X-RAY: A Non-Invasive Exclusive Caching Mechanism for RAIDs - PowerPoint PPT Presentation

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X-RAY: A Non-Invasive Exclusive Caching Mechanism for RAIDs

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X-RAY: A Non-Invasive Exclusive Caching Mechanism for RAIDs Lakshmi N. Bairavasundaram Muthian Sivathanu Andrea C. Arpaci-Dusseau Remzi H. Arpaci-Dusseau – PowerPoint PPT presentation

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Title: X-RAY: A Non-Invasive Exclusive Caching Mechanism for RAIDs


1
X-RAY A Non-Invasive Exclusive Caching Mechanism
for RAIDs
  • Lakshmi N. Bairavasundaram
  • Muthian Sivathanu
  • Andrea C. Arpaci-Dusseau
  • Remzi H. Arpaci-Dusseau

ADvanced Systems Laboratory Computer Sciences
Department University of Wisconsin Madison
2
Introduction
  • Caching in modern systems
  • Multiple levels
  • Storage 2-level hierarchy
  • Level 1 File system (FS) cache
  • Software-managed
  • Main memory of host/client
  • LRU-like cache replacement
  • Level 2 RAID cache
  • Firmware-managed
  • Memory inside RAID system
  • Usually LRU replacement

3
Introduction contd.
  • LRU
  • Replace LRU block
  • Cache placement on read

LRU
MRU
39
4
Introduction contd.
  • LRU
  • Replace LRU block
  • Cache placement on read
  • 2 levels of LRU
  • Redundant contents

FS Cache
..
10
LRU
MRU
RAID Cache
..
MRU
10
LRU
5
Introduction contd.
  • LRU
  • Cache placement on read
  • Replace LRU block
  • 2 levels of LRU
  • Redundant contents
  • Goal
  • Exclusive caching

FS Cache
LRU
10
11
12
.
MRU
RAID Cache
10
LRU
11
12
.
MRU
6
Improved RAID Caching
  • Multi-Queue (Zhou et al. 2001)
  • Add frequency component to cache policy
  • Not strictly exclusive!
  • DEMOTE (Wong and Wilkes 2002)
  • Change interface to disk
  • File system issues cache place command
  • Has perfect information and hence perfectly
    exclusive caches
  • Interface changes difficult to deploy

7
Ideal RAID Cache
  • Exclusive caching
  • File system and RAID caches should have different
    contents
  • Global LRU
  • Known to work well
  • RAID cache should be a victim cache
  • No interface changes

FS Cache
.
MRU
Victim Block
RAID Cache
Block Read

LRU
8
X-RAY
  • Observes disk traffic
  • Reads and writes to data and metadata
  • Builds a model of the FS cache
  • Uses semantic knowledge
  • Predicts size and contents of FS cache
  • Identifies set of exclusive blocks
  • Recent victims of the FS cache
  • Reads blocks from disk into cache
  • Result
  • A nearly exclusive cache without interface changes

Host
File system cache
RAID
X-RAY
Model of FS cache
RAID cache
9
Talk Outline
  • Introduction
  • File Systems
  • Information and Inferences
  • X-RAY Cache Design
  • Results
  • Conclusion

10
File System Operation
  • Applications perform file reads and writes
  • File system (Unix)
  • Translates file accesses to disk block requests
  • Metadata
  • To maintain application data on disk and manage
    disk blocks
  • Periodically written to disk
  • Examples inodes, bitmap blocks

11
File System Operation
  • Inode
  • Pointers to data blocks
  • File access information

Latest access time
File
Inode
Pointers to data blocks
Data Blocks
12
File System Operation
  • File access
  • Use inode to obtain pointers to disk data blocks
  • Read corresponding blocks from disk if they are
    not in FS cache
  • Update the access time information in inode
  • Metadata updates
  • Periodically check for dirty inodes and write
    to disk

13
The Problem
  • To observe disk traffic and infer the contents of
    FS cache
  • Why difficult?
  • FS cache size changes over time
  • Shares main memory with virtual memory system

14
The Problem
  • To observe disk traffic and infer the contents of
    FS cache
  • Why difficult?
  • FS cache size changes over time
  • Disk cannot observe all FS-level accesses

10
11
12
Read block
FS Cache
10
11
12
LRU
MRU
Disk Read
RAID
FS Cache Model
10
11
12
MRU
LRU
15
The Problem
  • To observe disk traffic and infer the contents of
    FS cache
  • Why difficult?
  • FS cache size changes over time
  • Disk cannot observe all FS-level accesses

10
13
Read block
FS Cache
10
11
12
LRU
MRU
Disk Read
RAID
FS Cache Model
10
11
12
MRU
LRU
16
The Problem
  • To observe disk traffic and infer the contents of
    FS cache
  • Why difficult?
  • FS cache size changes over time
  • Disk cannot observe all FS-level accesses

Read block
FS Cache
10
12
13
LRU
MRU
RAID
FS Cache Model
11
12
13
MRU
LRU
17
The Problem
  • To observe disk traffic and infer the contents of
    FS cache
  • Why difficult?
  • FS cache size changes over time
  • Disk cannot observe all FS-level accesses
  • Key observation
  • We need information about accesses that hit in FS
    cache
  • File system maintains access information in inodes

