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Introduction to Multiprocessor Synchronization Maurice Herlihy TexPoint fonts used in EMF. Read the TexPoint manual before you delete this box.: AAAA
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Art of Multiprocessor Programming 2 Moore's Law Clock speed flattening sharply Transistor count still rising
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Moore's Law (in practice) Art of Multiprocessor Programming3
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4 Nearly Extinct: the Uniprocesor memory cpu
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Art of Multiprocessor Programming 5 Endangered: The Shared Memory Multiprocessor (SMP) cache Bus shared memory cache
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Art of Multiprocessor Programming 6 The New Boss: The Multicore Processor (CMP) cache Bus shared memory cache All on the same chip Oracle Niagara Chip
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Art of Multiprocessor Programming 7 From the 2008 press… …Intel has announced a press conference in San Francisco on November 17th, where it will officially launch the Core i7 Nehalem processor… …Sun's next generation Enterprise T5140 and T5240 servers, based on the 3rd Generation UltraSPARC T2 Plus processor, were released two days ago…
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Art of Multiprocessor Programming 8 Why is Kunle Smiling? Niagara 1
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Art of Multiprocessor Programming 9 Why do we care? Time no longer cures software bloat –The “free ride” is over When you double your program's path length –You can't just wait 6 months –Your software must somehow exploit twice as much concurrency
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Art of Multiprocessor Programming 10 Traditional Scaling Process User code Traditional Uniprocessor Speedup 1.8x 7x 3.6x Time: Moore's law
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Ideal Multicore Scaling Process Art of Multiprocessor Programming 11 User code Multicore Speedup 1.8x7x3.6x Unfortunately, not so simple…
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Actual Multicore Scaling Process Art of Multiprocessor Programming 12 1.8x 2x 2.9x User code Multicore Speedup Parallelization and Synchronization require great care…
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Art of Multiprocessor Programming 13 Multicore Programming: Course Overview Fundamentals –Models, algorithms, impossibility Real-World programming –Architectures –Techniques
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Art of Multiprocessor Programming 14 Multicore Programming: Logistics Staff: Professor: Nir Shavit - 32-G622 shanir@csail.mit.edu TA: Will Hasenplaugh - 32-G770 whasenpl@mit.edu Grader: Alex Matveev
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Art of Multiprocessor Programming 15 Multicore Programming: Logistics Grades: Final Exam: 65% Assignments: 30% Class / Recitation Participation: 5%
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Art of Multiprocessor Programming 16 Multicore Programming: Logistics Homework: 7 Assignments Latter 5 include programming Gradually design and test more complex programs and more powerful primitives –such as transactional memory Lead up to final “firewall” design project
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Art of Multiprocessor Programming 17 Multicore Programming: Hardware The beast: Dell PowerEdge R910 4 chips x 10 cores x 2 hardware threads
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Art of Multiprocessor Programming 18 Sequential Computation memory object thread
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Art of Multiprocessor Programming 19 Concurrent Computation memory object threads
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Art of Multiprocessor Programming 20 Asynchrony Sudden unpredictable delays –Cache misses (short) –Page faults (long) –Scheduling quantum used up (really long)
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Art of Multiprocessor Programming 21 Model Summary Multiple threads Single shared memory Objects live in memory Unpredictable asynchronous delays
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22 Road Map We are going to focus on principles first, then practice –Start with idealized models –Look at simplistic problems –Emphasize correctness over pragmatism –“Correctness may be theoretical, but incorrectness has practical impact” Art of Multiprocessor Programming
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23 Concurrency Jargon Hardware –Processors Software –Threads, processes Sometimes OK to confuse them, sometimes not. Art of Multiprocessor Programming
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24 Parallel Primality Testing Challenge –Print primes from 1 to 10 10 Given –Ten-processor multiprocessor –One thread per processor Goal –Get ten-fold speedup (or close) Art of Multiprocessor Programming
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25 Load Balancing Split the work evenly Each thread tests range of 10 9 … …10 910 2·10 9 1 P0P0 P1P1 P9P9
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26 Procedure for Thread i void primePrint { int i = ThreadID.get(); // IDs in {0..9} for (j = i*10 9 +1, j<(i+1)*10 9 ; j++) { if (isPrime(j)) print(j); } Art of Multiprocessor Programming
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27 Issues Higher ranges have fewer primes Yet larger numbers harder to test Thread workloads –Uneven –Hard to predict Art of Multiprocessor Programming
