Should I run my database off of a RAID 5 configuration?
Solution 1:
RAID 10 is usually recommended since the I/O is so random. Here's an example. The calculations are a bit simplified, but pretty representative.
Let's say you have a 6 drive array and your drives can do 100 I/Os per second (IOPS). If you have 100% reads, all six drives will be used and you'll have about 600 IOPS for both RAID 10 and RAID 5.
The worst case scenario is 100% writes. In that scenario, RAID 10's performance will be cut in half (since each write goes to two drives), so it will get 300 IOPS. RAID-5 will convert each write into two reads followed by two writes, so it will get 1/4 the performance or about 150 IOPS. That's a pretty big hit.
Your actual read/write pattern will be somewhere in-between these two extremes, but this is why RAID 10 is usually recommended for databases.
However, if you don't have a busy database server, then you could even do RAID-6. I often do that if I know the database isn't going to be bottleneck since it gives you much more safety than RAID 10 or RAID 5.
Solution 2:
Transactional databases
RAID-5 is relatively slow to write as the controller needs to load in enough data to recalculate the parity on a write. Write operations will incur at least four disk operations:
Reading in the parity block
Reading in the old block (assuming it is not already in cache) to XOR the value with the parity block.
Writing the new parity block (old parity block XOR old data block XOR new data block)
Writing the new data block.
If the system does not use write-back caching this means that all of these oprations are on the critical path for I/O completion. Often, this is the case with database writes - in fact, Microsoft (for example) has a certification program for SAN equipment for use with SQL server that requires the vendors to guarantee this behaviour. Sometimes older RAID-5 equipment did not use this optimisation and had to recalculate the parity from the whole stripe.
RAID-10 has a mirror for every single drive and does not need to read additional data to calculate parity. This means that writes need much less physical I/O.
RAID-50 sits somewhere in the middle, with the volume split into multiple RAID-5 volumes, which are in turn striped. On a RAID-50 made from groups striped in a 3+1 scheme a write generates at most three additional disk I/O requests. If you feel so inclined you can view RAID-5 and RAID-10 as special cases of RAID-50. RAID-50 is mainly used to provide large volumes across many physical disks
Other parity schemes such as RAID-6 (a parity scheme with two redundant disks per set) also exist, Modern disks are large enough that rebulding an array can take quite a long time - long enough that the risk of a second disk failure during the rebuild is quite significant. RAID-6 mitigates this risk by having a second parity disk, requiring three disk failures to cause data loss. A similar trick to RAID-50 schemes can be used to make RAID-60 arrays.
Finally, a single mirrored pair (known as RAID-1) can provide redundancy and good enough performance for some tasks. In particular you will probably find that RAID-1 gves you sufficient throughput for quite a lot of database log traffic. More on this below.
If you have a write-heavy workload you will probably get a performance gain from a RAID-10 volume. This can be a win as you can probably get your required throughput from a smaller number of physical disks, assuming the disks have enough space). Some items such as logs or temporay areas on a database server should be on RAID-1 or RAID-10 volumes, as these get lots of write traffic.
Logs
Log volumes are characterised by a mostly sequential data access pattern, and are essentially a ring buffer consisting of commands along the lines of 'write this data to this block' They are written out as a producer by the core DBMS engine and processed as a conumer by the log reader function. A single mirrored pair will actually handle quite a lot of log traffic.
Read-heavy systems and file servers
On a read-heavy system such as a data warehouse you may want to use one or more RAID-5 volumes. On a file server, disk accesses will largely be done on a whole file basis, so writes will probably write out most of the blocks that make up the parity block anyway. In this case the performance penalyt for RAID-5 will be lighter.
In the past the cost savings on disk may have been significant but this is less likely to be an issue now.
Write-back caching and RAID-5
On a SAN or internal RAID controller with a battery-backed cache you may be able to enable 'Write-back' caching. This caches writes and returns control to the application. The I/O is reported by the controller as completed. However, it does not necessarily write the data out to disk immediately. This facility allows RAID-5 parity read/write operations to be substantially optimised and can soften the write performance penalty for RAID-5x volumes.
However, this still carries a small risk of data integrity issues. The host system has been told that this write has been completed when this is not in fact the case. It is possible for a hardware failure create data inconsistencies between (say) log and data volumes on a database server. For this reason, write-back caching is not recommended for transactional systems, although it may be a performance win for something like an ETL process.
Summary
Disk space is so cheap nowadays that transactional systems should probably use RAID-1 or RAID-10 for log volumes and RAID-10 for data volumes. The physical disk size is likely to be much larger than the database and RAID-10 will allow more write throughput for the same number of disks, potentially reducing the number of disk volumes needed to support the system.
On something like a data warehouse you can still chew space with large, heavily indexed fact tables so you might get small price win with RAID-5 or RAID-50 data volumes. However logs and tempdb should still be placed on a RAID-10 volume as they will probably get a lot of work during ETL processing. However, the cost saving on disk is likely to be fairly small.
Solution 3:
Depends on how much writing you're doing.
If it's a fairly lightweight "web app" then you're unlikely to see any performance hit on RAID5.
If you're building a multi-GB data warehouse with large ETL's, then the write buffer on the RAID 5 will quickly overflow and your straight into the "poor write performance" of RAID 5.
Every RAID5 write will cause at least 3 writes (plus a CRC calculation). When buffered, this is fine and fast (small short bursts of activity - single record updates and inserts). If this is sustained writes (large bulk insert / updates) then it will be noticed.
It's a balance between performance and space. RAID 10 (mirror of striped drives) gives both performance and resiliency, but 50% reduction in capacity.
RAID5 gives higher capacity, good read performance but poor (large) write performance.
Solution 4:
Well, it depends heavily on your fault/risk tolerance. RAID5 has a lot of issues. My DB server currently have two mirrored drives, and if I was to scale that up, I'd go for something with more parity, probably RAID6 or RAID10.
Also, if your application is uptime-critical, I'd probably recommend having two database servers with replication instead, master-master or hot spare or whatever. RAID only helps against disk failures, but there's a lot more that could go wrong on a server :)
Solution 5:
RAID 1, that's my final answer
Reasons:
mirrored pair gives adequate redundancy for failed disks and the RAID continues to function to the last disk.
mirrored pair yields greater I/O performance for reads if you place your data and indexes carefully... [hint: Use seperate volumes for data and its index(s)]. You can obtain even more performance by duplexing your controllers.