse/HBASE-8450[HBASE-]) -For more information on Bloom filters in relation to HBase, see <> for more information, or the following Quora discussion: link:http://www.quora.com/How-are-bloom-filters-used-in-HBase[How are bloom - filters used in HBase?]. +For more information on Bloom filters in relation to HBase, see <> for more information, or the following Quora discussion: link:http://www.quora.com/How-are-bloom-filters-used-in-HBase[How are bloom filters used in HBase?]. [[bloom.filters.when]] ==== When To Use Bloom Filters @@ -327,16 +324,16 @@ Since HBase 0.96, row-based Bloom filters are enabled by default. You may choose to disable them or to change some tables to use row+column Bloom filters, depending on the characteristics of your data and how it is loaded into HBase. To determine whether Bloom filters could have a positive impact, check the value of `blockCacheHitRatio` in the RegionServer metrics. -If Bloom filters are enabled, the value of `blockCacheHitRatio` should increase, because the Bloom filter is filtering out blocks that are definitely not needed. +If Bloom filters are enabled, the value of `blockCacheHitRatio` should increase, because the Bloom filter is filtering out blocks that are definitely not needed. You can choose to enable Bloom filters for a row or for a row+column combination. If you generally scan entire rows, the row+column combination will not provide any benefit. A row-based Bloom filter can operate on a row+column Get, but not the other way around. However, if you have a large number of column-level Puts, such that a row may be present in every StoreFile, a row-based filter will always return a positive result and provide no benefit. Unless you have one column per row, row+column Bloom filters require more space, in order to store more keys. -Bloom filters work best when the size of each data entry is at least a few kilobytes in size. +Bloom filters work best when the size of each data entry is at least a few kilobytes in size. -Overhead will be reduced when your data is stored in a few larger StoreFiles, to avoid extra disk IO during low-level scans to find a specific row. +Overhead will be reduced when your data is stored in a few larger StoreFiles, to avoid extra disk IO during low-level scans to find a specific row. Bloom filters need to be rebuilt upon deletion, so may not be appropriate in environments with a large number of deletions. @@ -345,7 +342,7 @@ Bloom filters need to be rebuilt upon deletion, so may not be appropriate in env Bloom filters are enabled on a Column Family. You can do this by using the setBloomFilterType method of HColumnDescriptor or using the HBase API. Valid values are `NONE` (the default), `ROW`, or `ROWCOL`. -See <> for more information on `ROW` versus `ROWCOL`. +See <> for more information on `ROW` versus `ROWCOL`. See also the API documentation for link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/HColumnDescriptor.html[HColumnDescriptor]. The following example creates a table and enables a ROWCOL Bloom filter on the `colfam1` column family. @@ -357,7 +354,7 @@ hbase> create 'mytable',{NAME => 'colfam1', BLOOMFILTER => 'ROWCOL'} ==== Configuring Server-Wide Behavior of Bloom Filters -You can configure the following settings in the _hbase-site.xml_. +You can configure the following settings in the _hbase-site.xml_. [cols="1,1,1", options="header"] |=== @@ -367,8 +364,7 @@ You can configure the following settings in the _hbase-site.xml_. | io.hfile.bloom.enabled | yes -| Set to no to kill bloom filters server-wide if - something goes wrong +| Set to no to kill bloom filters server-wide if something goes wrong | io.hfile.bloom.error.rate | .01 @@ -383,18 +379,16 @@ You can configure the following settings in the _hbase-site.xml_. | io.storefile.bloom.max.keys | 128000000 -| For default (single-block) Bloom filters, this specifies the maximum - number of keys. +| For default (single-block) Bloom filters, this specifies the maximum number of keys. | io.storefile.delete.family.bloom.enabled | true -| Master switch to enable Delete Family Bloom filters and store them in - the StoreFile. +| Master switch to enable Delete Family Bloom filters and store them in the StoreFile. | io.storefile.bloom.block.size | 65536 | Target Bloom block size. Bloom filter blocks of approximately this size - are interleaved with data blocks. + are interleaved with data blocks. | hfile.block.bloom.cacheonwrite | false @@ -404,35 +398,35 @@ You can configure the following settings in the _hbase-site.xml_. [[schema.cf.blocksize]] === ColumnFamily BlockSize -The blocksize can be configured for each ColumnFamily in a table, and this defaults to 64k. +The blocksize can be configured for each ColumnFamily in a table, and defaults to 64k. Larger cell values require larger blocksizes. -There is an inverse relationship between blocksize and the resulting StoreFile indexes (i.e., if the blocksize is doubled then the resulting indexes should be roughly halved). +There is an inverse relationship between blocksize and the resulting StoreFile indexes (i.e., if the blocksize is doubled then the resulting indexes should be roughly halved). -See link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/HColumnDescriptor.html[HColumnDescriptor] and <>for more information. +See link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/HColumnDescriptor.html[HColumnDescriptor] and <>for more information. [[cf.in.memory]] === In-Memory ColumnFamilies ColumnFamilies can optionally be defined as in-memory. Data is still persisted to disk, just like any other ColumnFamily. -In-memory blocks have the highest priority in the <>, but it is not a guarantee that the entire table will be in memory. +In-memory blocks have the highest priority in the <>, but it is not a guarantee that the entire table will be in memory. -See link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/HColumnDescriptor.html[HColumnDescriptor] for more information. +See link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/HColumnDescriptor.html[HColumnDescriptor] for more information. [[perf.compression]] === Compression Production systems should use compression with their ColumnFamily definitions. -See <> for more information. +See <> for more information. [[perf.compression.however]] ==== However... Compression deflates data _on disk_. When it's in-memory (e.g., in the MemStore) or on the wire (e.g., transferring between RegionServer and Client) it's inflated. -So while using ColumnFamily compression is a best practice, but it's not going to completely eliminate the impact of over-sized Keys, over-sized ColumnFamily names, or over-sized Column names. +So while using ColumnFamily compression is a best practice, but it's not going to completely eliminate the impact of over-sized Keys, over-sized ColumnFamily names, or over-sized Column names. -See <> on for schema design tips, and <> for more information on HBase stores data internally. +See <> on for schema design tips, and <> for more information on HBase stores data internally. [[perf.general]] == HBase General Patterns @@ -444,7 +438,6 @@ When people get started with HBase they have a tendency to write code that looks [source,java] ---- - Get get = new Get(rowkey); Result r = htable.get(get); byte[] b = r.getValue(Bytes.toBytes("cf"), Bytes.toBytes("attr")); // returns current version of value @@ -455,7 +448,6 @@ It's better to use constants for the byte-arrays, like this: [source,java] ---- - public static final byte[] CF = "cf".getBytes(); public static final byte[] ATTR = "attr".getBytes(); ... @@ -471,61 +463,60 @@ byte[] b = r.getValue(CF, ATTR); // returns current version of value === Batch Loading Use the bulk load tool if you can. -See <>. -Otherwise, pay attention to the below. +See <>. +Otherwise, pay attention to the below. [[precreate.regions]] -=== Table Creation: Pre-Creating Regions +=== Table Creation: Pre-Creating Regions Tables in HBase are initially created with one region by default. For bulk imports, this means that all clients will write to the same region until it is large enough to split and become distributed across the cluster. A useful pattern to speed up the bulk import process is to pre-create empty regions. -Be somewhat conservative in this, because too-many regions can actually degrade performance. +Be somewhat conservative in this, because too-many regions can actually degrade performance. There are two different approaches to pre-creating splits. -The first approach is to rely on the default `HBaseAdmin` strategy (which is implemented in `Bytes.split`)... +The first approach is to rely on the default `HBaseAdmin` strategy (which is implemented in `Bytes.split`)... [source,java] ---- -byte[] startKey = ...; // your lowest key -byte[] endKey = ...; // your highest key -int numberOfRegions = ...; // # of regions to create +byte[] startKey = ...; // your lowest key +byte[] endKey = ...; // your highest key +int numberOfRegions = ...; // # of regions to create admin.createTable(table, startKey, endKey, numberOfRegions); ---- -And the other approach is to define the splits yourself... +And the other approach is to define the splits yourself... [source,java] ---- - byte[][] splits = ...; // create your own splits admin.createTable(table, splits); ---- -See <> for issues related to understanding your keyspace and pre-creating regions. -See <> for discussion on manually pre-splitting regions. +See <> for issues related to understanding your keyspace and pre-creating regions. +See <> for discussion on manually pre-splitting regions. [[def.log.flush]] -=== Table Creation: Deferred Log Flush +=== Table Creation: Deferred Log Flush The default behavior for Puts using the Write Ahead Log (WAL) is that `WAL` edits will be written immediately. If deferred log flush is used, WAL edits are kept in memory until the flush period. The benefit is aggregated and asynchronous `WAL`- writes, but the potential downside is that if the RegionServer goes down the yet-to-be-flushed edits are lost. -This is safer, however, than not using WAL at all with Puts. +This is safer, however, than not using WAL at all with Puts. Deferred log flush can be configured on tables via link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/HTableDescriptor.html[HTableDescriptor]. -The default value of `hbase.regionserver.optionallogflushinterval` is 1000ms. +The default value of `hbase.regionserver.optionallogflushinterval` is 1000ms. [[perf.hbase.client.autoflush]] === HBase Client: AutoFlush -When performing a lot of Puts, make sure that setAutoFlush is set to false on your link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/HTable.html[HTable] instance. +When performing a lot of Puts, make sure that setAutoFlush is set to false on your link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/HTable.html[HTable] instance. Otherwise, the Puts will be sent one at a time to the RegionServer. -Puts added via ` htable.add(Put)` and ` htable.add( Put)` wind up in the same write buffer. +Puts added via `htable.add(Put)` and `htable.add( Put)` wind up in the same write buffer. If `autoFlush = false`, these messages are not sent until the write-buffer is filled. -To explicitly flush the messages, call [method]+flushCommits+. -Calling [method]+close+ on the `HTable` instance will invoke [method]+flushCommits+. +To explicitly flush the messages, call `flushCommits`. +Calling `close` on the `HTable` instance will invoke `flushCommits`. [[perf.hbase.client.putwal]] === HBase Client: Turn off WAL on Puts @@ -536,47 +527,46 @@ Bulk loads can be re-run in the event of a crash, with little risk of data loss. WARNING: If you disable the WAL for anything other than bulk loads, your data is at risk. -In general, it is best to use WAL for Puts, and where loading throughput is a concern to use link:[bulk loading] techniques instead. +In general, it is best to use WAL for Puts, and where loading throughput is a concern to use bulk loading techniques instead. For normal Puts, you are not likely to see a performance improvement which would outweigh the risk. -To disable the WAL, see <>. +To disable the WAL, see <>. [[perf.hbase.client.regiongroup]] === HBase Client: Group Puts by RegionServer In addition to using the writeBuffer, grouping `Put`s by RegionServer can reduce the number of client RPC calls per writeBuffer flush. -There is a utility `HTableUtil` currently on TRUNK that does this, but you can either copy that or implement your own version for those still on 0.90.x or earlier. +There is a utility `HTableUtil` currently on TRUNK that does this, but you can either copy that or implement your own version for those still on 0.90.x or earlier. [[perf.hbase.write.mr.reducer]] === MapReduce: Skip The Reducer When writing a lot of data to an HBase table from a MR job (e.g., with link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/mapreduce/TableOutputFormat.html[TableOutputFormat]), and specifically where Puts are being emitted from the Mapper, skip the Reducer step. When a Reducer step is used, all of the output (Puts) from the Mapper will get spooled to disk, then sorted/shuffled to other Reducers that will most likely be off-node. -It's far more efficient to just write directly to HBase. +It's far more efficient to just write directly to HBase. -For summary jobs where HBase is used as a source and a sink, then writes will be coming from the Reducer step (e.g., summarize values then write out result). This is a different processing problem than from the the above case. +For summary jobs where HBase is used as a source and a sink, then writes will be coming from the Reducer step (e.g., summarize values then write out result). This is a different processing problem than from the the above case. [[perf.one.region]] === Anti-Pattern: One Hot Region -If all your data is being written to one region at a time, then re-read the section on processing link:[timeseries] data. +If all your data is being written to one region at a time, then re-read the section on processing timeseries data. -Also, if you are pre-splitting regions and all your data is _still_ winding up in a single region even though your keys aren't monotonically increasing, confirm that your keyspace actually works with the split strategy. +Also, if you are pre-splitting regions and all your data is _still_ winding up in a single region even though your keys aren't monotonically increasing, confirm that your keyspace actually works with the split strategy. There are a variety of reasons that regions may appear "well split" but won't work with your data. -As the HBase client communicates directly with the RegionServers, this can be obtained via link:hhttp://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/HTable.html#getRegionLocation(byte[])[HTable.getRegionLocation]. +As the HBase client communicates directly with the RegionServers, this can be obtained via link:hhttp://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/HTable.html#getRegionLocation(byte[])[HTable.getRegionLocation]. -See <>, as well as <> +See <>, as well as <> [[perf.reading]] == Reading from HBase The mailing list can help if you are having performance issues. -For example, here is a good general thread on what to look at addressing read-time issues: link:http://search-hadoop.com/m/qOo2yyHtCC1[HBase Random Read latency > - 100ms] +For example, here is a good general thread on what to look at addressing read-time issues: link:http://search-hadoop.com/m/qOo2yyHtCC1[HBase Random Read latency > 100ms] [[perf.hbase.client.caching]] === Scan Caching -If HBase is used as an input source for a MapReduce job, for example, make sure that the input link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Scan.html[Scan] instance to the MapReduce job has [method]+setCaching+ set to something greater than the default (which is 1). Using the default value means that the map-task will make call back to the region-server for every record processed. +If HBase is used as an input source for a MapReduce job, for example, make sure that the input link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Scan.html[Scan] instance to the MapReduce job has `setCaching` set to something greater than the default (which is 1). Using the default value means that the map-task will make call back to the region-server for every record processed. Setting this value to 500, for example, will transfer 500 rows at a time to the client to be processed. There is a cost/benefit to have the cache value be large because it costs more in memory for both client and RegionServer, so bigger isn't always better. @@ -585,18 +575,18 @@ There is a cost/benefit to have the cache value be large because it costs more i Scan settings in MapReduce jobs deserve special attention. Timeouts can result (e.g., UnknownScannerException) in Map tasks if it takes longer to process a batch of records before the client goes back to the RegionServer for the next set of data. -This problem can occur because there is non-trivial processing occuring per row. +This problem can occur because there is non-trivial processing occurring per row. If you process rows quickly, set caching higher. -If you process rows more slowly (e.g., lots of transformations per row, writes), then set caching lower. +If you process rows more slowly (e.g., lots of transformations per row, writes), then set caching lower. -Timeouts can also happen in a non-MapReduce use case (i.e., single threaded HBase client doing a Scan), but the processing that is often performed in MapReduce jobs tends to exacerbate this issue. +Timeouts can also happen in a non-MapReduce use case (i.e., single threaded HBase client doing a Scan), but the processing that is often performed in MapReduce jobs tends to exacerbate this issue. [[perf.hbase.client.selection]] === Scan Attribute Selection Whenever a Scan is used to process large numbers of rows (and especially when used as a MapReduce source), be aware of which attributes are selected. -If `scan.addFamily` is called then _all_ of the attributes in the specified ColumnFamily will be returned to the client. -If only a small number of the available attributes are to be processed, then only those attributes should be specified in the input scan because attribute over-selection is a non-trivial performance penalty over large datasets. +If `scan.addFamily` is called then _all_ of the attributes in the specified ColumnFamily will be returned to the client. +If only a small number of the available attributes are to be processed, then only those attributes should be specified in the input scan because attribute over-selection is a non-trivial performance penalty over large datasets. [[perf.hbase.client.seek]] === Avoid scan seeks @@ -610,7 +600,6 @@ The following code instructs the RegionServer to attempt two iterations of next [source,java] ---- - Scan scan = new Scan(); scan.addColumn(...); scan.setAttribute(Scan.HINT_LOOKAHEAD, Bytes.toBytes(2)); @@ -620,18 +609,17 @@ table.getScanner(scan); [[perf.hbase.mr.input]] === MapReduce - Input Splits -For MapReduce jobs that use HBase tables as a source, if there a pattern where the "slow" map tasks seem to have the same Input Split (i.e., the RegionServer serving the data), see the Troubleshooting Case Study in <>. +For MapReduce jobs that use HBase tables as a source, if there a pattern where the "slow" map tasks seem to have the same Input Split (i.e., the RegionServer serving the data), see the Troubleshooting Case Study in <>. [[perf.hbase.client.scannerclose]] === Close ResultScanners -This isn't so much about improving performance but rather _avoiding_ performance problems. -If you forget to close link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/ResultScanner.html[ResultScanners] you can cause problems on the RegionServers. -Always have ResultScanner processing enclosed in try/catch blocks... +This isn't so much about improving performance but rather _avoiding_ performance problems. +If you forget to close link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/ResultScanner.html[ResultScanners] you can cause problems on the RegionServers. +Always have ResultScanner processing enclosed in try/catch blocks. [source,java] ---- - Scan scan = new Scan(); // set attrs... ResultScanner rs = htable.getScanner(scan); @@ -647,44 +635,42 @@ htable.close(); [[perf.hbase.client.blockcache]] === Block Cache -link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Scan.html[Scan] instances can be set to use the block cache in the RegionServer via the [method]+setCacheBlocks+ method. +link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Scan.html[Scan] instances can be set to use the block cache in the RegionServer via the `setCacheBlocks` method. For input Scans to MapReduce jobs, this should be `false`. For frequently accessed rows, it is advisable to use the block cache. -Cache more data by moving your Block Cache offheap. -See <> +Cache more data by moving your Block Cache off-heap. +See <> [[perf.hbase.client.rowkeyonly]] === Optimal Loading of Row Keys -When performing a table link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Scan.html[scan] where only the row keys are needed (no families, qualifiers, values or timestamps), add a FilterList with a `MUST_PASS_ALL` operator to the scanner using [method]+setFilter+. -The filter list should include both a link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/filter/FirstKeyOnlyFilter.html[FirstKeyOnlyFilter] and a link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/filter/KeyOnlyFilter.html[KeyOnlyFilter]. -Using this filter combination will result in a worst case scenario of a RegionServer reading a single value from disk and minimal network traffic to the client for a single row. +When performing a table link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Scan.html[scan] where only the row keys are needed (no families, qualifiers, values or timestamps), add a FilterList with a `MUST_PASS_ALL` operator to the scanner using `setFilter`. +The filter list should include both a link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/filter/FirstKeyOnlyFilter.html[FirstKeyOnlyFilter] and a link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/filter/KeyOnlyFilter.html[KeyOnlyFilter]. +Using this filter combination will result in a worst case scenario of a RegionServer reading a single value from disk and minimal network traffic to the client for a single row. [[perf.hbase.read.dist]] === Concurrency: Monitor Data Spread When performing a high number of concurrent reads, monitor the data spread of the target tables. -If the target table(s) have too few regions then the reads could likely be served from too few nodes. +If the target table(s) have too few regions then the reads could likely be served from too few nodes. -See <>, as well as <> +See <>, as well as <> [[blooms]] === Bloom Filters Enabling Bloom Filters can save your having to go to disk and can help improve read latencies. -link:http://en.wikipedia.org/wiki/Bloom_filter[Bloom filters] were developed over in link:https://issues.apache.org/jira/browse/HBASE-1200[HBase-1200 Add - bloomfilters]. -For description of the development process -- why static blooms rather than dynamic -- and for an overview of the unique properties that pertain to blooms in HBase, as well as possible future directions, see the _Development Process_ section of the document link:https://issues.apache.org/jira/secure/attachment/12444007/Bloom_Filters_in_HBase.pdf[BloomFilters - in HBase] attached to link:https://issues.apache.org/jira/browse/HBASE-1200[HBase-1200]. +link:http://en.wikipedia.org/wiki/Bloom_filter[Bloom filters] were developed over in link:https://issues.apache.org/jira/browse/HBASE-1200[HBase-1200 Add bloomfilters]. +For description of the development process -- why static blooms rather than dynamic -- and for an overview of the unique properties that pertain to blooms in HBase, as well as possible future directions, see the _Development Process_ section of the document link:https://issues.apache.org/jira/secure/attachment/12444007/Bloom_Filters_in_HBase.pdf[BloomFilters in HBase] attached to link:https://issues.apache.org/jira/browse/HBASE-1200[HBASE-1200]. The bloom filters described here are actually version two of blooms in HBase. In versions up to 0.19.x, HBase had a dynamic bloom option based on work done by the link:http://www.one-lab.org[European Commission One-Lab Project 034819]. The core of the HBase bloom work was later pulled up into Hadoop to implement org.apache.hadoop.io.BloomMapFile. Version 1 of HBase blooms never worked that well. Version 2 is a rewrite from scratch though again it starts with the one-lab work. -See also <>. +See also <>. [[bloom_footprint]] ==== Bloom StoreFile footprint @@ -698,11 +684,11 @@ Bloom filters add an entry to the `StoreFile` general `FileInfo` data structure ===== BloomFilter entries in `StoreFile` metadata `BLOOM_FILTER_META` holds Bloom Size, Hash Function used, etc. -Its small in size and is cached on `StoreFile.Reader` load +It's small in size and is cached on `StoreFile.Reader` load `BLOOM_FILTER_DATA` is the actual bloomfilter data. Obtained on-demand. -Stored in the LRU cache, if it is enabled (Its enabled by default). +Stored in the LRU cache, if it is enabled (It's enabled by default). [[config.bloom]] ==== Bloom Filter Configuration @@ -723,8 +709,7 @@ to .5%) == +1 bit per bloom entry. `io.hfile.bloom.max.fold` = guaranteed minimum fold rate. Most people should leave this alone. Default = 7, or can collapse to at least 1/128th of original size. -See the _Development Process_ section of the document link:https://issues.apache.org/jira/secure/attachment/12444007/Bloom_Filters_in_HBase.pdf[BloomFilters - in HBase] for more on what this option means. +See the _Development Process_ section of the document link:https://issues.apache.org/jira/secure/attachment/12444007/Bloom_Filters_in_HBase.pdf[BloomFilters in HBase] for more on what this option means. === Hedged Reads @@ -736,12 +721,14 @@ Hedged reads can be helpful for times where a rare slow read is caused by a tran Because a HBase RegionServer is a HDFS client, you can enable hedged reads in HBase, by adding the following properties to the RegionServer's hbase-site.xml and tuning the values to suit your environment. -* .Configuration for Hedged Reads`dfs.client.hedged.read.threadpool.size` - the number of threads dedicated to servicing hedged reads. +.Configuration for Hedged Reads +* `dfs.client.hedged.read.threadpool.size` - the number of threads dedicated to servicing hedged reads. If this is set to 0 (the default), hedged reads are disabled. * `dfs.client.hedged.read.threshold.millis` - the number of milliseconds to wait before spawning a second read thread. .Hedged Reads Configuration Example ==== +[source,xml] ---- dfs.client.hedged.read.threadpool.size @@ -755,9 +742,10 @@ Because a HBase RegionServer is a HDFS client, you can enable hedged reads in HB ==== Use the following metrics to tune the settings for hedged reads on your cluster. -See <> for more information. +See <> for more information. -* .Metrics for Hedged ReadshedgedReadOps - the number of times hedged read threads have been triggered. +.Metrics for Hedged Reads +* hedgedReadOps - the number of times hedged read threads have been triggered. This could indicate that read requests are often slow, or that hedged reads are triggered too quickly. * hedgeReadOpsWin - the number of times the hedged read thread was faster than the original thread. This could indicate that a given RegionServer is having trouble servicing requests. @@ -770,24 +758,24 @@ See <> for more information. HBase tables are sometimes used as queues. In this case, special care must be taken to regularly perform major compactions on tables used in this manner. -As is documented in <>, marking rows as deleted creates additional StoreFiles which then need to be processed on reads. -Tombstones only get cleaned up with major compactions. +As is documented in <>, marking rows as deleted creates additional StoreFiles which then need to be processed on reads. +Tombstones only get cleaned up with major compactions. -See also <> and link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/HBaseAdmin.html#majorCompact%28java.lang.String%29[HBaseAdmin.majorCompact]. +See also <> and link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/HBaseAdmin.html#majorCompact%28java.lang.String%29[HBaseAdmin.majorCompact]. [[perf.deleting.rpc]] === Delete RPC Behavior Be aware that `htable.delete(Delete)` doesn't use the writeBuffer. It will execute an RegionServer RPC with each invocation. -For a large number of deletes, consider `htable.delete(List)`. +For a large number of deletes, consider `htable.delete(List)`. -See link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/HTable.html#delete%28org.apache.hadoop.hbase.client.Delete%29 +See http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/HTable.html#delete%28org.apache.hadoop.hbase.client.Delete%29 [[perf.hdfs]] == HDFS -Because HBase runs on <> it is important to understand how it works and how it affects HBase. +Because HBase runs on <> it is important to understand how it works and how it affects HBase. [[perf.hdfs.curr]] === Current Issues With Low-Latency Reads @@ -795,26 +783,22 @@ Because HBase runs on <> it is important to understand how The original use-case for HDFS was batch processing. As such, there low-latency reads were historically not a priority. With the increased adoption of Apache HBase this is changing, and several improvements are already in development. -See the link:https://issues.apache.org/jira/browse/HDFS-1599[Umbrella Jira Ticket for HDFS - Improvements for HBase]. +See the link:https://issues.apache.org/jira/browse/HDFS-1599[Umbrella Jira Ticket for HDFS Improvements for HBase]. [[perf.hdfs.configs.localread]] === Leveraging local data Since Hadoop 1.0.0 (also 0.22.1, 0.23.1, CDH3u3 and HDP 1.0) via link:https://issues.apache.org/jira/browse/HDFS-2246[HDFS-2246], it is possible for the DFSClient to take a "short circuit" and read directly from the disk instead of going through the DataNode when the data is local. What this means for HBase is that the RegionServers can read directly off their machine's disks instead of having to open a socket to talk to the DataNode, the former being generally much faster. -See JD's link:http://files.meetup.com/1350427/hug_ebay_jdcryans.pdf[Performance - Talk]. -Also see link:http://search-hadoop.com/m/zV6dKrLCVh1[HBase, mail # dev - read short - circuit] thread for more discussion around short circuit reads. +See JD's link:http://files.meetup.com/1350427/hug_ebay_jdcryans.pdf[Performance Talk]. +Also see link:http://search-hadoop.com/m/zV6dKrLCVh1[HBase, mail # dev - read short circuit] thread for more discussion around short circuit reads. To enable "short circuit" reads, it will depend on your version of Hadoop. The original shortcircuit read patch was much improved upon in Hadoop 2 in link:https://issues.apache.org/jira/browse/HDFS-347[HDFS-347]. -See link:http://blog.cloudera.com/blog/2013/08/how-improved-short-circuit-local-reads-bring-better-performance-and-security-to-hadoop/ for details on the difference between the old and new implementations. -See link:http://archive.cloudera.com/cdh4/cdh/4/hadoop/hadoop-project-dist/hadoop-hdfs/ShortCircuitLocalReads.html[Hadoop - shortcircuit reads configuration page] for how to enable the latter, better version of shortcircuit. +See http://blog.cloudera.com/blog/2013/08/how-improved-short-circuit-local-reads-bring-better-performance-and-security-to-hadoop/ for details on the difference between the old and new implementations. +See link:http://archive.cloudera.com/cdh4/cdh/4/hadoop/hadoop-project-dist/hadoop-hdfs/ShortCircuitLocalReads.html[Hadoop shortcircuit reads configuration page] for how to enable the latter, better version of shortcircuit. For example, here is a minimal config. -enabling short-circuit reads added to _hbase-site.xml_: +enabling short-circuit reads added to _hbase-site.xml_: [source,xml] ---- @@ -837,38 +821,37 @@ enabling short-circuit reads added to _hbase-site.xml_: ---- -Be careful about permissions for the directory that hosts the shared domain socket; dfsclient will complain if open to other than the hbase user. +Be careful about permissions for the directory that hosts the shared domain socket; dfsclient will complain if open to other than the hbase user. If you are running on an old Hadoop, one that is without link:https://issues.apache.org/jira/browse/HDFS-347[HDFS-347] but that has link:https://issues.apache.org/jira/browse/HDFS-2246[HDFS-2246], you must set two configurations. First, the hdfs-site.xml needs to be amended. -Set the property `dfs.block.local-path-access.user` to be the _only_ user that can use the shortcut. +Set the property `dfs.block.local-path-access.user` to be the _only_ user that can use the shortcut. This has to be the user that started HBase. -Then in hbase-site.xml, set `dfs.client.read.shortcircuit` to be `true` +Then in hbase-site.xml, set `dfs.client.read.shortcircuit` to be `true` -Services -- at least the HBase RegionServers -- will need to be restarted in order to pick up the new configurations. +Services -- at least the HBase RegionServers -- will need to be restarted in order to pick up the new configurations. .dfs.client.read.shortcircuit.buffer.size [NOTE] ==== -The default for this value is too high when running on a highly trafficed HBase. -In HBase, if this value has not been set, we set it down from the default of 1M to 128k (Since HBase 0.98.0 and 0.96.1). See link:https://issues.apache.org/jira/browse/HBASE-8143[HBASE-8143 HBase on Hadoop - 2 with local short circuit reads (ssr) causes OOM]). The Hadoop DFSClient in HBase will allocate a direct byte buffer of this size for _each_ block it has open; given HBase keeps its HDFS files open all the time, this can add up quickly. +The default for this value is too high when running on a highly trafficked HBase. +In HBase, if this value has not been set, we set it down from the default of 1M to 128k (Since HBase 0.98.0 and 0.96.1). See link:https://issues.apache.org/jira/browse/HBASE-8143[HBASE-8143 HBase on Hadoop 2 with local short circuit reads (ssr) causes OOM]). The Hadoop DFSClient in HBase will allocate a direct byte buffer of this size for _each_ block it has open; given HBase keeps its HDFS files open all the