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RAIDCTL(8) FreeBSD System Manager's Manual RAIDCTL(8) NAME raidctl -- configuration utility for the RAIDframe disk driver SYNOPSIS raidctl [-v] -a component dev raidctl [-v] -A [yes | no | root] dev raidctl [-v] -B dev raidctl [-v] -c config_file raidctl [-v] -C config_file raidctl [-v] -f component dev raidctl [-v] -F component dev raidctl [-v] -g component dev raidctl [-v] -i dev raidctl [-v] -I serial_number dev raidctl [-v] -p dev raidctl [-v] -P dev raidctl [-v] -r component dev raidctl [-v] -R component dev raidctl [-v] -s dev raidctl [-v] -S dev raidctl [-v] -u dev DESCRIPTION raidctl is the user-land control program for raid(4), the RAIDframe disk device. raidctl is primarily used to dynamically configure and unconfig- ure RAIDframe disk devices. For more information about the RAIDframe disk device, see raid(4). This document assumes the reader has at least rudimentary knowledge of RAID and RAID concepts. The command-line options for raidctl are as follows: -a component dev Add component as a hot spare for the device dev. -A yes dev Make the RAID set auto-configurable. The RAID set will be auto- matically configured at boot before the root file system is mounted. Note that all components of the set must be of type RAID in the disklabel. -A no dev Turn off auto-configuration for the RAID set. -A root dev Make the RAID set auto-configurable, and also mark the set as being eligible to be the root partition. A RAID set configured this way will override the use of the boot disk as the root device. All components of the set must be of type RAID in the disklabel. Note that the kernel being booted must currently reside on a non-RAID set. -B dev Initiate a copyback of reconstructed data from a spare disk to its original disk. This is performed after a component has failed, and the failed drive has been reconstructed onto a spare drive. -c config_file Configure a RAIDframe device according to the configuration given in config_file. A description of the contents of config_file is given later. -C config_file As for -c, but forces the configuration to take place. This is required the first time a RAID set is configured. -f component dev This marks the specified component as having failed, but does not initiate a reconstruction of that component. -F component dev Fails the specified component of the device, and immediately begin a reconstruction of the failed disk onto an available hot spare. This is one of the mechanisms used to start the recon- struction process if a component does have a hardware failure. -g component dev Get the component label for the specified component. -i dev Initialize the RAID device. In particular, (re-write) the parity on the selected device. This MUST be done for all RAID sets before the RAID device is labeled and before file systems are created on the RAID device. -I serial_number dev Initialize the component labels on each component of the device. serial_number is used as one of the keys in determining whether a particular set of components belong to the same RAID set. While not strictly enforced, different serial numbers should be used for different RAID sets. This step MUST be performed when a new RAID set is created. -p dev Check the status of the parity on the RAID set. Displays a sta- tus message, and returns successfully if the parity is up-to- date. -P dev Check the status of the parity on the RAID set, and initialize (re-write) the parity if the parity is not known to be up-to- date. This is normally used after a system crash (and before a fsck(8)) to ensure the integrity of the parity. -r component dev Remove the spare disk specified by component from the set of available spare components. -R component dev Fails the specified component, if necessary, and immediately begins a reconstruction back to component. This is useful for reconstructing back onto a component after it has been replaced following a failure. -s dev Display the status of the RAIDframe device for each of the compo- nents and spares. -S dev Check the status of parity re-writing, component reconstruction, and component copyback. The output indicates the amount of progress achieved in each of these areas. -u dev Unconfigure the RAIDframe device. -v Be more verbose. For operations such as reconstructions, parity re-writing, and copybacks, provide a progress indicator. The device used by raidctl is specified by dev. dev may be either the full name of the device, e.g. /dev/rraid0d, for the i386 architecture, and /dev/rraid0c for all others, or just simply raid0 (for /dev/rraid0d). The format of the configuration file is complex, and only an abbreviated treatment is given here. In the configuration files, a `#' indicates the beginning of a comment. There are 4 required sections of a configuration file, and 2 optional sections. Each section begins with a `START', followed by the section name, and the configuration parameters associated with that