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| {{Article}} | | <noinclude> |
| = Introduction = | | {{InstallPart|процесс разбиения диска и создания файловых систем}} |
| | </noinclude> |
| | === Подготовка жесткого диска === |
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| LVM (Logical Volume Management) offers a great flexibility in managing your storage and significantly reduces server downtimes by allowing on-line disk space management: The great idea beneath LVM is to '''make the data and its storage loosely coupled''' through several layers of abstraction. You (the system administrator) have the hand of each of those layers making the entire space management process extremely simple and flexible through various set of coherent commands.
| | В этой части мы научимся различным способам установки Funtoo Linux -- и загрузки с -- жесткий диск. |
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| Several other well-known binary Linux distributions makes an aggressive use of LVM and several Unixes including HP-UX, AIX and Solaris offers since a while a similar functionality modulo the commands to be used. LVM is not mandatory but its usage can bring you additional flexibility and make your everyday life much more simpler.
| | ==== Введение ==== |
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| = Concepts =
| | В прежние времена существовал лишь один способ загрузить PC-совместимый компьютер. Все наши дектопы и сервера имели стандартный PC BIOS, все наши харды использовали MBR и были разбиты используя схему разбивки MBR. Вот как это все было и нам это нравилось! |
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| As usual, having a good idea of the concepts lying beneath is mandatory. LVM is not very complicated, but it is easy to become confused, especially because it is a multi-layered system; however LVM designers had the good idea of keeping the command names consistent between all LVM command sets, making your life easier.
| | Затем появились EFI и UEFI, встроенные программы нового образца наряду со схемой разбивки GPT, поддерживающая диски размером более 2.2TБ. Неожиданно, нам стали доступны различные способы установки и загрузки Линукс систем . То, что было единым методом, стало чем-то более сложным. |
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| LVM consists of, mainly, three things:
| | Let's take a moment to review the options available to you for configuring a hard drive to boot Funtoo Linux. This Install Guide uses, and recommends, the old-school method of BIOS booting and using an MBR. It works and (except for rare cases) is universally supported. There's nothing wrong with it. If your system disk is 2TB or smaller in size, it won't prevent you from using all of your disk's capacity, either. |
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| * '''Physical volumes (or ''PV'')''': nothing more than a physical storage space. A physical volume can by anything like a partition on a local hard disk, a partition located on a remote SAN disk, a USB key or whatever else that could offer a storage space (so yes, technically it could be possible to use an optical storage device accessed in packet writing mode). The storage space on a physical volumes is divided (and managed) in small units called '''Physical Extents''' (or ''PE''). Just to give an analogy if you are a bit familiar with RAID, PE are a bit like RAID stripes.
| | But, there are some situations where the old-school method isn't optimal. If you have a system disk >2TB in size, then MBR partitions won't allow you to access all your storage. So that's one reason. Another reason is that there are some so-called "PC" systems out there that don't support BIOS booting anymore, and force you to use UEFI to boot. So, out of compassion for people who fall into this predicament, this Install Guide documents UEFI booting too. |
| * '''Volume Groups (or ''VG'')''': a group of at least one PV. VG are '''named''' entities and will appear in the system via the device mapper as '''/dev/''volume-group-name'''''.
| |
| * '''Logical Volumes (or ''LV'')''': a '''named''' division of a volume group in which a filesystem is created and that can be mounted in the VFS. Just for the record, just as for the PE in PV, a LV is managed as chucks known as Logical Extents (or ''LE''). Most of the time those LE are hidden to the system administrator due to a 1:1 mapping between them and the PE lying be just beneath but a cool fact to know about LEs is that they can be spread over PV just like RAID stripes in a RAID-0 volume. However, researches done on the Web tends to demonstrate system administrators prefer to build RAID volumes with mdadm than use LVM over them for performance reasons.