time, this can add up quickly. ==== [[perf.hdfs.comp]] === Performance Comparisons of HBase vs. HDFS A fairly common question on the dist-list is why HBase isn't as performant as HDFS files in a batch context (e.g., as a MapReduce source or sink). The short answer is that HBase is doing a lot more than HDFS (e.g., reading the KeyValues, returning the most current row or specified timestamps, etc.), and as such HBase is 4-5 times slower than HDFS in this processing context. -There is room for improvement and this gap will, over time, be reduced, but HDFS will always be faster in this use-case. +There is room for improvement and this gap will, over time, be reduced, but HDFS will always be faster in this use-case. [[perf.ec2]] == Amazon EC2 Performance questions are common on Amazon EC2 environments because it is a shared environment. You will not see the same throughput as a dedicated server. -In terms of running tests on EC2, run them several times for the same reason (i.e., it's a shared environment and you don't know what else is happening on the server). +In terms of running tests on EC2, run them several times for the same reason (i.e., it's a shared environment and you don't know what else is happening on the server). -If you are running on EC2 and post performance questions on the dist-list, please state this fact up-front that because EC2 issues are practically a separate class of performance issues. +If you are running on EC2 and post performance questions on the dist-list, please state this fact up-front that because EC2 issues are practically a separate class of performance issues. [[perf.hbase.mr.cluster]] == Collocating HBase and MapReduce @@ -877,17 +860,17 @@ It is often recommended to have different clusters for HBase and MapReduce. A better qualification of this is: don't collocate a HBase that serves live requests with a heavy MR workload. OLTP and OLAP-optimized systems have conflicting requirements and one will lose to the other, usually the former. For example, short latency-sensitive disk reads will have to wait in line behind longer reads that are trying to squeeze out as much throughput as possible. -MR jobs that write to HBase will also generate flushes and compactions, which will in turn invalidate blocks in the <>. +MR jobs that write to HBase will also generate flushes and compactions, which will in turn invalidate blocks in the <>. -If you need to process the data from your live HBase cluster in MR, you can ship the deltas with <> or use replication to get the new data in real time on the OLAP cluster. -In the worst case, if you really need to collocate both, set MR to use less Map and Reduce slots than you'd normally configure, possibly just one. +If you need to process the data from your live HBase cluster in MR, you can ship the deltas with <> or use replication to get the new data in real time on the OLAP cluster. +In the worst case, if you really need to collocate both, set MR to use less Map and Reduce slots than you'd normally configure, possibly just one. -When HBase is used for OLAP operations, it's preferable to set it up in a hardened way like configuring the ZooKeeper session timeout higher and giving more memory to the MemStores (the argument being that the Block Cache won't be used much since the workloads are usually long scans). +When HBase is used for OLAP operations, it's preferable to set it up in a hardened way like configuring the ZooKeeper session timeout higher and giving more memory to the MemStores (the argument being that the Block Cache won't be used much since the workloads are usually long scans). [[perf.casestudy]] == Case Studies -For Performance and Troubleshooting Case Studies, see <>. +For Performance and Troubleshooting Case Studies, see <>. ifdef::backend-docbook[] [index] diff --git a/src/main/asciidoc/_chapters/preface.adoc b/src/main/asciidoc/_chapters/preface.adoc index 4f8941acb94..2eb84114025 100644 --- a/src/main/asciidoc/_chapters/preface.adoc +++ b/src/main/asciidoc/_chapters/preface.adoc @@ -29,25 +29,20 @@ This is the official reference guide for the link:http://hbase.apache.org/[HBase] version it ships with. -Herein you will find either the definitive documentation on an HBase topic as of its standing when the referenced HBase version shipped, or it will point to the location in link:http://hbase.apache.org/apidocs/index.html[javadoc], link:https://issues.apache.org/jira/browse/HBASE[JIRA] or link:http://wiki.apache.org/hadoop/Hbase[wiki] where the pertinent information can be found. +Herein you will find either the definitive documentation on an HBase topic as of its standing when the referenced HBase version shipped, or it will point to the location in link:http://hbase.apache.org/apidocs/index.html[Javadoc], link:https://issues.apache.org/jira/browse/HBASE[JIRA] or link:http://wiki.apache.org/hadoop/Hbase[wiki] where the pertinent information can be found. .About This Guide -This reference guide is a work in progress. The source for this guide can be found in the _src/main/dasciidoc_ directory of the HBase source. This reference guide is marked up using Asciidoc, from which the the finished guide is generated as part of the 'site' build target. Run +This reference guide is a work in progress. The source for this guide can be found in the _src/main/asciidoc directory of the HBase source. This reference guide is marked up using link:http://asciidoc.org/[AsciiDoc] from which the finished guide is generated as part of the 'site' build target. Run [source,bourne] ---- mvn site ----- +---- to generate this documentation. Amendments and improvements to the documentation are welcomed. Click link:https://issues.apache.org/jira/secure/CreateIssueDetails!init.jspa?pid=12310753&issuetype=1&components=12312132&summary=SHORT+DESCRIPTION[this link] to file a new documentation bug against Apache HBase with some values pre-selected. .Contributing to the Documentation -For an overview of Asciidoc and suggestions to get started contributing to the documentation, see <>. - -.Providing Feedback -This guide allows you to leave comments or questions on any page, using Disqus. -Look for the Comments area at the bottom of the page. -Answering these questions is a volunteer effort, and may be delayed. +For an overview of AsciiDoc and suggestions to get started contributing to the documentation, see the <>. .Heads-up if this is your first foray into the world of distributed computing... If this is your first foray into the wonderful world of Distributed Computing, then you are in for some interesting times. @@ -57,8 +52,8 @@ Your cluster's operation can hiccup because of any of a myriad set of reasons fr Here is one good starting point: link:http://en.wikipedia.org/wiki/Fallacies_of_Distributed_Computing[Fallacies of Distributed Computing]. That said, you are welcome. + -Its a fun place to be. + -Yours, the HBase Community. +It's a fun place to be. + +Yours, the HBase Community. :numbered: diff --git a/src/main/asciidoc/_chapters/schema_design.adoc b/src/main/asciidoc/_chapters/schema_design.adoc index 7570d6c0751..c9306168374 100644 --- a/src/main/asciidoc/_chapters/schema_design.adoc +++ b/src/main/asciidoc/_chapters/schema_design.adoc @@ -27,15 +27,12 @@ :icons: font :experimental: -A good general introduction on the strength and weaknesses modelling on the various non-rdbms datastores is Ian Varley's Master thesis, link:http://ianvarley.com/UT/MR/Varley_MastersReport_Full_2009-08-07.pdf[No Relation: - The Mixed Blessings of Non-Relational Databases]. -Recommended. -Also, read <> for how HBase stores data internally, and the section on <>. +A good general introduction on the strength and weaknesses modelling on the various non-rdbms datastores is Ian Varley's Master thesis, link:http://ianvarley.com/UT/MR/Varley_MastersReport_Full_2009-08-07.pdf[No Relation: The Mixed Blessings of Non-Relational Databases]. Also, read <> for how HBase stores data internally, and the section on <>. [[schema.creation]] -== Schema Creation +== Schema Creation -HBase schemas can be created or updated with <> or by using link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/HBaseAdmin.html[HBaseAdmin] in the Java API. +HBase schemas can be created or updated using the <> or by using link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/HBaseAdmin.html[HBaseAdmin] in the Java API. Tables must be disabled when making ColumnFamily modifications, for example: @@ -58,30 +55,30 @@ admin.enableTable(table); See <> for more information about configuring client connections. -Note: online schema changes are supported in the 0.92.x codebase, but the 0.90.x codebase requires the table to be disabled. +NOTE: online schema changes are supported in the 0.92.x codebase, but the 0.90.x codebase requires the table to be disabled. [[schema.updates]] === Schema Updates -When changes are made to either Tables or ColumnFamilies (e.g., region size, block size), these changes take effect the next time there is a major compaction and the StoreFiles get re-written. +When changes are made to either Tables or ColumnFamilies (e.g. region size, block size), these changes take effect the next time there is a major compaction and the StoreFiles get re-written. -See <> for more information on StoreFiles. +See <> for more information on StoreFiles. [[number.of.cfs]] -== On the number of column families +== On the number of column families HBase currently does not do well with anything above two or three column families so keep the number of column families in your schema low. -Currently, flushing and compactions are done on a per Region basis so if one column family is carrying the bulk of the data bringing on flushes, the adjacent families will also be flushed though the amount of data they carry is small. -When many column families the flushing and compaction interaction can make for a bunch of needless i/o loading (To be addressed by changing flushing and compaction to work on a per column family basis). For more information on compactions, see <>. +Currently, flushing and compactions are done on a per Region basis so if one column family is carrying the bulk of the data bringing on flushes, the adjacent families will also be flushed even though the amount of data they carry is small. +When many column families exist the flushing and compaction interaction can make for a bunch of needless i/o (To be addressed by changing flushing and compaction to work on a per column family basis). For more information on compactions, see <>. Try to make do with one column family if you can in your schemas. Only introduce a second and third column family in the case where data access is usually column scoped; i.e. -you query one column family or the other but usually not both at the one time. +you query one column family or the other but usually not both at the one time. [[number.of.cfs.card]] === Cardinality of ColumnFamilies -Where multiple ColumnFamilies exist in a single table, be aware of the cardinality (i.e., number of rows). If ColumnFamilyA has 1 million rows and ColumnFamilyB has 1 billion rows, ColumnFamilyA's data will likely be spread across many, many regions (and RegionServers). This makes mass scans for ColumnFamilyA less efficient. +Where multiple ColumnFamilies exist in a single table, be aware of the cardinality (i.e., number of rows). If ColumnFamilyA has 1 million rows and ColumnFamilyB has 1 billion rows, ColumnFamilyA's data will likely be spread across many, many regions (and RegionServers). This makes mass scans for ColumnFamilyA less efficient. [[rowkey.design]] == Rowkey Design @@ -105,7 +102,7 @@ Salting in this sense has nothing to do with cryptography, but refers to adding In this case, salting refers to adding a randomly-assigned prefix to the row key to cause it to sort differently than it otherwise would. The number of possible prefixes correspond to the number of regions you want to spread the data across. Salting can be helpful if you have a few "hot" row key patterns which come up over and over amongst other more evenly-distributed rows. -Consider the following example, which shows that salting can spread write load across multiple regionservers, and illustrates some of the negative implications for reads. +Consider the following example, which shows that salting can spread write load across multiple RegionServers, and illustrates some of the negative implications for reads. .Salting Example ==== @@ -154,7 +151,7 @@ In this way, salting attempts to increase throughput on writes, but has a cost d .Hashing -Instead of a random assignment, you could use a one-way [firstterm]_hash_ that would cause a given row to always be "salted" with the same prefix, in a way that would spread the load across the regionservers, but allow for predictability during reads. +Instead of a random assignment, you could use a one-way [firstterm]_hash_ that would cause a given row to always be "salted" with the same prefix, in a way that would spread the load across the RegionServers, but allow for predictability during reads. Using a deterministic hash allows the client to reconstruct the complete rowkey and use a Get operation to retrieve that row as normal. .Hashing Example @@ -167,71 +164,66 @@ You could also optimize things so that certain pairs of keys were always in the A third common trick for preventing hotspotting is to reverse a fixed-width or numeric row key so that the part that changes the most often (the least significant digit) is first. This effectively randomizes row keys, but sacrifices row ordering properties. -See link:https://communities.intel.com/community/itpeernetwork/datastack/blog/2013/11/10/discussion-on-designing-hbase-tables, and link:http://phoenix.apache.org/salted.html[article on Salted Tables] from the Phoenix project, and the discussion in the comments of link:https://issues.apache.org/jira/browse/HBASE-11682[HBASE-11682] for more information about avoiding hotspotting. +See https://communities.intel.com/community/itpeernetwork/datastack/blog/2013/11/10/discussion-on-designing-hbase-tables, and link:http://phoenix.apache.org/salted.html[article on Salted Tables] from the Phoenix project, and the discussion in the comments of link:https://issues.apache.org/jira/browse/HBASE-11682[HBASE-11682] for more information about avoiding hotspotting. [[timeseries]] -=== Monotonically Increasing Row Keys/Timeseries Data +=== Monotonically Increasing Row Keys/Timeseries Data -In the HBase chapter of Tom White's book link:http://oreilly.com/catalog/9780596521981[Hadoop: The Definitive Guide] (O'Reilly) there is a an optimization note on watching out for a phenomenon where an import process walks in lock-step with all clients in concert pounding one of the table's regions (and thus, a single node), then moving onto the next region, etc. +In the HBase chapter of Tom White's book link:http://oreilly.com/catalog/9780596521981[Hadoop: The Definitive Guide] (O'Reilly) there is a an optimization note on watching out for a phenomenon where an import process walks in lock-step with all clients in concert pounding one of the table's regions (and thus, a single node), then moving onto the next region, etc. With monotonically increasing row-keys (i.e., using a timestamp), this will happen. -See this comic by IKai Lan on why monotonically increasing row keys are problematic in BigTable-like datastores: link:http://ikaisays.com/2011/01/25/app-engine-datastore-tip-monotonically-increasing-values-are-bad/[monotonically - increasing values are bad]. -The pile-up on a single region brought on by monotonically increasing keys can be mitigated by randomizing the input records to not be in sorted order, but in general it's best to avoid using a timestamp or a sequence (e.g. -1, 2, 3) as the row-key. +See this comic by IKai Lan on why monotonically increasing row keys are problematic in BigTable-like datastores: link:http://ikaisays.com/2011/01/25/app-engine-datastore-tip-monotonically-increasing-values-are-bad/[monotonically increasing values are bad]. +The pile-up on a single region brought on by monotonically increasing keys can be mitigated by randomizing the input records to not be in sorted order, but in general it's best to avoid using a timestamp or a sequence (e.g. 1, 2, 3) as the row-key. If you do need to upload time series data into HBase, you should study link:http://opentsdb.net/[OpenTSDB] as a successful example. It has a page describing the link: http://opentsdb.net/schema.html[schema] it uses in HBase. The key format in OpenTSDB is effectively [metric_type][event_timestamp], which would appear at first glance to contradict the previous advice about not using a timestamp as the key. -However, the difference is that the timestamp is not in the _lead_ position of the key, and the design assumption is that there are dozens or hundreds (or more) of different metric types. -Thus, even with a continual stream of input data with a mix of metric types, the Puts are distributed across various points of regions in the table. +However, the difference is that the timestamp is not in the _lead_ position of the key, and the design assumption is that there are dozens or hundreds (or more) of different metric types. +Thus, even with a continual stream of input data with a mix of metric types, the Puts are distributed across various points of regions in the table. -See <> for some rowkey design examples. +See <> for some rowkey design examples. [[keysize]] === Try to minimize row and column sizes In HBase, values are always freighted with their coordinates; as a cell value passes through the system, it'll be accompanied by its row, column name, and timestamp - always. If your rows and column names are large, especially compared to the size of the cell value, then you may run up against some interesting scenarios. -One such is the case described by Marc Limotte at the tail of link:https://issues.apache.org/jira/browse/HBASE-3551?page=com.atlassian.jira.plugin.system.issuetabpanels:comment-tabpanel&focusedCommentId=13005272#comment-13005272[HBASE-3551] (recommended!). Therein, the indices that are kept on HBase storefiles (<>) to facilitate random access may end up occupyng large chunks of the HBase allotted RAM because the cell value coordinates are large. +One such is the case described by Marc Limotte at the tail of link:https://issues.apache.org/jira/browse/HBASE-3551?page=com.atlassian.jira.plugin.system.issuetabpanels:comment-tabpanel&focusedCommentId=13005272#comment-13005272[HBASE-3551] (recommended!). Therein, the indices that are kept on HBase storefiles (<>) to facilitate random access may end up occupying large chunks of the HBase allotted RAM because the cell value coordinates are large. Mark in the above cited comment suggests upping the block size so entries in the store file index happen at a larger interval or modify the table schema so it makes for smaller rows and column names. Compression will also make for larger indices. -See the thread link:http://search-hadoop.com/m/hemBv1LiN4Q1/a+question+storefileIndexSize&subj=a+question+storefileIndexSize[a - question storefileIndexSize] up on the user mailing list. +See the thread link:http://search-hadoop.com/m/hemBv1LiN4Q1/a+question+storefileIndexSize&subj=a+question+storefileIndexSize[a question storefileIndexSize] up on the user mailing list. -Most of the time small inefficiencies don't matter all that much. -Unfortunately, this is a case where they do. -Whatever patterns are selected for ColumnFamilies, attributes, and rowkeys they could be repeated several billion times in your data. +Most of the time small inefficiencies don't matter all that much. Unfortunately, this is a case where they do. +Whatever patterns are selected for ColumnFamilies, attributes, and rowkeys they could be repeated several billion times in your data. See <> for more information on HBase stores data internally to see why this is important. [[keysize.cf]] ==== Column Families -Try to keep the ColumnFamily names as small as possible, preferably one character (e.g. -"d" for data/default). +Try to keep the ColumnFamily names as small as possible, preferably one character (e.g. "d" for data/default). -See <> for more information on HBase stores data internally to see why this is important. +See <> for more information on HBase stores data internally to see why this is important. [[keysize.attributes]] ==== Attributes -Although verbose attribute names (e.g., "myVeryImportantAttribute") are easier to read, prefer shorter attribute names (e.g., "via") to store in HBase. +Although verbose attribute names (e.g., "myVeryImportantAttribute") are easier to read, prefer shorter attribute names (e.g., "via") to store in HBase. See <> for more information on HBase stores data internally to see why this is important. [[keysize.row]] ==== Rowkey Length -Keep them as short as is reasonable such that they can still be useful for required data access (e.g., Get vs. +Keep them as short as is reasonable such that they can still be useful for required data access (e.g. Get vs. Scan). A short key that is useless for data access is not better than a longer key with better get/scan properties. -Expect tradeoffs when designing rowkeys. +Expect tradeoffs when designing rowkeys. [[keysize.patterns]] ==== Byte Patterns A long is 8 bytes. You can store an unsigned number up to 18,446,744,073,709,551,615 in those eight bytes. -If you stored this number as a String -- presuming a byte per character -- you need nearly 3x the bytes. +If you stored this number as a String -- presuming a byte per character -- you need nearly 3x the bytes. Not convinced? Below is some sample code that you can run on your own. @@ -244,7 +236,7 @@ long l = 1234567890L; byte[] lb = Bytes.toBytes(l); System.out.println("long bytes length: " + lb.length); // returns 8 -String s = "" + l; +String s = String.valueOf(l); byte[] sb = Bytes.toBytes(s); System.out.println("long as string length: " + sb.length); // returns 10 @@ -277,7 +269,7 @@ COLUMN CELL The shell makes a best effort to print a string, and it this case it decided to just print the hex. The same will happen to your row keys inside the region names. It can be okay if you know what's being stored, but it might also be unreadable if arbitrary data can be put in the same cells. -This is the main trade-off. +This is the main trade-off. [[reverse.timestamp]] === Reverse Timestamps @@ -285,33 +277,32 @@ This is the main trade-off. .Reverse Scan API [NOTE] ==== -link:https://issues.apache.org/jira/browse/HBASE-4811[HBASE-4811] implements an API to scan a table or a range within a table in reverse, reducing the need to optimize your schema for forward or reverse scanning. +link:https://issues.apache.org/jira/browse/HBASE-4811[HBASE-4811] implements an API to scan a table or a range within a table in reverse, reducing the need to optimize your schema for forward or reverse scanning. This feature is available in HBase 0.98 and later. -See link:https://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Scan.html#setReversed%28boolean for more information. +See https://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Scan.html#setReversed%28boolean for more information. ==== A common problem in database processing is quickly finding the most recent version of a value. A technique using reverse timestamps as a part of the key can help greatly with a special case of this problem. -Also found in the HBase chapter of Tom White's book Hadoop: The Definitive Guide (O'Reilly), the technique involves appending (`Long.MAX_VALUE - - timestamp`) to the end of any key, e.g., [key][reverse_timestamp]. +Also found in the HBase chapter of Tom White's book Hadoop: The Definitive Guide (O'Reilly), the technique involves appending (`Long.MAX_VALUE - timestamp`) to the end of any key, e.g. [key][reverse_timestamp]. The most recent value for [key] in a table can be found by performing a Scan for [key] and obtaining the first record. -Since HBase keys are in sorted order, this key sorts before any older row-keys for [key] and thus is first. +Since HBase keys are in sorted order, this key sorts before any older row-keys for [key] and thus is first. -This technique would be used instead of using <> where the intent is to hold onto all versions "forever" (or a very long time) and at the same time quickly obtain access to any other version by using the same Scan technique. +This technique would be used instead of using <> where the intent is to hold onto all versions "forever" (or a very long time) and at the same time quickly obtain access to any other version by using the same Scan technique. [[rowkey.scope]] === Rowkeys and ColumnFamilies Rowkeys are scoped to ColumnFamilies. -Thus, the same rowkey could exist in each ColumnFamily that exists in a table without collision. +Thus, the same rowkey could exist in each ColumnFamily that exists in a table without collision. [[changing.rowkeys]] === Immutability of Rowkeys Rowkeys cannot be changed. The only way they can be "changed" in a table is if the row is deleted and then re-inserted. -This is a fairly common question on the HBase dist-list so it pays to get the rowkeys right the first time (and/or before you've inserted a lot of data). +This is a fairly common question on the HBase dist-list so it pays to get the rowkeys right the first time (and/or before you've inserted a lot of data). [[rowkey.regionsplits]] === Relationship Between RowKeys and Region Splits @@ -332,21 +323,20 @@ As an example of why this is important, consider the example of using displayabl 102 102 102 102 102 102 102 102 102 102 102 102 102 102 102 102 // f ---- -... (note: the lead byte is listed to the right as a comment.) Given that the first split is a '0' and the last split is an 'f', everything is great, right? Not so fast. +(note: the lead byte is listed to the right as a comment.) Given that the first split is a '0' and the last split is an 'f', everything is great, right? Not so fast. The problem is that all the data is going to pile up in the first 2 regions and the last region thus creating a "lumpy" (and possibly "hot") region problem. To understand why, refer to an link:http://www.asciitable.com[ASCII Table]. -'0' is byte 48, and 'f' is byte 102, but there is a huge gap in byte values (bytes 58 to 96) that will _never - appear in this keyspace_ because the only values are [0-9] and [a-f]. Thus, the middle regions regions will never be used. -To make pre-spliting work with this example keyspace, a custom definition of splits (i.e., and not relying on the built-in split method) is required. +'0' is byte 48, and 'f' is byte 102, but there is a huge gap in byte values (bytes 58 to 96) that will _never appear in this keyspace_ because the only values are [0-9] and [a-f]. Thus, the middle regions regions will never be used. +To make pre-spliting work with this example keyspace, a custom definition of splits (i.e., and not relying on the built-in split method) is required. Lesson #1: Pre-splitting tables is generally a best practice, but you need to pre-split them in such a way that all the regions are accessible in the keyspace. While this example demonstrated the problem with a hex-key keyspace, the same problem can happen with _any_ keyspace. -Know your data. +Know your data. -Lesson #2: While generally not advisable, using hex-keys (and more generally, displayable data) can still work with pre-split tables as long as all the created regions are accessible in the keyspace. +Lesson #2: While generally not advisable, using hex-keys (and more generally, displayable data) can still work with pre-split tables as long as all the created regions are accessible in the keyspace. -To conclude this example, the following is an example of how appropriate splits can be pre-created for hex-keys:. +To conclude this example, the following is an example of how appropriate splits can be pre-created for hex-keys:. [source,java] ---- @@ -379,59 +369,58 @@ public static byte[][] getHexSplits(String startKey, String endKey, int numRegio ---- [[schema.versions]] -== Number of Versions +== Number of Versions [[schema.versions.max]] === Maximum Number of Versions The maximum number of row versions to store is configured per column family via link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/HColumnDescriptor.html[HColumnDescriptor]. The default for max versions is 1. -This is an important parameter because as described in <> section HBase does _not_ overwrite row values, but rather stores different values per row by time (and qualifier). Excess versions are removed during major compactions. -The number of max versions may need to be increased or decreased depending on application needs. +This is an important parameter because as described in <> section HBase does _not_ overwrite row values, but rather stores different values per row by time (and qualifier). Excess versions are removed during major compactions. +The number of max versions may need to be increased or decreased depending on application needs. -It is not recommended setting the number of max versions to an exceedingly high level (e.g., hundreds or more) unless those old values are very dear to you because this will greatly increase StoreFile size. +It is not recommended setting the number of max versions to an exceedingly high level (e.g., hundreds or more) unless those old values are very dear to you because this will greatly increase StoreFile size. [[schema.minversions]] -=== Minimum Number of Versions +=== Minimum Number of Versions Like maximum number of row versions, the minimum number of row versions to keep is configured per column family via link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/HColumnDescriptor.html[HColumnDescriptor]. The default for min versions is 0, which means the feature is disabled. -The minimum number of row versions parameter is used together with the time-to-live parameter and can be combined with the number of row versions parameter to allow configurations such as "keep the last T minutes worth of data, at most N versions, _but keep at least M versions - around_" (where M is the value for minimum number of row versions, M>, and that includes versioning. -Take that into consideration when making your design, as well as block size for the ColumnFamily. +All rows in HBase conform to the <>, and that includes versioning. +Take that into consideration when making your design, as well as block size for the ColumnFamily. === Counters -One supported datatype that deserves special mention are "counters" (i.e., the ability to do atomic increments of numbers). See link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/HTable.html#increment%28org.apache.hadoop.hbase.client.Increment%29[Increment] in HTable. +One supported datatype that deserves special mention are "counters" (i.e., the ability to do atomic increments of numbers). See link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/HTable.html#increment%28org.apache.hadoop.hbase.client.Increment%29[Increment] in HTable. -Synchronization on counters are done on the RegionServer, not in the client. +Synchronization on counters are done on the RegionServer, not in the client. [[schema.joins]] == Joins -If you have multiple tables, don't forget to factor in the potential for <> into the schema design. +If you have multiple tables, don't forget to factor in the potential for <> into the schema design. [[ttl]] == Time To Live (TTL) ColumnFamilies can set a TTL length in seconds, and HBase will automatically delete rows once the expiration time is reached. This applies to _all_ versions of a row - even the current one. -The TTL time encoded in the HBase for the row is specified in UTC. +The TTL time encoded in the HBase for the row is specified in UTC. Store files which contains only expired rows are deleted on minor compaction. Setting `hbase.store.delete.expired.storefile` to `false` disables this feature. -Setting link:[minimum number of versions] to other than 0 also disables this. +Setting minimum number of versions to other than 0 also disables this. -See link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/HColumnDescriptor.html[HColumnDescriptor] for more information. +See link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/HColumnDescriptor.html[HColumnDescriptor] for more information. Recent versions of HBase also support setting time to live on a per cell basis. See link:https://issues.apache.org/jira/browse/HBASE-10560[HBASE-10560] for more information. @@ -443,17 +432,17 @@ There are two notable differences between cell TTL handling and ColumnFamily TTL * A cell TTLs cannot extend the effective lifetime of a cell beyond a ColumnFamily level TTL setting. [[cf.keep.deleted]] -== Keeping Deleted Cells +== Keeping Deleted Cells By default, delete markers extend back to the beginning of time. -Therefore, link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Get.html[Get] or link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Scan.html[Scan] operations will not see a deleted cell (row or column), even when the Get or Scan operation indicates a time range before the delete marker was placed. +Therefore, link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Get.html[Get] or link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Scan.html[Scan] operations will not see a deleted cell (row or column), even when the Get or Scan operation indicates a time range before the delete marker was placed. ColumnFamilies can optionally keep deleted cells. In this case, deleted cells can still be retrieved, as long as these operations specify a time range that ends before the timestamp of any delete that would affect the cells. -This allows for point-in-time queries even in the presence of deletes. +This allows for point-in-time queries even in the presence of deletes. Deleted cells are still subject to TTL and there will never be more than "maximum number of versions" deleted cells. -A new "raw" scan options returns all deleted rows and the delete markers. +A new "raw" scan options returns all deleted rows and the delete markers. .Change the Value of `KEEP_DELETED_CELLS` Using HBase Shell ==== @@ -472,45 +461,43 @@ HColumnDescriptor.setKeepDeletedCells(true); ---- ==== -See the API documentation for link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/HColumnDescriptor.html#KEEP_DELETED_CELLS[KEEP_DELETED_CELLS] for more information. +See the API documentation for