section. The first section is the `array' section, and it specifies the number of rows, columns, and spare disks in the RAID set. For example: START array 1 3 0 indicates an array with 1 row, 3 columns, and 0 spare disks. Note that although multi-dimensional arrays may be specified, they are NOT sup- ported in the driver. The second section, the `disks' section, specifies the actual components of the device. For example: START disks /dev/da0s1e /dev/da1s1e /dev/da2s1e specifies the three component disks to be used in the RAID device. If any of the specified drives cannot be found when the RAID device is con- figured, then they will be marked as `failed', and the system will oper- ate in degraded mode. Note that it is imperative that the order of the components in the configuration file does not change between configura- tions of a RAID device. Changing the order of the components will result in data loss if the set is configured with the -C option. In normal cir- cumstances, the RAID set will not configure if only -c is specified, and the components are out-of-order. The next section, which is the `spare' section, is optional, and, if present, specifies the devices to be used as `hot spares' -- devices which are on-line, but are not actively used by the RAID driver unless one of the main components fail. A simple `spare' section might be: START spare /dev/da3s1e for a configuration with a single spare component. If no spare drives are to be used in the configuration, then the `spare' section may be omitted. The next section is the `layout' section. This section describes the general layout parameters for the RAID device, and provides such informa- tion as sectors per stripe unit, stripe units per parity unit, stripe units per reconstruction unit, and the parity configuration to use. This section might look like: START layout # sectPerSU SUsPerParityUnit SUsPerReconUnit RAID_level 32 1 1 5 The sectors per stripe unit specifies, in blocks, the interleave factor; i.e. the number of contiguous sectors to be written to each component for a single stripe. Appropriate selection of this value (32 in this exam- ple) is the subject of much research in RAID architectures. The stripe units per parity unit and stripe units per reconstruction unit are nor- mally each set to 1. While certain values above 1 are permitted, a dis- cussion of valid values and the consequences of using anything other than 1 are outside the scope of this document. The last value in this section (5 in this example) indicates the parity configuration desired. Valid entries include: 0 RAID level 0. No parity, only simple striping. 1 RAID level 1. Mirroring. The parity is the mirror. 4 RAID level 4. Striping across components, with parity stored on the last component. 5 RAID level 5. Striping across components, parity distributed across all components. There are other valid entries here, including those for Even-Odd parity, RAID level 5 with rotated sparing, Chained declustering, and Interleaved declustering, but as of this writing the code for those parity operations has not been tested with FreeBSD. The next required section is the `queue' section. This is most often specified as: START queue fifo 100 where the queuing method is specified as fifo (first-in, first-out), and the size of the per-component queue is limited to 100 requests. Other queuing methods may also be specified, but a discussion of them is beyond the scope of this document. The final section, the `debug' section, is optional. For more details on this the reader is referred to the RAIDframe documentation discussed in the HISTORY section. See EXAMPLES for a more complete configuration file example. EXAMPLES It is highly recommended that before using the RAID driver for real file systems that the system administrator(s) become quite familiar with the use of raidctl, and that they understand how the component reconstruction process works. The examples in this section will focus on configuring a number of different RAID sets of varying degrees of redundancy. By work- ing through these examples, administrators should be able to develop a good feel for how to configure a RAID set, and how to initiate recon- struction of failed components. In the following examples `raid0' will be used to denote the RAID device. Depending on the architecture, `/dev/rraid0c' or `/dev/rraid0d' may be used in place of `raid0'. Initialization and Configuration The initial step in configuring a RAID set is to identify the components that will be used in the RAID set. All components should be the same size. Each component should have a disklabel type of FS_RAID, and a typ- ical disklabel entry for a RAID component might look like: f: 1800000 200495 RAID # (Cyl. 405*- 4041*) While FS_BSDFFS will also work as the component type, the type FS_RAID is preferred for RAIDframe use, as it is required for features such as auto- configuration. As part of the initial configuration of each RAID set, each