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| In short words: LVM logical volumes (LV) are containers that can hold a single filesystem and which are created inside a volume group (VG) itself composed by an aggregation of at least one physical volumes (PV) themselves stored on various media (usb key, harddisk partition and so on). The data is stored in chunks spread over the various PV.
| | Our recommendation is still to go old-school unless you have reason not to. The boot loader we will be using to load the Linux kernel in this guide is called GRUB, so we call this method the '''BIOS + GRUB (MBR)''' method. It's the traditional method of setting up a PC-compatible system to boot Linux. |
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| {{fancynote|Retain what PV, VG and LV means as we will use those abbreviations in the rest of this article.}}
| | If you need to use UEFI to boot, we recommend not using the MBR at all for booting, as some systems support this, but others don't. Instead, we recommend using UEFI to boot GRUB, which in turn will load Linux. We refer to this method as the '''UEFI + GRUB (GPT)''' method. |
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| = Your first tour of LVM =
| | And yes, there are even more methods, some of which are documented on the [[Boot Methods]] page. We used to recommend a '''BIOS + GRUB (GPT)''' method but it is not consistently supported across a wide variety of hardware. |
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| == Physical volumes creation ==
| | '''The big question is -- which boot method should you use?''' Here's how to tell. |
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| {{fancynote|We give the same size to all volumes for the sake of the demonstration. This is not mandatory and be possible to have mixed sizes PV inside a same VG. }}
| | ;Principle 1 - Old School: If you can reliably boot System Rescue CD and it shows you an initial light blue menu, you are booting the CD using the BIOS, and it's likely that you can thus boot Funtoo Linux using the BIOS. So, go old-school and use BIOS booting, ''unless'' you have some reason to use UEFI, such as having a >2.2TB system disk. In that case, see Principle 2, as your system may also support UEFI booting. |
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| To start with, just create three raw disk images:
| | ;Principle 2 - New School: If you can reliably boot System Rescue CD and it shows you an initial black and white menu -- congratulations, your system is configured to support UEFI booting. This means that you are ready to install Funtoo Linux to boot via UEFI. Your system may still support BIOS booting, but just be trying UEFI first. You can poke around in your BIOS boot configuration and play with this. |
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| <pre> | | ;What's the Big Difference between Old School and New School?: Here's the deal. If you go with old-school MBR partitions, your <code>/boot</code> partition will be an ext2 filesystem, and you'll use <code>fdisk</code> to create your MBR partitions. If you go with new-school GPT partitions and UEFI booting, your <code>/boot</code> partition will be a vfat filesystem, because this is what UEFI is able to read, and you will use <code>gdisk</code> to create your GPT partitions. And you'll install GRUB a bit differently. That's about all it comes down to, in case you were curious. |
| # dd if=/dev/zero of=/tmp/hdd1.img bs=2G count=1
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| # dd if=/dev/zero of=/tmp/hdd2.img bs=2G count=1
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| # dd if=/dev/zero of=/tmp/hdd3.img bs=2G count=1
| |
| </pre>
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| and associate them to a loopback device: | | ;Also Note: To install Funtoo Linux to boot via the New School UEFI method, you must boot System Rescue CD using UEFI -- and see an initial black and white screen. Otherwise, UEFI will not be active and you will not be able to set it up! |
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| <pre>
| | {{Note|'''Some motherboards may appear to support UEFI, but don't.''' Do your research. For example, the Award BIOS in my Gigabyte GA-990FXA-UD7 rev 1.1 has an option to enable UEFI boot for CD/DVD. '''This is not sufficient for enabling UEFI boot for hard drives and installing Funtoo Linux.''' UEFI must be supported for both removable media (so you can boot System Rescue CD using UEFI) as well as fixed media (so you can boot your new Funtoo Linux installation.) It turns out that later revisions of this board (rev 3.0) have a new BIOS that fully supports UEFI boot. This may point to a third principle -- know thy hardware.}} |
| # losetup -f
| |
| /dev/loop0 | |
| # losetup /dev/loop0 /tmp/hdd1.img
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| # losetup /dev/loop1 /tmp/hdd2.img
| |
| # losetup /dev/loop2 /tmp/hdd3.img
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| </pre>
| | ==== Old-School (BIOS/MBR) Method ==== |
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|
| Okay nothing really exciting there, but wait the fun is coming! First check that '''sys-fs/lvm2''' is present on your system and emerge it if not. At this point, we must tell you a secret: although several articles and authors uses the taxonomy "LVM" it denotes "LVM version 2" or "LVM 2" nowadays. You must know that LVM had, in the old good times (RHEL 3.x and earlier), a previous revision known as "LVM version 1". LVM 1 is now considered as an extincted specie and is not compatible with LVM 2, although LVM 2 tools maintain a backward compatibility.
