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MAP REDUCE BASICS CHAPTER 2 Basics • Divide and conquer – Partition large problem into smaller subproblems – Worker work on subproblems in parallel Basics • MR – abstraction that hides system-level details from programmer • Move code to data – Spread data across disks – DFS manages storage Topics • Functional programming • MapReduce • Distributed file system Functional Programming Roots • MapReduce = functional programming plus distributed processing on steroids – Not a new idea… dates back to the 50’s (or even 30’s) • What is functional programming? – Computation as application of functions – Computation is evaluation of mathematical functions – Avoids state and mutable data – Emphasizes application of functions instead of changes in state Functional Programming Roots • How is it different? – Traditional notions of “data” and “instructions” are not applicable – Data flows are implicit in program – Different orders of execution are possible – Theoretical foundation provided by lambda calculus • a formal system for function definition • Exemplified by LISP, Scheme Overview of Lisp • Functions written in prefix notation where operators precede operands (+ 1 2) (* 3 4) (sqrt ( (define (* x 5) 3 12 + (* 3 3) (* 4 4))) 5 x 3) x 15 Functions • Functions = lambda (anonymous) expressions bound to variables Example expressed with lambda:(+ 1 2) 3 (define foo (lambda (x y) (sqrt (+ (* x x) (* y y))))) • Above expression is equivalent to: (define (foo x y) (sqrt (+ (* x x) (* y y)))) • Once defined, function can be applied: (foo 3 4) 5 λxλy.x+y Functional Programming Roots • Map and Fold • Two important concepts in functional programming – Map: do something to everything in a list – Fold: combine results of a list in some way Functional Programming Map • Higher order functions – accept other functions as arguments – Map • Takes a function f and its argument, which is a list • applies to all elements in list • Returns a list as result • Lists are primitive data types – [1 2 3 4 5] – [[a 1] [b 2] [c 3]] Map/Fold in Action • Simple map example: (map (lambda (x) (* x x)) [1 2 3 4 5]) [1 4 9 16 25] Functional Programming Reduce – Fold • Takes function g, which has 2 arguments: an initial value and a list. • The g applied to initial value and 1st item in list • Result stored in intermediate variable • Intermediate variable and next item in list 2nd application of g, etc. • Fold returns final value of intermediate variable Map/Fold in Action • Simple map example: (map (lambda (x) (* x x)) [1 2 3 4 5]) [1 4 9 16 25] • Fold examples: (fold + 0 [1 2 3 4 5]) 15 (fold * 1 [1 2 3 4 5]) 120 • Write Sum of squares: (define (sum-of-squares v) // where v is a list (fold + 0 (map (lambda (x) (* x x)) v))) (sum-of-squares [1 2 3 4 5]) 55 Functional Programming Roots • • • • • Use map/fold in combination Map – transformation of dataset Fold- aggregation operation Can apply map in parallel Fold – more restrictions, elements must be brought together – Many applications do not require g be applied to all elements of list, fold aggregations in parallel MapReduce - Functional Programming Roots • Input to function, apply function • Function emits output – Can use output as input to next stage MapReduce • Map in MapReduce is same as in functional programming • Reduce corresponds to fold • 2 stages: – User specified computation applied over all input, can occur in parallel, return intermediate output – Output aggregated by another user-specified computation Mappers/Reducers • Key-value pair (k,v) – basic data structure in MR • Keys, values – int, strings, etc., user defined – e.g. (k – URLs, v – HTML content) – e.g. (k – node ids, v – adjacency lists of nodes) Map: (k1, v1) -> [(k2, v2)] Reduce: (k2, [v2]) -> [(k3, v2)] Where […] denotes a list Notice output of Map, input to Reduce different General Flow • Apply mapper to every input key-value pair stored in DFS • Generate arbitrary number of intermediate (k,v) • Group by operation on intermediate keys within mapper (really a sort? But called a shuffle)) • Distribute intermediate results by key – not across reducers but across the network (really a shuffle? But called a sort) • Aggregate intermediate results • Generate final output to DFS – one file per reducer What function is implemented? 