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Transactional Memory Companion slides for The Art of Multiprocessor Programming by Maurice Herlihy & Nir Shavit TexPoint fonts used in EMF. Read the TexPoint.

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Presentation on theme: "Transactional Memory Companion slides for The Art of Multiprocessor Programming by Maurice Herlihy & Nir Shavit TexPoint fonts used in EMF. Read the TexPoint."— Presentation transcript:

1 Transactional Memory Companion slides for The Art of Multiprocessor Programming by Maurice Herlihy & Nir Shavit TexPoint fonts used in EMF. Read the TexPoint manual before you delete this box.: A A AA A

2 2 Our Vision for the Future In this course, we covered …. Best practices … New and clever ideas … And common-sense observations. Art of Multiprocessor Programming

3 3 Our Vision for the Future In this course, we covered …. Best practices … New and clever ideas … And common-sense observations. Nevertheless … Concurrent programming is still too hard … Here we explore why this is …. And what we can do about it. Art of Multiprocessor Programming

4 4 Locking Art of Multiprocessor Programming

5 5 Coarse-Grained Locking Easily made correct … But not scalable. Art of Multiprocessor Programming

6 6 Fine-Grained Locking Can be tricky … Art of Multiprocessor Programming

7 7 Locks are not Robust If a thread holding a lock is delayed … No one else can make progress Art of Multiprocessor Programming

8 Locking Relies on Conventions Relation between –Lock bit and object bits –Exists only in programmer’s mind /* * When a locked buffer is visible to the I/O layer * BH_Launder is set. This means before unlocking * we must clear BH_Launder,mb() on alpha and then * clear BH_Lock, so no reader can see BH_Launder set * on an unlocked buffer and then risk to deadlock. */ Actual comment from Linux Kernel (hat tip: Bradley Kuszmaul) Art of Multiprocessor Programming

9 9 Simple Problems are hard enq(x) enq(y) double-ended queue No interference if ends “far apart” Interference OK if queue is small Clean solution is publishable result: [Michael & Scott PODC 97] Clean solution is publishable result: [Michael & Scott PODC 97] Art of Multiprocessor Programming

10 10 Locks Not Composable Transfer item from one queue to another Must be atomic : No duplicate or missing items Must be atomic : No duplicate or missing items

11 Art of Multiprocessor Programming 11 Locks Not Composable Lock source Lock target Unlock source & target

12 Art of Multiprocessor Programming 12 Locks Not Composable Lock source Lock target Unlock source & target Methods cannot provide internal synchronization Objects must expose locking protocols to clients Clients must devise and follow protocols Abstraction broken!

13 13 Monitor Wait and Signal zzz Empty buffer Yes! Art of Multiprocessor Programming If buffer is empty, wait for item to show up If buffer is empty, wait for item to show up

14 14 Wait and Signal do not Compose empty zzz… Art of Multiprocessor Programming Wait for either?

15 Art of Multiprocessor Programming 15 The Transactional Manifesto Current practice inadequate –to meet the multicore challenge Research Agenda –Replace locking with a transactional API –Design languages or libraries –Implement efficient run-times

16 Art of Multiprocessor Programming 16 Transactions Block of code …. Atomic: appears to happen instantaneously Serializable: all appear to happen in one-at-a-time order Commit: takes effect (atomically) Abort: has no effect (typically restarted)

17 Art of Multiprocessor Programming 17 atomic { x.remove(3); y.add(3); } atomic { y = null; } Atomic Blocks

18 Art of Multiprocessor Programming 18 atomic { x.remove(3); y.add(3); } atomic { y = null; } Atomic Blocks No data race

19 Art of Multiprocessor Programming 19 public void LeftEnq(item x) { Qnode q = new Qnode(x); q.left = this.left; this.left.right = q; this.left = q; } A Double-Ended Queue Write sequential Code

20 Art of Multiprocessor Programming 20 public void LeftEnq(item x) atomic { Qnode q = new Qnode(x); q.left = this.left; this.left.right = q; this.left = q; } A Double-Ended Queue

