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Depending on your application needs, Elastic Block Store’s volumes can be configured for optimal performance and higher availability. In this session, we will present the different design characteristics of EBS Standard and Provisioned IOPS volumes, provide technical insights on how to think about EBS performance and availability, and share best practices to achieve higher availability and performance.
Citation preview
Jafar Shameem
Business Development Manager
Eric Anderson
CTO and Co-Founder, CopperEgg
Understanding Amazon EBS Availability and Performance
Agenda
• Overview of Elastic Block Store
• Some key concepts
• Performance
• Availability
Storage Options on AWS
Block Storage (Elastic Block Store)
Object Storage (S3, Glacier)
Use for: • Access to raw
unformatted block level storage
• Persistent Storage
Use for: • Pictures, videos,
highly durable media storage
• Cold storage for long-term archive
Amazon Elastic Block Store (EBS) Elastic Block Storage: Persistent Storage for EC2
Feature Details
High performance file system
Mount EBS as drives and format as required
Flexible size Volumes from 1GB to 1TB in size
Secure Private to your instances
Available Replicated within an Availability Zone
Backups Volumes can be snapshotted for point in time restore
Monitoring Detailed metrics captured via Cloud Watch
What are some of our customers doing with EBS?
Enterprises
Enterprise workloads are built on block
storage
Oracle, SAP, Microsoft
Applications
Convenient, cost-effective,
reliable file server
Gaming/Social/ Mobile/Education
Very high performance
and consistent IO
for NoSQL and relational
DBs
Marketing / Analytics
Fast sequential IO
access
Key EBS concepts
• Standard and Provisioned IOPS
Volumes
• Block Size
• Queue Depth
• Snapshots
Standard and Provisioned IOPS Volume Types
Standard Volumes Provisioned IOPS Volumes
Optimized for Workloads with low or moderate IOPS needs and occasional bursts.
Transactional workloads requiring consistent IOPS.
Volume Attributes
Up to 1 TB, average 100 IOPS per volume. Best effort performance. Can be striped together for larger size and higher IOPS.
Up to 1TB, 2,000 IOPS per volume. Consistent IOPS. Can be striped together for larger size and higher IOPS.
Workloads File server, Log processing, Websites, Analytics, Boot, etc.
Business applications, MongoDB, SQL server, MySQL, Postgres, Oracle, etc.
Block Size
Queue Depth
Maintain a number of pending I/O requests to get the most out of your Provisioned IOPS volume. The volumes must maintain an average queue length of 1 (rounded up to the nearest whole number) for every 200 provisioned IOPS in a minute
Snapshots
• Create snapshots (backups) of any Amazon EBS volume.
• The volume need not be attached to a running instance in order to take a
snapshot.
• These snapshots can be used to create multiple new Amazon EBS volumes,
expand the size of a volume, or move volumes across Availability Zones.
• The snapshots can be shared with specific AWS accounts or made public.
• You can use this functionality to increase the size of an existing volume, rapidly
replicate development and testing environments, or use Snapshot Copy to copy
snapshots to another region for disaster recovery or regional expansion.
Performance
• Architecting for Performance
– Avoid throughput saturation
– Striping
• Achieving Consistent Performance
– Pre-warm Provisioned IOPS volumes
– Plan for snapshot
• Snapshot Performance
Architecting for Performance: Use EBS Optimized Instances
Architecting for Performance: Avoid Throughput Saturation
• Example:
– Cluster Compute instance types have 2Gb/s bandwidth to EBS, more than 6 PIOPS volumes at 2000 IOPS each will saturate 2 Gb/s network
– EBS Optimized M3.2Xlarge instance has 1 Gb/s bandwidth dedicated to EBS, more than 12 PIOPS volumes at 500 IOPS each will saturate the 1 GB/s network
Architecting for Performance: Striping
sudo mdadm --verbose --create /dev/md0 --level=10 --chunk=256 --raid-
devices=4 /dev/sdh1 /dev/sdh2 /dev/sdh3 /dev/sdh4
Achieving Consistent Performance: Pre-warm Provisioned
IOPS volumes
• There is a 5 to 50 percent performance reduction in IOPS when you first access the data on a Provisioned IOPS volume.
• Write to all blocks on volumes before first use
– $ dd of=/dev/md0 if=/dev/null
Achieving Consistent Performance: Plan for Snapshot
To minimize the impact of snapshots on performance of a master node:
– create snapshots from a read replica of your data
– Plan snapshots during off-peak usage
Snapshot Performance
• To improve snapshot performance
– Increase the frequency of snapshots
Benchmarking performance
• http://docs.aws.amazon.com/AWSEC2/latest/UserGuide/EBSPerformance.html
#benchmark_piops
• fio
• Linux, Windows • For benchmarking I/O performance. (Note that fio has a dependency on libaio-devel.)
• Oracle ORION • Linux, Windows • For calibrating the I/O performance of storage systems to be used with Oracle databases.
• SQLIO • Windows • For calibrating the I/O performance of storage systems to be used with Microsoft SQL Server.
Testing random 4K reads
• One Volume: ~200 MongoOPS with some variability, <1mb/s
• Loaded instance: ~ 1000 MongoOPS with some variability <10mb/s
PIOPS
+
EBS
• One Volume: 2000 MongoOPS with <1% variability, 3mb/s • Loaded Instance: 20000 MongoOPS with <1% variability, 60mb/s
SSD • Hi1.4xlarge ephemeral: ~64,000 MongoOPS with low variability, ~245mb/s
Stab
le Testing random 4K reads
EBS
PIOPS
+ SSD PIOPS
+
Stab
le
Availability
• RAID
• Snapshots
RAID
• RAID 10: provides increased redundancy
– Replace EBS volume without application downtime
– Increases read throughput
– However, 50% reduction of provisioned aggregate write performance
– E.g., MongoDB optimized around the benefits of RAID 10
• RAID 0:
– All EBS volumes are replicated in the same AZ
– Increased throughput
Snapshots
CopperEgg: EBS Use Case
• How CopperEgg uses EBS
• EBS vs Provisioned IOPS EBS
• EBS and RAID
• Backup/Snapshot best practices
• Filesystem selection and tuning
• Monitoring/Migrations/Planning
How CopperEgg uses EBS
• Real-time monitoring (every 5s) – System information
– Processes
– Synthetic HTTP/TCP/etc
– Application metrics
– Tons more..