link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/HColumnDescriptor.html#KEEP_DELETED_CELLS[KEEP_DELETED_CELLS] for more information. [[secondary.indexes]] -== Secondary Indexes and Alternate Query Paths +== Secondary Indexes and Alternate Query Paths This section could also be titled "what if my table rowkey looks like _this_ but I also want to query my table like _that_." A common example on the dist-list is where a row-key is of the format "user-timestamp" but there are reporting requirements on activity across users for certain time ranges. -Thus, selecting by user is easy because it is in the lead position of the key, but time is not. +Thus, selecting by user is easy because it is in the lead position of the key, but time is not. -There is no single answer on the best way to handle this because it depends on... +There is no single answer on the best way to handle this because it depends on... * Number of users * Data size and data arrival rate -* Flexibility of reporting requirements (e.g., completely ad-hoc date selection vs. - pre-configured ranges) -* Desired execution speed of query (e.g., 90 seconds may be reasonable to some for an ad-hoc report, whereas it may be too long for others) +* Flexibility of reporting requirements (e.g., completely ad-hoc date selection vs. pre-configured ranges) +* Desired execution speed of query (e.g., 90 seconds may be reasonable to some for an ad-hoc report, whereas it may be too long for others) -... and solutions are also influenced by the size of the cluster and how much processing power you have to throw at the solution. +and solutions are also influenced by the size of the cluster and how much processing power you have to throw at the solution. Common techniques are in sub-sections below. -This is a comprehensive, but not exhaustive, list of approaches. +This is a comprehensive, but not exhaustive, list of approaches. It should not be a surprise that secondary indexes require additional cluster space and processing. This is precisely what happens in an RDBMS because the act of creating an alternate index requires both space and processing cycles to update. RDBMS products are more advanced in this regard to handle alternative index management out of the box. -However, HBase scales better at larger data volumes, so this is a feature trade-off. +However, HBase scales better at larger data volumes, so this is a feature trade-off. -Pay attention to <> when implementing any of these approaches. +Pay attention to <> when implementing any of these approaches. -Additionally, see the David Butler response in this dist-list thread link:http://search-hadoop.com/m/nvbiBp2TDP/Stargate%252Bhbase&subj=Stargate+hbase[HBase, - mail # user - Stargate+hbase] +Additionally, see the David Butler response in this dist-list thread link:http://search-hadoop.com/m/nvbiBp2TDP/Stargate%252Bhbase&subj=Stargate+hbase[HBase, mail # user - Stargate+hbase] [[secondary.indexes.filter]] -=== Filter Query +=== Filter Query -Depending on the case, it may be appropriate to use <>. +Depending on the case, it may be appropriate to use <>. In this case, no secondary index is created. -However, don't try a full-scan on a large table like this from an application (i.e., single-threaded client). +However, don't try a full-scan on a large table like this from an application (i.e., single-threaded client). [[secondary.indexes.periodic]] -=== Periodic-Update Secondary Index +=== Periodic-Update Secondary Index A secondary index could be created in an other table which is periodically updated via a MapReduce job. The job could be executed intra-day, but depending on load-strategy it could still potentially be out of sync with the main data table. @@ -518,12 +505,12 @@ The job could be executed intra-day, but depending on load-strategy it could sti See <> for more information. [[secondary.indexes.dualwrite]] -=== Dual-Write Secondary Index +=== Dual-Write Secondary Index Another strategy is to build the secondary index while publishing data to the cluster (e.g., write to data table, write to index table). If this is approach is taken after a data table already exists, then bootstrapping will be needed for the secondary index with a MapReduce job (see <>). [[secondary.indexes.summary]] -=== Summary Tables +=== Summary Tables Where time-ranges are very wide (e.g., year-long report) and where the data is voluminous, summary tables are a common approach. These would be generated with MapReduce jobs into another table. @@ -531,29 +518,27 @@ These would be generated with MapReduce jobs into another table. See <> for more information. [[secondary.indexes.coproc]] -=== Coprocessor Secondary Index +=== Coprocessor Secondary Index -Coprocessors act like RDBMS triggers. -These were added in 0.92. -For more information, see <> +Coprocessors act like RDBMS triggers. These were added in 0.92. +For more information, see <> == Constraints HBase currently supports 'constraints' in traditional (SQL) database parlance. -The advised usage for Constraints is in enforcing business rules for attributes in the table (eg. -make sure values are in the range 1-10). Constraints could also be used to enforce referential integrity, but this is strongly discouraged as it will dramatically decrease the write throughput of the tables where integrity checking is enabled. -Extensive documentation on using Constraints can be found at: link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/constraint[Constraint] since version 0.94. +The advised usage for Constraints is in enforcing business rules for attributes in the table (e.g. make sure values are in the range 1-10). Constraints could also be used to enforce referential integrity, but this is strongly discouraged as it will dramatically decrease the write throughput of the tables where integrity checking is enabled. +Extensive documentation on using Constraints can be found at: link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/constraint[Constraint] since version 0.94. [[schema.casestudies]] == Schema Design Case Studies The following will describe some typical data ingestion use-cases with HBase, and how the rowkey design and construction can be approached. Note: this is just an illustration of potential approaches, not an exhaustive list. -Know your data, and know your processing requirements. +Know your data, and know your processing requirements. -It is highly recommended that you read the rest of the <> first, before reading these case studies. +It is highly recommended that you read the rest of the <> first, before reading these case studies. -The following case studies are described: +The following case studies are described: * Log Data / Timeseries Data * Log Data / Timeseries on Steroids @@ -564,21 +549,21 @@ The following case studies are described: [[schema.casestudies.log_timeseries]] === Case Study - Log Data and Timeseries Data -Assume that the following data elements are being collected. +Assume that the following data elements are being collected. * Hostname * Timestamp * Log event * Value/message -We can store them in an HBase table called LOG_DATA, but what will the rowkey be? From these attributes the rowkey will be some combination of hostname, timestamp, and log-event - but what specifically? +We can store them in an HBase table called LOG_DATA, but what will the rowkey be? From these attributes the rowkey will be some combination of hostname, timestamp, and log-event - but what specifically? [[schema.casestudies.log_timeseries.tslead]] ==== Timestamp In The Rowkey Lead Position -The rowkey `[timestamp][hostname][log-event]` suffers from the monotonically increasing rowkey problem described in <>. +The rowkey `[timestamp][hostname][log-event]` suffers from the monotonically increasing rowkey problem described in <>. -There is another pattern frequently mentioned in the dist-lists about ``bucketing'' timestamps, by performing a mod operation on the timestamp. +There is another pattern frequently mentioned in the dist-lists about "bucketing" timestamps, by performing a mod operation on the timestamp. If time-oriented scans are important, this could be a useful approach. Attention must be paid to the number of buckets, because this will require the same number of scans to return results. @@ -588,7 +573,7 @@ Attention must be paid to the number of buckets, because this will require the s long bucket = timestamp % numBuckets; ---- -... to construct: +to construct: [source] ---- @@ -597,40 +582,39 @@ long bucket = timestamp % numBuckets; ---- As stated above, to select data for a particular timerange, a Scan will need to be performed for each bucket. -100 buckets, for example, will provide a wide distribution in the keyspace but it will require 100 Scans to obtain data for a single timestamp, so there are trade-offs. +100 buckets, for example, will provide a wide distribution in the keyspace but it will require 100 Scans to obtain data for a single timestamp, so there are trade-offs. [[schema.casestudies.log_timeseries.hostlead]] ==== Host In The Rowkey Lead Position The rowkey `[hostname][log-event][timestamp]` is a candidate if there is a large-ish number of hosts to spread the writes and reads across the keyspace. -This approach would be useful if scanning by hostname was a priority. +This approach would be useful if scanning by hostname was a priority. [[schema.casestudies.log_timeseries.revts]] ==== Timestamp, or Reverse Timestamp? -If the most important access path is to pull most recent events, then storing the timestamps as reverse-timestamps (e.g., `timestamp = Long.MAX_VALUE – - timestamp`) will create the property of being able to do a Scan on `[hostname][log-event]` to obtain the quickly obtain the most recently captured events. +If the most important access path is to pull most recent events, then storing the timestamps as reverse-timestamps (e.g., `timestamp = Long.MAX_VALUE – timestamp`) will create the property of being able to do a Scan on `[hostname][log-event]` to obtain the quickly obtain the most recently captured events. -Neither approach is wrong, it just depends on what is most appropriate for the situation. +Neither approach is wrong, it just depends on what is most appropriate for the situation. .Reverse Scan API [NOTE] ==== -link:https://issues.apache.org/jira/browse/HBASE-4811[HBASE-4811] implements an API to scan a table or a range within a table in reverse, reducing the need to optimize your schema for forward or reverse scanning. +link:https://issues.apache.org/jira/browse/HBASE-4811[HBASE-4811] implements an API to scan a table or a range within a table in reverse, reducing the need to optimize your schema for forward or reverse scanning. This feature is available in HBase 0.98 and later. -See link:https://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Scan.html#setReversed%28boolean for more information. +See https://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/Scan.html#setReversed%28boolean for more information. ==== [[schema.casestudies.log_timeseries.varkeys]] ==== Variangle Length or Fixed Length Rowkeys? It is critical to remember that rowkeys are stamped on every column in HBase. -If the hostname is ``a'' and the event type is ``e1'' then the resulting rowkey would be quite small. -However, what if the ingested hostname is ``myserver1.mycompany.com'' and the event type is ``com.package1.subpackage2.subsubpackage3.ImportantService''? +If the hostname is `a` and the event type is `e1` then the resulting rowkey would be quite small. +However, what if the ingested hostname is `myserver1.mycompany.com` and the event type is `com.package1.subpackage2.subsubpackage3.ImportantService`? It might make sense to use some substitution in the rowkey. There are at least two approaches: hashed and numeric. -In the Hostname In The Rowkey Lead Position example, it might look like this: +In the Hostname In The Rowkey Lead Position example, it might look like this: Composite Rowkey With Hashes: @@ -638,33 +622,30 @@ Composite Rowkey With Hashes: * [MD5 hash of event-type] = 16 bytes * [timestamp] = 8 bytes -Composite Rowkey With Numeric Substitution: +Composite Rowkey With Numeric Substitution: For this approach another lookup table would be needed in addition to LOG_DATA, called LOG_TYPES. -The rowkey of LOG_TYPES would be: +The rowkey of LOG_TYPES would be: -* [type] (e.g., byte indicating hostname vs. - event-type) +* [type] (e.g., byte indicating hostname vs. event-type) * [bytes] variable length bytes for raw hostname or event-type. -A column for this rowkey could be a long with an assigned number, which could be obtained by using an link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/HTable.html#incrementColumnValue%28byte[],%20byte[],%20byte[],%20long%29[HBase - counter]. +A column for this rowkey could be a long with an assigned number, which could be obtained by using an link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/client/HTable.html#incrementColumnValue%28byte[],%20byte[],%20byte[],%20long%29[HBase counter]. -So the resulting composite rowkey would be: +So the resulting composite rowkey would be: * [substituted long for hostname] = 8 bytes * [substituted long for event type] = 8 bytes * [timestamp] = 8 bytes -In either the Hash or Numeric substitution approach, the raw values for hostname and event-type can be stored as columns. +In either the Hash or Numeric substitution approach, the raw values for hostname and event-type can be stored as columns. [[schema.casestudies.log_steroids]] === Case Study - Log Data and Timeseries Data on Steroids This effectively is the OpenTSDB approach. What OpenTSDB does is re-write data and pack rows into columns for certain time-periods. -For a detailed explanation, see: link:http://opentsdb.net/schema.html, and link:http://www.cloudera.com/content/cloudera/en/resources/library/hbasecon/video-hbasecon-2012-lessons-learned-from-opentsdb.html[Lessons - Learned from OpenTSDB] from HBaseCon2012. +For a detailed explanation, see: link:http://opentsdb.net/schema.html, and link:http://www.cloudera.com/content/cloudera/en/resources/library/hbasecon/video-hbasecon-2012-lessons-learned-from-opentsdb.html[Lessons Learned from OpenTSDB] from HBaseCon2012. But this is how the general concept works: data is ingested, for example, in this manner... @@ -675,52 +656,52 @@ But this is how the general concept works: data is ingested, for example, in thi [hostname][log-event][timestamp3] ---- -... with separate rowkeys for each detailed event, but is re-written like this... +with separate rowkeys for each detailed event, but is re-written like this... ---- [hostname][log-event][timerange] ---- -... and each of the above events are converted into columns stored with a time-offset relative to the beginning timerange (e.g., every 5 minutes). This is obviously a very advanced processing technique, but HBase makes this possible. +and each of the above events are converted into columns stored with a time-offset relative to the beginning timerange (e.g., every 5 minutes). This is obviously a very advanced processing technique, but HBase makes this possible. [[schema.casestudies.custorder]] === Case Study - Customer/Order Assume that HBase is used to store customer and order information. -There are two core record-types being ingested: a Customer record type, and Order record type. +There are two core record-types being ingested: a Customer record type, and Order record type. -The Customer record type would include all the things that you'd typically expect: +The Customer record type would include all the things that you'd typically expect: * Customer number * Customer name * Address (e.g., city, state, zip) * Phone numbers, etc. -The Order record type would include things like: +The Order record type would include things like: * Customer number * Order number * Sales date -* A series of nested objects for shipping locations and line-items (see <> for details) +* A series of nested objects for shipping locations and line-items (see <> for details) -Assuming that the combination of customer number and sales order uniquely identify an order, these two attributes will compose the rowkey, and specifically a composite key such as: +Assuming that the combination of customer number and sales order uniquely identify an order, these two attributes will compose the rowkey, and specifically a composite key such as: ---- [customer number][order number] ---- -... for a ORDER table. -However, there are more design decisions to make: are the _raw_ values the best choices for rowkeys? +for a ORDER table. +However, there are more design decisions to make: are the _raw_ values the best choices for rowkeys? The same design questions in the Log Data use-case confront us here. -What is the keyspace of the customer number, and what is the format (e.g., numeric? alphanumeric?) As it is advantageous to use fixed-length keys in HBase, as well as keys that can support a reasonable spread in the keyspace, similar options appear: +What is the keyspace of the customer number, and what is the format (e.g., numeric? alphanumeric?) As it is advantageous to use fixed-length keys in HBase, as well as keys that can support a reasonable spread in the keyspace, similar options appear: -Composite Rowkey With Hashes: +Composite Rowkey With Hashes: * [MD5 of customer number] = 16 bytes * [MD5 of order number] = 16 bytes -Composite Numeric/Hash Combo Rowkey: +Composite Numeric/Hash Combo Rowkey: * [substituted long for customer number] = 8 bytes * [MD5 of order number] = 16 bytes @@ -729,20 +710,20 @@ Composite Numeric/Hash Combo Rowkey: ==== Single Table? Multiple Tables? A traditional design approach would have separate tables for CUSTOMER and SALES. -Another option is to pack multiple record types into a single table (e.g., CUSTOMER++). +Another option is to pack multiple record types into a single table (e.g., CUSTOMER++). -Customer Record Type Rowkey: +Customer Record Type Rowkey: * [customer-id] * [type] = type indicating `1' for customer record type -Order Record Type Rowkey: +Order Record Type Rowkey: * [customer-id] * [type] = type indicating `2' for order record type * [order] -The advantage of this particular CUSTOMER++ approach is that organizes many different record-types by customer-id (e.g., a single scan could get you everything about that customer). The disadvantage is that it's not as easy to scan for a particular record-type. +The advantage of this particular CUSTOMER++ approach is that organizes many different record-types by customer-id (e.g., a single scan could get you everything about that customer). The disadvantage is that it's not as easy to scan for a particular record-type. [[schema.casestudies.custorder.obj]] ==== Order Object Design @@ -756,52 +737,52 @@ Order:: LineItem:: (a ShippingLocation can have multiple LineItems -... there are multiple options on storing this data. +there are multiple options on storing this data. [[schema.casestudies.custorder.obj.norm]] ===== Completely Normalized -With this approach, there would be separate tables for ORDER, SHIPPING_LOCATION, and LINE_ITEM. +With this approach, there would be separate tables for ORDER, SHIPPING_LOCATION, and LINE_ITEM. -The ORDER table's rowkey was described above: <> +The ORDER table's rowkey was described above: <> -The SHIPPING_LOCATION's composite rowkey would be something like this: +The SHIPPING_LOCATION's composite rowkey would be something like this: * [order-rowkey] * [shipping location number] (e.g., 1st location, 2nd, etc.) -The LINE_ITEM table's composite rowkey would be something like this: +The LINE_ITEM table's composite rowkey would be something like this: * [order-rowkey] * [shipping location number] (e.g., 1st location, 2nd, etc.) * [line item number] (e.g., 1st lineitem, 2nd, etc.) Such a normalized model is likely to be the approach with an RDBMS, but that's not your only option with HBase. -The cons of such an approach is that to retrieve information about any Order, you will need: +The cons of such an approach is that to retrieve information about any Order, you will need: * Get on the ORDER table for the Order * Scan on the SHIPPING_LOCATION table for that order to get the ShippingLocation instances * Scan on the LINE_ITEM for each ShippingLocation -... granted, this is what an RDBMS would do under the covers anyway, but since there are no joins in HBase you're just more aware of this fact. +granted, this is what an RDBMS would do under the covers anyway, but since there are no joins in HBase you're just more aware of this fact. [[schema.casestudies.custorder.obj.rectype]] ===== Single Table With Record Types -With this approach, there would exist a single table ORDER that would contain +With this approach, there would exist a single table ORDER that would contain The Order rowkey was described above: <> * [order-rowkey] * [ORDER record type] -The ShippingLocation composite rowkey would be something like this: +The ShippingLocation composite rowkey would be something like this: * [order-rowkey] * [SHIPPING record type] * [shipping location number] (e.g., 1st location, 2nd, etc.) -The LineItem composite rowkey would be something like this: +The LineItem composite rowkey would be something like this: * [order-rowkey] * [LINE record type] @@ -811,16 +792,15 @@ The LineItem composite rowkey would be something like this: [[schema.casestudies.custorder.obj.denorm]] ===== Denormalized -A variant of the Single Table With Record Types approach is to denormalize and flatten some of the object hierarchy, such as collapsing the ShippingLocation attributes onto each LineItem instance. +A variant of the Single Table With Record Types approach is to denormalize and flatten some of the object hierarchy, such as collapsing the ShippingLocation attributes onto each LineItem instance. -The LineItem composite rowkey would be something like this: +The LineItem composite rowkey would be something like this: * [order-rowkey] * [LINE record type] -* [line item number] (e.g., 1st lineitem, 2nd, etc. - - care must be taken that there are unique across the entire order) +* [line item number] (e.g., 1st lineitem, 2nd, etc., care must be taken that there are unique across the entire order) -... and the LineItem columns would be something like this: +and the LineItem columns would be something like this: * itemNumber * quantity @@ -831,42 +811,42 @@ The LineItem composite rowkey would be something like this: * shipToState (denormalized from ShippingLocation) * shipToZip (denormalized from ShippingLocation) -The pros of this approach include a less complex object heirarchy, but one of the cons is that updating gets more complicated in case any of this information changes. +The pros of this approach include a less complex object hierarchy, but one of the cons is that updating gets more complicated in case any of this information changes. [[schema.casestudies.custorder.obj.singleobj]] ===== Object BLOB With this approach, the entire Order object graph is treated, in one way or another, as a BLOB. -For example, the ORDER table's rowkey was described above: <>, and a single column called "order" would contain an object that could be deserialized that contained a container Order, ShippingLocations, and LineItems. +For example, the ORDER table's rowkey was described above: <>, and a single column called "order" would contain an object that could be deserialized that contained a container Order, ShippingLocations, and LineItems. There are many options here: JSON, XML, Java Serialization, Avro, Hadoop Writables, etc. All of them are variants of the same approach: encode the object graph to a byte-array. -Care should be taken with this approach to ensure backward compatibilty in case the object model changes such that older persisted structures can still be read back out of HBase. +Care should be taken with this approach to ensure backward compatibilty in case the object model changes such that older persisted structures can still be read back out of HBase. -Pros are being able to manage complex object graphs with minimal I/O (e.g., a single HBase Get per Order in this example), but the cons include the aforementioned warning about backward compatiblity of serialization, language dependencies of serialization (e.g., Java Serialization only works with Java clients), the fact that you have to deserialize the entire object to get any piece of information inside the BLOB, and the difficulty in getting frameworks like Hive to work with custom objects like this. +Pros are being able to manage complex object graphs with minimal I/O (e.g., a single HBase Get per Order in this example), but the cons include the aforementioned warning about backward compatiblity of serialization, language dependencies of serialization (e.g., Java Serialization only works with Java clients), the fact that you have to deserialize the entire object to get any piece of information inside the BLOB, and the difficulty in getting frameworks like Hive to work with custom objects like this. [[schema.smackdown]] === Case Study - "Tall/Wide/Middle" Schema Design Smackdown This section will describe additional schema design questions that appear on the dist-list, specifically about tall and wide tables. -These are general guidelines and not laws - each application must consider its own needs. +These are general guidelines and not laws - each application must consider its own needs. [[schema.smackdown.rowsversions]] ==== Rows vs. Versions A common question is whether one should prefer rows or HBase's built-in-versioning. -The context is typically where there are "a lot" of versions of a row to be retained (e.g., where it is significantly above the HBase default of 1 max versions). The rows-approach would require storing a timestamp in some portion of the rowkey so that they would not overwite with each successive update. +The context is typically where there are "a lot" of versions of a row to be retained (e.g., where it is significantly above the HBase default of 1 max versions). The rows-approach would require storing a timestamp in some portion of the rowkey so that they would not overwite with each successive update. -Preference: Rows (generally speaking). +Preference: Rows (generally speaking). [[schema.smackdown.rowscols]] ==== Rows vs. Columns Another common question is whether one should prefer rows or columns. -The context is typically in extreme cases of wide tables, such as having 1 row with 1 million attributes, or 1 million rows with 1 columns apiece. +The context is typically in extreme cases of wide tables, such as having 1 row with 1 million attributes, or 1 million rows with 1 columns apiece. Preference: Rows (generally speaking). To be clear, this guideline is in the context is in extremely wide cases, not in the standard use-case where one needs to store a few dozen or hundred columns. -But there is also a middle path between these two options, and that is "Rows as Columns." +But there is also a middle path between these two options, and that is "Rows as Columns." [[schema.smackdown.rowsascols]] ==== Rows as Columns @@ -875,17 +855,17 @@ The middle path between Rows vs. Columns is packing data that would be a separate row into columns, for certain rows. OpenTSDB is the best example of this case where a single row represents a defined time-range, and then discrete events are treated as columns. This approach is often more complex, and may require the additional complexity of re-writing your data, but has the advantage of being I/O efficient. -For an overview of this approach, see <>. +For an overview of this approach, see <>. [[casestudies.schema.listdata]] === Case Study - List Data -The following is an exchange from the user dist-list regarding a fairly common question: how to handle per-user list data in Apache HBase. +The following is an exchange from the user dist-list regarding a fairly common question: how to handle per-user list data in Apache HBase. *** QUESTION *** We're looking at how to store a large amount of (per-user) list data in HBase, and we were trying to figure out what kind of access pattern made the most sense. -One option is store the majority of the data in a key, so we could have something like: +One option is store the majority of the data in a key, so we could have something like: [source] ---- @@ -905,7 +885,7 @@ The other option we had was to do this entirely using: ---- where each row would contain multiple values. -So in one case reading the first thirty values would be: +So in one case reading the first thirty values would be: [source,java] ---- @@ -913,7 +893,7 @@ So in one case reading the first thirty values would be: scan { STARTROW => 'FixedWidthUsername' LIMIT => 30} ---- -And in the second case it would be +And in the second case it would be [source] ---- @@ -923,21 +903,21 @@ get 'FixedWidthUserName\x00\x00\x00\x00' The general usage pattern would be to read only the first 30 values of these lists, with infrequent access reading deeper into the lists. Some users would have <= 30 total values in these lists, and some users would have millions (i.e. -power-law distribution) +power-law distribution) The single-value format seems like it would take up more space on HBase, but would offer some improved retrieval / pagination flexibility. -Would there be any significant performance advantages to be able to paginate via gets vs paginating with scans? +Would there be any significant performance advantages to be able to paginate via gets vs paginating with scans? My initial understanding was that doing a scan should be faster if our paging size is unknown (and caching is set appropriately), but that gets should be faster if we'll always need the same page size. I've ended up hearing different people tell me opposite things about performance. I assume the page sizes would be relatively consistent, so for most use cases we could guarantee that we only wanted one page of data in the fixed-page-length case. -I would also assume that we would have infrequent updates, but may have inserts into the middle of these lists (meaning we'd need to update all subsequent rows). +I would also assume that we would have infrequent updates, but may have inserts into the middle of these lists (meaning we'd need to update all subsequent rows). -Thanks for help / suggestions / follow-up questions. +Thanks for help / suggestions / follow-up questions. *** ANSWER *** -If I understand you correctly, you're ultimately trying to store triples in the form "user, valueid, value", right? E.g., something like: +If I understand you correctly, you're ultimately trying to store triples in the form "user, valueid, value", right? E.g., something like: [source] ---- @@ -946,29 +926,29 @@ If I understand you correctly, you're ultimately trying to store triples in the "user234, lastname, Smith" ---- -(But the usernames are fixed width, and the valueids are fixed width). +(But the usernames are fixed width, and the valueids are fixed width). -And, your access pattern is along the lines of: "for user X, list the next 30 values, starting with valueid Y". Is that right? And these values should be returned sorted by valueid? +And, your access pattern is along the lines of: "for user X, list the next 30 values, starting with valueid Y". Is that right? And these values should be returned sorted by valueid? -The tl;dr version is that you should probably go with one row per user+value, and not build a complicated intra-row pagination scheme on your own unless you're really sure it is needed. +The tl;dr version is that you should probably go with one row per user+value, and not build a complicated intra-row pagination scheme on your own unless you're really sure it is needed. Your two options mirror a common question people have when designing HBase schemas: should I go "tall" or "wide"? Your first schema is "tall": each row represents one value for one user, and so there are many rows in the table for each user; the row key is user + valueid, and there would be (presumably) a single column qualifier that means "the value". This is great if you want to scan over rows in sorted order by row key (thus my question above, about whether these ids are sorted correctly). You can start a scan at any user+valueid, read the next 30, and be done. What you're giving up is the ability to have transactional guarantees around all the rows for one user, but it doesn't sound like you need that. -Doing it this way is generally recommended (see here link:http://hbase.apache.org/book.html#schema.smackdown). +Doing it this way is generally recommended (see here link:http://hbase.apache.org/book.html#schema.smackdown). Your second option is "wide": you store a bunch of values in one row, using different qualifiers (where the qualifier is the valueid). The simple way to do that would be to just store ALL values for one user in a single row. I'm guessing you jumped to the "paginated" version because you're assuming that storing millions of columns in a single row would be bad for performance, which may or may not be true; as long as you're not trying to do too much in a single request, or do things like scanning over and returning all of the cells in the row, it shouldn't be fundamentally worse. -The client has methods that allow you to get specific slices of columns. +The client has methods that allow you to get specific slices of columns. Note that neither case fundamentally uses more disk space than the other; you're just "shifting" part of the identifying information for a value either to the left (into the row key, in option one) or to the right (into the column qualifiers in option 2). Under the covers, every key/value still stores the whole row key, and column family name. -(If this is a bit confusing, take an hour and watch Lars George's excellent video about understanding HBase schema design: link:http://www.youtube.com/watch?v=_HLoH_PgrLk). +(If this is a bit confusing, take an hour and watch Lars George's excellent video about understanding HBase schema design: link:http://www.youtube.com/watch?v=_HLoH_PgrLk). A manually paginated version has lots more complexities, as you note, like having to keep track of how many things are in each page, re-shuffling if new values are inserted, etc. That seems significantly more complex. It might have some slight speed advantages (or disadvantages!) at extremely high throughput, and the only way to really know that would be to try it out. -If you don't have time to build it both ways and compare, my advice would be to start