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28 Issues Higher ranges have fewer primes Yet larger numbers harder to test Thread workloads –Uneven –Hard to predict Need dynamic load balancing rejected
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Art of Multiprocessor Programming 29 17 18 19 Shared Counter each thread takes a number
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30 Procedure for Thread i int counter = new Counter(1); void primePrint { long j = 0; while (j < 10 10 ) { j = counter.getAndIncrement(); if (isPrime(j)) print(j); } Art of Multiprocessor Programming
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31 Counter counter = new Counter(1); void primePrint { long j = 0; while (j < 10 10 ) { j = counter.getAndIncrement(); if (isPrime(j)) print(j); } Procedure for Thread i Shared counter object
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Art of Multiprocessor Programming 32 Where Things Reside cache Bus cache 1 shared counter shared memory void primePrint { int i = ThreadID.get(); // IDs in {0..9} for (j = i*10 9 +1, j<(i+1)*10 9 ; j++) { if (isPrime(j)) print(j); } code Local variables
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Art of Multiprocessor Programming 33 Procedure for Thread i Counter counter = new Counter(1); void primePrint { long j = 0; while (j < 10 10 ) { j = counter.getAndIncrement(); if (isPrime(j)) print(j); } Stop when every value taken
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Art of Multiprocessor Programming 34 Counter counter = new Counter(1); void primePrint { long j = 0; while (j < 10 10 ) { j = counter.getAndIncrement(); if (isPrime(j)) print(j); } Procedure for Thread i Increment & return each new value
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35 Counter Implementation public class Counter { private long value; public long getAndIncrement() { return value++; } Art of Multiprocessor Programming
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36 Counter Implementation public class Counter { private long value; public long getAndIncrement() { return value++; } OK for single thread, not for concurrent threads
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Art of Multiprocessor Programming 37 What It Means public class Counter { private long value; public long getAndIncrement() { return value++; }
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Art of Multiprocessor Programming 38 What It Means public class Counter { private long value; public long getAndIncrement() { return value++; } temp = value; value = temp + 1; return temp;
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Art of Multiprocessor Programming 39 time Not so good… Value… 1 read 1 read 1 write 2 read 2 write 3 write 2 232
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Art of Multiprocessor Programming 40 Is this problem inherent? If we could only glue reads and writes together… read write read write !!
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41 Challenge public class Counter { private long value; public long getAndIncrement() { temp = value; value = temp + 1; return temp; } Art of Multiprocessor Programming
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42 Challenge public class Counter { private long value; public long getAndIncrement() { temp = value; value = temp + 1; return temp; } Make these steps atomic (indivisible)
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Art of Multiprocessor Programming 43 Hardware Solution public class Counter { private long value; public long getAndIncrement() { temp = value; value = temp + 1; return temp; } ReadModifyWrite() instruction
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Art of Multiprocessor Programming 44 An Aside: Java™ public class Counter { private long value; public long getAndIncrement() { synchronized { temp = value; value = temp + 1; } return temp; }
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Art of Multiprocessor Programming 45 An Aside: Java™ public class Counter { private long value; public long getAndIncrement() { synchronized { temp = value; value = temp + 1; } return temp; } Synchronized block
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Art of Multiprocessor Programming 46 An Aside: Java™ public class Counter { private long value; public long getAndIncrement() { synchronized { temp = value; value = temp + 1; } return temp; } Mutual Exclusion
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47 Mutual Exclusion, or “Alice & Bob share a pond” AB Art of Multiprocessor Programming
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48 Alice has a pet AB Art of Multiprocessor Programming
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49 Bob has a pet AB Art of Multiprocessor Programming
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50 The Problem AB The pets don't get along Art of Multiprocessor Programming
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51 Formalizing the Problem Two types of formal properties in asynchronous computation: Safety Properties –Nothing bad happens ever Liveness Properties –Something good happens eventually Art of Multiprocessor Programming
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52 Formalizing our Problem Mutual Exclusion –Both pets never in pond simultaneously –This is a safety property No Deadlock –if only one wants in, it gets in –if both want in, one gets in –This is a liveness property Art of Multiprocessor Programming
