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Balaji Prabhakar Departments of EE and CS Stanford University

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1 Balaji Prabhakar Departments of EE and CS Stanford University
Randomized switch scheduling algorithms Balaji Prabhakar Departments of EE and CS Stanford University

2 Randomized algorithms
Randomization is a method that can be used to simplify the implementation The main idea base decisions upon a small, randomly chosen sample of the state/input, instead of the complete state/input randomized algorithms are also robust to adversarial attacks (decisions depend on chance events)

3 An illustrative example
Find the youngest person from a population of 1 billion Deterministic algorithm: linear search has a complexity of 1 billion A randomized version: find the youngest of 30 randomly chosen people has a complexity of 30 Performance linear search will find the absolute youngest person (rank = 1) if R is the person found by randomized algorithm, we can say thus, we can say that the performance of the randomized algorithm is good with a high probability

4 Randomizing iterative schemes
Often, we want to perform some operation iteratively Example: find the youngest person each year Say in 2007 you choose 30 people at random and store the identity of the youngest person in memory in 2008 you choose 29 new people at random let R be the youngest person from these = 30 people or

5 Randomized approximation to the Max Wt Matching algorithm joint work with Paolo Giaccone and Devavrat Shah

6 Notation and definitions
Arrivals: Aij(t), i.i.d. Bernoulli, E(Aij(t)) = Q(t) = [Qij(t)] are backlogs at time t 1 2 3 Scheduling problem: Given Q(t), determine a matching, S(t), of inputs and outputs to maximize throughput and minimize backlogs Q(t+1) = [Q(t) + A(t) – S(t)]+

7 Useful performance metrics
Throughput an algorithm is stable (or delivers 100% throughput) if for any admissible arrival, the average backlog is bounded; i.e. (equivalent to positive recurrence of Q(t)) Minimize average backlogs or, equivalently, packet delays

8 Scheduling: Bipartite graph matching
19 3 4 21 1 18 7 Schedule or Matching

9 Scheduling algorithms
19 3 4 21 1 18 7 Max Wt Matching 19 18 Max Size Matching 19 1 7 Practical Maximal Matchings  Stable (Tassiulas-Ephremides 92, McKeown et. al. 96, Dai-Prabhakar 00)  Not stable  Not stable (McKeown-Ananthram-Walrand 96)

10 The Maximum Weight Matching Algorithm
MWM: performance throughput: stable (Tassiulas-Ephremides 92; McKeown et al 96; Dai-Prabhakar 00) backlogs: very low on average (Leonardi et al 01; Shah-Kopikare 02) MWM: implementation has cubic worst-case complexity (approx. 27,000 iterations for a 30-port switch) MWM algorithms involve backtracking: i.e. edges laid down in one iteration may be removed in a subsequent iteration algorithm not amenable to pipelining

11 Switch algorithms Better performance Easier implementation 19 19 18 1
Max Wt Matching 19 18 Maximal matching Max Size Matching 19 1 7 Not stable Not stable Stable and low backlogs Better performance Easier implementation

12 Randomized approximation to MWM
Consider the following randomized approximation: At every time - sample d matchings independently and uniformly - use the heaviest of these d matchings to schedule packets Ideally we would like to use a small value of d. However,… Theorem. Even with d = N, this algorithm is not stable. In fact, when d = N, the throughput is at most (Giaccone-Prabhakar-Shah 02)

13 Proof Let Eij be the edge connecting input i to output j, then
Since the edge Eij can be served only if it is chosen by at least one of the d matching, it follows that the throughput is at most 63%

14 Tassiulas’ algorithm Previous matching S(t-1) Random Matching R(t)
Next time MAX Current matching S(t)

15 Tassiulas’ algorithm MAX S(t-1) R(t) W(R(t))=150 W(S(t-1))=160 S(t) 10
40 30 MAX 10 70 10 60 20 S(t-1) R(t) W(S(t-1))=160 W(R(t))=150 S(t)

16 Performance of Tassiulas’ algorithm
Theorem (Tassiulas 98): The above scheme is stable under any admissible Bernoulli IID inputs.

17 Backlogs under Tassiulas’ algorithm

18 Reducing backlogs: the Merge operation
10 50 10 40 30 10 70 Merge 10 60 20 S(t-1) R(t) W(S(t-1))=160 W(R(t))=150 30 v/s 120 130 v/s 30

19 Reducing backlogs: the Merge operation
10 50 10 40 30 10 Merge 70 10 60 20 S(t-1) R(t) W(S(t-1))=160 W(R(t))=150 W(S(t)) = 250

20 Performance of Merge algorithm
Theorem (GPS): The Merge scheme is stable under any admissible Bernoulli IID inputs.

21 Merge v/s Max

22 Use arrival information: Serena
23 7 47 89 3 11 31 2 97 5 S(t-1) The arrival graph W(S(t-1))=209

23 Use arrival information: Serena
23 47 89 3 11 31 2 97 5 S(t-1) The arrival graph W(S(t-1))=209

24 Use arrival information: Serena
23 23 47 89 3 11 31 Merge 97 6 S(t-1) W=121 W(S(t))=243 S(t) 89 3 23 31 97 W(S(t-1))=209

25 Performance of Serena algorithm
Theorem (GPS): The Serena algorithm is stable under any admissible Bernoulli IID inputs.

26 Backlogs under Serena

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