component will be given a `component label'. A `component label' contains important information about the component, including a user- specified serial number, the row and column of that component in the RAID set, the redundancy level of the RAID set, a 'modification counter', and whether the parity information (if any) on that component is known to be correct. Component labels are an integral part of the RAID set, since they are used to ensure that components are configured in the correct order, and used to keep track of other vital information about the RAID set. Component labels are also required for the auto-detection and auto- configuration of RAID sets at boot time. For a component label to be considered valid, that particular component label must be in agreement with the other component labels in the set. For example, the serial num- ber, `modification counter', number of rows and number of columns must all be in agreement. If any of these are different, then the component is not considered to be part of the set. See raid(4) for more informa- tion about component labels. Once the components have been identified, and the disks have appropriate labels, raidctl is then used to configure the raid(4) device. To config- ure the device, a configuration file which looks something like: START array # numRow numCol numSpare 1 3 1 START disks /dev/da1s1e /dev/da2s1e /dev/da3s1e START spare /dev/da4s1e START layout # sectPerSU SUsPerParityUnit SUsPerReconUnit RAID_level_5 32 1 1 5 START queue fifo 100 is created in a file. The above configuration file specifies a RAID 5 set consisting of the components /dev/da1s1e, /dev/da2s1e, and /dev/da3s1e, with /dev/da4s1e available as a `hot spare' in case one of the three main drives should fail. A RAID 0 set would be specified in a similar way: START array # numRow numCol numSpare 1 4 0 START disks /dev/da1s10e /dev/da1s11e /dev/da1s12e /dev/da1s13e START layout # sectPerSU SUsPerParityUnit SUsPerReconUnit RAID_level_0 64 1 1 0 START queue fifo 100 In this case, devices /dev/da1s10e, /dev/da1s11e, /dev/da1s12e, and /dev/da1s13e are the components that make up this RAID set. Note that there are no hot spares for a RAID 0 set, since there is no way to recover data if any of the components fail. For a RAID 1 (mirror) set, the following configuration might be used: START array # numRow numCol numSpare 1 2 0 START disks /dev/da2s10e /dev/da2s11e START layout # sectPerSU SUsPerParityUnit SUsPerReconUnit RAID_level_1 128 1 1 1 START queue fifo 100 In this case, /dev/da2s10e and /dev/da2s11e are the two components of the mirror set. While no hot spares have been specified in this configura- tion, they easily could be, just as they were specified in the RAID 5 case above. Note as well that RAID 1 sets are currently limited to only 2 components. At present, n-way mirroring is not possible. The first time a RAID set is configured, the -C option must be used: raidctl -C raid0.conf where `raid0.conf' is the name of the RAID configuration file. The -C forces the configuration to succeed, even if any of the component labels are incorrect. The -C option should not be used lightly in situations other than initial configurations, as if the system is refusing to con- figure a RAID set, there is probably a very good reason for it. After the initial configuration is done (and appropriate component labels are added with the -I option) then raid0 can be configured normally with: raidctl -c raid0.conf When the RAID set is configured for the first time, it is necessary to initialize the component labels, and to initialize the parity on the RAID set. Initializing the component labels is done with: raidctl -I 112341 raid0 where `112341' is a user-specified serial number for the RAID set. This initialization step is required for all RAID sets. As well, using dif- ferent serial numbers between RAID sets is strongly encouraged, as using the same serial number for all RAID sets will only serve to decrease the usefulness of the component label checking. Initializing the RAID set is done via the -i option. This initialization MUST be done for all RAID sets, since among other things it verifies that the parity (if any) on the RAID set is correct. Since this initializa- tion may be quite time-consuming, the -v option may be also used in con- junction with -i: raidctl -iv raid0 This will give more verbose output on the status of the initialization: Initiating re-write of parity Parity Re-write status: 10% |**** | ETA: 06:03 / The output provides a `Percent Complete' in both a numeric and graphical format, as well as an estimated time to completion of the operation. Since it is the parity that provides the `redundancy' part of RAID, it is critical that the parity is correct as much as possible. If the parity is not correct, then there is no guarantee that data will not be lost if a component fails. Once the parity is known to be correct, it is then safe to perform disklabel(8), newfs(8), or