| | {{Note|Use this method if you are booting using your BIOS, and if your System Rescue CD initial boot menu was light blue. If you're going to use the new-school method, [[#New-School (UEFI/GPT) Method|click here to jump down to UEFI/GPT.]]}} |
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| The very frst step in LVM is to create the physical devices or ''PV''. "Wait create ''what''?! Aren't the loopback devices present on the system?" Yes they are present but they are empty, we must initialize them some metadata to make them usable by LVM. This is simply done by:
| | ===== Preparation ===== |
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| |
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| <pre> | | First, it's a good idea to make sure that you've found the correct hard disk to partition. Try this command and verify that <code>/dev/sda</code> is the disk that you want to partition: |
| # pvcreate /dev/loop0
| |
| Physical volume "/dev/loop0" successfully created
| |
| # pvcreate /dev/loop1
| |
| Physical volume "/dev/loop1" successfully created
| |
| # pvcreate /dev/loop2
| |
| Physical volume "/dev/loop2" successfully created
| |
| </pre> | |
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| It is absolutely normal that nothing in particular is printed at the output of each command but we assure you: you have three LVM PVs. You can check them by issuing:
| | <console> |
| | # ##i##fdisk -l /dev/sda |
|
| |
|
| <pre>
| | Disk /dev/sda: 640.1 GB, 640135028736 bytes, 1250263728 sectors |
| # pvs
| | Units = sectors of 1 * 512 = 512 bytes |
| PV VG Fmt Attr PSize PFree
| | Sector size (logical/physical): 512 bytes / 512 bytes |
| /dev/loop0 lvm2 a- 2.00g 2.00g
| | I/O size (minimum/optimal): 512 bytes / 512 bytes |
| /dev/loop1 lvm2 a- 2.00g 2.00g
| | Disk label type: gpt |
| /dev/loop2 lvm2 a- 2.00g 2.00g
| |
| </pre>
| |
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| Some good information there:
| | # Start End Size Type Name |
| * PV: indicates the physical path the PV lies on
| | 1 2048 1250263694 596.2G Linux filesyste Linux filesystem |
| * VG indicates the VG the PV belongs to. At this time, we didn't created any VG yet and the column remains empty.
| | </console> |
| * Fmt: indicates the format of the PV (here it says we have a LVM version 2 PV)
| |
| * Attrs: indicates some status information, the 'a' here just says that the PV is accessible.
| |
| * PSize and PFree: indicates the PV size and the amount of remaining space for this PV. Here we have three empty PV so it bascially says "2 gigabytes large, 2 out of gigabytes free"
| |
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| It is now time to introduce you to another command: '''pvdisplay'''. Just run it without any arguments:
| | Now, it's recommended that you erase any existing MBR or GPT partition tables on the disk, which could confuse the system's BIOS at boot time. We do this using <code>sgdisk</code>: |
| | {{fancywarning|This will make any existing partitions inaccessible! You are '''strongly''' cautioned and advised to backup any critical data before proceeding.}} |
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|
| <pre> | | <console> |
| pvdisplay
| | # ##i##sgdisk --zap-all /dev/sda |
| "/dev/loop0" is a new physical volume of "2.00 GiB"
| |
| --- NEW Physical volume ---
| |
| PV Name /dev/loop0
| |
| VG Name
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| PV Size 2.00 GiB
| |
| Allocatable NO
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| PE Size 0
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| Total PE 0
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| Free PE 0
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| Allocated PE 0
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| PV UUID b9i1Hi-llka-egCF-2vU2-f7tp-wBqh-qV4qEk
| |
|
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| "/dev/loop1" is a new physical volume of "2.00 GiB"
| |
| --- NEW Physical volume ---
| |
| PV Name /dev/loop1
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| VG Name
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| PV Size 2.00 GiB
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| Allocatable NO
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| PE Size 0
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| Total PE 0
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| Free PE 0
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| Allocated PE 0
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| PV UUID i3mdBO-9WIc-EO2y-NqRr-z5Oa-ItLS-jbjq0E
| |
|
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| "/dev/loop2" is a new physical volume of "2.00 GiB"
| |
| --- NEW Physical volume ---
| |
| PV Name /dev/loop2
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| VG Name
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| PV Size 2.00 GiB
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| Allocatable NO
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| PE Size 0
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| Total PE 0
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| Free PE 0
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| Allocated PE 0
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| PV UUID dEwVuO-a5vQ-ipcH-Rvlt-5zWt-iAB2-2F0XBf
| |
| </pre>
| |
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| |
|
| The third three lines of each PV shows:
| | Creating new GPT entries. |
| * what is the storage device beneath a PV
| | GPT data structures destroyed! You may now partition the disk using fdisk or |
| * the VG it is tied to
| | other utilities. |
| * the size of this PV.