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53 Simple Protocol Idea –Just look at the pond Gotcha –Not atomic –Trees obscure the view Art of Multiprocessor Programming
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54 Interpretation Threads can't “see” what other threads are doing Explicit communication required for coordination Art of Multiprocessor Programming
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55 Cell Phone Protocol Idea –Bob calls Alice (or vice-versa) Gotcha –Bob takes shower –Alice recharges battery –Bob out shopping for pet food … Art of Multiprocessor Programming
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56 Interpretation Message-passing doesn't work Recipient might not be –Listening –There at all Communication must be –Persistent (like writing) –Not transient (like speaking) Art of Multiprocessor Programming
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57 Can Protocol cola Art of Multiprocessor Programming
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58 Bob conveys a bit AB cola Art of Multiprocessor Programming
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59 Bob conveys a bit AB cola Art of Multiprocessor Programming
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60 Can Protocol Idea –Cans on Alice's windowsill –Strings lead to Bob's house –Bob pulls strings, knocks over cans Gotcha –Cans cannot be reused –Bob runs out of cans Art of Multiprocessor Programming
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61 Interpretation Cannot solve mutual exclusion with interrupts –Sender sets fixed bit in receiver's space –Receiver resets bit when ready –Requires unbounded number of interrupt bits Art of Multiprocessor Programming
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62 Flag Protocol AB Art of Multiprocessor Programming
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63 Alice's Protocol (sort of) AB Art of Multiprocessor Programming
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64 Bob's Protocol (sort of) AB Art of Multiprocessor Programming
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65 Alice's Protocol Raise flag Wait until Bob's flag is down Unleash pet Lower flag when pet returns Art of Multiprocessor Programming
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66 Bob's Protocol Raise flag Wait until Alice's flag is down Unleash pet Lower flag when pet returns danger!
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67 Bob's Protocol (2 nd try) Raise flag While Alice's flag is up –Lower flag –Wait for Alice's flag to go down –Raise flag Unleash pet Lower flag when pet returns Art of Multiprocessor Programming
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68 Bob's Protocol Raise flag While Alice's flag is up –Lower flag –Wait for Alice's flag to go down –Raise flag Unleash pet Lower flag when pet returns Bob defers to Alice
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69 The Flag Principle Raise the flag Look at other's flag Flag Principle: –If each raises and looks, then –Last to look must see both flags up Art of Multiprocessor Programming
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70 Proof of Mutual Exclusion Assume both pets in pond –Derive a contradiction –By reasoning backwards Consider the last time Alice and Bob each looked before letting the pets in Without loss of generality assume Alice was the last to look… Art of Multiprocessor Programming
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71 Proof time Alice's last look Alice last raised her flag Bob's last look QED Alice must have seen Bob's Flag. A Contradiction Bob last raised flag
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72 Proof of No Deadlock If only one pet wants in, it gets in. Art of Multiprocessor Programming
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73 Proof of No Deadlock If only one pet wants in, it gets in. Deadlock requires both continually trying to get in. Art of Multiprocessor Programming
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74 Proof of No Deadlock If only one pet wants in, it gets in. Deadlock requires both continually trying to get in. If Bob sees Alice's flag, he gives her priority (a gentleman…) QED
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75 Remarks Protocol is unfair –Bob's pet might never get in Protocol uses waiting –If Bob is eaten by his pet, Alice's pet might never get in Art of Multiprocessor Programming
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76 Moral of Story Mutual Exclusion cannot be solved by –transient communication (cell phones) –interrupts (cans) It can be solved by – one-bit shared variables – that can be read or written Art of Multiprocessor Programming
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77 The Arbiter Problem (an aside) Pick a point
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78 The Fable Continues Alice and Bob fall in love & marry Art of Multiprocessor Programming
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79 The Fable Continues Alice and Bob fall in love & marry Then they fall out of love & divorce –She gets the pets –He has to feed them Art of Multiprocessor Programming
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80 The Fable Continues Alice and Bob fall in love & marry Then they fall out of love & divorce –She gets the pets –He has to feed them Leading to a new coordination problem: Producer-Consumer Art of Multiprocessor Programming
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81 Bob Puts Food in the Pond A Art of Multiprocessor Programming
