CSCE 668 DISTRIBUTED ALGORITHMS AND SYSTEMS

1. Set 10: Consensus with Byzantine Failures CSCE 668DISTRIBUTED ALGORITHMS AND SYSTEMS Fall 2011 Prof. Jennifer Welch

2. Consensus with Byzantine Failures • How many processors total are needed to solve consensus when f = 1 ? • Suppose n = 2. If p0 has input 0 and p1 has 1, someone has to change, but not both. What if one processor is faulty? How can the other one know? • Suppose n = 3. If p0 has input 0, p1 has input 1, and p2 is faulty, then a tie-breaker is needed, but p2 can act maliciously. Set 10: Consensus with Byzantine Failures

3. B p1 A C p2 p0 Processor Lower Bound for f = 1 Theorem (5.7): Any consensus algorithm for 1 Byzantine failure must have at least 4 processors. Proof: Suppose in contradiction there is a consensus algorithm A = (A,B,C) for 3 processors and 1 Byzantine failure. Set 10: Consensus with Byzantine Failures

4. 1 1 1 0 B C 0 0 p1 p2 A A p0 p3 p5 p4 C B Specifying Faulty Behavior • Consider a ring of 6 nonfaulty processors running components of A like this: • This execution  probably doesn't solve consensus (it doesn't have to). • But the processors do something -- this behavior is used to specify the behavior of faulty processors in executions of A in the triangle. Set 10: Consensus with Byzantine Failures

5. Getting a Contradiction • Let 0 be this execution: B p1 p1 and p2 must decide 0 act like p3 to p4 in  0 0 0 C p2 p0 act like p0 to p5 in  Set 10: Consensus with Byzantine Failures

6. Getting a Contradiction • Let 1 be this execution: B p0 and p1 must decide 1 p1 act like p2 to p1 in  1 1 1 p2 p0 A act like p5 to p0 in  Set 10: Consensus with Byzantine Failures

7. The Contradiction • Let  be this execution: What do p0 and p2 decide? act like p1 to p0 in  act like p4 to p5 in  p1 ? 1 0 p2 p0 A C view of p0 in  = view of p0 in  = view of p0 in 1 p0 decides 1 view of p2 in  = view of p2 in  = view of p2 in 0 p2 decides 0 Contradiction! Set 10: Consensus with Byzantine Failures

8. B C B act like p1 to p0 in  act like p4 to p5 in  p1 p1 p1 act like p2 to p1 in  p2 1 ? A 1 1 1 0 A p0 p2 p2 p0 p0 A A C p3 act like p5 to p0 in  p5 p4 C B Views 1 1 β: 1 0 0 0 : 1: Set 10: Consensus with Byzantine Failures

9. Processor Lower Bound for Any f Theorem: Any consensus algorithm for f Byzantine failures must have at least 3f+1 processors. Proof: Use a reduction to the 3:1 case. • Suppose in contradiction there is an algorithm A for f > 1 failures and n = 3f total processors. • Use A as a subroutine to construct an algorithm for 1 failure and 3 processors, a contradiction to theorem just proved. Set 10: Consensus with Byzantine Failures

10. The Reduction • Partition the n ≤ 3f processors into three sets, P0, P1, and P2, each of size at most f. • In the n = 3 case, let • p0 simulate P0 • p1simulate P1 • p2simulate P2 • If one processor is faulty in the n = 3 system, then at most f processors are faulty in the simulated system. • Thus the simulated system is correct. • Let the processors in the n = 3 system decide the same as the simulated processors, and their decisions will also be correct. Set 10: Consensus with Byzantine Failures

11. Exponential Tree Algorithm • This algorithm uses • f + 1 rounds (optimal) • n = 3f + 1 processors (optimal) • exponential size messages (sub-optimal) • Each processor keeps a tree data structure in its local state • Values are filled in the tree during the f + 1 rounds • At the end, the values in the tree are used to calculate the decision. Set 10: Consensus with Byzantine Failures

12. Local Tree Data Structure • Each tree node is labeled with a sequence of unique processor indices. • Root's label is empty sequence ; root has level 0 • Root has n children, labeled 0 through n - 1 • Child node labeled i has n - 1 children, labeled i : 0 through i : n-1 (skipping i : i) • Node at level d labeled v has n - d children, labeled v : 0 through v : n-1 (skipping any index appearing in v) • Nodes at level f + 1 are leaves. Set 10: Consensus with Byzantine Failures

13. Example of Local Tree The tree when n = 4 and f = 1 : Set 10: Consensus with Byzantine Failures

14. Filling in the Tree Nodes • Initially store your input in the root (level 0) • Round 1: • send level 0 of your tree to all • store value x received from each pj in tree node labeled j (level 1); use a default if necessary • "pj told me that pj 's input was x" • Round 2: • send level 1 of your tree to all • store value x received from each pj for each tree node k in tree node labeled k : j (level 2); use a default if necessary • "pj told me that pk told pj that pk's input was x" • Continue for f + 1 rounds Set 10: Consensus with Byzantine Failures

15. Calculating the Decision • In round f + 1, each processor uses the values in its tree to compute its decision. • Recursively compute the "resolved" value for the root of the tree, resolve(), based on the "resolved" values for the other tree nodes: value in tree node labeled  if it is a leaf resolve() = majority{resolve( ') : ' is a child of } otherwise (use a default if tied) Set 10: Consensus with Byzantine Failures

