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Sherlock – Diagnosing Problems in the Enterprise

Sherlock – Diagnosing Problems in the Enterprise. Srikanth Kandula Victor Bahl, Ranveer Chandra, Albert Greenberg, David Maltz, Ming Zhang. Enterprise Management: Between a Rock and a Hard Place. Manageability Stick with tried software, never change infrastructure Cheap

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Sherlock – Diagnosing Problems in the Enterprise

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  1. Sherlock – Diagnosing Problems in the Enterprise Srikanth Kandula Victor Bahl, Ranveer Chandra, Albert Greenberg, David Maltz, Ming Zhang

  2. Enterprise Management: Between a Rock and a Hard Place Manageability • Stick with tried software, never change infrastructure • Cheap • Upgrades are hard, forget about innovation! Usability • Keep pace with technology • Expensive • IT staff in 1000s • 72% of MS IT budget is staff • Reliability Issues • Cost of down-time

  3. Well-Managed Enterprises Still Unreliable Response time of a Web server (ms) .1 .08 85% Normal Fraction Of Requests .06 10% Troubled 0.7% Down .04 .02 0 10 100 1000 10000 10% responses take up to 10x longer than normal How do we manage evolving enterprise networks?

  4. Current Tools Miss the Forest for the Trees Authentication Server Web Server SQL Backend DNS • Monitor Individual Boxes or Protocols • Flood admin with alerts • Don’t convey the end-to-end picture But, the primary goal of enterprise management is to diagnose user-perceived problems! Client

  5. Sherlock Instead of looking at the nitty-gritty of individual components, use an end-to-end approach that focuses on user problems

  6. Challenges for the End-to-End Approach • Don’t know what user’s performance depends on

  7. Auth. Server Web Server SQL Backend DNS Challenges for the End-to-End Approach E.g., Web Connection • Don’t know what user’s performance depends on • Dependencies are distributed • Dependencies are non-deterministic • Don’t know which dependency is causing the problem • Server CPU 70%, link dropped 10 packets, but which affected user? Client

  8. Sherlock’s Contributions • Passively infersdependencies from logs • Builds a unified dependency graph incorporating network, server and application dependencies • Diagnoses user problems in the enterprise • Deployed in a part of the Microsoft Enterprise

  9. Sherlock’s Architecture

  10. Sherlock’s Architecture Network Dependency Graph Servers Inference Engine Web1 1000ms Web2 30ms File1 Timeout + User Observations Clients = List Troubled Components Sherlock works for various client-server applications

  11. Video Server Data Store DNS How do you automatically learn such distributed dependencies?

  12.  Not Practical Strawman: Instrument all applications and libraries Sherlock exploits timing info My Client talks to B My Client talks to C Time t If talks to B, whenever talks to C  Dependent Connections

  13. Strawman: Instrument all applications and libraries  Not Practical Sherlock exploits timing info B B B B B B B C Time t False Dependence If talks to B, whenever talks to C  Dependent Connections

  14. Strawman: Instrument all applications and libraries  Not Practical Sherlock exploits timing info B B C Time t Inter-access time Dependent iff t << Inter-access time If talks to B, whenever talks to C  Dependent Connections As long as this occurs with probability higher than chance

  15. Store Video DNS Dependency Graph Sherlock’s Algorithm to Infer Dependencies • Infer dependent connections from timing

  16. Bill’s Client Store Video DNS Video Store DNS Dependency Graph Sherlock’s Algorithm to Infer Dependencies • Infer dependent connections from timing • Infer topology from Traceroutes & configurations Video Store Bill DNS Bill Video Bill Watches Video • Works with legacy applications • Adapts to changing conditions

  17. But hard dependencies are not enough…

  18. Video Store DNS But hard dependencies are not enough… Bill’s Client Video Store Bill DNS Bill Video p3 p1 p1=10% p2 p2=100% Bill watches Video If Bill caches server’s IP  DNS down but Bill gets video  Need Probabilities Sherlock uses the frequency with which a dependence occurs in logs as its edge probability

  19. How do we use the dependency graph to diagnose user problems?

  20. Video Store DNS Diagnosing User Problems Bill’s Client Video Store Bill DNS Bill Video Bill Watches Video • Which components caused the problem? • Need to disambiguate!!

