Disk array controller: Difference between revisions

* BackThe back-end interface communicates with the controlled disks. Hence, its protocol is usually [[Advanced Technology Attachment|ATA]] (a.k.a. PATA), [[Serial ATA|SATA]], [[SCSI]], [[Fibre Channel|FC]] or [[Serial Attached SCSI|SAS]].

* FrontThe front-end interface communicates with a computer's [[host adapter]] (HBA, Host Bus Adapter) and uses:

** one of ATA, SATA, SCSI, FC; these are popular protocols used by disks, so by using one of them a controller may transparently [[emulator|emulate]] a disk for a computer.

** somewhat less popular protocol dedicated protocols for a specific solutionsolutions: [[FICON]]/[[ESCON]], [[iSCSI]], [[HyperSCSI]], [[ATA over Ethernet]] or [[InfiniBand]].

In a modern enterprise architecture disk array controllers (sometimes also called '''storage processors''', or '''SPs'''<ref>{{Cite web|url=http://vmtoday.com/2010/03/storage-basics-part-v-controllers-cache-and-coalescing/|title = Storage Basics - Part V: Controllers, Cache and Coalescing|date = 23 March 2010}}</ref>) are parts of physically independent [[disk enclosure|enclosure]]s, such as [[disk array]]s placed in a [[storage area network]] (SAN) or [[network-attached storage]] (NAS) [[Server (computing)|server]]s.

[[Image:Promise Ultra33.jpg|thumb|250px|[[Promise Technology]] ATA RAID controller]]

A simple disk array controller may fit inside a computer, either as a [[Peripheral Component Interconnect|PCI]]/[[PCIe]] [[expansion card]] or just built onto a [[motherboard]]. Such a controller usually provides [[Host adapter|host bus adapter]] (HBA) functionality itself to save physical space. Hence it is sometimes called a '''RAID adapter'''.

{{As of | 2007 | February }} [[Intel]] started integrating their own [[Intel Matrix RAID|Matrix RAID controller]] in their more upmarket motherboards, giving control over 4 devices and an additional 2 SATA connectors, and totalling 6 SATA connections (3Gbit3&nbsp;Gbit/s each). For backward compatibility one IDE connector able to connect 2 ATA devices (100 &nbsp;Mbit/s) is also present.

While hardware RAID controllers werehave been available for a long time, they alwaysinitially required expensive [[Parallel SCSI]] hard drives and aimed at the server and high-end computing market. SCSI technology advantages include allowing up to 15 devices on one bus, independent data transfers, [[hot-swapping]], much higher [[MTBF]].

Around 1997, with the introduction of [[Atapi|ATAPI-4]] (and thus the [[Direct memory accessUDMA|Ultra-DMA-Mode 0]], which enabled fast data- transfers with less [[CPU]] utilization) the first ATA RAID controllers were introduced as PCI expansion cards. Those RAID systems made their way to the consumer market, where thefor users wantedwanting the fault-tolerance of RAID without investing in expensive SCSI drives.

ATAFast consumer drives make it possible to build RAID systems at lower cost than with SCSI, but most ATA RAID controllers lack a dedicated buffer or high-performance XOR hardware for parity calculation. As a result, ATA RAID performs relatively poorly compared to most SCSI RAID controllers. Additionally, data safety suffers if there is no [[Battery (electricity)|battery]] backup to finish writes interrupted by a power outage.

Because the hardware RAID controllers present assembled [[RAID]] volumes, [[operating system]]s aren't strictly required to implement the complete configuration and assembly for each controller. Very often only the basic features are implemented in the [[open-source software]] driver, with extended features being provided through [[binary blob]]s directly by the hardware manufacturer.

For example, in [[FreeBSD]], in order to access the configuration of [[Adaptec]] RAID controllers, users are required to enable [[FreeBSD#OS compatibility layers|Linux compatibility layer]], and use the Linux tooling from Adaptec,{{r|f-aac}} potentially compromising the stability, reliability and security of their setup, especially when taking the [[long term]] view in mind.{{r|lyrics-38}} However, this greatly depends on the controller, and whether appropriate hardware documentation is available in order to write a driver, and some controllers do have open-source versions of their configuration utilities, for example, <code>mfiutil</code> and <code>mptutil</code> is available for FreeBSD since FreeBSD 8.0 (2009),{{r|mfiutil|mptutil}} as well as <code>mpsutil</code>/<code>mprutil</code> since 2015,{{r|mpsutil}} each supporting only their respective device drivers, this latter fact contributing to [[code bloat]].

Some other operating systems have implemented their own generic frameworks for interfacing with any RAID controller, and provide tools for monitoring RAID volume status, as well as facilitation of drive identification through LED blinking, alarm management, [[hot spare disk]] designations and {{section link|data scrubbing#RAID}} from within the operating system without having to reboot into card BIOS. For example, this was the approach taken by [[OpenBSD]] in 2005 with its [[bio(4)]] [[pseudo-device]] driver and the [[bioctl]] utility, which provide volume status, and allow LED/alarm/hotspare control, as well as the sensors (including the [[hw.sensors#drive|drive sensor]]) for health monitoring;<ref name=theo-misc-38/> this approach has subsequently been adopted and extended by [[NetBSD]] in 2007 as well.{{r|sensors-mmath}}

With [[bioctl]], the feature set is intentionally kept to a minimum, so that each controller can be supported by the tool in the same way; the initial configuration of the controller is meant to be performed through card BIOS,{{r|theo-misc-38}} but after the initial configuration, all day-to-day monitoring and repair should be possible with unified and generic tools, which is what [[bioctl]] is set to accomplish.

|publisher= [[FreeBSD]]

|publisher= [[FreeBSD]]

|publisher = [[OpenBSD]]