with the simplest option (one row per user+value). Start simple and iterate! :) +If you don't have time to build it both ways and compare, my advice would be to start with the simplest option (one row per user+value). Start simple and iterate! :) [[schema.ops]] == Operational and Performance Configuration Options -See the Performance section <> for more information operational and performance schema design options, such as Bloom Filters, Table-configured regionsizes, compression, and blocksizes. +See the Performance section <> for more information operational and performance schema design options, such as Bloom Filters, Table-configured regionsizes, compression, and blocksizes. diff --git a/src/main/asciidoc/_chapters/security.adoc b/src/main/asciidoc/_chapters/security.adoc index f89efcc0554..21698fac4ea 100644 --- a/src/main/asciidoc/_chapters/security.adoc +++ b/src/main/asciidoc/_chapters/security.adoc @@ -31,7 +31,7 @@ HBase provides mechanisms to secure various components and aspects of HBase and == Using Secure HTTP (HTTPS) for the Web UI -A default HBase install uses insecure HTTP connections for web UIs for the master and region servers. +A default HBase install uses insecure HTTP connections for Web UIs for the master and region servers. To enable secure HTTP (HTTPS) connections instead, set `hadoop.ssl.enabled` to `true` in _hbase-site.xml_. This does not change the port used by the Web UI. To change the port for the web UI for a given HBase component, configure that port's setting in hbase-site.xml. @@ -63,8 +63,7 @@ If you know how to fix this without opening a second port for HTTPS, patches are == Secure Client Access to Apache HBase Newer releases of Apache HBase (>= 0.92) support optional SASL authentication of clients. -See also Matteo Bertozzi's article on link:http://www.cloudera.com/blog/2012/09/understanding-user-authentication-and-authorization-in-apache-hbase/[Understanding - User Authentication and Authorization in Apache HBase]. +See also Matteo Bertozzi's article on link:http://www.cloudera.com/blog/2012/09/understanding-user-authentication-and-authorization-in-apache-hbase/[Understanding User Authentication and Authorization in Apache HBase]. This describes how to set up Apache HBase and clients for connection to secure HBase resources. @@ -77,13 +76,13 @@ Hadoop Authentication Configuration:: Otherwise, you would be using strong authentication for HBase but not for the underlying HDFS, which would cancel out any benefit. Kerberos KDC:: - You need to have a working Kerberos KDC. + You need to have a working Kerberos KDC. === Server-side Configuration for Secure Operation First, refer to <> and ensure that your underlying HDFS configuration is secure. -Add the following to the `hbase-site.xml` file on every server machine in the cluster: +Add the following to the `hbase-site.xml` file on every server machine in the cluster: [source,xml] ---- @@ -101,13 +100,13 @@ Add the following to the `hbase-site.xml` file on every server machine in the cl ---- -A full shutdown and restart of HBase service is required when deploying these configuration changes. +A full shutdown and restart of HBase service is required when deploying these configuration changes. === Client-side Configuration for Secure Operation -First, refer to <> and ensure that your underlying HDFS configuration is secure. +First, refer to <> and ensure that your underlying HDFS configuration is secure. -Add the following to the `hbase-site.xml` file on every client: +Add the following to the `hbase-site.xml` file on every client: [source,xml] ---- @@ -117,12 +116,12 @@ Add the following to the `hbase-site.xml` file on every client: ---- -The client environment must be logged in to Kerberos from KDC or keytab via the `kinit` command before communication with the HBase cluster will be possible. +The client environment must be logged in to Kerberos from KDC or keytab via the `kinit` command before communication with the HBase cluster will be possible. -Be advised that if the `hbase.security.authentication` in the client- and server-side site files do not match, the client will not be able to communicate with the cluster. +Be advised that if the `hbase.security.authentication` in the client- and server-side site files do not match, the client will not be able to communicate with the cluster. Once HBase is configured for secure RPC it is possible to optionally configure encrypted communication. -To do so, add the following to the `hbase-site.xml` file on every client: +To do so, add the following to the `hbase-site.xml` file on every client: [source,xml] ---- @@ -133,7 +132,7 @@ To do so, add the following to the `hbase-site.xml` file on every client: ---- This configuration property can also be set on a per connection basis. -Set it in the `Configuration` supplied to `HTable`: +Set it in the `Configuration` supplied to `HTable`: [source,java] ---- @@ -142,12 +141,12 @@ conf.set("hbase.rpc.protection", "privacy"); HTable table = new HTable(conf, tablename); ---- -Expect a ~10% performance penalty for encrypted communication. +Expect a ~10% performance penalty for encrypted communication. [[security.client.thrift]] === Client-side Configuration for Secure Operation - Thrift Gateway -Add the following to the `hbase-site.xml` file for every Thrift gateway: +Add the following to the `hbase-site.xml` file for every Thrift gateway: [source,xml] ---- @@ -161,28 +160,28 @@ Add the following to the `hbase-site.xml` file for every Thrift gateway: You may have to put the concrete full hostname. --> ----- +---- -Substitute the appropriate credential and keytab for [replaceable]_$USER_ and [replaceable]_$KEYTAB_ respectively. +Substitute the appropriate credential and keytab for _$USER_ and _$KEYTAB_ respectively. In order to use the Thrift API principal to interact with HBase, it is also necessary to add the `hbase.thrift.kerberos.principal` to the `_acl_` table. -For example, to give the Thrift API principal, `thrift_server`, administrative access, a command such as this one will suffice: +For example, to give the Thrift API principal, `thrift_server`, administrative access, a command such as this one will suffice: [source,sql] ---- grant 'thrift_server', 'RWCA' ---- -For more information about ACLs, please see the <> section +For more information about ACLs, please see the <> section The Thrift gateway will authenticate with HBase using the supplied credential. No authentication will be performed by the Thrift gateway itself. -All client access via the Thrift gateway will use the Thrift gateway's credential and have its privilege. +All client access via the Thrift gateway will use the Thrift gateway's credential and have its privilege. [[security.gateway.thrift]] === Configure the Thrift Gateway to Authenticate on Behalf of the Client -<> describes how to authenticate a Thrift client to HBase using a fixed user. +<> describes how to authenticate a Thrift client to HBase using a fixed user. As an alternative, you can configure the Thrift gateway to authenticate to HBase on the client's behalf, and to access HBase using a proxy user. This was implemented in link:https://issues.apache.org/jira/browse/HBASE-11349[HBASE-11349] for Thrift 1, and link:https://issues.apache.org/jira/browse/HBASE-11474[HBASE-11474] for Thrift 2. @@ -195,8 +194,8 @@ If you use framed transport, you cannot yet take advantage of this feature, beca To enable it, do the following. -. Be sure Thrift is running in secure mode, by following the procedure described in <>. -. Be sure that HBase is configured to allow proxy users, as described in <>. +. Be sure Thrift is running in secure mode, by following the procedure described in <>. +. Be sure that HBase is configured to allow proxy users, as described in <>. . In _hbase-site.xml_ for each cluster node running a Thrift gateway, set the property `hbase.thrift.security.qop` to one of the following three values: + * `auth-conf` - authentication, integrity, and confidentiality checking @@ -204,14 +203,14 @@ To enable it, do the following. * `auth` - authentication checking only . Restart the Thrift gateway processes for the changes to take effect. - If a node is running Thrift, the output of the +jps+ command will list a `ThriftServer` process. - To stop Thrift on a node, run the command +bin/hbase-daemon.sh stop thrift+. - To start Thrift on a node, run the command +bin/hbase-daemon.sh start thrift+. + If a node is running Thrift, the output of the `jps` command will list a `ThriftServer` process. + To stop Thrift on a node, run the command `bin/hbase-daemon.sh stop thrift`. + To start Thrift on a node, run the command `bin/hbase-daemon.sh start thrift`. [[security.gateway.thrift.doas]] === Configure the Thrift Gateway to Use the `doAs` Feature -<> describes how to configure the Thrift gateway to authenticate to HBase on the client's behalf, and to access HBase using a proxy user. The limitation of this approach is that after the client is initialized with a particular set of credentials, it cannot change these credentials during the session session. The `doAs` feature provides a flexible way to impersonate multiple principals using the same client. This feature was implemented in link:https://issues.apache.org/jira/browse/HBASE-12640[HBASE-12640] for Thrift 1, but is currently not available for Thrift 2. +<> describes how to configure the Thrift gateway to authenticate to HBase on the client's behalf, and to access HBase using a proxy user. The limitation of this approach is that after the client is initialized with a particular set of credentials, it cannot change these credentials during the session. The `doAs` feature provides a flexible way to impersonate multiple principals using the same client. This feature was implemented in link:https://issues.apache.org/jira/browse/HBASE-12640[HBASE-12640] for Thrift 1, but is currently not available for Thrift 2. *To allow proxy users*, add the following to the _hbase-site.xml_ file for every HBase node: @@ -249,7 +248,7 @@ Take a look at the link:https://github.com/apache/hbase/blob/master/hbase-exampl === Client-side Configuration for Secure Operation - REST Gateway -Add the following to the `hbase-site.xml` file for every REST gateway: +Add the following to the `hbase-site.xml` file for every REST gateway: [source,xml] ---- @@ -263,24 +262,24 @@ Add the following to the `hbase-site.xml` file for every REST gateway: ---- -Substitute the appropriate credential and keytab for [replaceable]_$USER_ and [replaceable]_$KEYTAB_ respectively. +Substitute the appropriate credential and keytab for _$USER_ and _$KEYTAB_ respectively. The REST gateway will authenticate with HBase using the supplied credential. No authentication will be performed by the REST gateway itself. -All client access via the REST gateway will use the REST gateway's credential and have its privilege. +All client access via the REST gateway will use the REST gateway's credential and have its privilege. In order to use the REST API principal to interact with HBase, it is also necessary to add the `hbase.rest.kerberos.principal` to the `_acl_` table. -For example, to give the REST API principal, `rest_server`, administrative access, a command such as this one will suffice: +For example, to give the REST API principal, `rest_server`, administrative access, a command such as this one will suffice: [source,sql] ---- grant 'rest_server', 'RWCA' ---- -For more information about ACLs, please see the <> section +For more information about ACLs, please see the <> section -It should be possible for clients to authenticate with the HBase cluster through the REST gateway in a pass-through manner via SPEGNO HTTP authentication. -This is future work. +It should be possible for clients to authenticate with the HBase cluster through the REST gateway in a pass-through manner via SPNEGO HTTP authentication. +This is future work. [[security.rest.gateway]] === REST Gateway Impersonation Configuration @@ -292,11 +291,11 @@ The actual users are unknown. You can turn on the impersonation support. With impersonation, the REST gateway user is a proxy user. The HBase server knows the acutal/real user of each request. -So it can apply proper authorizations. +So it can apply proper authorizations. -To turn on REST gateway impersonation, we need to configure HBase servers (masters and region servers) to allow proxy users; configure REST gateway to enable impersonation. +To turn on REST gateway impersonation, we need to configure HBase servers (masters and region servers) to allow proxy users; configure REST gateway to enable impersonation. -To allow proxy users, add the following to the `hbase-site.xml` file for every HBase server: +To allow proxy users, add the following to the `hbase-site.xml` file for every HBase server: [source,xml] ---- @@ -314,9 +313,9 @@ To allow proxy users, add the following to the `hbase-site.xml` file for every H ---- -Substitute the REST gateway proxy user for $USER, and the allowed group list for $GROUPS. +Substitute the REST gateway proxy user for _$USER_, and the allowed group list for _$GROUPS_. -To enable REST gateway impersonation, add the following to the `hbase-site.xml` file for every REST gateway. +To enable REST gateway impersonation, add the following to the `hbase-site.xml` file for every REST gateway. [source,xml] ---- @@ -334,35 +333,34 @@ To enable REST gateway impersonation, add the following to the `hbase-site.xml` ---- -Substitute the keytab for HTTP for $KEYTAB. +Substitute the keytab for HTTP for _$KEYTAB_. [[hbase.secure.simpleconfiguration]] == Simple User Access to Apache HBase Newer releases of Apache HBase (>= 0.92) support optional SASL authentication of clients. -See also Matteo Bertozzi's article on link:http://www.cloudera.com/blog/2012/09/understanding-user-authentication-and-authorization-in-apache-hbase/[Understanding - User Authentication and Authorization in Apache HBase]. +See also Matteo Bertozzi's article on link:http://www.cloudera.com/blog/2012/09/understanding-user-authentication-and-authorization-in-apache-hbase/[Understanding User Authentication and Authorization in Apache HBase]. This describes how to set up Apache HBase and clients for simple user access to HBase resources. -=== Simple Versus Secure Access +=== Simple versus Secure Access The following section shows how to set up simple user access. Simple user access is not a secure method of operating HBase. This method is used to prevent users from making mistakes. -It can be used to mimic the Access Control using on a development system without having to set up Kerberos. +It can be used to mimic the Access Control using on a development system without having to set up Kerberos. This method is not used to prevent malicious or hacking attempts. To make HBase secure against these types of attacks, you must configure HBase for secure operation. -Refer to the section link:[Secure Client Access to HBase] and complete all of the steps described there. +Refer to the section <> and complete all of the steps described there. === Prerequisites -None +None === Server-side Configuration for Simple User Access Operation -Add the following to the `hbase-site.xml` file on every server machine in the cluster: +Add the following to the `hbase-site.xml` file on every server machine in the cluster: [source,xml] ---- @@ -388,7 +386,7 @@ Add the following to the `hbase-site.xml` file on every server machine in the cl ---- -For 0.94, add the following to the `hbase-site.xml` file on every server machine in the cluster: +For 0.94, add the following to the `hbase-site.xml` file on every server machine in the cluster: [source,xml] ---- @@ -406,11 +404,11 @@ For 0.94, add the following to the `hbase-site.xml` file on every server machine ---- -A full shutdown and restart of HBase service is required when deploying these configuration changes. +A full shutdown and restart of HBase service is required when deploying these configuration changes. === Client-side Configuration for Simple User Access Operation -Add the following to the `hbase-site.xml` file on every client: +Add the following to the `hbase-site.xml` file on every client: [source,xml] ---- @@ -420,7 +418,7 @@ Add the following to the `hbase-site.xml` file on every client: ---- -For 0.94, add the following to the `hbase-site.xml` file on every server machine in the cluster: +For 0.94, add the following to the `hbase-site.xml` file on every server machine in the cluster: [source,xml] ---- @@ -430,42 +428,42 @@ For 0.94, add the following to the `hbase-site.xml` file on every server machine ---- -Be advised that if the `hbase.security.authentication` in the client- and server-side site files do not match, the client will not be able to communicate with the cluster. +Be advised that if the `hbase.security.authentication` in the client- and server-side site files do not match, the client will not be able to communicate with the cluster. ==== Client-side Configuration for Simple User Access Operation - Thrift Gateway The Thrift gateway user will need access. -For example, to give the Thrift API user, `thrift_server`, administrative access, a command such as this one will suffice: +For example, to give the Thrift API user, `thrift_server`, administrative access, a command such as this one will suffice: [source,sql] ---- grant 'thrift_server', 'RWCA' ---- -For more information about ACLs, please see the link:[Access Control] section +For more information about ACLs, please see the <> section The Thrift gateway will authenticate with HBase using the supplied credential. No authentication will be performed by the Thrift gateway itself. -All client access via the Thrift gateway will use the Thrift gateway's credential and have its privilege. +All client access via the Thrift gateway will use the Thrift gateway's credential and have its privilege. ==== Client-side Configuration for Simple User Access Operation - REST Gateway The REST gateway will authenticate with HBase using the supplied credential. No authentication will be performed by the REST gateway itself. -All client access via the REST gateway will use the REST gateway's credential and have its privilege. +All client access via the REST gateway will use the REST gateway's credential and have its privilege. The REST gateway user will need access. -For example, to give the REST API user, `rest_server`, administrative access, a command such as this one will suffice: +For example, to give the REST API user, `rest_server`, administrative access, a command such as this one will suffice: [source,sql] ---- grant 'rest_server', 'RWCA' ---- -For more information about ACLs, please see the link:[Access Control] section +For more information about ACLs, please see the <> section -It should be possible for clients to authenticate with the HBase cluster through the REST gateway in a pass-through manner via SPEGNO HTTP authentication. -This is future work. +It should be possible for clients to authenticate with the HBase cluster through the REST gateway in a pass-through manner via SPNEGO HTTP authentication. +This is future work. == Securing Access To Your Data @@ -496,8 +494,9 @@ When copying keys, configuration files, or other files containing sensitive stri ==== .Procedure: Basic Server-Side Configuration -. Enable HFile v3, by setting +hfile.format.version +to 3 in _hbase-site.xml_. - This is the default for HBase 1.0 and newer. + +. Enable HFile v3, by setting `hfile.format.version` to 3 in _hbase-site.xml_. + This is the default for HBase 1.0 and newer. ++ [source,xml] ---- @@ -506,7 +505,7 @@ When copying keys, configuration files, or other files containing sensitive stri ---- -. Enable SASL and Kerberos authentication for RPC and ZooKeeper, as described in <> and <>. +. Enable SASL and Kerberos authentication for RPC and ZooKeeper, as described in <> and <>. [[hbase.tags]] === Tags @@ -528,7 +527,7 @@ You can enable or disable tag encoding at the level of the column family, and it Use the `HColumnDescriptor#setCompressionTags(boolean compressTags)` method to manage encoding settings on a column family. You also need to enable the DataBlockEncoder for the column family, for encoding of tags to take effect. -You can enable compression of each tag in the WAL, if WAL compression is also enabled, by setting the value of +hbase.regionserver.wal.tags.enablecompression+ to `true` in _hbase-site.xml_. +You can enable compression of each tag in the WAL, if WAL compression is also enabled, by setting the value of `hbase.regionserver.wal.tags.enablecompression` to `true` in _hbase-site.xml_. Tag compression uses dictionary encoding. Tag compression is not supported when using WAL encryption. @@ -541,8 +540,7 @@ Tag compression is not supported when using WAL encryption. ACLs in HBase are based upon a user's membership in or exclusion from groups, and a given group's permissions to access a given resource. ACLs are implemented as a coprocessor called AccessController. -HBase does not maintain a private group mapping, but relies on a [firstterm]_Hadoop - group mapper_, which maps between entities in a directory such as LDAP or Active Directory, and HBase users. +HBase does not maintain a private group mapping, but relies on a [firstterm]_Hadoop group mapper_, which maps between entities in a directory such as LDAP or Active Directory, and HBase users. Any supported Hadoop group mapper will work. Users are then granted specific permissions (Read, Write, Execute, Create, Admin) against resources (global, namespaces, tables, cells, or endpoints). @@ -555,21 +553,21 @@ No distinction is made between an insert (new record) and update (of existing re HBase access levels are granted independently of each other and allow for different types of operations at a given scope. -* Read \(R) - can read data at the given scope -* +Write (W)+ - can write data at the given scope -* +Execute (X)+ - can execute coprocessor endpoints at the given scope -* +Create (C)+ - can create tables or drop tables (even those they did not create) at the given scope -* +Admin (A)+ - can perform cluster operations such as balancing the cluster or assigning regions at the given scope +* _Read \(R)_ - can read data at the given scope +* _Write (W)_ - can write data at the given scope +* _Execute (X)_ - can execute coprocessor endpoints at the given scope +* _Create \(C)_ - can create tables or drop tables (even those they did not create) at the given scope +* _Admin (A)_ - can perform cluster operations such as balancing the cluster or assigning regions at the given scope The possible scopes are: -* +Superuser+ - superusers can perform any operation available in HBase, to any resource. +* _Superuser_ - superusers can perform any operation available in HBase, to any resource. The user who runs HBase on your cluster is a superuser, as are any principals assigned to the configuration property `hbase.superuser` in _hbase-site.xml_ on the HMaster. -* +Global+ - permissions granted at _global_ scope allow the admin to operate on all tables of the cluster. -* +Namespace+ - permissions granted at _namespace_ scope apply to all tables within a given namespace. -* +Table+ - permissions granted at _table_ scope apply to data or metadata within a given table. -* +ColumnFamily+ - permissions granted at _ColumnFamily_ scope apply to cells within that ColumnFamily. -* +Cell+ - permissions granted at _cell_ scope apply to that exact cell coordinate (key, value, timestamp). This allows for policy evolution along with data. +* _Global_ - permissions granted at _global_ scope allow the admin to operate on all tables of the cluster. +* _Namespace_ - permissions granted at _namespace_ scope apply to all tables within a given namespace. +* _Table_ - permissions granted at _table_ scope apply to data or metadata within a given table. +* _ColumnFamily_ - permissions granted at _ColumnFamily_ scope apply to cells within that ColumnFamily. +* _Cell_ - permissions granted at _cell_ scope apply to that exact cell coordinate (key, value, timestamp). This allows for policy evolution along with data. + To change an ACL on a specific cell, write an updated cell with new ACL to the precise coordinates of the original. + @@ -587,12 +585,11 @@ In a production environment, it is useful to think of access levels in terms of The following list describes appropriate access levels for some common types of HBase users. It is important not to grant more access than is required for a given user to perform their required tasks. -* Superusers - In a production system, only the HBase user should have superuser access. +* _Superusers_ - In a production system, only the HBase user should have superuser access. In a development environment, an administrator may need superuser access in order to quickly control and manage the cluster. However, this type of administrator should usually be a Global Admin rather than a superuser. -* Global Admins - A global admin can perform tasks and access every table in HBase. +* _Global Admins_ - A global admin can perform tasks and access every table in HBase. In a typical production environment, an admin should not have Read or Write permissions to data within tables. -+ * A global admin with Admin permissions can perform cluster-wide operations on the cluster, such as balancing, assigning or unassigning regions, or calling an explicit major compaction. This is an operations role. * A global admin with Create permissions can create or drop any table within HBase. @@ -602,20 +599,20 @@ In a production environment, it is likely that different users will have only on + [WARNING] ==== -In the current implementation, a Global Admin with `Admin` permission can grant himself `Read` and `Write` permissions on a table and gain access to that table's data. +In the current implementation, a Global Admin with `Admin` permission can grant himself `Read` and `Write` permissions on a table and gain access to that table's data. For this reason, only grant `Global Admin` permissions to trusted user who actually need them. -Also be aware that a `Global Admin` with `Create` permission can perform a `Put` operation on the ACL table, simulating a `grant` or `revoke` and circumventing the authorization check for `Global Admin` permissions. +Also be aware that a `Global Admin` with `Create` permission can perform a `Put` operation on the ACL table, simulating a `grant` or `revoke` and circumventing the authorization check for `Global Admin` permissions. -Due to these issues, be cautious with granting `Global Admin` privileges. +Due to these issues, be cautious with granting `Global Admin` privileges. ==== -* +Namespace Admins+ - a namespace admin with `Create` permissions can create or drop tables within that namespace, and take and restore snapshots. +* _Namespace Admins_ - a namespace admin with `Create` permissions can create or drop tables within that namespace, and take and restore snapshots. A namespace admin with `Admin` permissions can perform operations such as splits or major compactions on tables within that namespace. -* +Table Admins+ - A table admin can perform administrative operations only on that table. +* _Table Admins_ - A table admin can perform administrative operations only on that table. A table admin with `Create` permissions can create snapshots from that table or restore that table from a snapshot. A table admin with `Admin` permissions can perform operations such as splits or major compactions on that table. -* +Users+ - Users can read or write data, or both. +* _Users_ - Users can read or write data, or both. Users can also execute coprocessor endpoints, if given `Executable` permissions. .Real-World Example of Access Levels @@ -625,17 +622,16 @@ Due to these issues, be cautious with granting `Global Admin` p | Scope | Permissions | Description + | Senior Administrator | Global | Access, Create -| Manages the cluster and gives access to Junior - Administrators. +| Manages the cluster and gives access to Junior Administrators. | Junior Administrator | Global | Create -| Creates tables and gives access to Table - Administrators. +| Creates tables and gives access to Table Administrators. | Table Administrator | Table @@ -650,8 +646,7 @@ Due to these issues, be cautious with granting `Global Admin` p | Web Application | Table | Read, Write -| Puts data into HBase and uses HBase data to perform - operations. +| Puts data into HBase and uses HBase data to perform operations. |=== .ACL Matrix @@ -659,7 +654,7 @@ For more details on how ACLs map to specific HBase operations and tasks, see <>). In order to use cell-level ACLs, you must be using HFile v3 and HBase 0.98 or newer. +Cell-level ACLs are implemented using tags (see <>). In order to use cell-level ACLs, you must be using HFile v3 and HBase 0.98 or newer. . Files created by HBase are owned by the operating system user running the HBase process. To interact with HBase files, you should use the API or bulk load facility. @@ -670,13 +665,12 @@ Cell-level ACLs are implemented using tags (see <>). In o ===== Server-Side Configuration - -. As a prerequisite, perform the steps in <>. +. As a prerequisite, perform the steps in <>. . Install and configure the AccessController coprocessor, by setting the following properties in _hbase-site.xml_. - These properties take a list of classes. + These properties take a list of classes. + NOTE: If you use the AccessController along with the VisibilityController, the AccessController must come first in the list, because with both components active, the VisibilityController will delegate access control on its system tables to the AccessController. -For an example of using both together, see <>. +For an example of using both together, see <>. + [source,xml] ---- @@ -698,7 +692,7 @@ For an example of using both together, see < ---- + -Optionally, you can enable transport security, by setting +hbase.rpc.protection+ to `auth-conf`. +Optionally, you can enable transport security, by setting `hbase.rpc.protection` to `auth-conf`. This requires HBase 0.98.4 or newer. . Set up the Hadoop group mapper in the Hadoop namenode's _core-site.xml_. @@ -756,11 +750,11 @@ This requires HBase 0.98.4 or newer. . Optionally, enable the early-out evaluation strategy. Prior to HBase 0.98.0, if a user was not granted access to a column family, or at least a column qualifier, an AccessDeniedException would be thrown. HBase 0.98.0 removed this exception in order to allow cell-level exceptional grants. - To restore the old behavior in HBase 0.98.0-0.98.6, set +hbase.security.access.early_out+ to `true` in _hbase-site.xml_. + To restore the old behavior in HBase 0.98.0-0.98.6, set `hbase.security.access.early_out` to `true` in _hbase-site.xml_. In HBase 0.98.6, the default has been returned to `true`. . Distribute your configuration and restart your cluster for changes to take effect. -. To test your configuration, log into HBase Shell as a given user and use the +whoami+ command to report the groups your user is part of. - In this example, the user is reported as being a member of the `services` group. +. To test your configuration, log into HBase Shell as a given user and use the `whoami` command to report the groups your user is part of. + In this example, the user is reported as being a member of the `services` group. + ---- hbase> whoami @@ -798,7 +792,7 @@ grant 'user', 'RWXCA', 'TABLE', 'CF', 'CQ' ---- + Groups and users are granted access in the same way, but groups are prefixed with an `@` symbol. -In the same way, tables and namespaces are specified in the same way, but namespaces are prefixed with an `@` symbol. +In the same way, tables and namespaces are specified in the same way, but namespaces are prefixed with an `@` symbol. + It is also possible to grant multiple permissions against the same resource in a single statement, as in this example. The first sub-clause maps users to ACLs and the second sub-clause specifies the resource. @@ -853,9 +847,9 @@ grant