9 Another Example: unigram (word count) • (docid, doc) on DFS, doc is text • Mapper tokenizes (docid, doc), emits (k,v) for every word – (word, 1) • Execution framework all same keys brought together in reducer • Reducer – sums all counts (of 1) for word • Each reduce writes to one file • Words within file sorted, file same # words • Can use output as input to another MR • Hadoop libraries for MapReduce Combine - Bandwidth Optimization • Issue: Can be a large number of key-value pairs – Example – word count (word, 1) – If copy across network intermediate data > input Combine - Bandwidth Optimization • Solution: use Combiner functions – allow local aggregation (after mapper) before shuffle sort • Word Count - Aggregate (count each word locally) – intermediate = # unique words – Executed on same machine as mapper – no output from other mappers – Results in a “mini-reduce” right after the map phase – (k,v) of same type as input/output – If operation associative and commutative, reduce can be same as combiner – Reduces key-value pairs to save bandwidth Partitioners – Load Balance • Issue: Intermediate results can all be on one reducer • Solution: use Partitioner functions – divide up intermediate key space and assign (k,v) to reducers – Specifies task to which copy (k,v) – Reducer processes keys in sorted order – Partitioner applies function to key – Hopefully same number of each to each reducer • But may be- Zipfian MapReduce • Programmers specify two functions: map (k, v) → <k’, v’>* reduce (k’, v’) → <k’, v’>* – All v’ with the same k’ are reduced together • Usually, programmers also specify: partition (k’, number of partitions ) → partition for k’ – Often a simple hash of the key, e.g. hash(k’) mod n • Where n is the number of reducers – Allows reduce operations for different keys in parallel 9 Its not just Map and Reduce • Apply mapper to every input key-value pair stored in DFS • Generate arbitrary number of intermediate (k,v) • Aggregate locally • Assign to reducers • Group by operation on intermediate keys • Distribute intermediate results by key not across reducers • Aggregate intermediate results • Generate final output to DFS – one file per reducer Execution Framework • MapReduce program (job) contains • • • • • Code for mappers Combiners (optional) Partitioners (optional) Code for reducers Configuration parameters (where is input, store output) – Execution framework takes care of everything else – Developer submits job to submission node of cluster (jobtracker) Recall these problems? • • • • • • How do we assign work units to workers? What if we have more work units than workers? What if workers need to share partial results? How do we aggregate partial results? How do we know all the workers have finished? What if workers die? • MapReduce takes care of all this Execution Framework of MapReduce • Scheduling – Job divided into tasks (certain block of (k,v) pairs) – Can have 1000s jobs need to be assigned – May exceed number that can run concurrently – Task queue – Coordination among tasks from different jobs Execution Framework • Synchronization – Concurrently running processes join up – Intermediate (k,v) grouped by key, copy intermediate data over network, shuffle/sort • Number of copy operations (M mappers, R reducers) • Worst case? – M X R copy operations • Each mapper may send intermediate results to every reducer – Reduce computation cannot start until all mappers finished, (k,v) shuffled/sorted • Differs from functional programming – But can copy intermediate (k,v) over network to reducer when mapper finishes • Reducer then waits until notified all mappers done • Why must reducers wait until all mappers finished? • Reducer might receive more input data from unfinished mappers • Can change the order it processes its input • Note: Mappers can start another task Execution Framework of MapReduce • Speculative execution • Map phase only as fast as? – slowest map task • Problem: Stragglers, flaky hardware • Solution: Use speculative execution: – Exact copy of same task on different machine – Uses result of fastest task in attempt to finish – Better for map or reduce? – Can improve running time by 44% (Google) – Doesn’t help if skewed distribution of values Execution Framework • Data/code co-location – Execute near data – If not possible must stream data • Try to keep within same rack Execution Framework • Error/fault handling – The norm – Disk failures, RAM errors, datacenter outages – Software errors – Corrupted data Map Reduce • Implementations: – Google has a proprietary implementation in C++ – Hadoop is an open source implementation in Java (lead by Yahoo now Apache) • Hadoop is a framework for storage and large scale processing of data sets on clusters of commodity hardware • Walmart uses Hadoop for storage (although they originally broke it – wouldn’t scale as needed) • P&G uses HIVE – For data analytics built on top of Hadoop Differences in MapReduce Implementations • Hadoop (Apache) vs. Google – Google – program can specify 2ndary sort, can’t