21 Art of Multiprocessor Programming 21 public void LeftEnq(item x) { atomic { Qnode q = new Qnode(x); q.left = this.left; this.left.right = q; this.left = q; } A Double-Ended Queue Enclose in atomic block

22 Art of Multiprocessor Programming 22 Warning Not always this simple –Conditional waits –Enhanced concurrency –Complex patterns But often it is…

23 Art of Multiprocessor Programming 23 Composition?

24 Art of Multiprocessor Programming 24 Composition? public void Transfer(Queue q1, q2) { atomic { T x = q1.deq(); q2.enq(x); } Trivial or what?

25 Art of Multiprocessor Programming 25 public T LeftDeq() { atomic { if (this.left == null) retry; … } Conditional Waiting Roll back transaction and restart when something changes

26 Art of Multiprocessor Programming 26 Composable Conditional Waiting atomic { x = q1.deq(); } orElse { x = q2.deq(); } Run 1 st method. If it retries … Run 2 nd method. If it retries … Entire statement retries

27 Art of Multiprocessor Programming 27 Hardware Transactional Memory Exploit Cache coherence Already almost does it –Invalidation –Consistency checking Speculative execution –Branch prediction = optimistic synch!

28 Art of Multiprocessor Programming 28 HW Transactional Memory Interconnect caches memory read active T

29 Art of Multiprocessor Programming 29 Transactional Memory read active TT caches memory

30 Art of Multiprocessor Programming 30 Transactional Memory active TT committed caches memory

31 Art of Multiprocessor Programming 31 Transactional Memory write active committed TD caches memory

32 Art of Multiprocessor Programming 32 Rewind active TT write aborted D caches memory

33 Art of Multiprocessor Programming 33 Transaction Commit At commit point –If no cache conflicts, we win. Mark transactional entries –Read-only: valid –Modified: dirty (eventually written back) That’s all, folks! –Except for a few details …

34 Art of Multiprocessor Programming 34 Not all Skittles and Beer Limits to –Transactional cache size –Scheduling quantum Transaction cannot commit if it is –Too big –Too slow –Actual limits platform-dependent

35 HTM Strengths & Weaknesses Ideal for lock-free data structures

36 HTM Strengths & Weaknesses Ideal for lock-free data structures Practical proposals have limits on –Transaction size and length –Bounded HW resources –Guarantees vs best-effort

37 HTM Strengths & Weaknesses Ideal for lock-free data structures Practical proposals have limits on –Transaction size and length –Bounded HW resources –Guarantees vs best-effort On fail –Diagnostics essential –Retry in software?

38 Composition Locks don’t compose, transactions do. Composition necessary for Software Engineering. But practical HTM doesn’t really support composition! Why we need STM

39 Art of Multiprocessor Programming 39 Simple Lock-Based STM STMs come in different forms –Lock-based –Lock-free Here : a simple lock-based STM

40 Art of Multiprocessor Programming 40 Synchronization Transaction keeps –Read set: locations & values read –Write set: locations & values to be written Deferred update –Changes installed at commit Lazy conflict detection –Conflicts detected at commit

41 Art of Multiprocessor Programming 41 STM: Transactional Locking Map Application Memory V# Array of version #s & locks

42 Art of Multiprocessor Programming 42 Reading an Object Mem Locks V# Add version numbers & values to read set

43 Art of Multiprocessor Programming 43 To Write an Object Mem Locks V# Add version numbers & new values to write set

44 Art of Multiprocessor Programming 44 To Commit Mem Locks V# X Y V#+1 Acquire write locks Check version numbers unchanged Install new values Increment version numbers Unlock.

45 Problem: Internal Inconsistency A Zombie is an active transaction destined to abort. If Zombies see inconsistent states bad things can happen

46 Art of Multiprocessor Programming 46 Internal Consistency x y 4 2 8 4 Invariant: x = 2y Transaction A: reads x = 4 Transaction B: writes 8 to x, 16 to y, aborts A ) Transaction B: writes 8 to x, 16 to y, aborts A ) Transaction A: (zombie) reads y = 4 computes 1/(x-y) Transaction A: (zombie) reads y = 4 computes 1/(x-y) Divide by zero FAIL!