, \ { } ---- + -* [replaceable]__ is the user or group name, prefixed with `@` in the case of a group. -* [replaceable]__ is a string containing any or all of "RWXCA", though only R and W are meaningful at cell scope. -* [replaceable]__ is the scanner specification syntax and conventions used by the 'scan' shell command. +* __ is the user or group name, prefixed with `@` in the case of a group. +* __ is a string containing any or all of "RWXCA", though only R and W are meaningful at cell scope. +* __ is the scanner specification syntax and conventions used by the 'scan' shell command. For some examples of scanner specifications, issue the following HBase Shell command. + ---- @@ -920,9 +914,9 @@ put.setACL(“user1”, new Permission(Permission.Action.READ)) . Revoking Access Control From a Namespace, Table, Column Family, or Cell + -The +revoke+ command and API are twins of the grant command and API, and the syntax is exactly the same. +The `revoke` command and API are twins of the grant command and API, and the syntax is exactly the same. The only exception is that you cannot revoke permissions at the cell level. -You can only revoke access that has previously been granted, and a +revoke+ statement is not the same thing as explicit denial to a resource. +You can only revoke access that has previously been granted, and a `revoke` statement is not the same thing as explicit denial to a resource. + NOTE: HBase Shell support for granting and revoking access is for testing and verification support, and should not be employed for production use because it won't apply the permissions to cells that don't exist yet. The correct way to apply cell-level permissions is to do so in the application code when storing the values. @@ -976,12 +970,12 @@ public static void verifyAllowed(User user, AccessTestAction action, int count) if (obj != null && obj instanceof List<?>) { List<?> results = (List<?>) obj; if (results != null && results.isEmpty()) { - fail("Empty non null results from action for user '" + user.getShortName() + "'"); + fail("Empty non null results from action for user '" ` user.getShortName() ` "'"); } assertEquals(count, results.size()); } } catch (AccessDeniedException ade) { - fail("Expected action to pass for user '" + user.getShortName() + "' but was denied"); + fail("Expected action to pass for user '" ` user.getShortName() ` "' but was denied"); } } ---- @@ -1000,25 +994,25 @@ Visibility labels have no meaning on their own, and may be used to denote sensit If a user's labels do not match a cell's label or expression, the user is denied access to the cell. In HBase 0.98.6 and newer, UTF-8 encoding is supported for visibility labels and expressions. -When creating labels using the `addLabels(conf, labels)` method provided by the `org.apache.hadoop.hbase.security.visibility.VisibilityClient` class and passing labels in Authorizations via Scan or Get, labels can contain UTF-8 characters, as well as the logical operators normally used in visibility labels, with normal Java notations, without needing any escaping method. +When creating labels using the `addLabels(conf, labels)` method provided by the `org.apache.hadoop.hbase.security.visibility.VisibilityClient` class and passing labels in Authorizations via Scan or Get, labels can contain UTF-8 characters, as well as the logical operators normally used in visibility labels, with normal Java notations, without needing any escaping method. However, when you pass a CellVisibility expression via a Mutation, you must enclose the expression with the `CellVisibility.quote()` method if you use UTF-8 characters or logical operators. -See `TestExpressionParser` and the source file _hbase-client/src/test/java/org/apache/hadoop/hbase/client/TestScan.java_. +See `TestExpressionParser` and the source file _hbase-client/src/test/java/org/apache/hadoop/hbase/client/TestScan.java_. A user adds visibility expressions to a cell during a Put operation. -In the default configuration, the user does not need to access to a label in order to label cells with it. -This behavior is controlled by the configuration option +hbase.security.visibility.mutations.checkauths+. +In the default configuration, the user does not need to have access to a label in order to label cells with it. +This behavior is controlled by the configuration option `hbase.security.visibility.mutations.checkauths`. If you set this option to `true`, the labels the user is modifying as part of the mutation must be associated with the user, or the mutation will fail. Whether a user is authorized to read a labelled cell is determined during a Get or Scan, and results which the user is not allowed to read are filtered out. This incurs the same I/O penalty as if the results were returned, but reduces load on the network. Visibility labels can also be specified during Delete operations. -For details about visibility labels and Deletes, see link:https://issues.apache.org/jira/browse/HBASE-10885[HBASE-10885]. +For details about visibility labels and Deletes, see link:https://issues.apache.org/jira/browse/HBASE-10885[HBASE-10885]. The user's effective label set is built in the RPC context when a request is first received by the RegionServer. The way that users are associated with labels is pluggable. The default plugin passes through labels specified in Authorizations added to the Get or Scan and checks those against the calling user's authenticated labels list. When the client passes labels for which the user is not authenticated, the default plugin drops them. -You can pass a subset of user authenticated labels via the `Get#setAuthorizations(Authorizations(String,...))` and `Scan#setAuthorizations(Authorizations(String,...));` methods. +You can pass a subset of user authenticated labels via the `Get#setAuthorizations(Authorizations(String,...))` and `Scan#setAuthorizations(Authorizations(String,...));` methods. Visibility label access checking is performed by the VisibilityController coprocessor. You can use interface `VisibilityLabelService` to provide a custom implementation and/or control the way that visibility labels are stored with cells. @@ -1026,29 +1020,32 @@ See the source file _hbase-server/src/test/java/org/apache/hadoop/hbase/security Visibility labels can be used in conjunction with ACLs. +NOTE: The labels have to be explicitly defined before they can be used in visibility labels. See below for an example of how this can be done. + +NOTE: There is currently no way to determine which labels have been applied to a cell. See link:https://issues.apache.org/jira/browse/HBASE-12470[HBASE-12470] for details. + +NOTE: Visibility labels are not currently applied for superusers. + .Examples of Visibility Expressions [cols="l,1", options="header"] |=== | Expression | Interpretation + | fulltime -| Allow accesss to users associated with the - fulltime label. +| Allow accesss to users associated with the fulltime label. | !public -| Allow access to users not associated with the - public label. +| Allow access to users not associated with the public label. | ( secret \| topsecret ) & !probationary -| Allow access to users associated with either the - secret or topsecret label and not - associated with the probationary label. +| Allow access to users associated with either the secret or topsecret label and not associated with the probationary label. |=== ==== Server-Side Configuration -. As a prerequisite, perform the steps in <>. +. As a prerequisite, perform the steps in <>. . Install and configure the VisibilityController coprocessor by setting the following properties in _hbase-site.xml_. These properties take a list of class names. + @@ -1070,7 +1067,7 @@ NOTE: If you use the AccessController and VisibilityController coprocessors toge + By default, users can label cells with any label, including labels they are not associated with, which means that a user can Put data that he cannot read. For example, a user could label a cell with the (hypothetical) 'topsecret' label even if the user is not associated with that label. -If you only want users to be able to label cells with labels they are associated with, set +hbase.security.visibility.mutations.checkauths+ to `true`. +If you only want users to be able to label cells with labels they are associated with, set `hbase.security.visibility.mutations.checkauths` to `true`. In that case, the mutation will fail if it makes use of labels the user is not associated with. . Distribute your configuration and restart your cluster for changes to take effect. @@ -1104,10 +1101,8 @@ hbase> add_labels [ 'admin', 'service', 'developer', 'test' ] ==== [source,java] ---- - public static void addLabels() throws Exception { - PrivilegedExceptionAction action = - new PrivilegedExceptionAction() { + PrivilegedExceptionAction action = new PrivilegedExceptionAction() { public VisibilityLabelsResponse run() throws Exception { String[] labels = { SECRET, TOPSECRET, CONFIDENTIAL, PUBLIC, PRIVATE, COPYRIGHT, ACCENT, UNICODE_VIS_TAG, UC1, UC2 }; @@ -1145,7 +1140,6 @@ hbase> set_auths 'qa', [ 'test', 'developer' ] ==== [source,java] ---- - public void testSetAndGetUserAuths() throws Throwable { final String user = "user1"; PrivilegedExceptionAction action = new PrivilegedExceptionAction() { @@ -1182,7 +1176,6 @@ hbase> clear_auths 'qa', [ 'test', 'developer' ] ==== [source,java] ---- - ... auths = new String[] { SECRET, PUBLIC, CONFIDENTIAL }; VisibilityLabelsResponse response = null; @@ -1190,7 +1183,8 @@ try { response = VisibilityClient.clearAuths(conf, auths, user); } catch (Throwable e) { fail("Should not have failed"); -... + ... +} ---- ==== @@ -1202,18 +1196,15 @@ The label is associated with a given version of the cell. .HBase Shell ==== ---- -hbase> set_visibility 'user', 'admin|service|developer', \ - { COLUMNS => 'i' } +hbase> set_visibility 'user', 'admin|service|developer', { COLUMNS => 'i' } ---- ---- -hbase> set_visibility 'user', 'admin|service', \ - { COLUMNS => ' pii' } +hbase> set_visibility 'user', 'admin|service', { COLUMNS => 'pii' } ---- ---- -hbase> COLUMNS => [ 'i', 'pii' ], \ - FILTER => "(PrefixFilter ('test'))" } +hbase> set_visibility 'user', 'test', { COLUMNS => [ 'i', 'pii' ], FILTER => "(PrefixFilter ('test'))" } ---- ==== + @@ -1257,7 +1248,7 @@ You can also configure a set of `ScanLabelGenerators` to be used by the system, ==== Replicating Visibility Tags as Strings -As mentioned in the above sections, the interface `VisibilityLabelService` could be used to implement a different way of storing the visibility expressions in the cells. Clusters with replication enabled also must replicate the visibility expressions to the peer cluster. If `DefaultVisibilityLabelServiceImpl` is used as the implementation for `VisibilityLabelService`, all the visibility expression are converted to the corresponding expression based on the ordinals for each visibility label stored in the labels table. During replication, visible cellsare also replicated with the ordinal-based expression intact. The peer cluster may not have the same `labels` table with the same ordinal mapping for the visibility labels. In that case, replicating the ordinals makes no sense. It would be better if the replication occurred with the visibility expressions transmitted as strings. To replicate the visibility expression as strings to the peer cluster, create a `RegionServerObserver` configuration which works based on the implementation of the `VisibilityLabelService` interface. The configuration below enables replication of visibility expressions to peer clusters as strings. See link:https://issues.apache.org/jira/browse/HBASE-11639[HBASE-11639] for more details. +As mentioned in the above sections, the interface `VisibilityLabelService` could be used to implement a different way of storing the visibility expressions in the cells. Clusters with replication enabled also must replicate the visibility expressions to the peer cluster. If `DefaultVisibilityLabelServiceImpl` is used as the implementation for `VisibilityLabelService`, all the visibility expression are converted to the corresponding expression based on the ordinals for each visibility label stored in the labels table. During replication, visible cells are also replicated with the ordinal-based expression intact. The peer cluster may not have the same `labels` table with the same ordinal mapping for the visibility labels. In that case, replicating the ordinals makes no sense. It would be better if the replication occurred with the visibility expressions transmitted as strings. To replicate the visibility expression as strings to the peer cluster, create a `RegionServerObserver` configuration which works based on the implementation of the `VisibilityLabelService` interface. The configuration below enables replication of visibility expressions to peer clusters as strings. See link:https://issues.apache.org/jira/browse/HBASE-11639[HBASE-11639] for more details. [source,xml] ---- @@ -1286,7 +1277,7 @@ The master key may be stored on the cluster servers, protected by a secure KeySt This master key is resolved as needed by HBase processes through the configured key provider. Next, encryption use can be specified in the schema, per column family, by creating or modifying a column descriptor to include two additional attributes: the name of the encryption algorithm to use (currently only "AES" is supported), and optionally, a data key wrapped (encrypted) with the cluster master key. -If a data key is not explictly configured for a ColumnFamily, HBase will create a random data key per HFile. +If a data key is not explicitly configured for a ColumnFamily, HBase will create a random data key per HFile. This provides an incremental improvement in security over the alternative. Unless you need to supply an explicit data key, such as in a case where you are generating encrypted HFiles for bulk import with a given data key, only specify the encryption algorithm in the ColumnFamily schema metadata and let HBase create data keys on demand. Per Column Family keys facilitate low impact incremental key rotation and reduce the scope of any external leak of key material. @@ -1338,23 +1329,23 @@ In the example below, replace [replaceable]_****_ with the password. [source,xml] ---- - hbase.crypto.keyprovider - org.apache.hadoop.hbase.io.crypto.KeyStoreKeyProvider + hbase.crypto.keyprovider + org.apache.hadoop.hbase.io.crypto.KeyStoreKeyProvider - hbase.crypto.keyprovider.parameters - jceks:///path/to/hbase/conf/hbase.jks?password=**** + hbase.crypto.keyprovider.parameters + jceks:///path/to/hbase/conf/hbase.jks?password=**** ---- + By default, the HBase service account name will be used to resolve the cluster master key. -However, you can store it with an arbitrary alias (in the +keytool+ command). In that case, set the following property to the alias you used. +However, you can store it with an arbitrary alias (in the `keytool` command). In that case, set the following property to the alias you used. + [source,xml] ---- - hbase.crypto.master.key.name - my-alias + hbase.crypto.master.key.name + my-alias ---- + @@ -1365,24 +1356,22 @@ For previous versions, set the following property in your _hbase-site.xml_ [source,xml] ---- - hfile.format.version - 3 + hfile.format.version + 3 ---- + -Optionally, you can use a different cipher provider, either a Java Cryptography Encryption (JCE) algorithm provider or a custom HBase cipher implementation. +Optionally, you can use a different cipher provider, either a Java Cryptography Encryption (JCE) algorithm provider or a custom HBase cipher implementation. + -* JCE: -+ -* Install a signed JCE provider (supporting ``AES/CTR/NoPadding'' mode with 128 bit keys) -* Add it with highest preference to the JCE site configuration file _$JAVA_HOME/lib/security/java.security_. -* Update +hbase.crypto.algorithm.aes.provider+ and +hbase.crypto.algorithm.rng.provider+ options in _hbase-site.xml_. +* JCE: +** Install a signed JCE provider (supporting `AES/CTR/NoPadding` mode with 128 bit keys) +** Add it with highest preference to the JCE site configuration file _$JAVA_HOME/lib/security/java.security_. +** Update `hbase.crypto.algorithm.aes.provider` and `hbase.crypto.algorithm.rng.provider` options in [path]_hbase-site.xml_. -* Custom HBase Cipher: -+ -* Implement `org.apache.hadoop.hbase.io.crypto.CipherProvider`. -* Add the implementation to the server classpath. -* Update +hbase.crypto.cipherprovider+ in _hbase-site.xml_. +* Custom HBase Cipher: +** Implement `org.apache.hadoop.hbase.io.crypto.CipherProvider`. +** Add the implementation to the server classpath. +** Update `hbase.crypto.cipherprovider` in _hbase-site.xml_. . Configure WAL encryption. @@ -1452,10 +1441,12 @@ Rotate the Master Key:: [[hbase.secure.bulkload]] === Secure Bulk Load -Bulk loading in secure mode is a bit more involved than normal setup, since the client has to transfer the ownership of the files generated from the mapreduce job to HBase. -Secure bulk loading is implemented by a coprocessor, named link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/security/access/SecureBulkLoadEndpoint.html[SecureBulkLoadEndpoint], which uses a staging directory configured by the configuration property +hbase.bulkload.staging.dir+, which defaults to _/tmp/hbase-staging/_. +Bulk loading in secure mode is a bit more involved than normal setup, since the client has to transfer the ownership of the files generated from the MapReduce job to HBase. +Secure bulk loading is implemented by a coprocessor, named link:http://hbase.apache.org/apidocs/org/apache/hadoop/hbase/security/access/SecureBulkLoadEndpoint.html[SecureBulkLoadEndpoint], which uses a staging directory configured by the configuration property `hbase.bulkload.staging.dir`, which defaults to _/tmp/hbase-staging/_. -* .Secure Bulk Load AlgorithmOne time only, create a staging directory which is world-traversable and owned by the user which runs HBase (mode 711, or `rwx--x--x`). A listing of this directory will look similar to the following: +.Secure Bulk Load Algorithm + +* One time only, create a staging directory which is world-traversable and owned by the user which runs HBase (mode 711, or `rwx--x--x`). A listing of this directory will look similar to the following: + [source,bash] ---- @@ -1468,7 +1459,7 @@ drwx--x--x 2 hbase hbase 68 3 Sep 14:54 /tmp/hbase-staging * Internally, HBase creates a secret staging directory which is globally readable/writable (`-rwxrwxrwx, 777`). For example, _/tmp/hbase-staging/averylongandrandomdirectoryname_. The name and location of this directory is not exposed to the user. HBase manages creation and deletion of this directory. -* The user makes the data world-readable and world-writable, moves it into the random staging directory, then calls the `SecureBulkLoadClient#bulkLoadHFiles` method. +* The user makes the data world-readable and world-writable, moves it into the random staging directory, then calls the `SecureBulkLoadClient#bulkLoadHFiles` method. The strength of the security lies in the length and randomness of the secret directory. @@ -1541,29 +1532,29 @@ All options have been discussed separately in the sections above. - hbase.crypto.keyprovider - org.apache.hadoop.hbase.io.crypto.KeyStoreKeyProvider + hbase.crypto.keyprovider + org.apache.hadoop.hbase.io.crypto.KeyStoreKeyProvider - hbase.crypto.keyprovider.parameters - jceks:///path/to/hbase/conf/hbase.jks?password=*** + hbase.crypto.keyprovider.parameters + jceks:///path/to/hbase/conf/hbase.jks?password=*** - hbase.crypto.master.key.name - hbase + hbase.crypto.master.key.name + hbase - hbase.regionserver.hlog.reader.impl - org.apache.hadoop.hbase.regionserver.wal.SecureProtobufLogReader + hbase.regionserver.hlog.reader.impl + org.apache.hadoop.hbase.regionserver.wal.SecureProtobufLogReader - hbase.regionserver.hlog.writer.impl - org.apache.hadoop.hbase.regionserver.wal.SecureProtobufLogWriter + hbase.regionserver.hlog.writer.impl + org.apache.hadoop.hbase.regionserver.wal.SecureProtobufLogWriter - hbase.regionserver.wal.encryption - true + hbase.regionserver.wal.encryption + true diff --git a/src/main/asciidoc/_chapters/shell.adoc b/src/main/asciidoc/_chapters/shell.adoc index 1b8d8a0e83f..237089ea5c8 100644 --- a/src/main/asciidoc/_chapters/shell.adoc +++ b/src/main/asciidoc/_chapters/shell.adoc @@ -38,13 +38,13 @@ To run the HBase shell, do as follows: $ ./bin/hbase shell ---- -Type +help+ and then ++ to see a listing of shell commands and options. -Browse at least the paragraphs at the end of the help emission for the gist of how variables and command arguments are entered into the HBase shell; in particular note how table names, rows, and columns, etc., must be quoted. +Type `help` and then `` to see a listing of shell commands and options. +Browse at least the paragraphs at the end of the help output for the gist of how variables and command arguments are entered into the HBase shell; in particular note how table names, rows, and columns, etc., must be quoted. -See <> for example basic shell operation. +See <> for example basic shell operation. Here is a nicely formatted listing of link:http://learnhbase.wordpress.com/2013/03/02/hbase-shell-commands/[all shell - commands] by Rajeshbabu Chintaguntla. + commands] by Rajeshbabu Chintaguntla. [[scripting]] == Scripting with Ruby @@ -64,27 +64,26 @@ A new non-interactive mode has been added to the HBase Shell (link:https://issue Non-interactive mode captures the exit status (success or failure) of HBase Shell commands and passes that status back to the command interpreter. If you use the normal interactive mode, the HBase Shell will only ever return its own exit status, which will nearly always be `0` for success. -To invoke non-interactive mode, pass the +-n+ or +--non-interactive+ option to HBase Shell. +To invoke non-interactive mode, pass the `-n` or `--non-interactive` option to HBase Shell. [[hbase.shell.noninteractive]] == HBase Shell in OS Scripts You can use the HBase shell from within operating system script interpreters like the Bash shell which is the default command interpreter for most Linux and UNIX distributions. -The following guidelines use Bash syntax, but could be adjusted to work with C-style shells such as csh or tcsh, and could probably be modified to work with the Microsoft Windows script interpreter as well. -Submissions are welcome. +The following guidelines use Bash syntax, but could be adjusted to work with C-style shells such as csh or tcsh, and could probably be modified to work with the Microsoft Windows script interpreter as well. Submissions are welcome. NOTE: Spawning HBase Shell commands in this way is slow, so keep that in mind when you are deciding when combining HBase operations with the operating system command line is appropriate. .Passing Commands to the HBase Shell ==== -You can pass commands to the HBase Shell in non-interactive mode (see <>) using the +echo+ command and the `|` (pipe) operator. +You can pass commands to the HBase Shell in non-interactive mode (see <>) using the `echo` command and the `|` (pipe) operator. Be sure to escape characters in the HBase commands which would otherwise be interpreted by the shell. Some debug-level output has been truncated from the example below. [source,bash] ---- $ echo "describe 'test1'" | ./hbase shell -n - + Version 0.98.3-hadoop2, rd5e65a9144e315bb0a964e7730871af32f5018d5, Sat May 31 19:56:09 PDT 2014 describe 'test1' @@ -122,7 +121,7 @@ This is a naive script that shows one way to store the return value and make a d echo "describe 'test'" | ./hbase shell -n > /dev/null 2>&1 status=$? -echo "The status was " $status +echo "The status was " $status if ($status == 0); then echo "The command succeeded" else @@ -134,7 +133,7 @@ return $status === Checking for Success or Failure In Scripts -Getting an exit code of 0 means that the command you scripted definitely succeeded. +Getting an exit code of `0` means that the command you scripted definitely succeeded. However, getting a non-zero exit code does not necessarily mean the command failed. The command could have succeeded, but the client lost connectivity, or some other event obscured its success. This is because RPC commands are stateless. @@ -163,10 +162,9 @@ enable 'test' .Directing HBase Shell to Execute the Commands ==== -Pass the path to the command file as the only argument to the +hbase - shell+ command. +Pass the path to the command file as the only argument to the `hbase shell` command. Each command is executed and its output is shown. -If you do not include the +exit+ command in your script, you are returned to the HBase shell prompt. +If you do not include the `exit` command in your script, you are returned to the HBase shell prompt. There is no way to programmatically check each individual command for success or failure. Also, though you see the output for each command, the commands themselves are not echoed to the screen so it can be difficult to line up the command with its output. @@ -206,14 +204,14 @@ COLUMN CELL == Passing VM Options to the Shell -You can pass VM options to the HBase Shell using the `HBASE_SHELL_OPTS` environment variable. +You can pass VM options to the HBase Shell using the `HBASE_SHELL_OPTS` environment variable. You can set this in your environment, for instance by editing _~/.bashrc_, or set it as part of the command to launch HBase Shell. The following example sets several garbage-collection-related variables, just for the lifetime of the VM running the HBase Shell. The command should be run all on a single line, but is broken by the `\` character, for readability. [source,bash] ---- -$ HBASE_SHELL_OPTS="-verbose:gc -XX:+PrintGCApplicationStoppedTime -XX:+PrintGCDateStamps \ +$ HBASE_SHELL_OPTS="-verbose:gc -XX:+PrintGCApplicationStoppedTime -XX:+PrintGCDateStamps \ -XX:+PrintGCDetails -Xloggc:$HBASE_HOME/logs/gc-hbase.log" ./bin/hbase shell ---- @@ -221,10 +219,10 @@ $ HBASE_SHELL_OPTS="-verbose:gc -XX:+PrintGCApplicationStoppedTime -XX:+PrintGCD === Table variables -HBase 0.95 adds shell commands that provide a jruby-style object-oriented references for tables. +HBase 0.95 adds shell commands that provides jruby-style object-oriented references for tables. Previously all of the shell commands that act upon a table have a procedural style that always took the name of the table as an argument. HBase 0.95 introduces the ability to assign a table to a jruby variable. -The table reference can be used to perform data read write operations such as puts, scans, and gets well as admin functionality such as disabling, dropping, describing tables. +The table reference can be used to perform data read write operations such as puts, scans, and gets well as admin functionality such as disabling, dropping, describing tables. For example, previously you would always specify a table name: @@ -234,17 +232,17 @@ hbase(main):000:0> create ‘t’, ‘f’ hbase(main):001:0> put 't', 'rold', 'f', 'v' 0 row(s) in 0.0080 seconds -hbase(main):002:0> scan 't' -ROW COLUMN+CELL - rold column=f:, timestamp=1378473207660, value=v +hbase(main):002:0> scan 't' +ROW COLUMN+CELL + rold column=f:, timestamp=1378473207660, value=v 1 row(s) in 0.0130 seconds hbase(main):003:0> describe 't' -DESCRIPTION ENABLED - 't', {NAME => 'f', DATA_BLOCK_ENCODING => 'NONE', BLOOMFILTER => 'ROW', REPLICATION_ true - SCOPE => '0', VERSIONS => '1', COMPRESSION => 'NONE', MIN_VERSIONS => '0', TTL => '2 - 147483647', KEEP_DELETED_CELLS => 'false', BLOCKSIZE => '65536', IN_MEMORY => 'false - ', BLOCKCACHE => 'true'} +DESCRIPTION ENABLED + 't', {NAME => 'f', DATA_BLOCK_ENCODING => 'NONE', BLOOMFILTER => 'ROW', REPLICATION_ true + SCOPE => '0', VERSIONS => '1', COMPRESSION => 'NONE', MIN_VERSIONS => '0', TTL => '2 + 147483647', KEEP_DELETED_CELLS => 'false', BLOCKSIZE => '65536', IN_MEMORY => 'false + ', BLOCKCACHE => 'true'} 1 row(s) in 1.4430 seconds hbase(main):004:0> disable 't' @@ -266,15 +264,15 @@ hbase(main):007 > t = create 't', 'f' hbase(main):008 > t.put 'r', 'f', 'v' 0 row(s) in 0.0640 seconds hbase(main):009 > t.scan -ROW COLUMN+CELL - r column=f:, timestamp=1331865816290, value=v +ROW COLUMN+CELL + r column=f:, timestamp=1331865816290, value=v 1 row(s) in 0.0110 seconds hbase(main):010:0> t.describe -DESCRIPTION ENABLED - 't', {NAME => 'f', DATA_BLOCK_ENCODING => 'NONE', BLOOMFILTER => 'ROW', REPLICATION_ true - SCOPE => '0', VERSIONS => '1', COMPRESSION => 'NONE', MIN_VERSIONS => '0', TTL => '2 - 147483647', KEEP_DELETED_CELLS => 'false', BLOCKSIZE => '65536', IN_MEMORY => 'false - ', BLOCKCACHE => 'true'} +DESCRIPTION ENABLED + 't', {NAME => 'f', DATA_BLOCK_ENCODING => 'NONE', BLOOMFILTER => 'ROW', REPLICATION_ true + SCOPE => '0', VERSIONS => '1', COMPRESSION => 'NONE', MIN_VERSIONS => '0', TTL => '2 + 147483647', KEEP_DELETED_CELLS => 'false', BLOCKSIZE => '65536', IN_MEMORY => 'false + ', BLOCKCACHE => 'true'} 1 row(s) in 0.0210 seconds hbase(main):038:0> t.disable 0 row(s) in 6.2350 seconds @@ -293,11 +291,11 @@ hbase(main):012:0> tab = get_table 't' 0 row(s) in 0.0010 seconds => Hbase::Table - t -hbase(main):013:0> tab.put ‘r1’ ,’f’, ‘v’ +hbase(main):013:0> tab.put ‘r1’ ,’f’, ‘v’ 0 row(s) in 0.0100 seconds hbase(main):014:0> tab.scan -ROW COLUMN+CELL - r1 column=f:, timestamp=1378473876949, value=v +ROW COLUMN+CELL + r1 column=f:, timestamp=1378473876949, value=v 1 row(s) in 0.0240 seconds hbase(main):015:0> ---- @@ -308,8 +306,8 @@ The list_snapshots command also acts similarly. ---- hbase(main):016 > tables = list(‘t.*’) -TABLE -t +TABLE +t 1 row(s) in 0.1040 seconds => #<#:0x21d377a4> @@ -333,7 +331,7 @@ IRB.conf[:SAVE_HISTORY] = 100 IRB.conf[:HISTORY_FILE] = "#{ENV['HOME']}/.irb-save-history" ---- -See the +ruby+ documentation of _.irbrc_ to learn about other possible configurations. +See the `ruby` documentation of _.irbrc_ to learn about other possible configurations. === LOG data to timestamp @@ -352,7 +350,7 @@ hbase(main):021:0> import java.util.Date hbase(main):022:0> Date.new(1218920189000).toString() => "Sat Aug 16 20:56:29 UTC 2008" ---- -To output in a format that is exactly like that of the HBase log format will take a little messing with link:http://download.oracle.com/javase/6/docs/api/java/text/SimpleDateFormat.html[SimpleDateFormat]. +To output in a format that is exactly like that of the HBase log format will take a little messing with link:http://download.oracle.com/javase/6/docs/api/java/text/SimpleDateFormat.html[SimpleDateFormat]. === Debug @@ -368,7 +366,7 @@ hbase> debug ==== DEBUG log level -To enable DEBUG level logging in the shell, launch it with the +-d+ option. +To enable DEBUG level logging in the shell, launch it with the `-d` option. [source,bash] ---- @@ -380,13 +378,13 @@ $ ./bin/hbase shell -d ==== count Count command returns the number of rows in a table. -It's quite fast when configured with the right CACHE +It's quite fast when configured with the right CACHE [source] ---- hbase> count '', CACHE => 1000 ----- +---- The above count fetches 1000 rows at a time. Set CACHE lower if your rows are big. -Default is to fetch one row at a time. +Default is to fetch one row at a time. diff --git a/src/main/asciidoc/_chapters/thrift_filter_language.adoc b/src/main/asciidoc/_chapters/thrift_filter_language.adoc index 46f816a63a9..744cec672d6 100644 --- a/src/main/asciidoc/_chapters/thrift_filter_language.adoc +++ b/src/main/asciidoc/_chapters/thrift_filter_language.adoc @@ -31,18 +31,18 @@ Apache link:http://thrift.apache.org/[Thrift] is a cross-platform, cross-language development framework. HBase includes a Thrift API and filter language. The Thrift API relies on client and server processes. -Documentation about the HBase Thrift API is located at link:http://wiki.apache.org/hadoop/Hbase/ThriftApi. +Documentation about the HBase Thrift API is located at http://wiki.apache.org/hadoop/Hbase/ThriftApi. -You can configure Thrift for secure authentication at the server and client side, by following the procedures in <> and <>. +You can configure Thrift for secure authentication at the server and client side, by following the procedures in <> and <>. The rest of this chapter discusses the filter language provided by the Thrift API. [[thrift.filter_language]] == Filter Language -Thrift Filter Language was introduced in APache HBase 0.92. +Thrift Filter Language was introduced in HBase 0.92. It allows you to perform server-side filtering when accessing HBase over Thrift or in the HBase shell. -You can find out more about shell integration by using the `scan help` command in the shell. +You can find out more about shell integration by using the `scan help` command in the shell. You specify a filter as a string, which is parsed on the server to construct the filter. @@ -69,7 +69,7 @@ Keep the following syntax guidelines in mind. .Binary Operators `AND`:: - If the `AND` operator is used, the key-vallue must satisfy both the filters. + If the `AND` operator is used, the key-value must satisfy both filters. `OR`:: If the `OR` operator is used, the key-value must satisfy at least one of the filters. @@ -79,7 +79,7 @@ Keep the following syntax guidelines in mind. For a particular row, if any of the key-values fail the filter condition, the entire row is skipped. `WHILE`:: - For a particular row, key-values will be emitted until a key-value is reached t hat fails the filter condition. + For a particular row, key-values will be emitted until a key-value is reached that fails the filter condition. .Compound Operators ==== @@ -142,8 +142,7 @@ A comparator can be any of the following: The comparison is case insensitive. Only EQUAL and NOT_EQUAL comparisons are valid with this comparator -The general syntax of a comparator is:` - ComparatorType:ComparatorValue` +The general syntax of a comparator is: `ComparatorType:ComparatorValue` The ComparatorType for the various comparators is as follows: @@ -155,7 +154,7 @@ The ComparatorType for the various comparators is as follows: The ComparatorValue can be any value. .Example ComparatorValues -. `binary:abc` will match everything that is lexicographically greater than "abc" +. `binary:abc` will match everything that is lexicographically greater than "abc" . `binaryprefix:abc` will match everything whose first 3 characters are lexicographically equal to "abc" . `regexstring:ab*yz` will match everything that doesn't begin with "ab" and ends with "yz" . `substring:abc123` will match everything that begins with the substring "abc123" @@ -165,48 +164,39 @@ The ComparatorValue can be any value. [source,php] ---- -', ); - $hbase->open(); - $client = $hbase->getClient(); - $result = $client->scannerOpenWithFilterString('table_name', "(PrefixFilter ('row2') AND (QualifierFilter (>=, 'binary:xyz'))) AND (TimestampsFilter ( 123, 456))"); - $to_print = $client->scannerGetList($result,1); - while ($to_print) { - print_r($to_print); - $to_print = $client->scannerGetList($result,1); - } - $client->scannerClose($result); +', ); + $hbase->open(); + $client = $hbase->getClient(); + $result = $client->scannerOpenWithFilterString('table_name', "(PrefixFilter ('row2') AND (QualifierFilter (>=, 'binary:xyz'))) AND (TimestampsFilter ( 123, 456))"); + $to_print = $client->scannerGetList($result,1); + while ($to_print) { + print_r($to_print); + $to_print = $client->scannerGetList($result,1); + } + $client->scannerClose($result); ?