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82 mmm… Alice releases her pets to Feed B mmm… Art of Multiprocessor Programming
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83 Producer/Consumer Alice and Bob can't meet –Each has restraining order on other –So he puts food in the pond –And later, she releases the pets Avoid –Releasing pets when there's no food –Putting out food if uneaten food remains Art of Multiprocessor Programming
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84 Producer/Consumer Need a mechanism so that –Bob lets Alice know when food has been put out –Alice lets Bob know when to put out more food Art of Multiprocessor Programming
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85 Surprise Solution AB cola Art of Multiprocessor Programming
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86 Bob puts food in Pond AB cola Art of Multiprocessor Programming
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87 Bob knocks over Can AB cola Art of Multiprocessor Programming
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88 Alice Releases Pets AB cola yum… B Art of Multiprocessor Programming
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89 Alice Resets Can when Pets are Fed AB cola Art of Multiprocessor Programming
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90 Pseudocode while (true) { while (can.isUp()){}; pet.release(); pet.recapture(); can.reset(); } Alice's code
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Art of Multiprocessor Programming 91 Pseudocode while (true) { while (can.isUp()){}; pet.release(); pet.recapture(); can.reset(); } Alice's code while (true) { while (can.isDown()){}; pond.stockWithFood(); can.knockOver(); } Bob's code
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92 Correctness Mutual Exclusion –Pets and Bob never together in pond Art of Multiprocessor Programming
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93 Correctness Mutual Exclusion –Pets and Bob never together in pond No Starvation if Bob always willing to feed, and pets always famished, then pets eat infinitely often. Art of Multiprocessor Programming
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94 Correctness Mutual Exclusion –Pets and Bob never together in pond No Starvation if Bob always willing to feed, and pets always famished, then pets eat infinitely often. Producer/Consumer The pets never enter pond unless there is food, and Bob never provides food if there is unconsumed food. safety liveness safety
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95 Could Also Solve Using Flags AB Art of Multiprocessor Programming
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96 Waiting Both solutions use waiting –while(mumble){} In some cases waiting is problematic –If one participant is delayed –So is everyone else –But delays are common & unpredictable Art of Multiprocessor Programming
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97 The Fable drags on … Bob and Alice still have issues Art of Multiprocessor Programming
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98 The Fable drags on … Bob and Alice still have issues So they need to communicate Art of Multiprocessor Programming
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99 The Fable drags on … Bob and Alice still have issues So they need to communicate They agree to use billboards … Art of Multiprocessor Programming
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100 E 1 D 2 C 3 Billboards are Large B 3 A 1 Letter Tiles From Scrabble™ box Art of Multiprocessor Programming
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101 E 1 D 2 C 3 Write One Letter at a Time … B 3 A 1 W 4 A 1 S 1 H 4 Art of Multiprocessor Programming
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102 To post a message W 4 A 1 S 1 H 4 A 1 C 3 R 1 T 1 H 4 E 1 whew Art of Multiprocessor Programming
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103 S 1 Let's send another message S 1 E 1 L 1 L 1 L 1 V 4 L 1 A 1 M 3 A 1 A 1 P 3 Art of Multiprocessor Programming
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104 Uh-Oh A 1 C 3 R 1 T 1 H 4 E 1 S 1 E 1 L 1 L 1 L 1 OK Art of Multiprocessor Programming
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105 Readers/Writers Devise a protocol so that –Writer writes one letter at a time –Reader reads one letter at a time –Reader sees “snapshot” Old message or new message No mixed messages Art of Multiprocessor Programming
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106 Readers/Writers (continued) Easy with mutual exclusion But mutual exclusion requires waiting –One waits for the other –Everyone executes sequentially Remarkably –We can solve R/W without mutual exclusion Art of Multiprocessor Programming
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107 Esoteric? Java container size() method Single shared counter? –incremented with each add() and –decremented with each remove() Threads wait to exclusively access counter performance bottleneck
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108 Readers/Writers Solution Each thread i has size[i] counter –only it increments or decrements. To get object's size, a thread reads a “snapshot” of all counters without mutex This eliminates the bottleneck Art of Multiprocessor Programming 4 3001 4 2007 size
![108 Readers/Writers Solution Each thread i has size[i] counter –only it increments or decrements.](http://images.slideplayer.com/16/5262502/slides/slide_108.jpg "To get object s size, a thread reads a snapshot of all counters without mutex This eliminates the bottleneck Art of Multiprocessor Programming size.")