Read block
FS Cache
10
12
13
LRU
MRU
RAID
FS Cache Model
11
12
13
MRU
LRU
18
Talk Outline
  • Introduction
  • File Systems
  • Information and Inferences
  • X-RAY Cache Design
  • Results
  • Conclusion

19
Information
  • Obtain information from observing disk traffic
  • Knowledge of file system structures and
    operations
  • File system maintains time of last access in
    inodes
  • Periodic inode writes
  • Assuming whole file access, all blocks are in FS
    cache
  • Assume file system cache policy is LRU

20
Inferences
  • Read for data block
  • Block will be placed in file system cache (MRU
    block)
  • Read for previously read data block
  • Block became victim in file system cache
  • Blocks with an earlier access time should also be
    victims
  • Inode write new access time , no disk read
    observed
  • All blocks belonging to file are in FS cache
  • Other blocks with later access time should also
    be present

21
Talk Outline
  • Introduction
  • File Systems
  • Information and Inferences
  • X-RAY Cache Design
  • Results
  • Conclusion

22
Design
Block number
Access time
  • Recency list (R-list)
  • List of data blocks ordered by access time
  • Cache Begin (CB) pointer
  • Divides R-list into inclusive and exclusive
    regions
  • RAID Cache contents
  • Subset of blocks in exclusive region

MRU
A, 1
LRU
Inclusive region
Exclusive region
CB
Blocks the RAID should cache
Blocks expected to be in FS cache
23
Disk Read
LRU
MRU
A , 1
B , 1
C , 2
D , 3
E , 3
F , 4
Inclusive region
Exclusive region
CB
24
Disk Read
LRU
MRU
A , 1
B , 1
C , 2
D , 3
E , 3
F , 4
Exclusive region
Inclusive region
CB
25
Disk Read
LRU
MRU
A , 1
B , 1
C , 2
D , 6
E , 3
F , 4
Exclusive region
Inclusive region
CB
26
Inode Write Access time change
LRU
MRU
A , 1
B , 1
C , 2
D , 3
E , 4
F , 5
G , 7
Exclusive region
Inclusive region
CB
27
Inode Write Access time change
LRU
MRU
A , 1
B , 1
C , 2
D , 3
E , 4
F , 5
G , 7
Exclusive region
Inclusive region
CB
28
Inode Write Access time change
D , 6
E , 6
LRU
MRU
A , 1
B , 1
C , 2
F , 5
G , 7
Exclusive region
Inclusive region
CB
29
X-RAY Cache
RAID Cache (size 2 blocks)
LRU
MRU
A , 1
B , 1
C , 2
F , 5
D , 6
E , 6
G , 7
Exclusive region
Inclusive region
CB
  • Keep track of additions to window in exclusive
    region

30
X-RAY Cache
RAID Cache (size 2 blocks)
LRU
MRU
A , 1
B , 1
C , 2
F , 5
D , 6
E , 6
G , 7
Exclusive region
Inclusive region
CB
  • Read newly-added blocks from disk
  • Replace blocks no longer in the window
  • Additional disk bandwidth
  • Idle time, extra internal bandwidth, freeblock
    scheduling

31
Talk Outline
  • Introduction
  • File Systems
  • Information and Inferences
  • X-RAY Cache Design
  • Results
  • Tracking FS Cache Contents
  • RAID Cache Performance
  • Conclusion

32
Results Tracking
  • Accurate size and content prediction
  • Highly responsive to FS cache size changes
  • Tolerates changes in inode write interval
  • Partial file reads
  • X-RAY performs well if percentage of partially
    accessed files is lt 40 (typical traces have less
    than 30)

33
Results Cache Performance
  • Performs better than LRU and Multi-Queue
  • Close to DEMOTE, in spite of imperfect
    information
  • Hit rate advantage translates to lower read
    latency

34
Additional Results
  • File system cache policy is not LRU
  • Clock, 2Q
  • X-RAY performs nearly as well as before
  • It performs better than both LRU and Multi-Queue
  • Idle time requirements
  • X-RAY reads blocks into cache only during idle
    time
  • It performs well if idle time is greater than
    one-third of actual idle time observed in the
    trace
  • More in the paper

35
Conclusion
  • Easy deployment is an important goal in
    developing technology
  • Avoid interface changes use non-invasive
    mechanisms
  • Higher-level systems maintain various pieces of
    information about data they manage
  • Provide low-level systems with basic semantic
    knowledge
  • Semantic intelligence for managing RAID caches
  • Use access information in metadata to track file
    system cache contents and cache exclusive blocks
  • In spite of imperfect information, X-RAY performs
    nearly as well as changing the interface
  • Semantically-smart Disk Systems
  • Availability, security and performance
    improvements

36
Questions ?
  • ADvanced Systems Laboratory (ADSL)
  • Computer Sciences, University of
    Wisconsin-Madison
  • http//www.cs.wisc.edu/adsl
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