fsck(8) on the device or its file systems, and then to mount the file systems for use. Under certain circumstances (e.g. the additional component has not arrived, or data is being migrated off of a disk destined to become a component) it may be desirable to to configure a RAID 1 set with only a single component. This can be achieved by configuring the set with a physically existing component (as either the first or second component) and with a `fake' component. In the following: START array # numRow numCol numSpare 1 2 0 START disks /dev/da6s1e /dev/da0s1e START layout # sectPerSU SUsPerParityUnit SUsPerReconUnit RAID_level_1 128 1 1 1 START queue fifo 100 /dev/da0s1e is the real component, and will be the second disk of a RAID 1 set. The component /dev/da6s1e, which must exist, but have no physical device associated with it, is simply used as a placeholder. Configura- tion (using -C and -I 12345 as above) proceeds normally, but initializa- tion of the RAID set will have to wait until all physical components are present. After configuration, this set can be used normally, but will be operating in degraded mode. Once a second physical component is obtained, it can be hot-added, the existing data mirrored, and normal operation resumed. Maintenance of the RAID set After the parity has been initialized for the first time, the command: raidctl -p raid0 can be used to check the current status of the parity. To check the par- ity and rebuild it necessary (for example, after an unclean shutdown) the command: raidctl -P raid0 is used. Note that re-writing the parity can be done while other opera- tions on the RAID set are taking place (e.g. while doing a fsck(8) on a file system on the RAID set). However: for maximum effectiveness of the RAID set, the parity should be known to be correct before any data on the set is modified. To see how the RAID set is doing, the following command can be used to show the RAID set's status: raidctl -s raid0 The output will look something like: Components: /dev/da1s1e: optimal /dev/da2s1e: optimal /dev/da3s1e: optimal Spares: /dev/da4s1e: spare Component label for /dev/da1s1e: Row: 0 Column: 0 Num Rows: 1 Num Columns: 3 Version: 2 Serial Number: 13432 Mod Counter: 65 Clean: No Status: 0 sectPerSU: 32 SUsPerPU: 1 SUsPerRU: 1 RAID Level: 5 blocksize: 512 numBlocks: 1799936 Autoconfig: No Last configured as: raid0 Component label for /dev/da2s1e: Row: 0 Column: 1 Num Rows: 1 Num Columns: 3 Version: 2 Serial Number: 13432 Mod Counter: 65 Clean: No Status: 0 sectPerSU: 32 SUsPerPU: 1 SUsPerRU: 1 RAID Level: 5 blocksize: 512 numBlocks: 1799936 Autoconfig: No Last configured as: raid0 Component label for /dev/da3s1e: Row: 0 Column: 2 Num Rows: 1 Num Columns: 3 Version: 2 Serial Number: 13432 Mod Counter: 65 Clean: No Status: 0 sectPerSU: 32 SUsPerPU: 1 SUsPerRU: 1 RAID Level: 5 blocksize: 512 numBlocks: 1799936 Autoconfig: No Last configured as: raid0 Parity status: clean Reconstruction is 100% complete. Parity Re-write is 100% complete. Copyback is 100% complete. This indicates that all is well with the RAID set. Of importance here are the component lines which read `optimal', and the `Parity status' line which indicates that the parity is up-to-date. Note that if there are file systems open on the RAID set, the individual components will not be `clean' but the set as a whole can still be clean. To check the component label of /dev/da1s1e, the following is used: raidctl -g /dev/da1s1e raid0 The output of this command will look something like: Component label for /dev/da1s1e: Row: 0 Column: 0 Num Rows: 1 Num Columns: 3 Version: 2 Serial Number: 13432 Mod Counter: 65 Clean: No Status: 0 sectPerSU: 32 SUsPerPU: 1 SUsPerRU: 1 RAID Level: 5 blocksize: 512 numBlocks: 1799936 Autoconfig: No Last configured as: raid0 Dealing with Component Failures If for some reason (perhaps to test reconstruction) it is necessary to pretend a drive has failed, the following will perform that function: raidctl -f /dev/da2s1e raid0 The system will then be performing all operations in degraded mode, where missing data is re-computed from existing data and the parity. In this case, obtaining the status of raid0 will return (in part): Components: /dev/da1s1e: optimal /dev/da2s1e: failed /dev/da3s1e: optimal Spares: /dev/da4s1e: spare Note that with the use of -f a reconstruction has not been started. To both fail the disk and start a reconstruction, the -F option must be used: raidctl -F /dev/da2s1e raid0 The -f option may be used first, and then the -F option used later, on the same disk, if desired. Immediately after the reconstruction is started, the status will report: Components: /dev/da1s1e: optimal /dev/da2s1e: reconstructing /dev/da3s1e: optimal Spares: /dev/da4s1e: used_spare [...] Parity status: clean Reconstruction is 10% complete. Parity Re-write is 100% complete. Copyback is 100% complete. This indicates that a reconstruction is in progress. To find out how the reconstruction is progressing