| | </console> |
| ''Allocatable'' indicates whether the PV is used to store data. As the PV is not a member of a VG, it cannot not be used (yet) hence the "NO" shown. Another set of information is the lines starting with ''PE''. ''PE'' stands for ''' ''Physical Extents'' ''' (data stripe) and is the finest granularity LVM can manipulate. The size of a PE is "0" here because we have a blank PV however it typically holds 32 MB of data. Following ''PE Size'' are ''Total PE'' which show the the total '''number''' of PE available on this PV and ''Free PE'' the number of PE remaining available for use. ''Allocated PE'' just show the difference between ''Total PE'' and ''Free PE''.
| |
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| The latest line (''PV UUID'') is a unique identifier used internally by LVM to name the PV. You have to know that it exists because it is sometimes useful when having to recover from corruption or do weird things with PV however most of the time you don't have to worry about its existence.
| | This output is also nothing to worry about, as the command still succeded: |
|
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| {{fancynote|It is possible to force how LVM handles the alignments on the physical storage. This is useful when dealing with 4K sectors drives that lies on their physical sectors size. Refer to the manual page. }}
| |
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| == Volume group creation ==
| | <console> |
| | *************************************************************** |
| | Found invalid GPT and valid MBR; converting MBR to GPT format |
| | in memory. |
| | *************************************************************** |
| | </console> |
|
| |
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| We have the blank PV at this time but to make them a bit more usable for storage we must tell to LVM how they are grouped to form a VG (storage pool) where LV will be created. A nice aspect of VGs resides in the fact that they are not "written in the stone" once created: you can still add, remove or exchange PV (in the case the device the PV is stored on fails for example) inside a VG at a later time. To create our first volume group named ''vgtest'':
| | ===== Partitioning ===== |
|
| |
|
| <pre> | | Now we will use <code>fdisk</code> to create the MBR partition table and partitions: |
| # vgcreate vgtest /dev/loop0 /dev/loop1 /dev/loop2
| |
| Volume group "vgtest" successfully created
| |
| </pre> | |
|
| |
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| Just like we did before with PV, we can get a list of what are the VG known by the system. This is done through the command '''vgs''':
| | <console> |
| | # ##i##fdisk /dev/sda |
| | </console> |
|
| |
|
| <pre> | | Within <code>fdisk</code>, follow these steps: |
| # vgs
| |
| VG #PV #LV #SN Attr VSize VFree
| |
| vgtest 3 0 0 wz--n- 5.99g 5.99g
| |
| </pre> | |
|
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| '''vgs''' show you a tabluar view of information: | | '''Empty the partition table''': |
| * '''VG:''' the name of the VG
| |
| * '''#PV:''' the number of PV composing the VG
| |
| * '''#LV:''' the number of logical volumes (LV) located inside the VG
| |
| * '''Attrs:''' a status field. w, z and n here means that VG is:
| |
| ** '''w:''' '''w'''ritable
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| ** '''z:''' resi'''z'''able
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| ** '''n:''' using the allocation policy '''''n'''ormal'' (tweaking allocation policies is beyond the scope of this article, we will use the default value ''normal'' in the rest of this article)
| |
| * VSize and VFree gives statistics on how full a VG is versus its size
| |
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|
| Note the dashes in ''Attrs'', they mean that the attribute is not active:
| | <console> |
| * First dash (3rd position) indicates if the VG would have been exported (a 'x' would have been showed at this position in that case).
| | Command (m for help): ##i##o ↵ |
| * Second dash (4th position) indicates if the VG would have been partial (a 'p' would have been showed at this position in that case).
| | </console> |
| * Third dash (rightmost position) indicates if the VG is a clustered (a 'c' would have been showed at this position in that case).
