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Apache Hadoop 1.1

Apache Hadoop 1.1

BigData, hadoop, MapReduce, OpenSource, Map-Reduce #WebUI , hive

Sperasoft

June 23, 2014
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  1. • Before 2004 “Google have implemented hundreds of special-purpose computations

    that process large amounts of raw data, such as crawled documents, web request logs, etc., to compute various kinds of derived data, such as inverted indices etc.” • Nutch search system at 2004 was effectively limited to 100M web pages Use Cases
  2. • 2002: Doug Cutting started Nutch: crawler & search system

    • 2003: GoogleFS paper • 2004: Start of NDFS project (Nutch Distributed FS) • 2004: Google MapReduce paper • 2005: MapReduce implementation in Nutch • 2006: HDFS and MapReduce to Hadoop subproject • 2008: Yahoo! Production search index by a 10000-core Hadoop cluster • 2008: Hadoop – top-level Apache project Hadoop History
  3. • Need to process Multi Petabyte Datasets • Need to

    provide framework for reliable application execution • Need to encapsulate nodes failures from application developer. – Failure is expected, rather than exceptional. – The number of nodes in a cluster is not constant. • Need common infrastructure – Efficient, reliable, Open Source Apache License Hadoop Objectives
  4. • Very Large Distributed File System – 10K nodes, 100

    million files, 10 PB • Assumes Commodity Hardware – Files are replicated to handle hardware failure – Detect failures and recovers from them • Optimized for Batch Processing – Data locations exposed so that computations can move to where data resides – Provides very high aggregate bandwidth Goals of GFS/HDFS
  5. • Data Coherency – Write-once-read-many access model – Client can

    only append to existing files • Files are broken up into blocks – Typically 128 MB block size – Each block replicated on multiple DataNodes • Intelligent Client – Client can find location of blocks – Client accesses data directly from DataNode HFDS Details
  6. • Java API • Command Line – hadoop dfs -mkdir

    /foodir – hadoop dfs -cat /foodir/myfile.txt – hadoop dfs -rm /foodir myfile.txt – hadoop dfsadmin –report – hadoop dfsadmin -decommission datanodename • Web Interface – http://host:port/dfshealth.jsp HDFS User Interface
  7. • The Map-Reduce programming model – Framework for distributed processing

    of large data sets – Pluggable user code runs in generic framework • Common design pattern in data processing cat * | grep | sort | uniq -c | cat > file input | map | shuffle | reduce | output • Natural for: – Log processing – Web search indexing – Ad-hoc queries Hadoop MapReduce
  8. Pro: • Cheap components • Replication • Fault tolerance •

    Parallel processing • Free license • Linear scalability • Amazon support Con: • No realtime • Difficult to add MR tasks • File edit is not supported • High support cost Summary
  9. • Distributed Grep • Count of URL Access Frequency •

    Reverse Web-Link Graph • Inverted Index Examples
  10. API to MapReduce that uses Unix standard streams as the

    interface between Hadoop and your program MAP: map.rb #!/usr/bin/env ruby STDIN.each_line do |line| val = line year, temp, q = val[15,4], val[87,5], val[92,1] puts "#{year}\t#{temp}" if (temp != "+9999" && q =~ /[01459]/) end % cat input/ncdc/sample.txt | map.rb 1950 +0000 1950 +0022 1950 -0011 1949 +0111 1949 +0078 LOCAL EXECUTION Hadoop Streaming (1)
  11. REDUCE: reduce.rb #!/usr/bin/env ruby last_key, max_val = nil, 0 STDIN.each_line

    do |line| key, val = line.split("\t") if last_key && last_key != key puts "#{last_key}\t#{max_val}" last_key, max_val = key, val.to_i else last_key, max_val = key, [max_val, val.to_i].max end end puts "#{last_key}\t#{max_val}" if last_key % cat input/ncdc/sample.txt | map.rb | sort | reduce.rb 1949 111 1950 22 LOCAL EXECUTION Hadoop Streaming (2)
  12.  Intuitive  Make the unstructured data looks like tables

    regardless how it really lay out  SQL based query can be directly against these tables  Generate specify execution plan for this query  What’s Hive  A data warehousing system to store structured data on Hadoop file system  Provide an easy query these data by execution Hadoop MapReduce plans Hive: overview
  13. hive> SHOW TABLES; hive> CREATE TABLE shakespeare (freq INT, word