47 Art of Multiprocessor Programming 47 Solution: The Global Clock Have one shared global clock Incremented by (small subset of) writing transactions Read by all transactions Used to validate that state worked on is always consistent

48 100 Art of Multiprocessor Programming 48 Read-Only Transactions Mem Locks 12 32 56 19 17 100 Shared Version Clock Private Read Version (RV) Copy version clock to local read version clock

49 100 Art of Multiprocessor Programming 49 Read-Only Transactions Mem Locks 12 32 56 19 17 100 Shared Version Clock Private Read Version (RV) Copy version clock to local read version clock Read lock, version #, and memory

50 100 Art of Multiprocessor Programming 50 Read-Only Transactions Mem Locks 12 32 56 19 17 100 Shared Version Clock Private Read Version (RV) Copy version clock to local read version clock Read lock, version #, and memory On Commit: check unlocked & version # unchanged On Commit: check unlocked & version # unchanged

51 Art of Multiprocessor Programming 51 Read-Only Transactions Mem Locks 12 32 56 19 17 100 Shared Version Clock Private Read Version (RV) Copy version clock to local read version clock Read lock, version #, and memory On Commit: check unlocked & version # unchanged On Commit: check unlocked & version # unchanged Check that version #s less than local read clock 100

52 Art of Multiprocessor Programming 52 Read-Only Transactions Mem Locks 12 32 56 19 17 100 Shared Version Clock Private Read Version (RV) Copy version clock to local read version clock Read lock, version #, and memory On Commit: check unlocked & version # unchanged On Commit: check unlocked & version # unchanged Check that version #s less than local read clock 100 We have taken a snapshot without keeping an explicit read set!

53 100 Art of Multiprocessor Programming 53 Regular Transactions Mem Locks 12 32 56 19 17 100 Shared Version Clock Private Read Version (RV) Copy version clock to local read version clock

54 100 Art of Multiprocessor Programming 54 Regular Transactions Mem Locks 12 32 56 19 17 100 Shared Version Clock Private Read Version (RV) Copy version clock to local read version clock On read/write, check: Unlocked & version # < RV Add to R/W set On read/write, check: Unlocked & version # < RV Add to R/W set

55 Art of Multiprocessor Programming 55 On Commit Mem Locks 100 Shared Version Clock 100 12 32 56 19 17 Private Read Version (RV) Acquire write locks

56 Art of Multiprocessor Programming 56 On Commit Mem Locks 100 Shared Version Clock 100 101 12 32 56 19 17 Private Read Version (RV) Acquire write locks Increment Version Clock

57 Art of Multiprocessor Programming 57 On Commit Mem Locks 100 Shared Version Clock 100 101 12 32 56 19 17 Private Read Version (RV) Acquire write locks Increment Version Clock Check version numbers ≤ RV

58 Art of Multiprocessor Programming 58 On Commit Mem Locks 100 Shared Version Clock 100 101 12 32 56 19 17 Private Read Version (RV) Acquire write locks Increment Version Clock Check version numbers ≤ RV Update memory x y

59 Art of Multiprocessor Programming 59 On Commit Mem Locks 100 Shared Version Clock 100 101 12 32 56 19 17 Private Read Version (RV) Acquire write locks Increment Version Clock Check version numbers ≤ RV Update memory Update write version #s x y 100

60 Art of Multiprocessor Programming 60 TM Design Issues Implementation choices Language design issues Semantic issues

61 Art of Multiprocessor Programming 61 Granularity Object –managed languages, Java, C#, … –Easy to control interactions between transactional & non-trans threads Word –C, C++, … –Hard to control interactions between transactional & non-trans threads

62 Art of Multiprocessor Programming 62 Direct/Deferred Update Deferred –modify private copies & install on commit –Commit requires work –Consistency easier Direct –Modify in place, roll back on abort –Makes commit efficient –Consistency harder

63 Art of Multiprocessor Programming 63 Conflict Detection Eager –Detect before conflict arises –“Contention manager” module resolves Lazy –Detect on commit/abort Mixed –Eager write/write, lazy read/write …

64 Art of Multiprocessor Programming 64 Conflict Detection Eager detection may abort transactions that could have committed. Lazy detection discards more computation.