| |
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| |
|
| Exporting a VG and clustered VG are a bit more advanced aspects of LVM and won't be covered here especially the clustered VGs which are used in the case of a shared storage space used in a cluster of machines. Talking about clustered VGs management in particular would require and entire article in itself. '''For now the only detail you have to worry about those dashes in ''Attrs'' is to see a dash at the 4th position of ''Attrs'' instead of a ''p'''''. Seeing ''p'' there would be a bad news: the VG would have missing parts (PV) making it not usable.
| | '''Create Partition 1''' (boot): |
|
| |
|
| {{fancynote|In the exact same manner you can see a detailed information about physical volumes with '''pvdisplay''', you can see detailed information of a volume group with '''vgdisplay'''. We will demonstrate that latter command in the paragraphs to follow.}}
| | <console> |
| | Command (m for help): ##i##n ↵ |
| | Partition type (default p): ##i##↵ |
| | Partition number (1-4, default 1): ##i##↵ |
| | First sector: ##i##↵ |
| | Last sector: ##i##+128M ↵ |
| | </console> |
|
| |
|
| Before leaving the volume group aspect, do you remember the '''pvs''' command shown in the previous paragraphs? Try it gain:
| | '''Create Partition 2''' (swap): |
|
| |
|
| <pre> | | <console> |
| # pvs | | Command (m for help): ##i##n ↵ |
| PV VG Fmt Attr PSize PFree
| | Partition type (default p): ##i##↵ |
| /dev/loop0 vgtest lvm2 a- 2.00g 2.00g
| | Partition number (2-4, default 2): ##i##↵ |
| /dev/loop1 vgtest lvm2 a- 2.00g 2.00g
| | First sector: ##i##↵ |
| /dev/loop2 vgtest lvm2 a- 2.00g 2.00g
| | Last sector: ##i##+2G ↵ |
| </pre> | | Command (m for help): ##i##t ↵ |
| | Partition number (1,2, default 2): ##i## ↵ |
| | Hex code (type L to list all codes): ##i##82 ↵ |
| | </console> |
|
| |
|
| Now it shows the VG our PVs belong to :-)
| | '''Create the root partition:''' |
|
| |
|
| == Logical volumes creation ==
| | <console> |
| | Command (m for help): ##i##n ↵ |
| | Partition type (default p): ##i##↵ |
| | Partition number (3,4, default 3): ##i##↵ |
| | First sector: ##i##↵ |
| | Last sector: ##i##↵ |
| | </console> |
|
| |
|
| Now the final steps: we will create the storage areas (logical volumes or ''LV'') inside the VG where we will then create filesystems on. Just like a VG has a name, a LV has also a name which is unique in the VG.
| | '''Verify the partition table:''' |
|
| |
|
| {{fancynote|Two LV can be given the same name as long as they are located on a different VG.}}
| | <console> |
| | Command (m for help): ##i##p |
|
| |
|
| To divide our VG like below:
| | Disk /dev/sda: 298.1 GiB, 320072933376 bytes, 625142448 sectors |
| | Units: sectors of 1 * 512 = 512 bytes |
| | Sector size (logical/physical): 512 bytes / 512 bytes |
| | I/O size (minimum/optimal): 512 bytes / 512 bytes |
| | Disklabel type: dos |
| | Disk identifier: 0x82abc9a6 |
|
| |
|
| * lvdata1: 2 GB
| | Device Boot Start End Blocks Id System |
| * lvdata2: 1 GB
| | /dev/sda1 2048 264191 131072 83 Linux |
| * lvdata3 : 10% of the VG size
| | /dev/sda2 264192 4458495 2097152 82 Linux swap / Solaris |
| * lvdata4 : All of remaining free space in the VG
| | /dev/sda3 4458496 625142447 310341976 83 Linux |
| | </console> |
|
| |
|
| We use the following commands (notice the capital 'L' and the small 'l' to declare absolute or relative sizes):
| | '''Write the parition table to disk:''' |