    STRING) ROW FORMAT DELIMITED FIELDS TERMINATED BY ‘\t’ STORED AS TEXTFILE; hive> DESCRIBE shakespeare; loading data… hive> SELECT * FROM shakespeare LIMIT 10; hive> SELECT * FROM shakespeare WHERE freq > 100 SORT BY freq ASC LIMIT 10; Hive: shell
  14. -- max_temp.pig: Finds the maximum temperature by year records =

    LOAD 'input/ncdc/micro-tab/sample.txt' AS (year:chararray, temperature:int, quality:int); filtered_records = FILTER records BY temperature != 9999 AND (quality == 0 OR quality == 1 OR quality == 4 OR quality == 5 OR quality == 9); grouped_records = GROUP filtered_records BY year; max_temp = FOREACH grouped_records GENERATE group, MAX(filtered_records.temperature); DUMP max_temp; Pig
  15. Initial public launch Move from local workstation to shared, remote

    hosted MySQL instance with a well-defined schema. Service becomes more popular; too many reads hitting the database Add memcached to cache common queries. Reads are now no longer strictly ACID; cached data must expire. Service continues to grow in popularity; too many writes hitting the database Scale MySQL vertically by buying a beefed up server with 16 cores, 128 GB of RAM, and banks of 15 k RPM hard drives. Costly. RDBMS scaling story (1)
  16. New features increases query complexity; now we have too many

    joins Denormalize your data to reduce joins. Rising popularity swamps the server; things are too slow Stop doing any server-side computations. Some queries are still too slow Periodically prematerialize the most complex queries, try to stop joining in most cases. Reads are OK, but writes are getting slower and slower Drop secondary indexes and triggers (no indexes?). RDBMS scaling story (1)
  17. • Tables have one primary index, the row key •

    No join operators • Data is unstructured and untyped • No accessed or manipulated via SQL – Programmatic access via Java, REST, or Thrift APIs • There are three types of lookups: – Fast lookup using row key and optional timestamp – Full table scan – Range scan from region start to end Hbase: differences from RDBMS
  18. • Automatic partitioning • Scale linearly and automatically with new

    nodes • Commodity hardware • Fault tolerance: Apache Zookeeper • Batch processing: Apache Hadoop Hbase: benefits over RDBMS
  19.  Tables are sorted by Row  Table schema only

    define it’s column families .  Each family consists of any number of columns  Each column consists of any number of versions  Columns only exist when inserted, NULLs are free.  Columns within a family are sorted and stored together  Everything except table names are byte[]  (Row, Family: Column, Timestamp)  Value Row key Column Family value TimeStamp Hbase: data model
  20. • Master – Responsible for monitoring region servers – Load

    balancing for regions – Redirect client to correct region servers • regionserver slaves – Serving requests (Write/Read/Scan) of Client – Send HeartBeat to Master Hbase: members
  21. $ hbase shell > create 'test', 'data' 0 row(s) in

    4.3066 seconds > list test 1 row(s) in 0.1485 seconds > put 'test', 'row1', 'data:1', 'value1' 0 row(s) in 0.0454 seconds > put 'test', 'row2', 'data:2', 'value2' 0 row(s) in 0.0035 seconds > scan 'test' ROW COLUMN+CELL row1 column=data:1, timestamp=1240148026198, value=value1 row2 column=data:2, timestamp=1240148040035, value=value2 2 row(s) in 0.0825 seconds Hbase: shell
  22. • Amazon • Facebook • Google • IBM • Joost

    • Last.fm • New York Times • PowerSet • Veoh • Yahoo! Who uses Hadoop?