> ---- === Example Filter Strings -* `“PrefixFilter (‘Row’) AND PageFilter (1) AND FirstKeyOnlyFilter - ()”` will return all key-value pairs that match the following conditions: +* `"PrefixFilter ('Row') AND PageFilter (1) AND FirstKeyOnlyFilter ()"` will return all key-value pairs that match the following conditions: + -. The row containing the key-value should have prefix ``Row'' -. The key-value must be located in the first row of the table -. The key-value pair must be the first key-value in the row - - - -* `“(RowFilter (=, ‘binary:Row 1’) AND TimeStampsFilter (74689, - 89734)) OR ColumnRangeFilter (‘abc’, true, ‘xyz’, - false))”` will return all key-value pairs that match both the following conditions: +. The row containing the key-value should have prefix _Row_ +. The key-value must be located in the first row of the table +. The key-value pair must be the first key-value in the row + -* The key-value is in a row having row key ``Row 1'' -* The key-value must have a timestamp of either 74689 or 89734. -* Or it must match the following condition: +* `"(RowFilter (=, 'binary:Row 1') AND TimeStampsFilter (74689, 89734)) OR ColumnRangeFilter ('abc', true, 'xyz', false))"` will return all key-value pairs that match both the following conditions: +** The key-value is in a row having row key _Row 1_ +** The key-value must have a timestamp of either 74689 or 89734. +** Or it must match the following condition: +*** The key-value pair must be in a column that is lexicographically >= abc and < xyz  + -* The key-value pair must be in a column that is lexicographically >= abc and < xyz  - - - - -* `“SKIP ValueFilter (0)”` will skip the entire row if any of the values in the row is not 0 +* `"SKIP ValueFilter (0)"` will skip the entire row if any of the values in the row is not 0 [[individualfiltersyntax]] === Individual Filter Syntax @@ -279,7 +269,7 @@ SingleColumnValueFilter:: This filter takes a column family, a qualifier, a compare operator and a comparator. If the specified column is not found – all the columns of that row will be emitted. If the column is found and the comparison with the comparator returns true, all the columns of the row will be emitted. - If the condition fails, the row will not be emitted. + If the condition fails, the row will not be emitted. SingleColumnValueExcludeFilter:: This filter takes the same arguments and behaves same as SingleColumnValueFilter – however, if the column is found and the condition passes, all the columns of the row will be emitted except for the tested column value. diff --git a/src/main/asciidoc/_chapters/troubleshooting.adoc b/src/main/asciidoc/_chapters/troubleshooting.adoc index afe24fe0be2..6d35f1d6afa 100644 --- a/src/main/asciidoc/_chapters/troubleshooting.adoc +++ b/src/main/asciidoc/_chapters/troubleshooting.adoc @@ -32,36 +32,35 @@ Always start with the master log (TODO: Which lines?). Normally it's just printing the same lines over and over again. If not, then there's an issue. -Google or link:http://search-hadoop.com[search-hadoop.com] should return some hits for those exceptions you're seeing. +Google or link:http://search-hadoop.com[search-hadoop.com] should return some hits for those exceptions you're seeing. An error rarely comes alone in Apache HBase, usually when something gets screwed up what will follow may be hundreds of exceptions and stack traces coming from all over the place. -The best way to approach this type of problem is to walk the log up to where it all began, for example one trick with RegionServers is that they will print some metrics when aborting so grepping for _Dump_ should get you around the start of the problem. +The best way to approach this type of problem is to walk the log up to where it all began, for example one trick with RegionServers is that they will print some metrics when aborting so grepping for _Dump_ should get you around the start of the problem. -RegionServer suicides are ``normal'', as this is what they do when something goes wrong. -For example, if ulimit and max transfer threads (the two most important initial settings, see <> and <>) aren't changed, it will make it impossible at some point for DataNodes to create new threads that from the HBase point of view is seen as if HDFS was gone. +RegionServer suicides are 'normal', as this is what they do when something goes wrong. +For example, if ulimit and max transfer threads (the two most important initial settings, see <> and <>) aren't changed, it will make it impossible at some point for DataNodes to create new threads that from the HBase point of view is seen as if HDFS was gone. Think about what would happen if your MySQL database was suddenly unable to access files on your local file system, well it's the same with HBase and HDFS. Another very common reason to see RegionServers committing seppuku is when they enter prolonged garbage collection pauses that last longer than the default ZooKeeper session timeout. -For more information on GC pauses, see the link:http://www.cloudera.com/blog/2011/02/avoiding-full-gcs-in-hbase-with-memstore-local-allocation-buffers-part-1/[3 - part blog post] by Todd Lipcon and <> above. +For more information on GC pauses, see the link:http://www.cloudera.com/blog/2011/02/avoiding-full-gcs-in-hbase-with-memstore-local-allocation-buffers-part-1/[3 part blog post] by Todd Lipcon and <> above. [[trouble.log]] == Logs -The key process logs are as follows... (replace with the user that started the service, and for the machine name) +The key process logs are as follows... (replace with the user that started the service, and for the machine name) -NameNode: _$HADOOP_HOME/logs/hadoop--namenode-.log_ +NameNode: _$HADOOP_HOME/logs/hadoop--namenode-.log_ -DataNode: _$HADOOP_HOME/logs/hadoop--datanode-.log_ +DataNode: _$HADOOP_HOME/logs/hadoop--datanode-.log_ -JobTracker: _$HADOOP_HOME/logs/hadoop--jobtracker-.log_ +JobTracker: _$HADOOP_HOME/logs/hadoop--jobtracker-.log_ -TaskTracker: _$HADOOP_HOME/logs/hadoop--tasktracker-.log_ +TaskTracker: _$HADOOP_HOME/logs/hadoop--tasktracker-.log_ -HMaster: _$HBASE_HOME/logs/hbase--master-.log_ +HMaster: _$HBASE_HOME/logs/hbase--master-.log_ -RegionServer: _$HBASE_HOME/logs/hbase--regionserver-.log_ +RegionServer: _$HBASE_HOME/logs/hbase--regionserver-.log_ -ZooKeeper: _TODO_ +ZooKeeper: _TODO_ [[trouble.log.locations]] === Log Locations @@ -75,14 +74,14 @@ Production deployments need to run on a cluster. The NameNode log is on the NameNode server. The HBase Master is typically run on the NameNode server, and well as ZooKeeper. -For smaller clusters the JobTracker is typically run on the NameNode server as well. +For smaller clusters the JobTracker/ResourceManager is typically run on the NameNode server as well. [[trouble.log.locations.datanode]] ==== DataNode Each DataNode server will have a DataNode log for HDFS, as well as a RegionServer log for HBase. -Additionally, each DataNode server will also have a TaskTracker log for MapReduce task execution. +Additionally, each DataNode server will also have a TaskTracker/NodeManager log for MapReduce task execution. [[trouble.log.levels]] === Log Levels @@ -97,12 +96,12 @@ To enable RPC-level logging, browse to the RegionServer UI and click on _Log Lev Set the log level to `DEBUG` for the package `org.apache.hadoop.ipc` (Thats right, for `hadoop.ipc`, NOT, `hbase.ipc`). Then tail the RegionServers log. Analyze. -To disable, set the logging level back to `INFO` level. +To disable, set the logging level back to `INFO` level. [[trouble.log.gc]] === JVM Garbage Collection Logs -HBase is memory intensive, and using the default GC you can see long pauses in all threads including the _Juliet Pause_ aka "GC of Death". To help debug this or confirm this is happening GC logging can be turned on in the Java virtual machine. +HBase is memory intensive, and using the default GC you can see long pauses in all threads including the _Juliet Pause_ aka "GC of Death". To help debug this or confirm this is happening GC logging can be turned on in the Java virtual machine. To enable, in _hbase-env.sh_, uncomment one of the below lines : @@ -132,7 +131,7 @@ At this point you should see logs like so: ---- In this section, the first line indicates a 0.0007360 second pause for the CMS to initially mark. -This pauses the entire VM, all threads for that period of time. +This pauses the entire VM, all threads for that period of time. The third line indicates a "minor GC", which pauses the VM for 0.0101110 seconds - aka 10 milliseconds. It has reduced the "ParNew" from about 5.5m to 576k. @@ -158,16 +157,16 @@ Later on in this cycle we see: ---- The first line indicates that the CMS concurrent mark (finding garbage) has taken 2.4 seconds. -But this is a _concurrent_ 2.4 seconds, Java has not been paused at any point in time. +But this is a _concurrent_ 2.4 seconds, Java has not been paused at any point in time. -There are a few more minor GCs, then there is a pause at the 2nd last line: +There are a few more minor GCs, then there is a pause at the 2nd last line: [source] ---- 64901.616: [GC[YG occupancy: 645 K (5568 K)]64901.616: [Rescan (parallel) , 0.0020210 secs]64901.618: [weak refs processing, 0.0027950 secs] [1 CMS-remark: 2866753K(3055704K)] 2867399K(3061272K), 0.0049380 secs] [Times: user=0.00 sys=0.01, real=0.01 secs] ----- +---- -The pause here is 0.0049380 seconds (aka 4.9 milliseconds) to 'remark' the heap. +The pause here is 0.0049380 seconds (aka 4.9 milliseconds) to 'remark' the heap. At this point the sweep starts, and you can watch the heap size go down: @@ -180,20 +179,20 @@ At this point the sweep starts, and you can watch the heap size go down: 64904.953: [CMS-concurrent-sweep: 2.030/3.332 secs] [Times: user=9.57 sys=0.26, real=3.33 secs] ---- -At this point, the CMS sweep took 3.332 seconds, and heap went from about ~ 2.8 GB to 1.3 GB (approximate). +At this point, the CMS sweep took 3.332 seconds, and heap went from about ~ 2.8 GB to 1.3 GB (approximate). The key points here is to keep all these pauses low. -CMS pauses are always low, but if your ParNew starts growing, you can see minor GC pauses approach 100ms, exceed 100ms and hit as high at 400ms. +CMS pauses are always low, but if your ParNew starts growing, you can see minor GC pauses approach 100ms, exceed 100ms and hit as high at 400ms. This can be due to the size of the ParNew, which should be relatively small. -If your ParNew is very large after running HBase for a while, in one example a ParNew was about 150MB, then you might have to constrain the size of ParNew (The larger it is, the longer the collections take but if its too small, objects are promoted to old gen too quickly). In the below we constrain new gen size to 64m. +If your ParNew is very large after running HBase for a while, in one example a ParNew was about 150MB, then you might have to constrain the size of ParNew (The larger it is, the longer the collections take but if its too small, objects are promoted to old gen too quickly). In the below we constrain new gen size to 64m. -Add the below line in _hbase-env.sh_: +Add the below line in _hbase-env.sh_: [source,bourne] ---- export SERVER_GC_OPTS="$SERVER_GC_OPTS -XX:NewSize=64m -XX:MaxNewSize=64m" ----- +---- Similarly, to enable GC logging for client processes, uncomment one of the below lines in _hbase-env.sh_: @@ -212,8 +211,7 @@ Similarly, to enable GC logging for client processes, uncomment one of the below # If is not replaced, the log file(.gc) would be generated in the HBASE_LOG_DIR . ---- -For more information on GC pauses, see the link:http://www.cloudera.com/blog/2011/02/avoiding-full-gcs-in-hbase-with-memstore-local-allocation-buffers-part-1/[3 - part blog post] by Todd Lipcon and <> above. +For more information on GC pauses, see the link:http://www.cloudera.com/blog/2011/02/avoiding-full-gcs-in-hbase-with-memstore-local-allocation-buffers-part-1/[3 part blog post] by Todd Lipcon and <> above. [[trouble.resources]] == Resources @@ -222,19 +220,18 @@ For more information on GC pauses, see the link:http://www.cloudera.com/blog/201 === search-hadoop.com link:http://search-hadoop.com[search-hadoop.com] indexes all the mailing lists and is great for historical searches. -Search here first when you have an issue as its more than likely someone has already had your problem. +Search here first when you have an issue as its more than likely someone has already had your problem. [[trouble.resources.lists]] === Mailing Lists -Ask a question on the link:http://hbase.apache.org/mail-lists.html[Apache - HBase mailing lists]. +Ask a question on the link:http://hbase.apache.org/mail-lists.html[Apache HBase mailing lists]. The 'dev' mailing list is aimed at the community of developers actually building Apache HBase and for features currently under development, and 'user' is generally used for questions on released versions of Apache HBase. Before going to the mailing list, make sure your question has not already been answered by searching the mailing list archives first. -Use <>. +Use <>. Take some time crafting your question. See link:http://www.mikeash.com/getting_answers.html[Getting Answers] for ideas on crafting good questions. -A quality question that includes all context and exhibits evidence the author has tried to find answers in the manual and out on lists is more likely to get a prompt response. +A quality question that includes all context and exhibits evidence the author has tried to find answers in the manual and out on lists is more likely to get a prompt response. [[trouble.resources.irc]] === IRC @@ -244,7 +241,7 @@ A quality question that includes all context and exhibits evidence the author ha [[trouble.resources.jira]] === JIRA -link:https://issues.apache.org/jira/browse/HBASE[JIRA] is also really helpful when looking for Hadoop/HBase-specific issues. +link:https://issues.apache.org/jira/browse/HBASE[JIRA] is also really helpful when looking for Hadoop/HBase-specific issues. [[trouble.tools]] == Tools @@ -256,54 +253,54 @@ link:https://issues.apache.org/jira/browse/HBASE[JIRA] is also really helpful wh ==== Master Web Interface The Master starts a web-interface on port 16010 by default. -(Up to and including 0.98 this was port 60010) +(Up to and including 0.98 this was port 60010) -The Master web UI lists created tables and their definition (e.g., ColumnFamilies, blocksize, etc.). Additionally, the available RegionServers in the cluster are listed along with selected high-level metrics (requests, number of regions, usedHeap, maxHeap). The Master web UI allows navigation to each RegionServer's web UI. +The Master web UI lists created tables and their definition (e.g., ColumnFamilies, blocksize, etc.). Additionally, the available RegionServers in the cluster are listed along with selected high-level metrics (requests, number of regions, usedHeap, maxHeap). The Master web UI allows navigation to each RegionServer's web UI. [[trouble.tools.builtin.webregion]] ==== RegionServer Web Interface RegionServers starts a web-interface on port 16030 by default. -(Up to an including 0.98 this was port 60030) +(Up to an including 0.98 this was port 60030) -The RegionServer web UI lists online regions and their start/end keys, as well as point-in-time RegionServer metrics (requests, regions, storeFileIndexSize, compactionQueueSize, etc.). +The RegionServer web UI lists online regions and their start/end keys, as well as point-in-time RegionServer metrics (requests, regions, storeFileIndexSize, compactionQueueSize, etc.). -See <> for more information in metric definitions. +See <> for more information in metric definitions. [[trouble.tools.builtin.zkcli]] ==== zkcli `zkcli` is a very useful tool for investigating ZooKeeper-related issues. -To invoke: +To invoke: [source,bourne] ---- ./hbase zkcli -server host:port ----- +---- The commands (and arguments) are: [source] ---- - connect host:port - get path [watch] - ls path [watch] - set path data [version] - delquota [-n|-b] path - quit - printwatches on|off - create [-s] [-e] path data acl - stat path [watch] - close - ls2 path [watch] - history - listquota path - setAcl path acl - getAcl path - sync path - redo cmdno - addauth scheme auth - delete path [version] - setquota -n|-b val path + connect host:port + get path [watch] + ls path [watch] + set path data [version] + delquota [-n|-b] path + quit + printwatches on|off + create [-s] [-e] path data acl + stat path [watch] + close + ls2 path [watch] + history + listquota path + setAcl path acl + getAcl path + sync path + redo cmdno + addauth scheme auth + delete path [version] + setquota -n|-b val path ---- [[trouble.tools.external]] @@ -313,13 +310,13 @@ The commands (and arguments) are: ==== tail `tail` is the command line tool that lets you look at the end of a file. -Add the ``-f'' option and it will refresh when new data is available. -It's useful when you are wondering what's happening, for example, when a cluster is taking a long time to shutdown or startup as you can just fire a new terminal and tail the master log (and maybe a few RegionServers). +Add the `-f` option and it will refresh when new data is available. +It's useful when you are wondering what's happening, for example, when a cluster is taking a long time to shutdown or startup as you can just fire a new terminal and tail the master log (and maybe a few RegionServers). [[trouble.tools.top]] ==== top -`top` is probably one of the most important tool when first trying to see what's running on a machine and how the resources are consumed. +`top` is probably one of the most important tools when first trying to see what's running on a machine and how the resources are consumed. Here's an example from production system: [source] @@ -338,15 +335,15 @@ Swap: 16008732k total, 14348k used, 15994384k free, 11106908k cached ---- Here we can see that the system load average during the last five minutes is 3.75, which very roughly means that on average 3.75 threads were waiting for CPU time during these 5 minutes. -In general, the ``perfect'' utilization equals to the number of cores, under that number the machine is under utilized and over that the machine is over utilized. -This is an important concept, see this article to understand it more: link:http://www.linuxjournal.com/article/9001. +In general, the _perfect_ utilization equals to the number of cores, under that number the machine is under utilized and over that the machine is over utilized. +This is an important concept, see this article to understand it more: http://www.linuxjournal.com/article/9001. Apart from load, we can see that the system is using almost all its available RAM but most of it is used for the OS cache (which is good). The swap only has a few KBs in it and this is wanted, high numbers would indicate swapping activity which is the nemesis of performance of Java systems. -Another way to detect swapping is when the load average goes through the roof (although this could also be caused by things like a dying disk, among others). +Another way to detect swapping is when the load average goes through the roof (although this could also be caused by things like a dying disk, among others). The list of processes isn't super useful by default, all we know is that 3 java processes are using about 111% of the CPUs. -To know which is which, simply type ``c'' and each line will be expanded. -Typing ``1'' will give you the detail of how each CPU is used instead of the average for all of them like shown here. +To know which is which, simply type `c` and each line will be expanded. +Typing `1` will give you the detail of how each CPU is used instead of the average for all of them like shown here. [[trouble.tools.jps]] ==== jps @@ -366,7 +363,7 @@ hadoop@sv4borg12:~$ jps 18776 jmx ---- -In order, we see a: +In order, we see a: * Hadoop TaskTracker, manages the local Childs * HBase RegionServer, serves regions @@ -391,7 +388,7 @@ hadoop 17789 155 35.2 9067824 8604364 ? S<l Mar04 9855:48 /usr/java/j `jstack` is one of the most important tools when trying to figure out what a java process is doing apart from looking at the logs. It has to be used in conjunction with jps in order to give it a process id. -It shows a list of threads, each one has a name, and they appear in the order that they were created (so the top ones are the most recent threads). Here are a few example: +It shows a list of threads, each one has a name, and they appear in the order that they were created (so the top ones are the most recent threads). Here are a few example: The main thread of a RegionServer waiting for something to do from the master: @@ -452,12 +449,12 @@ A handler thread that's waiting for stuff to do (like put, delete, scan, etc): ---- "IPC Server handler 16 on 60020" daemon prio=10 tid=0x00007f16b011d800 nid=0x4a5e waiting on condition [0x00007f16afefd000..0x00007f16afefd9f0] java.lang.Thread.State: WAITING (parking) - at sun.misc.Unsafe.park(Native Method) - - parking to wait for <0x00007f16cd3f8dd8> (a java.util.concurrent.locks.AbstractQueuedSynchronizer$ConditionObject) - at java.util.concurrent.locks.LockSupport.park(LockSupport.java:158) - at java.util.concurrent.locks.AbstractQueuedSynchronizer$ConditionObject.await(AbstractQueuedSynchronizer.java:1925) - at java.util.concurrent.LinkedBlockingQueue.take(LinkedBlockingQueue.java:358) - at org.apache.hadoop.hbase.ipc.HBaseServer$Handler.run(HBaseServer.java:1013) + at sun.misc.Unsafe.park(Native Method) + - parking to wait for <0x00007f16cd3f8dd8> (a java.util.concurrent.locks.AbstractQueuedSynchronizer$ConditionObject) + at java.util.concurrent.locks.LockSupport.park(LockSupport.java:158) + at java.util.concurrent.locks.AbstractQueuedSynchronizer$ConditionObject.await(AbstractQueuedSynchronizer.java:1925) + at java.util.concurrent.LinkedBlockingQueue.take(LinkedBlockingQueue.java:358) + at org.apache.hadoop.hbase.ipc.HBaseServer$Handler.run(HBaseServer.java:1013) ---- And one that's busy doing an increment of a counter (it's in the phase where it's trying to create a scanner in order to read the last value): @@ -466,21 +463,21 @@ And one that's busy doing an increment of a counter (it's in the phase where it' ---- "IPC Server handler 66 on 60020" daemon prio=10 tid=0x00007f16b006e800 nid=0x4a90 runnable [0x00007f16acb77000..0x00007f16acb77cf0] java.lang.Thread.State: RUNNABLE - at org.apache.hadoop.hbase.regionserver.KeyValueHeap.(KeyValueHeap.java:56) - at org.apache.hadoop.hbase.regionserver.StoreScanner.(StoreScanner.java:79) - at org.apache.hadoop.hbase.regionserver.Store.getScanner(Store.java:1202) - at org.apache.hadoop.hbase.regionserver.HRegion$RegionScanner.(HRegion.java:2209) - at org.apache.hadoop.hbase.regionserver.HRegion.instantiateInternalScanner(HRegion.java:1063) - at org.apache.hadoop.hbase.regionserver.HRegion.getScanner(HRegion.java:1055) - at org.apache.hadoop.hbase.regionserver.HRegion.getScanner(HRegion.java:1039) - at org.apache.hadoop.hbase.regionserver.HRegion.getLastIncrement(HRegion.java:2875) - at org.apache.hadoop.hbase.regionserver.HRegion.incrementColumnValue(HRegion.java:2978) - at org.apache.hadoop.hbase.regionserver.HRegionServer.incrementColumnValue(HRegionServer.java:2433) - at sun.reflect.GeneratedMethodAccessor20.invoke(Unknown Source) - at sun.reflect.DelegatingMethodAccessorImpl.invoke(DelegatingMethodAccessorImpl.java:25) - at java.lang.reflect.Method.invoke(Method.java:597) - at org.apache.hadoop.hbase.ipc.HBaseRPC$Server.call(HBaseRPC.java:560) - at org.apache.hadoop.hbase.ipc.HBaseServer$Handler.run(HBaseServer.java:1027) + at org.apache.hadoop.hbase.regionserver.KeyValueHeap.(KeyValueHeap.java:56) + at org.apache.hadoop.hbase.regionserver.StoreScanner.(StoreScanner.java:79) + at org.apache.hadoop.hbase.regionserver.Store.getScanner(Store.java:1202) + at org.apache.hadoop.hbase.regionserver.HRegion$RegionScanner.(HRegion.java:2209) + at org.apache.hadoop.hbase.regionserver.HRegion.instantiateInternalScanner(HRegion.java:1063) + at org.apache.hadoop.hbase.regionserver.HRegion.getScanner(HRegion.java:1055) + at org.apache.hadoop.hbase.regionserver.HRegion.getScanner(HRegion.java:1039) + at org.apache.hadoop.hbase.regionserver.HRegion.getLastIncrement(HRegion.java:2875) + at org.apache.hadoop.hbase.regionserver.HRegion.incrementColumnValue(HRegion.java:2978) + at org.apache.hadoop.hbase.regionserver.HRegionServer.incrementColumnValue(HRegionServer.java:2433) + at sun.reflect.GeneratedMethodAccessor20.invoke(Unknown Source) + at sun.reflect.DelegatingMethodAccessorImpl.invoke(DelegatingMethodAccessorImpl.java:25) + at java.lang.reflect.Method.invoke(Method.java:597) + at org.apache.hadoop.hbase.ipc.HBaseRPC$Server.call(HBaseRPC.java:560) + at org.apache.hadoop.hbase.ipc.HBaseServer$Handler.run(HBaseServer.java:1027) ---- A thread that receives data from HDFS: @@ -489,26 +486,26 @@ A thread that receives data from HDFS: ---- "IPC Client (47) connection to sv4borg9/10.4.24.40:9000 from hadoop" daemon prio=10 tid=0x00007f16a02d0000 nid=0x4fa3 runnable [0x00007f16b517d000..0x00007f16b517dbf0] java.lang.Thread.State: RUNNABLE - at sun.nio.ch.EPollArrayWrapper.epollWait(Native Method) - at sun.nio.ch.EPollArrayWrapper.poll(EPollArrayWrapper.java:215) - at sun.nio.ch.EPollSelectorImpl.doSelect(EPollSelectorImpl.java:65) - at sun.nio.ch.SelectorImpl.lockAndDoSelect(SelectorImpl.java:69) - - locked <0x00007f17d5b68c00> (a sun.nio.ch.Util$1) - - locked <0x00007f17d5b68be8> (a java.util.Collections$UnmodifiableSet) - - locked <0x00007f1877959b50> (a sun.nio.ch.EPollSelectorImpl) - at sun.nio.ch.SelectorImpl.select(SelectorImpl.java:80) - at org.apache.hadoop.net.SocketIOWithTimeout$SelectorPool.select(SocketIOWithTimeout.java:332) - at org.apache.hadoop.net.SocketIOWithTimeout.doIO(SocketIOWithTimeout.java:157) - at org.apache.hadoop.net.SocketInputStream.read(SocketInputStream.java:155) - at org.apache.hadoop.net.SocketInputStream.read(SocketInputStream.java:128) - at java.io.FilterInputStream.read(FilterInputStream.java:116) - at org.apache.hadoop.ipc.Client$Connection$PingInputStream.read(Client.java:304) - at java.io.BufferedInputStream.fill(BufferedInputStream.java:218) - at java.io.BufferedInputStream.read(BufferedInputStream.java:237) - - locked <0x00007f1808539178> (a java.io.BufferedInputStream) - at java.io.DataInputStream.readInt(DataInputStream.java:370) - at org.apache.hadoop.ipc.Client$Connection.receiveResponse(Client.java:569) - at org.apache.hadoop.ipc.Client$Connection.run(Client.java:477) + at sun.nio.ch.EPollArrayWrapper.epollWait(Native Method) + at sun.nio.ch.EPollArrayWrapper.poll(EPollArrayWrapper.java:215) + at sun.nio.ch.EPollSelectorImpl.doSelect(EPollSelectorImpl.java:65) + at sun.nio.ch.SelectorImpl.lockAndDoSelect(SelectorImpl.java:69) + - locked <0x00007f17d5b68c00> (a sun.nio.ch.Util$1) + - locked <0x00007f17d5b68be8> (a java.util.Collections$UnmodifiableSet) + - locked <0x00007f1877959b50> (a sun.nio.ch.EPollSelectorImpl) + at sun.nio.ch.SelectorImpl.select(SelectorImpl.java:80) + at org.apache.hadoop.net.SocketIOWithTimeout$SelectorPool.select(SocketIOWithTimeout.java:332) + at org.apache.hadoop.net.SocketIOWithTimeout.doIO(SocketIOWithTimeout.java:157) + at org.apache.hadoop.net.SocketInputStream.read(SocketInputStream.java:155) + at org.apache.hadoop.net.SocketInputStream.read(SocketInputStream.java:128) + at java.io.FilterInputStream.read(FilterInputStream.java:116) + at org.apache.hadoop.ipc.Client$Connection$PingInputStream.read(Client.java:304) + at java.io.BufferedInputStream.fill(BufferedInputStream.java:218) + at java.io.BufferedInputStream.read(BufferedInputStream.java:237) + - locked <0x00007f1808539178> (a java.io.BufferedInputStream) + at java.io.DataInputStream.readInt(DataInputStream.java:370) + at org.apache.hadoop.ipc.Client$Connection.receiveResponse(Client.java:569) + at org.apache.hadoop.ipc.Client$Connection.run(Client.java:477) ---- And here is a master trying to recover a lease after a RegionServer died: @@ -518,84 +515,82 @@ And here is a master trying to recover a lease after a RegionServer died: "LeaseChecker" daemon prio=10 tid=0x00000000407ef800 nid=0x76cd waiting on condition [0x00007f6d0eae2000..0x00007f6d0eae2a70] -- java.lang.Thread.State: WAITING (on object monitor) - at java.lang.Object.wait(Native Method) - at java.lang.Object.wait(Object.java:485) - at org.apache.hadoop.ipc.Client.call(Client.java:726) - - locked <0x00007f6d1cd28f80> (a org.apache.hadoop.ipc.Client$Call) - at org.apache.hadoop.ipc.RPC$Invoker.invoke(RPC.java:220) - at $Proxy1.recoverBlock(Unknown Source) - at org.apache.hadoop.hdfs.DFSClient$DFSOutputStream.processDatanodeError(DFSClient.java:2636) - at org.apache.hadoop.hdfs.DFSClient$DFSOutputStream.(DFSClient.java:2832) - at org.apache.hadoop.hdfs.DFSClient.append(DFSClient.java:529) - at org.apache.hadoop.hdfs.DistributedFileSystem.append(DistributedFileSystem.java:186) - at org.apache.hadoop.fs.FileSystem.append(FileSystem.java:530) - at org.apache.hadoop.hbase.util.FSUtils.recoverFileLease(FSUtils.java:619) - at org.apache.hadoop.hbase.regionserver.wal.HLog.splitLog(HLog.java:1322) - at org.apache.hadoop.hbase.regionserver.wal.HLog.splitLog(HLog.java:1210) - at org.apache.hadoop.hbase.master.HMaster.splitLogAfterStartup(HMaster.java:648) - at org.apache.hadoop.hbase.master.HMaster.joinCluster(HMaster.java:572) - at org.apache.hadoop.hbase.master.HMaster.run(HMaster.java:503) + at java.lang.Object.wait(Native Method) + at java.lang.Object.wait(Object.java:485) + at org.apache.hadoop.ipc.Client.call(Client.java:726) + - locked <0x00007f6d1cd28f80> (a org.apache.hadoop.ipc.Client$Call) + at org.apache.hadoop.ipc.RPC$Invoker.invoke(RPC.java:220) + at $Proxy1.recoverBlock(Unknown Source) + at org.apache.hadoop.hdfs.DFSClient$DFSOutputStream.processDatanodeError(DFSClient.java:2636) + at org.apache.hadoop.hdfs.DFSClient$DFSOutputStream.(DFSClient.java:2832) + at org.apache.hadoop.hdfs.DFSClient.append(DFSClient.java:529) + at org.apache.hadoop.hdfs.DistributedFileSystem.append(DistributedFileSystem.java:186) + at org.apache.hadoop.fs.FileSystem.append(FileSystem.java:530) + at org.apache.hadoop.hbase.util.FSUtils.recoverFileLease(FSUtils.java:619) + at org.apache.hadoop.hbase.regionserver.wal.HLog.splitLog(HLog.java:1322) + at org.apache.hadoop.hbase.regionserver.wal.HLog.splitLog(HLog.java:1210) + at org.apache.hadoop.hbase.master.HMaster.splitLogAfterStartup(HMaster.java:648) + at org.apache.hadoop.hbase.master.HMaster.joinCluster(HMaster.java:572) + at org.apache.hadoop.hbase.master.HMaster.run(HMaster.java:503) ---- [[trouble.tools.opentsdb]] ==== OpenTSDB link:http://opentsdb.net[OpenTSDB] is an excellent alternative to Ganglia as it uses Apache HBase to store all the time series and doesn't have to downsample. -Monitoring your own HBase cluster that hosts OpenTSDB is a good exercise. +Monitoring your own HBase cluster that hosts OpenTSDB is a good exercise. -Here's an example of a cluster that's suffering from hundreds of compactions launched almost all around the same time, which severely affects the IO performance: (TODO: insert graph plotting compactionQueueSize) +Here's an example of a cluster that's suffering from hundreds of compactions launched almost all around the same time, which severely affects the IO performance: (TODO: insert graph plotting compactionQueueSize) It's a good practice to build dashboards with all the important graphs per machine and per cluster so that debugging issues can be done with a single quick look. For example, at StumbleUpon there's one dashboard per cluster with the most important metrics from both the OS and Apache HBase. -You can then go down at the machine level and get even more detailed metrics. +You can then go down at the machine level and get even more detailed metrics. [[trouble.tools.clustersshtop]] ==== clusterssh+top clusterssh+top, it's like a poor man's monitoring system and it can be quite useful when you have only a few machines as it's very easy to setup. Starting clusterssh will give you one terminal per machine and another terminal in which whatever you type will be retyped in every window. -This means that you can type ``top'' once and it will start it for all of your machines at the same time giving you full view of the current state of your cluster. -You can also tail all the logs at the same time, edit files, etc. +This means that you can type `top` once and it will start it for all of your machines at the same time giving you full view of the current state of your cluster. +You can also tail all the logs at the same time, edit files, etc. [[trouble.client]] == Client -For more information on the HBase client, see <>. +For more information on the HBase client, see <>. [[trouble.client.scantimeout]] === ScannerTimeoutException or UnknownScannerException This is thrown if the time between RPC calls from the client to RegionServer exceeds the scan timeout. For example, if `Scan.setCaching` is set to 500, then there will be an RPC call to fetch the next batch of rows every 500 `.next()` calls on the ResultScanner because data is being transferred in blocks of 500 rows to the client. -Reducing the setCaching value may be an option, but setting this value too low makes for inefficient processing on numbers of rows. +Reducing the setCaching value may be an option, but setting this value too low makes for inefficient processing on numbers of rows. -See <>. +See <>. === Performance Differences in Thrift and Java APIs -Poor performance, or even `ScannerTimeoutExceptions`, can occur if `Scan.setCaching` is too high, as discussed in <>. +Poor performance, or even `ScannerTimeoutExceptions`, can occur if `Scan.setCaching` is too high, as discussed in <>. If the Thrift client uses the wrong caching settings for a given workload, performance can suffer compared to the Java API. -To set caching for a given scan in the Thrift client, use the `scannerGetList(scannerId, - numRows)` method, where `numRows` is an integer representing the number of rows to cache. +To set caching for a given scan in the Thrift client, use the `scannerGetList(scannerId, numRows)` method, where `numRows` is an integer representing the number of rows to cache. In one case, it was found that reducing the cache for Thrift scans from 1000 to 100 increased performance to near parity with the Java API given the same queries. -See also Jesse Andersen's link:http://blog.cloudera.com/blog/2014/04/how-to-use-the-hbase-thrift-interface-part-3-using-scans/[blog post] about using Scans with Thrift. +See also Jesse Andersen's link:http://blog.cloudera.com/blog/2014/04/how-to-use-the-hbase-thrift-interface-part-3-using-scans/[blog post] about using Scans with Thrift. [[trouble.client.lease.exception]] -=== `LeaseException` when calling`Scanner.next` +=== `LeaseException` when calling `Scanner.next` -In some situations clients that fetch data from a RegionServer get a LeaseException instead of the usual <>. -Usually the source of the exception is `org.apache.hadoop.hbase.regionserver.Leases.removeLease(Leases.java:230)` (line number may vary). It tends to happen in the context of a slow/freezing RegionServer#next call. +In some situations clients that fetch data from a RegionServer get a LeaseException instead of the usual <>. +Usually the source of the exception is `org.apache.hadoop.hbase.regionserver.Leases.removeLease(Leases.java:230)` (line number may vary). It tends to happen in the context of a slow/freezing `RegionServer#next` call. It can be prevented by having `hbase.rpc.timeout` > `hbase.regionserver.lease.period`. -Harsh J investigated the issue as part of the mailing list thread link:http://mail-archives.apache.org/mod_mbox/hbase-user/201209.mbox/%3CCAOcnVr3R-LqtKhFsk8Bhrm-YW2i9O6J6Fhjz2h7q6_sxvwd2yw%40mail.gmail.com%3E[HBase, - mail # user - Lease does not exist exceptions] +Harsh J investigated the issue as part of the mailing list thread link:http://mail-archives.apache.org/mod_mbox/hbase-user/201209.mbox/%3CCAOcnVr3R-LqtKhFsk8Bhrm-YW2i9O6J6Fhjz2h7q6_sxvwd2yw%40mail.gmail.com%3E[HBase, mail # user - Lease does not exist exceptions] [[trouble.client.scarylogs]] -=== Shell or client application throws lots of scary exceptions during normaloperation +=== Shell or client application throws lots of scary exceptions during normal operation -Since 0.20.0 the default log level for `org.apache.hadoop.hbase.