65 Art of Multiprocessor Programming 65 Contention Management & Scheduling How to resolve conflicts? Who moves forward and who rolls back? Lots of empirical work but formal work in infancy

66 Art of Multiprocessor Programming 66 Contention Manager Strategies Exponential backoff Priority to –Oldest? –Most work? –Non-waiting? None Dominates But needed anyway Judgment of Solomon

67 Art of Multiprocessor Programming 67 I/O & System Calls? Some I/O revocable –Provide transaction- safe libraries –Undoable file system/DB calls Some not –Opening cash drawer –Firing missile

68 Art of Multiprocessor Programming 68 I/O & System Calls One solution: make transaction irrevocable –If transaction tries I/O, switch to irrevocable mode. There can be only one … –Requires serial execution No explicit aborts –In irrevocable transactions

69 Art of Multiprocessor Programming 69 Exceptions int i = 0; try { atomic { i++; node = new Node(); } } catch (Exception e) { print(i); } int i = 0; try { atomic { i++; node = new Node(); } } catch (Exception e) { print(i); }

70 Art of Multiprocessor Programming 70 Exceptions int i = 0; try { atomic { i++; node = new Node(); } } catch (Exception e) { print(i); } int i = 0; try { atomic { i++; node = new Node(); } } catch (Exception e) { print(i); } Throws OutOfMemoryException!

71 Art of Multiprocessor Programming 71 Exceptions int i = 0; try { atomic { i++; node = new Node(); } } catch (Exception e) { print(i); } int i = 0; try { atomic { i++; node = new Node(); } } catch (Exception e) { print(i); } Throws OutOfMemoryException! What is printed?

72 Art of Multiprocessor Programming 72 Unhandled Exceptions Aborts transaction –Preserves invariants –Safer Commits transaction –Like locking semantics –What if exception object refers to values modified in transaction?

73 Art of Multiprocessor Programming 73 Nested Transactions atomic void foo() { bar(); } atomic void bar() { … } atomic void foo() { bar(); } atomic void bar() { … }

74 Art of Multiprocessor Programming 74 Nested Transactions Needed for modularity –Who knew that cosine() contained a transaction? Flat nesting –If child aborts, so does parent First-class nesting –If child aborts, partial rollback of child only

75 Remember 1993?

76 Citation Count

77 TM Today 93,300

78 2,210,000 Second Opinion

79 Hatin’ on TM STM is too inefficient

80 Hatin’ on TM Requires radical change in programming style

81 Hatin’ on TM Erlang-style shared nothing only true path to salvation

82 Hatin’ on TM There is nothing wrong with what we do today.

83 Gartner Hype Cycle Hat tip: Jeremy Kemp

84 Art of Multiprocessor Programming 84 Multicore forces us to rethink almost everything I, for one, Welcome our new Multicore Overlords …

85 Art of Multiprocessor Programming 85 Multicore forces us to rethink almost everything Standard approaches too complex I, for one, Welcome our new Multicore Overlords …

86 Art of Multiprocessor Programming 86 Multicore forces us to rethink almost everything Standard approaches won’t scale Transactions might make life simpler… I, for one, Welcome our new Multicore Overlords …

87 Art of Multiprocessor Programming 87 Multicore forces us to rethink almost everything Standard approaches won’t scale Transactions might … Multicore programming Plenty more to do… Maybe it will be you… I, for one, Welcome our new Multicore Overlords …

88 Thanks ! תודה Art of Multiprocessor Programming 88

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