the -S option may be used. This will indi- cate the progress in terms of the percentage of the reconstruction that is completed. When the reconstruction is finished the -s option will show: Components: /dev/da1s1e: optimal /dev/da2s1e: spared /dev/da3s1e: optimal Spares: /dev/da4s1e: used_spare [...] Parity status: clean Reconstruction is 100% complete. Parity Re-write is 100% complete. Copyback is 100% complete. At this point there are at least two options. First, if /dev/da2s1e is known to be good (i.e. the failure was either caused by -f or -F, or the failed disk was replaced), then a copyback of the data can be initiated with the -B option. In this example, this would copy the entire contents of /dev/da4s1e to /dev/da2s1e. Once the copyback procedure is complete, the status of the device would be (in part): Components: /dev/da1s1e: optimal /dev/da2s1e: optimal /dev/da3s1e: optimal Spares: /dev/da4s1e: spare and the system is back to normal operation. The second option after the reconstruction is to simply use /dev/da4s1e in place of /dev/da2s1e in the configuration file. For example, the con- figuration file (in part) might now look like: START array 1 3 0 START drives /dev/da1s1e /dev/da4s1e /dev/da3s1e This can be done as /dev/da4s1e is completely interchangeable with /dev/da2s1e at this point. Note that extreme care must be taken when changing the order of the drives in a configuration. This is one of the few instances where the devices and/or their orderings can be changed without loss of data! In general, the ordering of components in a con- figuration file should never be changed. If a component fails and there are no hot spares available on-line, the status of the RAID set might (in part) look like: Components: /dev/da1s1e: optimal /dev/da2s1e: failed /dev/da3s1e: optimal No spares. In this case there are a number of options. The first option is to add a hot spare using: raidctl -a /dev/da4s1e raid0 After the hot add, the status would then be: Components: /dev/da1s1e: optimal /dev/da2s1e: failed /dev/da3s1e: optimal Spares: /dev/da4s1e: spare Reconstruction could then take place using -F as describe above. A second option is to rebuild directly onto /dev/da2s1e. Once the disk containing /dev/da2s1e has been replaced, one can simply use: raidctl -R /dev/da2s1e raid0 to rebuild the /dev/da2s1e component. As the rebuilding is in progress, the status will be: Components: /dev/da1s1e: optimal /dev/da2s1e: reconstructing /dev/da3s1e: optimal No spares. and when completed, will be: Components: /dev/da1s1e: optimal /dev/da2s1e: optimal /dev/da3s1e: optimal No spares. In circumstances where a particular component is completely unavailable after a reboot, a special component name will be used to indicate the missing component. For example: Components: /dev/da2s1e: optimal component1: failed No spares. indicates that the second component of this RAID set was not detected at all by the auto-configuration code. The name `component1' can be used anywhere a normal component name would be used. For example, to add a hot spare to the above set, and rebuild to that hot spare, the following could be done: raidctl -a /dev/da3s1e raid0 raidctl -F component1 raid0 at which point the data missing from `component1' would be reconstructed onto /dev/da3s1e. RAID on RAID RAID sets can be layered to create more complex and much larger RAID sets. A RAID 0 set, for example, could be constructed from four RAID 5 sets. The following configuration file shows such a setup: START array # numRow numCol numSpare 1 4 0 START disks /dev/raid1e /dev/raid2e /dev/raid3e /dev/raid4e START layout # sectPerSU SUsPerParityUnit SUsPerReconUnit RAID_level_0 128 1 1 0 START queue fifo 100 A similar configuration file might be used for a RAID 0 set constructed from components on RAID 1 sets. In such a configuration, the mirroring provides a high degree of redundancy, while the striping provides addi- tional speed benefits. Auto-configuration and Root on RAID RAID sets can also be auto-configured at boot. To make a set auto-con- figurable, simply prepare the RAID set as above, and then do a: raidctl -A yes raid0 to turn on auto-configuration for that set. To turn off auto-configura- tion, use: raidctl -A no raid0 RAID sets which are auto-configurable will be configured before the root file system is mounted. These RAID sets are thus available for use as a root file system, or for any other file system. A primary advantage of using the auto-configuration is that RAID components become more indepen- dent of the disks they reside on. For example, SCSI ID's can change, but auto-configured sets will always be configured correctly, even if the SCSI ID's of the component disks have become scrambled. Having a system's root file system (/) on a RAID set is also allowed, with the `a' partition of such a RAID set being used for /. To use raid0a as the root file system, simply use: raidctl -A root raid0 To return raid0a to be just an