• Requirements: – Store many terabytes of data
– Persist the data over long periods of time
– Backups (use snapshots)
– High IO: 50-60k+ ops/s per node • SSD + Provisioned IOPS EBS
– Consistent IO behavior (non-spikey)
EBS vs Provisioned IOPS EBS
• Standard EBS
– Good for low IO volume
– Bursty workloads may be a good
fit: do the math
• Provisioned IOPS EBS
– Great for steady IO patterns that
need consistency
– Not always more expensive than
standard!
– Be sure to use the IOPS you
provision!
EBS and RAID
• Which RAID? – Depends on your use case, but:
• We use stripes (RAID 0) for most things – Good performance, we build our fault tolerance at a different level
• RAID 10 (stripe of mirrors) – Good RAID0 performance, but increase in fault tolerance due to mirrors
– Twice the cost of RAID 0
• RAID 0+1 (mirror of stripes) – Don’t do this – same performance, worse fault tolerance
• RAID 5 (stripe with parity) – Could be dangerous: software RAID 5 can be bad if you have any write caching enabled.
– Maybe RAID 6 (dual parity) is an option..
• Block size – Use an appropriate stripe size for best results
• We use 64kb – but you need to test various configs to get the best fit for your application
Backup/Snapshot best practices
• Snapshot regularly – At least once per day, more if you can
– First snapshots take a while, subsequent are faster
– Schedule for when your IO load is lowest to reduce impact • We do it at around 9pm CST
• Use consistent naming for snapshots – {hostname}-{raid device}-{device}-{timestamp}
• Use the API for creation – Faster kickoff, more likely to be consistent (script it!) – ec2-create-snapshot –d “{hostname}-{raid device}-{device}-{timestamp}” vol-d726382
• Move older snapshots to S3/Glacier for long-term storage
• RAID makes this a bit more complex: – Make sure you unmount/snapshot/remount your file system, or use fsfreeze to keep
consistent snapshots!
Choosing a good file system
• We like ext3/4, but we love XFS
– High performance, consistent
– Robust and lots of options for tweaking/adjusting as needed
• Our favorite mount options: (your mileage may vary) – inode64, noatime, nodiratime, attr2, nobarrier, logbufs=8, logbsize=256k, osyncisdsync, nobootwait, noauto
– Yields great performance, reduces unnecessary writes, stable
• We like ZFS a lot too, but we want to see more runtime on linux first
– But FreeBSD/ZFS would be a fine choice
• However: test your workload!
– File systems behave differently under different workloads
EBS/File system performance tuning
• Tuning file systems:
– Set the scheduler to use ‘deadline’ (for each disk in RAID array/EBS): • [as root] echo deadline > /sys/block/[disk device]/queue/scheduler
– Adjust how aggressively the cache is written to disk. Tune these back if you are
bursty in write IO:
• vm.dirty_ratio=30
• vm.dirty_background_ratio=20
• Track what you change!
– Before changing anything, monitor it
– After you make the change, monitor it
– Then: KEEP monitoring it – things can change over time in unexpected ways
Monitoring
• Observing: – iostat –xcd –t 1
• Watch the sum of r/s and w/s – this is your IOPS metric. For PIOPS, you want it close to the provisioned amount. We monitor this using CopperEgg custom metrics, and alert if it goes low, or high.
– grep –A 1 dirty /proc/vmstat • If nr_dirty approaches nr_dirty_threshold, you need to tune down vm.dirty to flush writes more often.
• Reference: http://docs.neo4j.org/chunked/stable/linux-performance-guide.html
• Useful stats to capture: – In /proc/fs/xfs/stat
• xs_trans* -> transactions
• xs_read/write* -> read/write operations stats
• xb_* -> buffer stats
• Ignore SMART - does not work for EBS
• Watch the console log – Use the AWS API to look for warning signs of EBS issues
Migrations and Capacity Planning
• Using PIOPS? – Plan on a data migration path if you need to increase PIOPS
• You can’t (yet) increase IOPS on the fly
• Migration steps from an EBS backed RAID: 1. Snapshot 1hr before, then again, and again – each time it takes less time
2. Stop all services
3. Unmount the filesystem
4. Stop the RAID (mdadm –stop /dev/md0)
5. Take final snapshot
6. Create new volumes based on last snapshot
7. RAID attach new volumes – mdadm should detect the array and magically make it work.
8. Mount the filesystem
9. Restart services
Resources & Questions
• Jafar Shameem | [email protected] | @rafaj
• http://aws.amazon.com/ebs/
• Amazon Provisioned IOPS
– http://copperegg.com/amazon-provisioned-iops-ebs/
• Benchmarking EBS performance:
– http://docs.aws.amazon.com/AWSEC2/latest/UserGuide/EBSPerformance.html
• Stratalux: Putting Amazon’s Provisioned IOPS to the test
– http://www.stratalux.com/2012/08/09/putting-amazon’s-provisioned-iops-to-the-test/
• MongoDB on AWS: – http://docs.mongodb.org/ecosystem/platforms/#amazon-web-services-ec2