*`is DEBUG. +Since 0.20.0 the default log level for `org.apache.hadoop.hbase.*`is DEBUG. -On your clients, edit _$HBASE_HOME/conf/log4j.properties_ and change this: `log4j.logger.org.apache.hadoop.hbase=DEBUG` to this: `log4j.logger.org.apache.hadoop.hbase=INFO`, or even `log4j.logger.org.apache.hadoop.hbase=WARN`. +On your clients, edit _$HBASE_HOME/conf/log4j.properties_ and change this: `log4j.logger.org.apache.hadoop.hbase=DEBUG` to this: `log4j.logger.org.apache.hadoop.hbase=INFO`, or even `log4j.logger.org.apache.hadoop.hbase=WARN`. [[trouble.client.longpauseswithcompression]] === Long Client Pauses With Compression @@ -604,20 +599,19 @@ This is a fairly frequent question on the Apache HBase dist-list. The scenario is that a client is typically inserting a lot of data into a relatively un-optimized HBase cluster. Compression can exacerbate the pauses, although it is not the source of the problem. -See <> on the pattern for pre-creating regions and confirm that the table isn't starting with a single region. +See <> on the pattern for pre-creating regions and confirm that the table isn't starting with a single region. -See <> for cluster configuration, particularly `hbase.hstore.blockingStoreFiles`, `hbase.hregion.memstore.block.multiplier`, `MAX_FILESIZE` (region size), and `MEMSTORE_FLUSHSIZE.` +See <> for cluster configuration, particularly `hbase.hstore.blockingStoreFiles`, `hbase.hregion.memstore.block.multiplier`, `MAX_FILESIZE` (region size), and `MEMSTORE_FLUSHSIZE.` A slightly longer explanation of why pauses can happen is as follows: Puts are sometimes blocked on the MemStores which are blocked by the flusher thread which is blocked because there are too many files to compact because the compactor is given too many small files to compact and has to compact the same data repeatedly. This situation can occur even with minor compactions. Compounding this situation, Apache HBase doesn't compress data in memory. Thus, the 64MB that lives in the MemStore could become a 6MB file after compression - which results in a smaller StoreFile. -The upside is that more data is packed into the same region, but performance is achieved by being able to write larger files - which is why HBase waits until the flushize before writing a new StoreFile. +The upside is that more data is packed into the same region, but performance is achieved by being able to write larger files - which is why HBase waits until the flushsize before writing a new StoreFile. And smaller StoreFiles become targets for compaction. -Without compression the files are much bigger and don't need as much compaction, however this is at the expense of I/O. +Without compression the files are much bigger and don't need as much compaction, however this is at the expense of I/O. -For additional information, see this thread on link:http://search-hadoop.com/m/WUnLM6ojHm1/Long+client+pauses+with+compression&subj=Long+client+pauses+with+compression[Long - client pauses with compression]. +For additional information, see this thread on link:http://search-hadoop.com/m/WUnLM6ojHm1/Long+client+pauses+with+compression&subj=Long+client+pauses+with+compression[Long client pauses with compression]. [[trouble.client.security.rpc.krb]] === Secure Client Connect ([Caused by GSSException: No valid credentials provided...]) @@ -631,11 +625,11 @@ Secure Client Connect ([Caused by GSSException: No valid credentials provided This issue is caused by bugs in the MIT Kerberos replay_cache component, link:http://krbdev.mit.edu/rt/Ticket/Display.html?id=1201[#1201] and link:http://krbdev.mit.edu/rt/Ticket/Display.html?id=5924[#5924]. These bugs caused the old version of krb5-server to erroneously block subsequent requests sent from a Principal. -This caused krb5-server to block the connections sent from one Client (one HTable instance with multi-threading connection instances for each regionserver); Messages, such as `Request is a replay (34)`, are logged in the client log You can ignore the messages, because HTable will retry 5 * 10 (50) times for each failed connection by default. -HTable will throw IOException if any connection to the regionserver fails after the retries, so that the user client code for HTable instance can handle it further. +This caused krb5-server to block the connections sent from one Client (one HTable instance with multi-threading connection instances for each RegionServer); Messages, such as `Request is a replay (34)`, are logged in the client log You can ignore the messages, because HTable will retry 5 * 10 (50) times for each failed connection by default. +HTable will throw IOException if any connection to the RegionServer fails after the retries, so that the user client code for HTable instance can handle it further. Alternatively, update krb5-server to a version which solves these issues, such as krb5-server-1.10.3. -See JIRA link:https://issues.apache.org/jira/browse/HBASE-10379[HBASE-10379] for more details. +See JIRA link:https://issues.apache.org/jira/browse/HBASE-10379[HBASE-10379] for more details. [[trouble.client.zookeeper]] === ZooKeeper Client Connection Errors @@ -663,51 +657,46 @@ Errors like this... server localhost/127.0.0.1:2181 ---- -... are either due to ZooKeeper being down, or unreachable due to network issues. +...are either due to ZooKeeper being down, or unreachable due to network issues. -The utility <> may help investigate ZooKeeper issues. +The utility <> may help investigate ZooKeeper issues. [[trouble.client.oome.directmemory.leak]] -=== Client running out of memory though heap size seems to be stable (but theoff-heap/direct heap keeps growing) +=== Client running out of memory though heap size seems to be stable (but the off-heap/direct heap keeps growing) -You are likely running into the issue that is described and worked through in the mail thread link:http://search-hadoop.com/m/ubhrX8KvcH/Suspected+memory+leak&subj=Re+Suspected+memory+leak[HBase, - mail # user - Suspected memory leak] and continued over in link:http://search-hadoop.com/m/p2Agc1Zy7Va/MaxDirectMemorySize+Was%253A+Suspected+memory+leak&subj=Re+FeedbackRe+Suspected+memory+leak[HBase, - mail # dev - FeedbackRe: Suspected memory leak]. +You are likely running into the issue that is described and worked through in the mail thread link:http://search-hadoop.com/m/ubhrX8KvcH/Suspected+memory+leak&subj=Re+Suspected+memory+leak[HBase, mail # user - Suspected memory leak] and continued over in link:http://search-hadoop.com/m/p2Agc1Zy7Va/MaxDirectMemorySize+Was%253A+Suspected+memory+leak&subj=Re+FeedbackRe+Suspected+memory+leak[HBase, mail # dev - FeedbackRe: Suspected memory leak]. A workaround is passing your client-side JVM a reasonable value for `-XX:MaxDirectMemorySize`. -By default, the `MaxDirectMemorySize` is equal to your `-Xmx` max heapsize setting (if `-Xmx` is set). Try seting it to something smaller (for example, one user had success setting it to `1g` when they had a client-side heap of `12g`). If you set it too small, it will bring on `FullGCs` so keep it a bit hefty. -You want to make this setting client-side only especially if you are running the new experiemental server-side off-heap cache since this feature depends on being able to use big direct buffers (You may have to keep separate client-side and server-side config dirs). +By default, the `MaxDirectMemorySize` is equal to your `-Xmx` max heapsize setting (if `-Xmx` is set). Try setting it to something smaller (for example, one user had success setting it to `1g` when they had a client-side heap of `12g`). If you set it too small, it will bring on `FullGCs` so keep it a bit hefty. +You want to make this setting client-side only especially if you are running the new experimental server-side off-heap cache since this feature depends on being able to use big direct buffers (You may have to keep separate client-side and server-side config dirs). [[trouble.client.slowdown.admin]] === Client Slowdown When Calling Admin Methods (flush, compact, etc.) This is a client issue fixed by link:https://issues.apache.org/jira/browse/HBASE-5073[HBASE-5073] in 0.90.6. -There was a ZooKeeper leak in the client and the client was getting pummeled by ZooKeeper events with each additional invocation of the admin API. +There was a ZooKeeper leak in the client and the client was getting pummeled by ZooKeeper events with each additional invocation of the admin API. [[trouble.client.security.rpc]] === Secure Client Cannot Connect ([Caused by GSSException: No valid credentials provided(Mechanism level: Failed to find any Kerberos tgt)]) -There can be several causes that produce this symptom. +There can be several causes that produce this symptom. First, check that you have a valid Kerberos ticket. One is required in order to set up communication with a secure Apache HBase cluster. -Examine the ticket currently in the credential cache, if any, by running the klist command line utility. -If no ticket is listed, you must obtain a ticket by running the kinit command with either a keytab specified, or by interactively entering a password for the desired principal. +Examine the ticket currently in the credential cache, if any, by running the `klist` command line utility. +If no ticket is listed, you must obtain a ticket by running the `kinit` command with either a keytab specified, or by interactively entering a password for the desired principal. -Then, consult the link:http://docs.oracle.com/javase/1.5.0/docs/guide/security/jgss/tutorials/Troubleshooting.html[Java - Security Guide troubleshooting section]. -The most common problem addressed there is resolved by setting javax.security.auth.useSubjectCredsOnly system property value to false. +Then, consult the link:http://docs.oracle.com/javase/1.5.0/docs/guide/security/jgss/tutorials/Troubleshooting.html[Java Security Guide troubleshooting section]. +The most common problem addressed there is resolved by setting `javax.security.auth.useSubjectCredsOnly` system property value to `false`. Because of a change in the format in which MIT Kerberos writes its credentials cache, there is a bug in the Oracle JDK 6 Update 26 and earlier that causes Java to be unable to read the Kerberos credentials cache created by versions of MIT Kerberos 1.8.1 or higher. -If you have this problematic combination of components in your environment, to work around this problem, first log in with kinit and then immediately refresh the credential cache with kinit -R. -The refresh will rewrite the credential cache without the problematic formatting. +If you have this problematic combination of components in your environment, to work around this problem, first log in with `kinit` and then immediately refresh the credential cache with `kinit -R`. +The refresh will rewrite the credential cache without the problematic formatting. -Finally, depending on your Kerberos configuration, you may need to install the link:http://docs.oracle.com/javase/1.4.2/docs/guide/security/jce/JCERefGuide.html[Java - Cryptography Extension], or JCE. -Insure the JCE jars are on the classpath on both server and client systems. +Finally, depending on your Kerberos configuration, you may need to install the link:http://docs.oracle.com/javase/1.4.2/docs/guide/security/jce/JCERefGuide.html[Java Cryptography Extension], or JCE. +Insure the JCE jars are on the classpath on both server and client systems. -You may also need to download the link:http://www.oracle.com/technetwork/java/javase/downloads/jce-6-download-429243.html[unlimited - strength JCE policy files]. -Uncompress and extract the downloaded file, and install the policy jars into /lib/security. +You may also need to download the link:http://www.oracle.com/technetwork/java/javase/downloads/jce-6-download-429243.html[unlimited strength JCE policy files]. +Uncompress and extract the downloaded file, and install the policy jars into _/lib/security_. [[trouble.mapreduce]] == MapReduce @@ -717,9 +706,8 @@ Uncompress and extract the downloaded file, and install the policy jars into >. +For more information on the NameNode, see <>. [[trouble.namenode.disk]] === HDFS Utilization of Tables and Regions To determine how much space HBase is using on HDFS use the `hadoop` shell commands from the NameNode. -For example... +For example... [source,bourne] ---- hadoop fs -dus /hbase/ ----- -...returns the summarized disk utilization for all HBase objects. +---- +...returns the summarized disk utilization for all HBase objects. [source,bourne] ---- hadoop fs -dus /hbase/myTable ----- -...returns the summarized disk utilization for the HBase table 'myTable'. +---- +...returns the summarized disk utilization for the HBase table 'myTable'. [source,bourne] ---- hadoop fs -du /hbase/myTable ----- -...returns a list of the regions under the HBase table 'myTable' and their disk utilization. +---- +...returns a list of the regions under the HBase table 'myTable' and their disk utilization. -For more information on HDFS shell commands, see the link:http://hadoop.apache.org/common/docs/current/file_system_shell.html[HDFS - FileSystem Shell documentation]. +For more information on HDFS shell commands, see the link:http://hadoop.apache.org/common/docs/current/file_system_shell.html[HDFS FileSystem Shell documentation]. [[trouble.namenode.hbase.objects]] === Browsing HDFS for HBase Objects @@ -809,36 +793,35 @@ For more information on HDFS shell commands, see the link:http://hadoop.apache.o Sometimes it will be necessary to explore the HBase objects that exist on HDFS. These objects could include the WALs (Write Ahead Logs), tables, regions, StoreFiles, etc. The easiest way to do this is with the NameNode web application that runs on port 50070. -The NameNode web application will provide links to the all the DataNodes in the cluster so that they can be browsed seamlessly. +The NameNode web application will provide links to the all the DataNodes in the cluster so that they can be browsed seamlessly. -The HDFS directory structure of HBase tables in the cluster is... +The HDFS directory structure of HBase tables in the cluster is... [source] ---- /hbase - /
(Tables in the cluster) - / (Regions for the table) - / (ColumnFamilies for the Region for the table) - / (StoreFiles for the ColumnFamily for the Regions for the table) ----- + /
(Tables in the cluster) + / (Regions for the table) + / (ColumnFamilies for the Region for the table) + / (StoreFiles for the ColumnFamily for the Regions for the table) +---- -The HDFS directory structure of HBase WAL is.. +The HDFS directory structure of HBase WAL is.. [source] ---- /hbase - /.logs - / (RegionServers) - / (WAL files for the RegionServer) ----- + /.logs + / (RegionServers) + / (WAL files for the RegionServer) +---- -See the link:http://hadoop.apache.org/common/docs/current/hdfs_user_guide.html[HDFS User - Guide] for other non-shell diagnostic utilities like `fsck`. +See the link:http://hadoop.apache.org/common/docs/current/hdfs_user_guide.html[HDFS User Guide] for other non-shell diagnostic utilities like `fsck`. [[trouble.namenode.0size.hlogs]] ==== Zero size WALs with data in them -Problem: when getting a listing of all the files in a region server's .logs directory, one file has a size of 0 but it contains data. +Problem: when getting a listing of all the files in a RegionServer's _.logs_ directory, one file has a size of 0 but it contains data. Answer: It's an HDFS quirk. A file that's currently being written to will appear to have a size of 0 but once it's closed it will show its true size @@ -848,7 +831,7 @@ A file that's currently being written to will appear to have a size of 0 but onc Two common use-cases for querying HDFS for HBase objects is research the degree of uncompaction of a table. If there are a large number of StoreFiles for each ColumnFamily it could indicate the need for a major compaction. -Additionally, after a major compaction if the resulting StoreFile is "small" it could indicate the need for a reduction of ColumnFamilies for the table. +Additionally, after a major compaction if the resulting StoreFile is "small" it could indicate the need for a reduction of ColumnFamilies for the table. [[trouble.network]] == Network @@ -856,25 +839,25 @@ Additionally, after a major compaction if the resulting StoreFile is "small" it [[trouble.network.spikes]] === Network Spikes -If you are seeing periodic network spikes you might want to check the `compactionQueues` to see if major compactions are happening. +If you are seeing periodic network spikes you might want to check the `compactionQueues` to see if major compactions are happening. -See <> for more information on managing compactions. +See <> for more information on managing compactions. [[trouble.network.loopback]] === Loopback IP HBase expects the loopback IP Address to be 127.0.0.1. -See the Getting Started section on <>. +See the Getting Started section on <>. [[trouble.network.ints]] === Network Interfaces -Are all the network interfaces functioning correctly? Are you sure? See the Troubleshooting Case Study in <>. +Are all the network interfaces functioning correctly? Are you sure? See the Troubleshooting Case Study in <>. [[trouble.rs]] == RegionServer -For more information on the RegionServers, see <>. +For more information on the RegionServers, see <>. [[trouble.rs.startup]] === Startup Errors @@ -882,9 +865,9 @@ For more information on the RegionServers, see < - zookeeper.session.timeout - 1200000 + zookeeper.session.timeout + 1200000 - hbase.zookeeper.property.tickTime - 6000 + hbase.zookeeper.property.tickTime + 6000 ---- -Be aware that setting a higher timeout means that the regions served by a failed RegionServer will take at least that amount of time to be transfered to another RegionServer. -For a production system serving live requests, we would instead recommend setting it lower than 1 minute and over-provision your cluster in order the lower the memory load on each machines (hence having less garbage to collect per machine). +Be aware that setting a higher timeout means that the regions served by a failed RegionServer will take at least that amount of time to be transferred to another RegionServer. +For a production system serving live requests, we would instead recommend setting it lower than 1 minute and over-provision your cluster in order the lower the memory load on each machines (hence having less garbage to collect per machine). -If this is happening during an upload which only happens once (like initially loading all your data into HBase), consider bulk loading. +If this is happening during an upload which only happens once (like initially loading all your data into HBase), consider bulk loading. -See <> for other general information about ZooKeeper troubleshooting. +See <> for other general information about ZooKeeper troubleshooting. [[trouble.rs.runtime.notservingregion]] ==== NotServingRegionException This exception is "normal" when found in the RegionServer logs at DEBUG level. -This exception is returned back to the client and then the client goes back to hbase:meta to find the new location of the moved region. +This exception is returned back to the client and then the client goes back to `hbase:meta` to find the new location of the moved region. However, if the NotServingRegionException is logged ERROR, then the client ran out of retries and something probably wrong. @@ -1054,22 +1036,21 @@ However, if the NotServingRegionException is logged ERROR, then the client ran o Fix your DNS. In versions of Apache HBase before 0.92.x, reverse DNS needs to give same answer as forward lookup. -See link:https://issues.apache.org/jira/browse/HBASE-3431[HBASE 3431 - RegionServer is not using the name given it by the master; double entry in master listing of servers] for gorey details. +See link:https://issues.apache.org/jira/browse/HBASE-3431[HBASE 3431 RegionServer is not using the name given it by the master; double entry in master listing of servers] for gorey details. [[brand.new.compressor]] ==== Logs flooded with '2011-01-10 12:40:48,407 INFO org.apache.hadoop.io.compress.CodecPool: Gotbrand-new compressor' messages We are not using the native versions of compression libraries. See link:https://issues.apache.org/jira/browse/HBASE-1900[HBASE-1900 Put back native support when hadoop 0.21 is released]. -Copy the native libs from hadoop under hbase lib dir or symlink them into place and the message should go away. +Copy the native libs from hadoop under HBase lib dir or symlink them into place and the message should go away. [[trouble.rs.runtime.client_went_away]] ==== Server handler X on 60020 caught: java.nio.channels.ClosedChannelException If you see this type of message it means that the region server was trying to read/send data from/to a client but it already went away. Typical causes for this are if the client was killed (you see a storm of messages like this when a MapReduce job is killed or fails) or if the client receives a SocketTimeoutException. -It's harmless, but you should consider digging in a bit more if you aren't doing something to trigger them. +It's harmless, but you should consider digging in a bit more if you aren't doing something to trigger them. === Snapshot Errors Due to Reverse DNS @@ -1079,7 +1060,7 @@ If you see errors like the following on your RegionServers, check your reverse D ---- -2013-05-01 00:04:56,356 DEBUG org.apache.hadoop.hbase.procedure.Subprocedure: Subprocedure 'backup1' +2013-05-01 00:04:56,356 DEBUG org.apache.hadoop.hbase.procedure.Subprocedure: Subprocedure 'backup1' coordinator notified of 'acquire', waiting on 'reached' or 'abort' from coordinator. ---- @@ -1088,7 +1069,7 @@ You can see a hostname mismatch by looking for the following type of message in ---- -2013-05-01 00:03:00,614 INFO org.apache.hadoop.hbase.regionserver.HRegionServer: Master passed us hostname +2013-05-01 00:03:00,614 INFO org.apache.hadoop.hbase.regionserver.HRegionServer: Master passed us hostname to use. Was=myhost-1234, Now=ip-10-55-88-99.ec2.internal ---- @@ -1100,20 +1081,20 @@ to use. Was=myhost-1234, Now=ip-10-55-88-99.ec2.internal [[trouble.master]] == Master -For more information on the Master, see <>. +For more information on the Master, see <>. [[trouble.master.startup]] === Startup Errors [[trouble.master.startup.migration]] -==== Master says that you need to run the hbase migrations script +==== Master says that you need to run the HBase migrations script -Upon running that, the hbase migrations script says no files in root directory. +Upon running that, the HBase migrations script says no files in root directory. -HBase expects the root directory to either not exist, or to have already been initialized by hbase running a previous time. +HBase expects the root directory to either not exist, or to have already been initialized by HBase running a previous time. If you create a new directory for HBase using Hadoop DFS, this error will occur. Make sure the HBase root directory does not currently exist or has been initialized by a previous run of HBase. -Sure fire solution is to just use Hadoop dfs to delete the HBase root and let HBase create and initialize the directory itself. +Sure fire solution is to just use Hadoop dfs to delete the HBase root and let HBase create and initialize the directory itself. [[trouble.master.startup.zk.buffer]] ==== Packet len6080218 is out of range! @@ -1138,21 +1119,21 @@ A ZooKeeper server wasn't able to start, throws that error. xyz is the name of your server. This is a name lookup problem. -HBase tries to start a ZooKeeper server on some machine but that machine isn't able to find itself in the `hbase.zookeeper.quorum` configuration. +HBase tries to start a ZooKeeper server on some machine but that machine isn't able to find itself in the `hbase.zookeeper.quorum` configuration. Use the hostname presented in the error message instead of the value you used. -If you have a DNS server, you can set `hbase.zookeeper.dns.interface` and `hbase.zookeeper.dns.nameserver` in _hbase-site.xml_ to make sure it resolves to the correct FQDN. +If you have a DNS server, you can set `hbase.zookeeper.dns.interface` and `hbase.zookeeper.dns.nameserver` in _hbase-site.xml_ to make sure it resolves to the correct FQDN. [[trouble.zookeeper.general]] === ZooKeeper, The Cluster Canary -ZooKeeper is the cluster's "canary in the mineshaft". It'll be the first to notice issues if any so making sure its happy is the short-cut to a humming cluster. +ZooKeeper is the cluster's "canary in the mineshaft". It'll be the first to notice issues if any so making sure its happy is the short-cut to a humming cluster. See the link:http://wiki.apache.org/hadoop/ZooKeeper/Troubleshooting[ZooKeeper Operating Environment Troubleshooting] page. It has suggestions and tools for checking disk and networking performance; i.e. -the operating environment your ZooKeeper and HBase are running in. +the operating environment your ZooKeeper and HBase are running in. -Additionally, the utility <> may help investigate ZooKeeper issues. +Additionally, the utility <> may help investigate ZooKeeper issues. [[trouble.ec2]] == Amazon EC2 @@ -1161,7 +1142,7 @@ Additionally, the utility <> for more). + with client version 4 ...+ ...are you trying to talk to an Hadoop 2.0.x from an HBase that has an Hadoop 1.0.x client? Use the HBase built against Hadoop 2.0 or rebuild your HBase passing the +-Dhadoop.profile=2.0+ attribute to Maven (See <> for more). == IPC Configuration Conflicts with Hadoop @@ -1280,48 +1261,49 @@ These changes were backported to HBase 0.98.x and apply to all newer versions. | ipc.client.kill.max | hbase.ipc.client.kill.max -| ipc.server.scan.vtime.weight -| hbase.ipc.server.scan.vtime.weight +| ipc.server.scan.vtime.weight +| hbase.ipc.server.scan.vtime.weight |=== == HBase and HDFS General configuration guidance for Apache HDFS is out of the scope of this guide. -Refer to the documentation available at link:http://hadoop.apache.org/ for extensive information about configuring HDFS. -This section deals with HDFS in terms of HBase. +Refer to the documentation available at http://hadoop.apache.org/ for extensive information about configuring HDFS. +This section deals with HDFS in terms of HBase. In most cases, HBase stores its data in Apache HDFS. This includes the HFiles containing the data, as well as the write-ahead logs (WALs) which store data before it is written to the HFiles and protect against RegionServer crashes. HDFS provides reliability and protection to data in HBase because it is distributed. To operate with the most efficiency, HBase needs data to be available locally. -Therefore, it is a good practice to run an HDFS datanode on each RegionServer. +Therefore, it is a good practice to run an HDFS DataNode on each RegionServer. -.Important Information and Guidelines for HBase and HDFSHBase is a client of HDFS.:: +.Important Information and Guidelines for HBase and HDFS + +HBase is a client of HDFS.:: HBase is an HDFS client, using the HDFS `DFSClient` class, and references to this class appear in HBase logs with other HDFS client log messages. Configuration is necessary in multiple places.:: Some HDFS configurations relating to HBase need to be done at the HDFS (server) side. - Others must be done within HBase (at the client side). Other settings need to be set at both the server and client side. + Others must be done within HBase (at the client side). Other settings need to be set at both the server and client side. Write errors which affect HBase may be logged in the HDFS logs rather than HBase logs.:: - When writing, HDFS pipelines communications from one datanode to another. - HBase communicates to both the HDFS namenode and datanode, using the HDFS client classes. - Communication problems between datanodes are logged in the HDFS logs, not the HBase logs. + When writing, HDFS pipelines communications from one DataNode to another. + HBase communicates to both the HDFS NameNode and DataNode, using the HDFS client classes. + Communication problems between DataNodes are logged in the HDFS logs, not the HBase logs. HBase communicates with HDFS using two different ports.:: - HBase communicates with datanodes using the `ipc.Client` interface and the `DataNode` class. + HBase communicates with DataNodes using the `ipc.Client` interface and the `DataNode` class. References to these will appear in HBase logs. Each of these communication channels use a different port (50010 and 50020 by default). The ports are configured in the HDFS configuration, via the `dfs.datanode.address` and `dfs.datanode.ipc.address` parameters. Errors may be logged in HBase, HDFS, or both.:: When troubleshooting HDFS issues in HBase, check logs in both places for errors. -HDFS takes a while to mark a node as dead. You can configure HDFS to avoid using stale - datanodes.:: +HDFS takes a while to mark a node as dead. You can configure HDFS to avoid using stale DataNodes.:: By default, HDFS does not mark a node as dead until it is unreachable for 630 seconds. - In Hadoop 1.1 and Hadoop 2.x, this can be alleviated by enabling checks for stale datanodes, though this check is disabled by default. + In Hadoop 1.1 and Hadoop 2.x, this can be alleviated by enabling checks for stale DataNodes, though this check is disabled by default. You can enable the check for reads and writes separately, via `dfs.namenode.avoid.read.stale.datanode` and `dfs.namenode.avoid.write.stale.datanode settings`. - A stale datanode is one that has not been reachable for `dfs.namenode.stale.datanode.interval` (default is 30 seconds). Stale datanodes are avoided, and marked as the last possible target for a read or write operation. + A stale DataNode is one that has not been reachable for `dfs.namenode.stale.datanode.interval` (default is 30 seconds). Stale datanodes are avoided, and marked as the last possible target for a read or write operation. For configuration details, see the HDFS documentation. Settings for HDFS retries and timeouts are important to HBase.:: @@ -1332,9 +1314,9 @@ Settings for HDFS retries and timeouts are important to HBase.:: Check the Hadoop documentation for the most current values and recommendations. .Connection Timeouts -Connection timeouts occur between the client (HBASE) and the HDFS datanode. +Connection timeouts occur between the client (HBASE) and the HDFS DataNode. They may occur when establishing a connection, attempting to read, or attempting to write. -The two settings below are used in combination, and affect connections between the DFSClient and the datanode, the ipc.cClient and the datanode, and communication between two datanodes. +The two settings below are used in combination, and affect connections between the DFSClient and the DataNode, the ipc.cClient and the DataNode, and communication between two DataNodes. `dfs.client.socket-timeout` (default: 60000):: The amount of time before a client connection times out when establishing a connection or reading. @@ -1351,7 +1333,7 @@ The following types of errors are often seen in the logs. continue java.net.SocketTimeoutException: 60000 millis timeout while waiting for channel to be ready for connect. ch : java.nio.channels.SocketChannel[connection-pending remote=/region-server-1:50010]`:: - All datanodes for a block are dead, and recovery is not possible. + All DataNodes for a block are dead, and recovery is not possible. Here is the sequence of events that leads to this error: `INFO org.apache.hadoop.HDFS.DFSClient: Exception in createBlockOutputStream @@ -1360,7 +1342,7 @@ The following types of errors are often seen in the logs. xxx:50010]`:: This type of error indicates a write issue. In this case, the master wants to split the log. - It does not have a local datanode so it tries to connect to a remote datanode, but the datanode is dead. + It does not have a local DataNodes so it tries to connect to a remote DataNode, but the DataNode is dead. [[trouble.tests]] == Running unit or integration tests @@ -1397,12 +1379,12 @@ at org.apache.hadoop.hbase.HBaseTestingUtility.startMiniCluster ---- \... then try issuing the command +umask 022+ before launching tests. -This is a workaround for link:https://issues.apache.org/jira/browse/HDFS-2556[HDFS-2556] +This is a workaround for link:https://issues.apache.org/jira/browse/HDFS-2556[HDFS-2556] [[trouble.casestudy]] == Case Studies -For Performance and Troubleshooting Case Studies, see <>. +For Performance and Troubleshooting Case Studies, see <>. [[trouble.crypto]] == Cryptographic Features @@ -1415,30 +1397,30 @@ This problem manifests as exceptions ultimately caused by: [source] ---- Caused by: sun.security.pkcs11.wrapper.PKCS11Exception: CKR_ARGUMENTS_BAD - at sun.security.pkcs11.wrapper.PKCS11.C_DecryptUpdate(Native Method) - at sun.security.pkcs11.P11Cipher.implDoFinal(P11Cipher.java:795) + at sun.security.pkcs11.wrapper.PKCS11.C_DecryptUpdate(Native Method) + at sun.security.pkcs11.P11Cipher.implDoFinal(P11Cipher.java:795) ---- This problem appears to affect some versions of OpenJDK 7 shipped by some Linux vendors. NSS is configured as the default provider. -If the host has an x86_64 architecture, depending on if the vendor packages contain the defect, the NSS provider will not function correctly. +If the host has an x86_64 architecture, depending on if the vendor packages contain the defect, the NSS provider will not function correctly. To work around this problem, find the JRE home directory and edit the file _lib/security/java.security_. -Edit the file to comment out the line: +Edit the file to comment out the line: [source] ---- security.provider.1=sun.security.pkcs11.SunPKCS11 ${java.home}/lib/security/nss.cfg ---- -Then renumber the remaining providers accordingly. +Then renumber the remaining providers accordingly. == Operating System Specific Issues === Page Allocation Failure NOTE: This issue is known to affect CentOS 6.2 and possibly CentOS 6.5. -It may also affect some versions of Red Hat Enterprise Linux, according to link:https://bugzilla.redhat.com/show_bug.cgi?id=770545. +It may also affect some versions of Red Hat Enterprise Linux, according to https://bugzilla.redhat.com/show_bug.cgi?id=770545. Some users have reported seeing the following error: @@ -1447,7 +1429,7 @@ kernel: java: page allocation failure. order:4, mode:0x20 ---- Raising the value of `min_free_kbytes` was reported to fix this problem. -This