auto-configuring set simply use the -A yes arguments. Note that kernels can only be directly read from RAID 1 components on alpha and pmax architectures. On those architectures, the FS_RAID file system is recognized by the bootblocks, and will properly load the kernel directly from a RAID 1 component. For other architectures, or to support the root file system on other RAID sets, some other mechanism must be used to get a kernel booting. For example, a small partition containing only the secondary boot-blocks and an alternate kernel (or two) could be used. Once a kernel is booting however, and an auto-configuring RAID set is found that is eligible to be root, then that RAID set will be auto- configured and used as the root device. If two or more RAID sets claim to be root devices, then the user will be prompted to select the root device. At this time, RAID 0, 1, 4, and 5 sets are all supported as root devices. A typical RAID 1 setup with root on RAID might be as follows: 1. wd0a - a small partition, which contains a complete, bootable, basic NetBSD installation. 2. wd1a - also contains a complete, bootable, basic NetBSD installa- tion. 3. wd0e and wd1e - a RAID 1 set, raid0, used for the root file system. 4. wd0f and wd1f - a RAID 1 set, raid1, which will be used only for swap space. 5. wd0g and wd1g - a RAID 1 set, raid2, used for /usr, /home, or other data, if desired. 6. wd0h and wd0h - a RAID 1 set, raid3, if desired. RAID sets raid0, raid1, and raid2 are all marked as auto-configurable. raid0 is marked as being a root file system. When new kernels are installed, the kernel is not only copied to /, but also to wd0a and wd1a. The kernel on wd0a is required, since that is the kernel the system boots from. The kernel on wd1a is also required, since that will be the kernel used should wd0 fail. The important point here is to have redundant copies of the kernel available, in the event that one of the drives fail. There is no requirement that the root file system be on the same disk as the kernel. For example, obtaining the kernel from wd0a, and using da0s1e and da1s1e for raid0, and the root file system, is fine. It is critical, however, that there be multiple kernels available, in the event of media failure. Multi-layered RAID devices (such as a RAID 0 set made up of RAID 1 sets) are not supported as root devices or auto-configurable devices at this point. (Multi-layered RAID devices are supported in general, however, as mentioned earlier.) Note that in order to enable component auto-detec- tion and auto-configuration of RAID devices, the line: options RAID_AUTOCONFIG must be in the kernel configuration file. See raid(4) for more details. Unconfiguration The final operation performed by raidctl is to unconfigure a raid(4) device. This is accomplished via a simple: raidctl -u raid0 at which point the device is ready to be reconfigured. Performance Tuning Selection of the various parameter values which result in the best per- formance can be quite tricky, and often requires a bit of trial-and-error to get those values most appropriate for a given system. A whole range of factors come into play, including: 1. Types of components (e.g. SCSI vs. IDE) and their bandwidth 2. Types of controller cards and their bandwidth 3. Distribution of components among controllers 4. IO bandwidth 5. File system access patterns 6. CPU speed As with most performance tuning, benchmarking under real-life loads may be the only way to measure expected performance. Understanding some of the underlying technology is also useful in tuning. The goal of this section is to provide pointers to those parameters which may make signif- icant differences in performance. For a RAID 1 set, a SectPerSU value of 64 or 128 is typically sufficient. Since data in a RAID 1 set is arranged in a linear fashion on each compo- nent, selecting an appropriate stripe size is somewhat less critical than it is for a RAID 5 set. However: a stripe size that is too small will cause large IO's to be broken up into a number of smaller ones, hurting performance. At the same time, a large stripe size may cause problems with concurrent accesses to stripes, which may also affect performance. Thus values in the range of 32 to 128 are often the most effective. Tuning RAID 5 sets is trickier. In the best case, IO is presented to the RAID set one stripe at a time. Since the entire stripe is available at the beginning of the IO, the parity of that stripe can be calculated before the stripe is written, and then the stripe data and parity can be written in parallel. When the amount of data being written is less than a full stripe worth, the `small write' problem occurs. Since a `small write' means only a portion of the stripe on the components is going to change, the data (and parity) on the components must be updated slightly differently. First, the `old parity' and `old data' must be read from the components. Then the new parity is constructed, using the new