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PEDS17

Project: Performance Evaluation of Distributed Systems

https://disco.informatik.uni-kl.de/index.php/teaching/project

Task 1:

a). Analyze one day of wikipedia request:

  • Find most popular object
  • Max, Min, Mean object size

b). Determine hit ratios of caching the 10GB most-frequently requested objects.

Task 2:

a). Analyze 7 days of (anonymized) Wikipedia requests

  • Difference between daily 100 most-popular objects
  • Popularity Plot
  • Object size histogram
  • Object size CDF over time

b). Implement and evaluate Least-Recently-Used (LRU)

  • Get the Object Hit Ratio and Byte Hit Ratio for a 10GB LRU cache both for 1 day and 7 days of wikipedia requests
  • Common implementation: list + unordered_map
  • List keeps order of cached objects
  • Map allows to lookup position in list, when object is requested

Task 3:

a). Evaluate common caching policies

  • Policies: LRU, FIFO, GDSF, LFU-DA, GDS, S2LRU
  • Cache capacities: 1GB, 10GB, 30GB, 50GB, 100GB, 500GB, 1000GB
  • Measure Object/Byte Hit ratio
  • Measure throughput: how many requests per second is each policy able to process?

b). Literature research: Some more cache policies

Task 4:

a). Quantify the problem of one-hit-wonders:

  • How many requests go to objects that are only ever requested once
  • .. only ever requested twice
  • ... only ever requested four times
  • ... only ever requested 8, 16, 32, 64, 128 times.

b). Evaluate the FILTER policy to fight the one-hit-wonders problem

  • When a miss happens: FILTER admits only if this object has received N requests so far
  • For admitted objects: standard LRU policy
  • Evaluate hit ratios and throughput
  • Analyze throughput and memory consumption

Memory Consumption: Used memusg script which measures peak memory usage

Task 5:

a). Research bloom filters and counting bloom filters

b). Implement a bloom filter to solve the overhead problem

  • Incorporate bloom filter into your filter
  • Evaluate memory overhead and hit ratio for different parameters

Start with l=1MB and n=8

  • Also check

i). l=512KB, 2MB, 4MB, 8MB

ii). n=4, n=16, n=32

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