16. Example of Resolving Values The tree when n = 4 and f = 1 : (assuming 0 is the default) 0 0 0 1 1 0 1 0 0 0 1 1 1 1 1 0 0 Set 10: Consensus with Byzantine Failures

17. Resolved Values are Consistent Lemma (5.9): If pi and pjare nonfaulty, then pi 's resolved value for its tree node labeled 'j (what pj tells pifor node ') equals what pjstores in its node '. ' ' original value = v 'j resolved value = v part of pi's tree part of pj's tree Set 10: Consensus with Byzantine Failures

18. Resolved Values are Consistent Proof Ideas: • By induction on the height of the tree node. • Uses inductive hypothesis to know that resolved values for children of the tree node corresponding to nonfaulty procs are consistent. • Uses fact that n > 3f and fact that each tree node has at least n - f children to know that majority of children are nonfaulty. Set 10: Consensus with Byzantine Failures

19. Validity • Suppose all inputs are v. • Nonfaulty proc. pi decides resolve(), which is the majority among resolve(j), 0 ≤ j ≤ n-1, based on pi 's tree. • Since resolved values are consistent, resolve(j) (at pi) is value stored at the root of pj 's tree, which is pj's input value if pj is nonfaulty. • Since there are a majority of nonfaulty processors, pi decides v. Set 10: Consensus with Byzantine Failures

20. Common Nodes • A tree node  is common if all nonfaulty procs. compute the same value of resolve().   same resolved value part of pi's tree part of pj's tree Set 10: Consensus with Byzantine Failures

21. Common Frontiers • A tree node  has a common frontier if every path from  to a leaf contains a common node.  pink means common Set 10: Consensus with Byzantine Failures

22. Common Nodes and Frontiers Lemma (5.10): If  has a common frontier, then  is common. Proof Ideas: By induction on height of . Uses fact that resolve is defined using majority. Set 10: Consensus with Byzantine Failures

23. Agreement • The nodes on each path from a child of the root to a leaf correspond to f + 1 different procs. • Since there are at most f faulty processors, at least one such node corresponds to a nonfaulty processor. • This node is common (by the lemma about the consistency of resolved values). • Thus the root has a common frontier. • Thus the root is common (by preceding lemma). Set 10: Consensus with Byzantine Failures

24. Complexity Exponential tree algorithm uses • n > 3f processors • f + 1 rounds • exponential size messages: • each msg in round r contains n(n-1)(n-2)…(n-(r-2)) values • When r = f + 1, this is exponential if f is more than constant relative to n Set 10: Consensus with Byzantine Failures

25. A Polynomial Algorithm • We can reduce the message size to polynomial with a simple algorithm • The number of processors increases to n > 4f • The number of rounds increases to 2(f + 1) • Uses f + 1 phases, each taking two rounds Set 10: Consensus with Byzantine Failures

26. Phase King Algorithm Code foreach processor pi: pref := my input first round of phase k, 1 ≤ k ≤ f+1: send pref to all receive prefs of others let maj be value that occurs > n/2 times (0 if none) let mult be number of times maj occurs second round of phase k: if i = k then send maj to all // I am the phase king receive tie-breaker from pk (0 if none) if mult > n/2 + f then pref := maj else pref := tie-breaker if k = f + 1 then decide pref Set 10: Consensus with Byzantine Failures

27. Unanimous Phase Lemma Lemma (5.12): If all nonfaulty processors prefer v at start of phase k, then all do at end of phase k. Proof: • Each nonfaulty proc. receives at least n - f preferences for v in first round of phase k • Since n > 4f, it follows that n - f > n/2 + f • So each nonfaulty proc. still prefers v. Set 10: Consensus with Byzantine Failures

28. Phase King Validity Unanimous phase lemma implies validity: • Suppose all procs have input v. • Then at start of phase 1, all nf procs prefer v. • So at end of phase 1, all nf procs prefer v. • So at start of phase 2, all nf procs prefer v. • So at end of phase 2, all nf procs prefer v. • … • At end of phase f + 1, all nf procs prefer v and decide v. Set 10: Consensus with Byzantine Failures

29. Nonfaulty King Lemma Lemma (5.13): If king of phase k is nonfaulty, then all nonfaulty procs have same preference at end of phase k. Proof: Let pi and pj be nonfaulty. Case 1:pi and pj both use pk 's tie-breaker. Since pk is nonfaulty, they both have same preference. Set 10: Consensus with Byzantine Failures

30. Nonfaulty King Lemma Case 2:pi uses its majority value v and pj uses king's tie-breaker. • Then pi receives more than n/2 + f preferences for v • So pk receives more than n/2 preferences for v • So pk 's tie-breaker is v Set 10: Consensus with Byzantine Failures

31. Nonfaulty King Lemma Case 3:pi and pj both use their own majority values. • Suppose pi 's majority value is v • Then pi receives more than n/2 + f preferences for v • So pj receives more than n/2 preferences for v • So pj 's majority value is also v Set 10: Consensus with Byzantine Failures

32. Phase King Agreement Use previous two lemmas to prove agreement: • Since there are f + 1 phases, at least one has a nonfaulty king. • Nonfaulty King Lemma implies at the end of that phase, all nonfaulty processors have same preference • Unanimous Phase Lemma implies that from that phase onward, all nonfaulty processors have same preference • Thus all nonfaulty decisions are same. Set 10: Consensus with Byzantine Failures

33. Complexities of Phase King • number of processors n > 4f • 2(f + 1) rounds • O(n2f) messages, each of size log|V| Set 10: Consensus with Byzantine Failures