data to be written, and the old data and old parity. Finally, the new data and new parity are written. All this extra data shuffling results in a serious loss of performance, and is typically 2 to 4 times slower than a full stripe write (or read). To combat this problem in the real world, it may be useful to ensure that stripe sizes are small enough that a `large IO' from the system will use exactly one large stripe write. As is seen later, there are some file system dependencies which may come into play here as well. Since the size of a `large IO' is often (currently) only 32K or 64K, on a 5-drive RAID 5 set it may be desirable to select a SectPerSU value of 16 blocks (8K) or 32 blocks (16K). Since there are 4 data sectors per stripe, the maximum data per stripe is 64 blocks (32K) or 128 blocks (64K). Again, empirical measurement will provide the best indicators of which values will yeild better performance. The parameters used for the file system are also critical to good perfor- mance. For newfs(8), for example, increasing the block size to 32K or 64K may improve performance dramatically. As well, changing the cylin- ders-per-group parameter from 16 to 32 or higher is often not only neces- sary for larger file systems, but may also have positive performance implications. Summary Despite the length of this man-page, configuring a RAID set is a rela- tively straight-forward process. All that needs to be done is the fol- lowing steps: 1. Use disklabel(8) to create the components (of type RAID). 2. Construct a RAID configuration file: e.g. `raid0.conf' 3. Configure the RAID set with: raidctl -C raid0.conf 4. Initialize the component labels with: raidctl -I 123456 raid0 5. Initialize other important parts of the set with: raidctl -i raid0 6. Get the default label for the RAID set: disklabel raid0 > /tmp/label 7. Edit the label: vi /tmp/label 8. Put the new label on the RAID set: disklabel -R -r raid0 /tmp/label 9. Create the file system: newfs /dev/rraid0e 10. Mount the file system: mount /dev/raid0e /mnt 11. Use: raidctl -c raid0.conf To re-configure the RAID set the next time it is needed, or put raid0.conf into /etc where it will automatically be started by the /etc/rc scripts. WARNINGS Certain RAID levels (1, 4, 5, 6, and others) can protect against some data loss due to component failure. However the loss of two components of a RAID 4 or 5 system, or the loss of a single component of a RAID 0 system will result in the entire file system being lost. RAID is NOT a substitute for good backup practices. Recomputation of parity MUST be performed whenever there is a chance that it may have been compromised. This includes after system crashes, or before a RAID device has been used for the first time. Failure to keep parity correct will be catastrophic should a component ever fail -- it is better to use RAID 0 and get the additional space and speed, than it is to use parity, but not keep the parity correct. At least with RAID 0 there is no perception of increased data security. FILES /dev/{,r}raid* raid device special files. SEE ALSO raid(4), ccd(4), rc(8) BUGS Hot-spare removal is currently not available. HISTORY RAIDframe is a framework for rapid prototyping of RAID structures devel- oped by the folks at the Parallel Data Laboratory at Carnegie Mellon Uni- versity (CMU). A more complete description of the internals and func- tionality of RAIDframe is found in the paper "RAIDframe: A Rapid Proto- typing Tool for RAID Systems", by William V. Courtright II, Garth Gibson, Mark Holland, LeAnn Neal Reilly, and Jim Zelenka, and published by the Parallel Data Laboratory of Carnegie Mellon University. The raidctl command first appeared as a program in CMU's RAIDframe v1.1 distribution. This version of raidctl is a complete re-write, and first appeared in FreeBSD 4.4. COPYRIGHT The RAIDframe Copyright is as follows: Copyright (c) 1994-1996 Carnegie-Mellon University. All rights reserved. Permission to use, copy, modify and distribute this software and its documentation is hereby granted, provided that both the copyright notice and this permission notice appear in all copies of the software, derivative works or modified versions, and any portions thereof, and that both notices appear in supporting documentation. CARNEGIE MELLON ALLOWS FREE USE OF THIS SOFTWARE IN ITS "AS IS" CONDITION. CARNEGIE MELLON DISCLAIMS ANY LIABILITY OF ANY KIND FOR ANY DAMAGES WHATSOEVER RESULTING FROM THE USE OF THIS SOFTWARE. Carnegie Mellon requests users of this software to return to Software Distribution Coordinator or Software.Distribution@CS.CMU.EDU School of Computer Science Carnegie Mellon University Pittsburgh PA 15213-3890 any improvements or extensions that they make and grant Carnegie the rights to redistribute these changes. FreeBSD 11.1 November 6, 1998 FreeBSD 11.1
NAME | SYNOPSIS | DESCRIPTION | EXAMPLES | WARNINGS | FILES | SEE ALSO | BUGS | HISTORY | COPYRIGHT
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