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4.4. RAID Levels and Linear Support
RAID supports various configurations, including levels 0, 1, 4,
5, and linear. These RAID types are defined as follows:
Level 0 — RAID level 0, often
called "striping," is a performance-oriented striped data
mapping technique. This means the data being written to the
array is broken down into strips and written across the
member disks of the array, allowing high I/O performance at
low inherent cost but provides no redundancy. The storage
capacity of a level 0 array is equal to the total capacity
of the member disks in a Hardware RAID or the total capacity
of member partitions in a Software RAID.
Level 1 — RAID level 1, or
"mirroring," has been used longer than any other form of
RAID. Level 1 provides redundancy by writing identical data
to each member disk of the array, leaving a "mirrored" copy
on each disk. Mirroring remains popular due to its
simplicity and high level of data availability. Level 1
operates with two or more disks that may use parallel access
for high data-transfer rates when reading but more commonly
operate independently to provide high I/O transaction
rates. Level 1 provides very good data reliability and
improves performance for read-intensive applications but at
a relatively high cost. [2] The storage capacity of the level 1 array is
equal to the capacity of one of the mirrored hard disks in a
Hardware RAID or one of the mirrored partitions in a
Software RAID.
Level 4 — Level 4 uses parity
[3] concentrated on a single disk drive to protect
data. It is better suited to transaction I/O rather than
large file transfers. Because the dedicated parity disk
represents an inherent bottleneck, level 4 is seldom used
without accompanying technologies such as write-back
caching. Although RAID level 4 is an option in some RAID
partitioning schemes, it is not an option allowed in Red
Hat Enterprise Linux RAID installations. [4] The storage capacity of Hardware RAID level 4
is equal to the capacity of member disks, minus the
capacity of one member disk. The storage capacity of
Software RAID level 4 is equal to the capacity of the
member partitions, minus the size of one of the partitions
if they are of equal size.
Level 5 — This is the most common
type of RAID. By distributing parity across some or all of
an array's member disk drives, RAID level 5 eliminates the
write bottleneck inherent in level 4. The only performance
bottleneck is the parity calculation process. With modern
CPUs and Software RAID, that usually is not a very big
problem. As with level 4, the result is asymmetrical
performance, with reads substantially outperforming
writes. Level 5 is often used with write-back caching to
reduce the asymmetry. The storage capacity of Hardware RAID
level 5 is equal to the capacity of member disks, minus the
capacity of one member disk. The storage capacity of
Software RAID level 5 is equal to the capacity of the member
partitions, minus the size of one of the partitions if they
are of equal size.
Linear RAID — Linear RAID is a
simple grouping of drives to create a larger virtual
drive. In linear RAID, the chunks are allocated sequentially
from one member drive, going to the next drive only when the
first is completely filled. This grouping provides no
performance benefit, as it is unlikely that any I/O
operations will be split between member drives. Linear RAID
also offers no redundancy and, in fact, decreases
reliability — if any one member drive fails, the
entire array cannot be used. The capacity is the total of
all member disks.
[2]
RAID level 1 comes at a high cost because you write the
same information to all of the disks in the array, which
wastes drive space. For example, if you have RAID level 1
set up so that your root (/) partition exists on two 40G
drives, you have 80G total but are only able to access 40G
of that 80G. The other 40G acts like a mirror of the first
40G.
[3]
Parity information is calculated based on the contents
of the rest of the member disks in the array. This
information can then be used to reconstruct data when
one disk in the array fails. The reconstructed data can
then be used to satisfy I/O requests to the failed disk
before it is replaced and to repopulate the failed disk
after it has been replaced.
[4]
RAID level 4 takes up the same amount of space as RAID
level 5, but level 5 has more advantages. For this
reason, level 4 is not supported.