parameter is set to a percentage of the amount of RAM on your system, and is described in more detail at link:http://www.centos.org/docs/5/html/5.1/Deployment_Guide/s3-proc-sys-vm.html. +This parameter is set to a percentage of the amount of RAM on your system, and is described in more detail at http://www.centos.org/docs/5/html/5.1/Deployment_Guide/s3-proc-sys-vm.html. To find the current value on your system, run the following command: @@ -1460,7 +1442,7 @@ Try doubling, then quadrupling the value. Note that setting the value too low or too high could have detrimental effects on your system. Consult your operating system vendor for specific recommendations. -Use the following command to modify the value of `min_free_kbytes`, substituting [replaceable]__ with your intended value: +Use the following command to modify the value of `min_free_kbytes`, substituting __ with your intended value: ---- [user@host]# echo > /proc/sys/vm/min_free_kbytes @@ -1470,7 +1452,7 @@ Use the following command to modify the value of `min_free_kbytes`, substituting === NoSuchMethodError: java.util.concurrent.ConcurrentHashMap.keySet -If you see this in your logs: +If you see this in your logs: [source] ---- Caused by: java.lang.NoSuchMethodError: java.util.concurrent.ConcurrentHashMap.keySet()Ljava/util/concurrent/ConcurrentHashMap$KeySetView; @@ -1485,4 +1467,4 @@ Caused by: java.lang.NoSuchMethodError: java.util.concurrent.ConcurrentHashMap.k then check if you compiled with jdk8 and tried to run it on jdk7. If so, this won't work. Run on jdk8 or recompile with jdk7. -See link:https://issues.apache.org/jira/browse/HBASE-10607[HBASE-10607 [JDK8] NoSuchMethodError involving ConcurrentHashMap.keySet if running on JRE 7]. +See link:https://issues.apache.org/jira/browse/HBASE-10607[HBASE-10607 JDK8 NoSuchMethodError involving ConcurrentHashMap.keySet if running on JRE 7]. diff --git a/src/main/asciidoc/_chapters/upgrading.adoc b/src/main/asciidoc/_chapters/upgrading.adoc index e90b98a3ed4..ab3f1549967 100644 --- a/src/main/asciidoc/_chapters/upgrading.adoc +++ b/src/main/asciidoc/_chapters/upgrading.adoc @@ -27,9 +27,9 @@ :icons: font :experimental: -You cannot skip major versions upgrading. If you are upgrading from version 0.90.x to 0.94.x, you must first go from 0.90.x to 0.92.x and then go from 0.92.x to 0.94.x. +You cannot skip major versions when upgrading. If you are upgrading from version 0.90.x to 0.94.x, you must first go from 0.90.x to 0.92.x and then go from 0.92.x to 0.94.x. -Note:It may be possible to skip across versions -- for example go from 0.92.2 straight to 0.98.0 just following the 0.96.x upgrade instructions -- but we have not tried it so cannot say whether it works or not. +NOTE: It may be possible to skip across versions -- for example go from 0.92.2 straight to 0.98.0 just following the 0.96.x upgrade instructions -- but these scenarios are untested. Review <>, in particular <>. @@ -41,7 +41,7 @@ HBase has two versioning schemes, pre-1.0 and post-1.0. Both are detailed below. [[hbase.versioning.post10]] === Post 1.0 versions -Starting with 1.0.0 release, HBase uses link:http://semver.org/[Semantic Versioning] for its release versioning. In summary: +Starting with the 1.0.0 release, HBase uses link:http://semver.org/[Semantic Versioning] for its release versioning. In summary: .Given a version number MAJOR.MINOR.PATCH, increment the: * MAJOR version when you make incompatible API changes, @@ -90,7 +90,7 @@ In addition to the usual API versioning considerations HBase has other compatibi .Operational Compatibility * Metric changes * Behavioral changes of services -*Web page APIs +* Web page APIs .Summary * A patch upgrade is a drop-in replacement. Any change that is not Java binary compatible would not be allowed.footnote:[See http://docs.oracle.com/javase/specs/jls/se7/html/jls-13.html.] @@ -149,25 +149,25 @@ Our first "Development" Series was the 0.89 set that came out ahead of HBase 0.9 [[hbase.binary.compatibility]] .Binary Compatibility -When we say two HBase versions are compatible, we mean that the versions are wire and binary compatible. Compatible HBase versions means that clients can talk to compatible but differently versioned servers. It means too that you can just swap out the jars of one version and replace them with the jars of another, compatible version and all will just work. Unless otherwise specified, HBase point versions are (mostly) binary compatible. You can safely do rolling upgrades between binary compatible versions; i.e. across point versions: e.g. from 0.94.5 to 0.94.6. See link:[Does compatibility between versions also mean binary compatibility?] discussion on the hbaes dev mailing list. +When we say two HBase versions are compatible, we mean that the versions are wire and binary compatible. Compatible HBase versions means that clients can talk to compatible but differently versioned servers. It means too that you can just swap out the jars of one version and replace them with the jars of another, compatible version and all will just work. Unless otherwise specified, HBase point versions are (mostly) binary compatible. You can safely do rolling upgrades between binary compatible versions; i.e. across point versions: e.g. from 0.94.5 to 0.94.6. See link:[Does compatibility between versions also mean binary compatibility?] discussion on the HBase dev mailing list. [[hbase.rolling.upgrade]] === Rolling Upgrades -A rolling upgrade is the process by which you update the servers in your cluster a server at a time. You can rolling upgrade across HBase versions if they are binary or wire compatible. See <> for more on what this means. Coarsely, a rolling upgrade is a graceful stop each server, update the software, and then restart. You do this for each server in the cluster. Usually you upgrade the Master first and then the regionservers. See <> for tools that can help use the rolling upgrade process. +A rolling upgrade is the process by which you update the servers in your cluster a server at a time. You can rolling upgrade across HBase versions if they are binary or wire compatible. See <> for more on what this means. Coarsely, a rolling upgrade is a graceful stop each server, update the software, and then restart. You do this for each server in the cluster. Usually you upgrade the Master first and then the RegionServers. See <> for tools that can help use the rolling upgrade process. -For example, in the below, hbase was symlinked to the actual hbase install. On upgrade, before running a rolling restart over the cluser, we changed the symlink to point at the new HBase software version and then ran +For example, in the below, HBase was symlinked to the actual HBase install. On upgrade, before running a rolling restart over the cluser, we changed the symlink to point at the new HBase software version and then ran [source,bash] ---- $ HADOOP_HOME=~/hadoop-2.6.0-CRC-SNAPSHOT ~/hbase/bin/rolling-restart.sh --config ~/conf_hbase ---- -The rolling-restart script will first gracefully stop and restart the master, and then each of the regionservers in turn. Because the symlink was changed, on restart the server will come up using the new hbase version. Check logs for errors as the rolling upgrade proceeds. +The rolling-restart script will first gracefully stop and restart the master, and then each of the RegionServers in turn. Because the symlink was changed, on restart the server will come up using the new HBase version. Check logs for errors as the rolling upgrade proceeds. [[hbase.rolling.restart]] .Rolling Upgrade Between Versions that are Binary/Wire Compatible -Unless otherwise specified, HBase point versions are binary compatible. You can do a <> between hbase point versions. For example, you can go to 0.94.6 from 0.94.5 by doing a rolling upgrade across the cluster replacing the 0.94.5 binary with a 0.94.6 binary. +Unless otherwise specified, HBase point versions are binary compatible. You can do a <> between HBase point versions. For example, you can go to 0.94.6 from 0.94.5 by doing a rolling upgrade across the cluster replacing the 0.94.5 binary with a 0.94.6 binary. In the minor version-particular sections below, we call out where the versions are wire/protocol compatible and in this case, it is also possible to do a <>. For example, in <>, we state that it is possible to do a rolling upgrade between hbase-0.98.x and hbase-1.0.0. @@ -176,7 +176,7 @@ In the minor version-particular sections below, we call out where the versions a [[upgrade1.0]] === Upgrading from 0.98.x to 1.0.x -In this section we first note the significant changes that come in with 1.0.0 HBase and then we go over the upgrade process. Be sure to read the significant changes section with care so you avoid surprises. +In this section we first note the significant changes that come in with 1.0.0 HBase and then we go over the upgrade process. Be sure to read the significant changes section with care so you avoid surprises. ==== Changes of Note! @@ -188,30 +188,30 @@ See <>. [[default.ports.changed]] .HBase Default Ports Changed -The ports used by HBase changed. The used to be in the 600XX range. In hbase-1.0.0 they have been moved up out of the ephemeral port range and are 160XX instead (Master web UI was 60010 and is now 16010; the RegionServer web UI was 60030 and is now 16030, etc). If you want to keep the old port locations, copy the port setting configs from _hbase-default.xml_ into _hbase-site.xml_, change them back to the old values from hbase-0.98.x era, and ensure you've distributed your configurations before you restart. +The ports used by HBase changed. They used to be in the 600XX range. In HBase 1.0.0 they have been moved up out of the ephemeral port range and are 160XX instead (Master web UI was 60010 and is now 16010; the RegionServer web UI was 60030 and is now 16030, etc.). If you want to keep the old port locations, copy the port setting configs from _hbase-default.xml_ into _hbase-site.xml_, change them back to the old values from the HBase 0.98.x era, and ensure you've distributed your configurations before you restart. [[upgrade1.0.hbase.bucketcache.percentage.in.combinedcache]] .hbase.bucketcache.percentage.in.combinedcache configuration has been REMOVED -You may have made use of this configuration if you are using BucketCache. If NOT using BucketCache, this change does not effect you. Its removal means that your L1 LruBlockCache is now sized using `hfile.block.cache.size` -- i.e. the way you would size the onheap L1 LruBlockCache if you were NOT doing BucketCache -- and the BucketCache size is not whatever the setting for hbase.bucketcache.size is. You may need to adjust configs to get the LruBlockCache and BucketCache sizes set to what they were in 0.98.x and previous. If you did not set this config., its default value was 0.9. If you do nothing, your BucketCache will increase in size by 10%. Your L1 LruBlockCache will become hfile.block.cache.size times your java heap size (`hfile.block.cache.size` is a float between 0.0 and 1.0). To read more, see link:https://issues.apache.org/jira/browse/HBASE-11520[HBASE-11520 Simplify offheap cache config by removing the confusing "hbase.bucketcache.percentage.in.combinedcache"]. +You may have made use of this configuration if you are using BucketCache. If NOT using BucketCache, this change does not effect you. Its removal means that your L1 LruBlockCache is now sized using `hfile.block.cache.size` -- i.e. the way you would size the on-heap L1 LruBlockCache if you were NOT doing BucketCache -- and the BucketCache size is not whatever the setting for `hbase.bucketcache.size` is. You may need to adjust configs to get the LruBlockCache and BucketCache sizes set to what they were in 0.98.x and previous. If you did not set this config., its default value was 0.9. If you do nothing, your BucketCache will increase in size by 10%. Your L1 LruBlockCache will become `hfile.block.cache.size` times your java heap size (`hfile.block.cache.size` is a float between 0.0 and 1.0). To read more, see link:https://issues.apache.org/jira/browse/HBASE-11520[HBASE-11520 Simplify offheap cache config by removing the confusing "hbase.bucketcache.percentage.in.combinedcache"]. [[hbase-12068]] -.If you have your own customer filters.... +.If you have your own customer filters. See the release notes on the issue link:https://issues.apache.org/jira/browse/HBASE-12068[HBASE-12068 [Branch-1\] Avoid need to always do KeyValueUtil#ensureKeyValue for Filter transformCell]; be sure to follow the recommendations therein. [[dlr]] .Distributed Log Replay -<> is off by default in hbase-1.0. Enabling it can make a big difference improving HBase MTTR. Enable this feature if you are doing a clean stop/start when you are upgrading. You cannot rolling upgrade on to this feature (caveat if you are running on a version of hbase in excess of hbase-0.98.4 -- see link:https://issues.apache.org/jira/browse/HBASE-12577[HBASE-12577 Disable distributed log replay by default] for more). +<> is off by default in HBase 1.0.0. Enabling it can make a big difference improving HBase MTTR. Enable this feature if you are doing a clean stop/start when you are upgrading. You cannot rolling upgrade to this feature (caveat if you are running on a version of HBase in excess of HBase 0.98.4 -- see link:https://issues.apache.org/jira/browse/HBASE-12577[HBASE-12577 Disable distributed log replay by default] for more). [[upgrade1.0.rolling.upgrade]] ==== Rolling upgrade from 0.98.x to HBase 1.0.0 .From 0.96.x to 1.0.0 -NOTE: You cannot do a <> from 0.96.x to 1.0.0 without first doing a rolling upgrade to 0.98.x. See comment in link:https://issues.apache.org/jira/browse/HBASE-11164?focusedCommentId=14182330&page=com.atlassian.jira.plugin.system.issuetabpanels:comment-tabpanel#comment-14182330[HBASE-11164 Document and test rolling updates from 0.98 -> 1.0] for the why. Also because hbase-1.0.0 enables hfilev3 by default, link:https://issues.apache.org/jira/browse/HBASE-9801[HBASE-9801 Change the default HFile version to V3], and support for hfilev3 only arrives in 0.98, this is another reason you cannot rolling upgrade from hbase-0.96.x; if the rolling upgrade stalls, the 0.96.x servers cannot open files written by the servers running the newer hbase-1.0.0 hfilev3 writing servers. +NOTE: You cannot do a <> from 0.96.x to 1.0.0 without first doing a rolling upgrade to 0.98.x. See comment in link:https://issues.apache.org/jira/browse/HBASE-11164?focusedCommentId=14182330&page=com.atlassian.jira.plugin.system.issuetabpanels:comment-tabpanel#comment-14182330[HBASE-11164 Document and test rolling updates from 0.98 -> 1.0] for the why. Also because HBase 1.0.0 enables HFile v3 by default, link:https://issues.apache.org/jira/browse/HBASE-9801[HBASE-9801 Change the default HFile version to V3], and support for HFile v3 only arrives in 0.98, this is another reason you cannot rolling upgrade from HBase 0.96.x; if the rolling upgrade stalls, the 0.96.x servers cannot open files written by the servers running the newer HBase 1.0.0 with HFile's of version 3. -There are no known issues running a <> from hbase-0.98.x to hbase-1.0.0. +There are no known issues running a <> from HBase 0.98.x to HBase 1.0.0. [[upgrade1.0.from.0.94]] ==== Upgrading to 1.0 from 0.94 -You cannot rolling upgrade from 0.94.x to 1.x.x. You must stop your cluster, install the 1.x.x software, run the migration described at <> (substituting 1.x.x. wherever we make mention of 0.96.x in the section below), and then restart. Be sure to upgrade your zookeeper if it is a version less than the required 3.4.x. +You cannot rolling upgrade from 0.94.x to 1.x.x. You must stop your cluster, install the 1.x.x software, run the migration described at <> (substituting 1.x.x. wherever we make mention of 0.96.x in the section below), and then restart. Be sure to upgrade your ZooKeeper if it is a version less than the required 3.4.x. [[upgrade0.98]] === Upgrading from 0.96.x to 0.98.x @@ -230,7 +230,7 @@ A rolling upgrade from 0.94.x directly to 0.98.x does not work. The upgrade path ==== The "Singularity" .HBase 0.96.x was EOL'd, September 1st, 2014 -NOTE: Do not deploy 0.96.x Deploy a 0.98.x at least. See link:https://issues.apache.org/jira/browse/HBASE-11642[EOL 0.96]. +NOTE: Do not deploy 0.96.x Deploy at least 0.98.x. See link:https://issues.apache.org/jira/browse/HBASE-11642[EOL 0.96]. You will have to stop your old 0.94.x cluster completely to upgrade. If you are replicating between clusters, both clusters will have to go down to upgrade. Make sure it is a clean shutdown. The less WAL files around, the faster the upgrade will run (the upgrade will split any log files it finds in the filesystem as part of the upgrade process). All clients must be upgraded to 0.96 too. @@ -242,7 +242,7 @@ The API has changed. You will need to recompile your code against 0.96 and you m .HDFS and ZooKeeper must be up! NOTE: HDFS and ZooKeeper should be up and running during the upgrade process. -hbase-0.96.0 comes with an upgrade script. Run +HBase 0.96.0 comes with an upgrade script. Run [source,bash] ---- @@ -251,11 +251,11 @@ $ bin/hbase upgrade to see its usage. The script has two main modes: `-check`, and `-execute`. .check -The check step is run against a running 0.94 cluster. Run it from a downloaded 0.96.x binary. The check step is looking for the presence of HFileV1 files. These are unsupported in hbase-0.96.0. To purge them -- have them rewritten as HFileV2 -- you must run a compaction. +The check step is run against a running 0.94 cluster. Run it from a downloaded 0.96.x binary. The check step is looking for the presence of HFile v1 files. These are unsupported in HBase 0.96.0. To have them rewritten as HFile v2 you must run a compaction. -The check step prints stats at the end of its run (grep for `“Result:”` in the log) printing absolute path of the tables it scanned, any HFileV1 files found, the regions containing said files (the regions we need to major compact to purge the HFileV1s), and any corrupted files if any found. A corrupt file is unreadable, and so is undefined (neither HFileV1 nor HFileV2). +The check step prints stats at the end of its run (grep for `“Result:”` in the log) printing absolute path of the tables it scanned, any HFile v1 files found, the regions containing said files (these regions will need a major compaction), and any corrupted files if found. A corrupt file is unreadable, and so is undefined (neither HFile v1 nor HFile v2). -To run the check step, run +To run the check step, run [source,bash] ---- @@ -286,23 +286,23 @@ hdfs://localhost:41020/myHBase/usertable/ecdd3eaee2d2fcf8184ac025555bb2af There are some HFileV1, or corrupt files (files with incorrect major version) ---- -In the above sample output, there are two HFileV1 in two regions, and one corrupt file. Corrupt files should probably be removed. The regions that have HFileV1s need to be major compacted. To major compact, start up the hbase shell and review how to compact an individual region. After the major compaction is done, rerun the check step and the HFileV1s shoudl be gone, replaced by HFileV2 instances. +In the above sample output, there are two HFile v1 files in two regions, and one corrupt file. Corrupt files should probably be removed. The regions that have HFile v1s need to be major compacted. To major compact, start up the hbase shell and review how to compact an individual region. After the major compaction is done, rerun the check step and the HFile v1 files should be gone, replaced by HFile v2 instances. -By default, the check step scans the hbase root directory (defined as hbase.rootdir in the configuration). To scan a specific directory only, pass the -dir option. +By default, the check step scans the HBase root directory (defined as `hbase.rootdir` in the configuration). To scan a specific directory only, pass the `-dir` option. [source,bash] ---- $ bin/hbase upgrade -check -dir /myHBase/testTable ---- -The above command would detect HFileV1s in the /myHBase/testTable directory. +The above command would detect HFile v1 files in the _/myHBase/testTable_ directory. -Once the check step reports all the HFileV1 files have been rewritten, it is safe to proceed with the upgrade. +Once the check step reports all the HFile v1 files have been rewritten, it is safe to proceed with the upgrade. .execute -After the _check_ step shows the cluster is free of HFileV1, it is safe to proceed with the upgrade. Next is the _execute_ step. You must *SHUTDOWN YOUR 0.94.x CLUSTER* before you can run the execute step. The execute step will not run if it detects running HBase masters or regionservers. +After the _check_ step shows the cluster is free of HFile v1, it is safe to proceed with the upgrade. Next is the _execute_ step. You must *SHUTDOWN YOUR 0.94.x CLUSTER* before you can run the execute step. The execute step will not run if it detects running HBase masters or RegionServers. [NOTE] ==== -HDFS and ZooKeeper should be up and running during the upgrade process. If zookeeper is managed by HBase, then you can start zookeeper so it is available to the upgrade by running +HDFS and ZooKeeper should be up and running during the upgrade process. If zookeeper is managed by HBase, then you can start zookeeper so it is available to the upgrade by running [source,bash] ---- $ ./hbase/bin/hbase-daemon.sh start zookeeper @@ -317,7 +317,7 @@ The execute upgrade step is made of three substeps. * WAL Log Splitting: If the 0.94.x cluster shutdown was not clean, we'll split WAL logs as part of migration before we startup on 0.96.0. This WAL splitting runs slower than the native distributed WAL splitting because it is all inside the single upgrade process (so try and get a clean shutdown of the 0.94.0 cluster if you can). -To run the _execute_ step, make sure that first you have copied hbase-0.96.0 binaries everywhere under servers and under clients. Make sure the 0.94.0 cluster is down. Then do as follows: +To run the _execute_ step, make sure that first you have copied HBase 0.96.0 binaries everywhere under servers and under clients. Make sure the 0.94.0 cluster is down. Then do as follows: [source,bash] ---- $ bin/hbase upgrade -execute @@ -339,7 +339,7 @@ Starting Log splitting ... Successfully completed Log splitting ---- - + If the output from the execute step looks good, stop the zookeeper instance you started to do the upgrade: [source,bash] ---- @@ -376,22 +376,22 @@ The migration is a one-time event. However, every time your cluster starts, `MET [[upgrade0.94]] === Upgrading from 0.92.x to 0.94.x -We used to think that 0.92 and 0.94 were interface compatible and that you can do a rolling upgrade between these versions but then we figured that link:https://issues.apache.org/jira/browse/HBASE-5357[">]HBASE-5357 Use builder pattern in HColumnDescriptor] changed method signatures so rather than return void they instead return HColumnDescriptor. This will throw`java.lang.NoSuchMethodError: org.apache.hadoop.hbase.HColumnDescriptor.setMaxVersions(I)V` so 0.92 and 0.94 are NOT compatible. You cannot do a rolling upgrade between them. +We used to think that 0.92 and 0.94 were interface compatible and that you can do a rolling upgrade between these versions but then we figured that link:https://issues.apache.org/jira/browse/HBASE-5357[HBASE-5357 Use builder pattern in HColumnDescriptor] changed method signatures so rather than return `void` they instead return `HColumnDescriptor`. This will throw`java.lang.NoSuchMethodError: org.apache.hadoop.hbase.HColumnDescriptor.setMaxVersions(I)V` so 0.92 and 0.94 are NOT compatible. You cannot do a rolling upgrade between them. [[upgrade0.92]] === Upgrading from 0.90.x to 0.92.x ==== Upgrade Guide -ou will find that 0.92.0 runs a little differently to 0.90.x releases. Here are a few things to watch out for upgrading from 0.90.x to 0.92.0. +You will find that 0.92.0 runs a little differently to 0.90.x releases. Here are a few things to watch out for upgrading from 0.90.x to 0.92.0. .tl:dr [NOTE] ==== -If you've not patience, here are the important things to know upgrading. +These are the important things to know before upgrading. . Once you upgrade, you can’t go back. . MSLAB is on by default. Watch that heap usage if you have a lot of regions. -. Distributed Log Splitting is on by default. It should make region server failover faster. +. Distributed Log Splitting is on by default. It should make RegionServer failover faster. . There’s a separate tarball for security. @@ -399,10 +399,10 @@ If you've not patience, here are the important things to know upgrading. ==== .You can’t go back! -To move to 0.92.0, all you need to do is shutdown your cluster, replace your hbase 0.90.x with hbase 0.92.0 binaries (be sure you clear out all 0.90.x instances) and restart (You cannot do a rolling restart from 0.90.x to 0.92.x -- you must restart). On startup, the `.META.` table content is rewritten removing the table schema from the `info:regioninfo` column. Also, any flushes done post first startup will write out data in the new 0.92.0 file format, <>. This means you cannot go back to 0.90.x once you’ve started HBase 0.92.0 over your HBase data directory. +To move to 0.92.0, all you need to do is shutdown your cluster, replace your HBase 0.90.x with HBase 0.92.0 binaries (be sure you clear out all 0.90.x instances) and restart (You cannot do a rolling restart from 0.90.x to 0.92.x -- you must restart). On startup, the `.META.` table content is rewritten removing the table schema from the `info:regioninfo` column. Also, any flushes done post first startup will write out data in the new 0.92.0 file format, <>. This means you cannot go back to 0.90.x once you’ve started HBase 0.92.0 over your HBase data directory. .MSLAB is ON by default -In 0.92.0, the `<>` flag is set to `true` (See <>). In 0.90.x it was false. When it is enabled, memstores will step allocate memory in MSLAB 2MB chunks even if the memstore has zero or just a few small elements. This is fine usually but if you had lots of regions per regionserver in a 0.90.x cluster (and MSLAB was off), you may find yourself OOME'ing on upgrade because the `thousands of regions * number of column families * 2MB MSLAB` (at a minimum) puts your heap over the top. Set `hbase.hregion.memstore.mslab.enabled` to `false` or set the MSLAB size down from 2MB by setting `hbase.hregion.memstore.mslab.chunksize` to something less. +In 0.92.0, the `<>` flag is set to `true` (See <>). In 0.90.x it was false. When it is enabled, memstores will step allocate memory in MSLAB 2MB chunks even if the memstore has zero or just a few small elements. This is fine usually but if you had lots of regions per RegionServer in a 0.90.x cluster (and MSLAB was off), you may find yourself OOME'ing on upgrade because the `thousands of regions * number of column families * 2MB MSLAB` (at a minimum) puts your heap over the top. Set `hbase.hregion.memstore.mslab.enabled` to `false` or set the MSLAB size down from 2MB by setting `hbase.hregion.memstore.mslab.chunksize` to something less. [[dls]] .Distributed Log Splitting is on by default @@ -412,18 +412,18 @@ Previous, WAL logs on crash were split by the Master alone. In 0.92.0, log split In 0.92.0, <> indices and bloom filters take up residence in the same LRU used caching blocks that come from the filesystem. In 0.90.x, the HFile v1 indices lived outside of the LRU so they took up space even if the index was on a ‘cold’ file, one that wasn’t being actively used. With the indices now in the LRU, you may find you have less space for block caching. Adjust your block cache accordingly. See the <> for more detail. The block size default size has been changed in 0.92.0 from 0.2 (20 percent of heap) to 0.25. .On the Hadoop version to use -Run 0.92.0 on Hadoop 1.0.x (or CDH3u3 when it ships). The performance benefits are worth making the move. Otherwise, our Hadoop prescription is as it has been; you need an Hadoop that supports a working sync. See <>. +Run 0.92.0 on Hadoop 1.0.x (or CDH3u3). The performance benefits are worth making the move. Otherwise, our Hadoop prescription is as it has been; you need an Hadoop that supports a working sync. See <>. If running on Hadoop 1.0.x (or CDH3u3), enable local read. See link:http://files.meetup.com/1350427/hug_ebay_jdcryans.pdf[Practical Caching] presentation for ruminations on the performance benefits ‘going local’ (and for how to enable local reads). .HBase 0.92.0 ships with ZooKeeper 3.4.2 -If you can, upgrade your zookeeper. If you can’t, 3.4.2 clients should work against 3.3.X ensembles (HBase makes use of 3.4.2 API). +If you can, upgrade your ZooKeeper. If you can’t, 3.4.2 clients should work against 3.3.X ensembles (HBase makes use of 3.4.2 API). .Online alter is off by default -In 0.92.0, we’ve added an experimental online schema alter facility (See <>). Its off by default. Enable it at your own risk. Online alter and splitting tables do not play well together so be sure your cluster quiescent using this feature (for now). +In 0.92.0, we’ve added an experimental online schema alter facility (See <>). It's off by default. Enable it at your own risk. Online alter and splitting tables do not play well together so be sure your cluster quiescent using this feature (for now). .WebUI -The webui has had a few additions made in 0.92.0. It now shows a list of the regions currently transitioning, recent compactions/flushes, and a process list of running processes (usually empty if all is well and requests are being handled promptly). Other additions including requests by region, a debugging servlet dump, etc. +The web UI has had a few additions made in 0.92.0. It now shows a list of the regions currently transitioning, recent compactions/flushes, and a process list of running processes (usually empty if all is well and requests are being handled promptly). Other additions including requests by region, a debugging servlet dump, etc. .Security tarball We now ship with two tarballs; secure and insecure HBase. Documentation on how to setup a secure HBase is on the way. @@ -432,10 +432,10 @@ We now ship with two tarballs; secure and insecure HBase. Documentation on how t 0.92.0 adds two new features: multi-slave and multi-master replication. The way to enable this is the same as adding a new peer, so in order to have multi-master you would just run add_peer for each cluster that acts as a master to the other slave clusters. Collisions are handled at the timestamp level which may or may not be what you want, this needs to be evaluated on a per use case basis. Replication is still experimental in 0.92 and is disabled by default, run it at your own risk. .RegionServer now aborts if OOME -If an OOME, we now have the JVM kill -9 the regionserver process so it goes down fast. Previous, a RegionServer might stick around after incurring an OOME limping along in some wounded state. To disable this facility, and recommend you leave it in place, you’d need to edit the bin/hbase file. Look for the addition of the -XX:OnOutOfMemoryError="kill -9 %p" arguments (See link:https://issues.apache.org/jira/browse/HBASE-4769[HBASE-4769 - ‘Abort RegionServer Immediately on OOME’]). +If an OOME, we now have the JVM kill -9 the RegionServer process so it goes down fast. Previous, a RegionServer might stick around after incurring an OOME limping along in some wounded state. To disable this facility, and recommend you leave it in place, you’d need to edit the bin/hbase file. Look for the addition of the -XX:OnOutOfMemoryError="kill -9 %p" arguments (See link:https://issues.apache.org/jira/browse/HBASE-4769[HBASE-4769 - ‘Abort RegionServer Immediately on OOME’]). -.HFile V2 and the “Bigger, Fewer” Tendency -0.92.0 stores data in a new format, <>. As HBase runs, it will move all your data from HFile v1 to HFile v2 format. This auto-migration will run in the background as flushes and compactions run. HFile V2 allows HBase run with larger regions/files. In fact, we encourage that all HBasers going forward tend toward Facebook axiom #1, run with larger, fewer regions. If you have lots of regions now -- more than 100s per host -- you should look into setting your region size up after you move to 0.92.0 (In 0.92.0, default size is now 1G, up from 256M), and then running online merge tool (See link:https://issues.apache.org/jira/browse/HBASE-1621[HBASE-1621 merge tool should work on online cluster, but disabled table]). +.HFile v2 and the “Bigger, Fewer” Tendency +0.92.0 stores data in a new format, <>. As HBase runs, it will move all your data from HFile v1 to HFile v2 format. This auto-migration will run in the background as flushes and compactions run. HFile v2 allows HBase run with larger regions/files. In fact, we encourage that all HBasers going forward tend toward Facebook axiom #1, run with larger, fewer regions. If you have lots of regions now -- more than 100s per host -- you should look into setting your region size up after you move to 0.92.0 (In 0.92.0, default size is now 1G, up from 256M), and then running online merge tool (See link:https://issues.apache.org/jira/browse/HBASE-1621[HBASE-1621 merge tool should work on online cluster, but disabled table]). [[upgrade0.90]] === Upgrading to HBase 0.90.x from 0.20.x or 0.89.x @@ -447,4 +447,4 @@ Finally, if upgrading from 0.20.x, check your .META. schema in the shell. In the ---- hbase> scan '-ROOT-' ---- -in the shell. This will output the current `.META.` schema. Check `MEMSTORE_FLUSHSIZE` size. Is it 16kb (16384)? If so, you will need to change this (The 'normal'/default value is 64MB (67108864)). Run the script `bin/set_meta_memstore_size.rb`. This will make the necessary edit to your `.META.` schema. Failure to run this change will make for a slow cluster. See link:https://issues.apache.org/jira/browse/HBASE-3499[HBASE-3499 Users upgrading to 0.90.0 need to have their .META. table updated with the right MEMSTORE_SIZE]. \ No newline at end of file +in the shell. This will output the current `.META.` schema. Check `MEMSTORE_FLUSHSIZE` size. Is it 16kb (16384)? If so, you will need to change this (The 'normal'/default value is 64MB (67108864)). Run the script `bin/set_meta_memstore_size.rb`. This will make the necessary edit to your `.META.` schema. Failure to run this change will make for a slow cluster. See link:https://issues.apache.org/jira/browse/HBASE-3499[HBASE-3499 Users upgrading to 0.90.0 need to have their .META. table updated with the right MEMSTORE_SIZE].