  21. Bill Sales Video Video2 Store Sales DNS Bill Sees Sales Diagnosing User Problems Bill’s Client Video2 Store Video Store Bill DNS Bill Video Paul Video2 Bill Watches Video Paul Watches Video2 • Which components caused the problem? • Disambiguate by correlating • Across logs from same client • Across clients • Prefer simpler explanations • Use correlation to disambiguate!!

  22. Will Correlation Scale?

  23. Will Correlation Scale? Microsoft Internal Network O(100,000) client desktops O(10,000) servers O(10,000) apps/services O(10,000) network devices Building Network Corporate Core Campus Core Dependency Graph is Huge Data Center

  24. Will Correlation Scale? Can we evaluate all combinations of component failures? The number of fault combinations is exponential! Impossible to compute!

  25. Scalable Algorithm to Correlate Only a few faults happen concurrently • But how many is few? • Evaluate enough to cover 99.9% of faults • For MS network, at most 2 concurrent faults  99.9% accurate Exponential  Polynomial

  26. Scalable Algorithm to Correlate Only a few faults happen concurrently Only few nodes change state • But how many is few? • Evaluate enough to cover 99.9% of faults • For MS network, at most 2 concurrent faults  99.9% accurate Exponential  Polynomial

  27. Scalable Algorithm to Correlate Only a few faults happen concurrently Only few nodes change state • But how many is few? • Evaluate enough to cover 99.9% of faults • For MS network, at most 2 concurrent faults  99.9% accurate • Re-evaluate only if an ancestor changes state Reduces the cost of evaluating a case by 30x-70x Exponential  Polynomial

  28. Results

  29. Experimental Setup • Evaluated on the Microsoft enterprise network • Monitored 23 clients, 40 production servers for 3 weeks • Clients are at MSR Redmond • Extra host on server’s Ethernet logs packets • Busy, operational network • Main Intranet Web site and software distribution file server • Load-balancing front-ends • Many paths to the data-center

  30. What Do Web Dependencies in the MS Enterprise Look Like?

  31. What Do Web Dependencies in the MS Enterprise Look Like? Auth. Server Client Accesses Portal

  32. What Do Web Dependencies in the MS Enterprise Look Like? Auth. Server Client Accesses Portal

  33. What Do Web Dependencies in the MS Enterprise Look Like? Auth. Server Client Accesses Portal Client Accesses Sales Sherlock discovers complex dependencies of real apps.

  34. What Do File-Server Dependencies Look Like? Backend Server 1 Backend Server 2 8% Backend Server 3 File Server Auth. Server WINS DNS Proxy 5% 1% Backend Server 4 5% 10% 6% 2% .3% 100% Client Accesses Software Distribution Server Sherlock works for many client-server applications

  35. Sherlock Identifies Causes of Poor Performance Component Index Time (days) Dependency Graph: 2565 nodes; 358 components that can fail 87% of problems localized to 16 components

  36. Sherlock Identifies Causes of Poor Performance Inference Graph: 2565 nodes; 358 components that can fail Component Index Time (days) Corroborated the three significant faults

  37. Sherlock Goes Beyond Traditional Tools • SNMP-reported utilization on a link flagged by Sherlock • Problems coincide with spikes Sherlock identifies the troubled link but SNMP cannot!

  38. Comparing with Alternatives • Dataset of known (fault, observations) pairs • Accuracy = 1 – (Prob. False Positives + Prob. False Negatives) SCORE (non-probabilistic) 53%

  39. Comparing with Alternatives • Dataset of known (fault, observations) pairs • Accuracy = 1 – (Prob. False Positives + Prob. False Negatives) Shrink (probabilistic) 59% SCORE (non-probabilistic) 53%

  40. Comparing with Alternatives • Dataset of known (fault, observations) pairs • Accuracy = 1 – (Prob. False Positives + Prob. False Negatives) Sherlock 91% Shrink (probabilistic) Shrink 59% SCORE (non-probabilistic) 53% Sherlock outperforms existing tools!

  41. Conclusions • Sherlock passively infers network-wide dependencies from logs and traceroutes • It diagnoses faults by correlating user observations • It works at scale! • Experiments in Microsoft’s Network show • Finds faults missed by existing tools like SNMP • Is more accurate than prior techniques • Steps towards a Microsoft product

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