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109 Why do we care About Sequential Bottlenecks? We want as much of the code as possible to execute in parallel A larger sequential part implies reduced performance Amdahl's law: this relation is not linear… Art of Multiprocessor Programming Eugene Amdahl
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Art of Multiprocessor Programming 110 Amdahl's Law Speedup = 1-thread execution time N-thread execution time
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Art of Multiprocessor Programming 111 Amdahl's Law Speedup =
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Art of Multiprocessor Programming 112 Amdahl's Law Speedup = Parallel fraction
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Art of Multiprocessor Programming 113 Amdahl's Law Speedup = Parallel fraction Sequential fraction
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Art of Multiprocessor Programming 114 Amdahl's Law Speedup = Parallel fraction Sequential fraction Number of threads
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Amdahl's Law (in practice) Art of Multiprocessor Programming115
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116 Example Ten processors 60% concurrent, 40% sequential How close to 10-fold speedup? Art of Multiprocessor Programming
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117 Example Ten processors 60% concurrent, 40% sequential How close to 10-fold speedup? Speedup = 2.17 = Art of Multiprocessor Programming
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118 Example Ten processors 80% concurrent, 20% sequential How close to 10-fold speedup? Art of Multiprocessor Programming
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119 Example Ten processors 80% concurrent, 20% sequential How close to 10-fold speedup? Speedup = 3.57 = Art of Multiprocessor Programming
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120 Example Ten processors 90% concurrent, 10% sequential How close to 10-fold speedup? Art of Multiprocessor Programming
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121 Example Ten processors 90% concurrent, 10% sequential How close to 10-fold speedup? Speedup = 5.26 =
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122 Example Ten processors 99% concurrent, 01% sequential How close to 10-fold speedup? Art of Multiprocessor Programming
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123 Example Ten processors 99% concurrent, 01% sequential How close to 10-fold speedup? Speedup = 9.17 =
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Back to Real-World Multicore Scaling Art of Multiprocessor Programming 124 1.8x 2x 2.9x User code Multicore Speedup Not reducing sequential % of code
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Shared Data Structures 75% Unshared 25% Shared Coarse Grained Fine Grained 75% Unshared 25% Shared
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Shared Data Structures 75% Unshared 25% Shared Coarse Grained Fine Grained Why only 2.9 speedup 75% Unshared 25% Shared Honk!
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Shared Data Structures 75% Unshared 25% Shared Coarse Grained Fine Grained Why fine-grained parallelism maters 75% Unshared 25% Shared Honk!
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Art of Multiprocessor Programming 128 This Course Learn to minimize parallelization overhead of the fraction P that is easy Learn how to introduce parallelism into the 1-P that are hard
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Art of Multiprocessor Programming Diminishing Returns This course is about the parts that are hard to make concurrent … but still have a big influence on speedup!
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Grading 11 Homeworks 55% 2 In-class midterms 45% Graduate credit: –Extra problem on each homework –Term project (talk to instructor) Art of Multiprocessor Programming
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Collaboration Permitted –talking about the homework problems with other students; using other textbooks; using the Internet. Not Permitted –obtaining the answer directly from anyone else in any form. Art of Multiprocessor Programming
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Crowdsourcing! You can annotate the textbook online –See something interesting? –Have a question? –Answer a question? –Like or dislike a note? http://nb.mit.edu –Play the video Details to follow … Art of Multiprocessor Programming
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133 This work is licensed under a Creative Commons Attribution- ShareAlike 2.5 License.Creative Commons Attribution- ShareAlike 2.5 License You are free: –to Share — to copy, distribute and transmit the work –to Remix — to adapt the work Under the following conditions: –Attribution. You must attribute the work to “The Art of Multiprocessor Programming” (but not in any way that suggests that the authors endorse you or your use of the work). –Share Alike. If you alter, transform, or build upon this work, you may distribute the resulting work only under the same, similar or a compatible license. For any reuse or distribution, you must make clear to others the license terms of this work. The best way to do this is with a link to –http://creativecommons.org/licenses/by-sa/3.0/. Any of the above conditions can be waived if you get permission from the copyright holder. Nothing in this license impairs or restricts the author's moral rights.
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