change key in reducer – Hadoop - Values arbitrarily ordered, can change key in reducer • Hadoop – Programmer can specify number of map tasks, but framework makes final decision – In reduce, programmer specified number of tasks is used Hadoop • Careful using external resources – e.g. bottleneck querying SQL DB • Mappers can emit arbitrary number of intermediate (k,v), can be of different type • Reduce can emit arbitrary number of final (k,v) and can be of different type than intermediate (k,v) • Different from functional programming, can have side effects (state change internal – may cause problems, external may write to files) • MapReduce can have no reduce, but must have mapper – Can just pass identity function to reducer – May not have any input • compute pi Other Sources • Other source can serve as source/destination for data from MapReduce – Google – BigTable – Hbase – BigTable clone – Hadoop – integrated RDB with parallel processing, can write to DB tables File Systems – GFS vs DFS • Distributed File System (DFS) – In HPC, storage distinct from computation – NAS (network attached storage) and SAN are common • Separate, dedicated nodes for storage – Fetch, load, process, write – Bottleneck • Higher performance networks $$ (10G Ethernet), special purpose interconnects $$$ (InfiniBand) – $$ increases non-linearly – In GFS Computation and storage not distinct components Hadoop Distributed File System - HDFS • GFS supports proprietary MapReduce • HDFS – supports Hadoop • Don’t have to run GFS on DFS, but misses advantages • Difference in GFS and HDFS vs. DFS: – Adapted to large data processing – divide user data into chunks/blocks – LARGE (was) – Replicate these across the local disk nodes in cluster – Master-slave architecture • https://hadoop.apache.org/docs/r1.2.1/hdfs_ design.html#Introduction • http://www.aosabook.org/en/hdfs.html HDFS vs GFS (Google File System) • Difference in HDFS: – Master-slave architecture • GFS: Master (master), slave (chunkserver) • HDFS: master (namenode), slave (datanode) – Master – namespace (metadata, directory structure, file to block mapping, location of blocks, access permission) – Slaves – manage actual data blocks – Client contacts namespace, gets data from slaves, 3 copies of each block, etc. – Block is 64 MB – Initially Files were immutable – once closed cannot be modified Figure 1. The HDFS architecture HDFS • Namenode – Namespace management – Coordinate file operations • Lazy garbage collection – Maintain file system health • Heartbeats, under-replication, balancing • Supports subset of POSIX API, pushed to application • No Security Hadoop Cluster Architecture • HDFS namenode runs daemon • Job submission node runs jobtracker – point of contact run MapReduce – Monitors progress of MapReduce jobs, coordinates Mappers and reducers • Slaves run tasktracker – Runs users code, datanode daemon, serve HDFS data – Send heartbeat messages to jobtracker Hadoop Cluster Architecture • Number of reduce tasks depends on reducers specified by programmer • Number of map tasks depends on – Hint from programmer – Number of input files – Number of HDFS data blocks of files Hadoop Cluster Architecture • Map tasks assigned – (k,v) called input split • Input splits computed automatically • Aligned on HDFS boundaries so associated with single block, simplifies scheduling • Data locality, if not stream across network (same rack if possible) • How can we use MapReduce to solve problems? • Refresh your memory on Dijkstra’s algorithm Hadoop Cluster Architecture • Mappers in Hadoop – Javaobjects with a MAP method – Mapper object instantiated for every map task by tasktracker – Life cycle – instantiation, hook in API for program specified code • Mappers can load state, static data sources, dictionaries, etc. – After initialization: MAP method called by framework on all (k,v) in input split – Method calls within same Java object, can preserve state across multiple (k,v) in same task – Can run programmer specified termination code Hadoop Cluster Architecture • Reducers in Hadoop – Execution similar to that of mappers • Instantiation, initialization, framework calls REDUCE method with intermediate key and iterator over all key values • Intermediate keys in sorted order • Can preserve state across multiple intermediate keys CAP Theorem • Consistency, availability, partition tolerance • Cannot satisfy all 3 • Partitioning unavoidable in large data systems, must trade off availability and consistency – If master fails, system is unavailable so consistent! – If multiple masters, more available, but inconsistent • Workaround to single namenode – Warm standby namenode – Hadoop community working on it