|
| |
|
| <pre> | | <console> |
| # lvcreate -n lvdata1 -L 2GB vgtest | | Command (m for help): ##i##w |
| Logical volume "lvdata1" created
| | </console> |
| # lvcreate -n lvdata2 -L 1GB vgtest | |
| Logical volume "lvdata2" created
| |
| # lvcreate -n lvdata3 -l 10%VG vgtest | |
| Logical volume "lvdata2" created
| |
| </pre> | |
|
| |
|
| What is going on so far? Let's check with the pvs/vgs counterpart known as '''lvs''':
| | Your new MBR partition table will now be written to your system disk. |
|
| |
|
| <pre>
| | {{Note|You're done with partitioning! Now, jump over to [[#Creating filesystems|Creating filesystems]].}} |
| # lvs | |
| LV VG Attr LSize Origin Snap% Move Log Copy% Convert
| |
| lvdata1 vgtest -wi-a- 2.00g
| |
| lvdata2 vgtest -wi-a- 1.00g
| |
| lvdata3 vgtest -wi-a- 612.00m
| |
| #
| |
| </pre>
| |
|
| |
|
| Notice the size of ''lvdata3'', it is roughly 600MB (10% of 6GB). How much free space remains in the VG? Time to see what '''vgs''' and '''vgdisplay''' returns:
| | ==== New-School (UEFI/GPT) Method ==== |
|
| |
|
| <pre>
| | {{Note|Use this method if you are booting using UEFI, and if your System Rescue CD initial boot menu was black and white. If it was light blue, this method will not work.}} |
| # vgs
| |
| VG #PV #LV #SN Attr VSize VFree
| |
| vgtest 3 3 0 wz--n- 5.99g 2.39g
| |
| # vgdisplay
| |
| --- Volume group ---
| |
| VG Name vgtest
| |
| System ID
| |
| Format lvm2
| |
| Metadata Areas 3
| |
| Metadata Sequence No 4
| |
| VG Access read/write
| |
| VG Status resizable
| |
| MAX LV 0
| |
| Cur LV 3
| |
| Open LV 0
| |
| Max PV 0
| |
| Cur PV 3
| |
| Act PV 3
| |
| VG Size 5.99 GiB
| |
| PE Size 4.00 MiB
| |
| Total PE 1533
| |
| Alloc PE / Size 921 / 3.60 GiB
| |
| Free PE / Size 612 / 2.39 GiB
| |
| VG UUID baM3vr-G0kh-PXHy-Z6Dj-bMQQ-KK6R-ewMac2
| |
| </pre>
| |
|
| |
|
| Basically it say we have 1533 PE (chunks) available for a total size of 5.99 GiB. On those 1533, 921 are used (for a size of 3.60 GiB) and 612 remains free (for a size of 2.39 GiB). So we expect to see lvdata4 having an approximative size of 2.4 GiB. Before creating it, have a look at some statistics at the PV level:
| | The <tt>gdisk</tt> commands to create a GPT partition table are as follows. Adapt sizes as necessary, although these defaults will work for most users. Start <code>gdisk</code>: |
|
| |
|
| <pre> | | <console> |
| # pvs | | # ##i##gdisk |
| PV VG Fmt Attr PSize PFree
| | </console> |
| /dev/loop0 vgtest lvm2 a- 2.00g 0
| |
| /dev/loop1 vgtest lvm2 a- 2.00g 404.00m
| |
| /dev/loop2 vgtest lvm2 a- 2.00g 2.00g
| |
|
| |
|
| # pvdisplay
| | Within <tt>gdisk</tt>, follow these steps: |
| --- Physical volume ---
| |
| PV Name /dev/loop0
| |
| VG Name vgtest
| |
| PV Size 2.00 GiB / not usable 4.00 MiB
| |
| Allocatable yes (but full)
| |
| PE Size 4.00 MiB
| |
| Total PE 511
| |
| Free PE 0
| |
| Allocated PE 511
| |
| PV UUID b9i1Hi-llka-egCF-2vU2-f7tp-wBqh-qV4qEk
| |
|
| |
| --- Physical volume ---
| |
| PV Name /dev/loop1
| |
| VG Name vgtest
| |
| PV Size 2.00 GiB / not usable 4.00 MiB
| |
| Allocatable yes
| |
| PE Size 4.00 MiB
| |
| Total PE 511
| |
| Free PE 101
| |
| Allocated PE 410
| |
| PV UUID i3mdBO-9WIc-EO2y-NqRr-z5Oa-ItLS-jbjq0E
| |
|
| |
| --- Physical volume ---
| |
| PV Name /dev/loop2
| |
| VG Name vgtest
| |
| PV Size 2.00 GiB / not usable 4.00 MiB
| |
| Allocatable yes
| |
| PE Size 4.00 MiB
| |
| Total PE 511
| |
| Free PE 511
| |
| Allocated PE 0
| |
| PV UUID dEwVuO-a5vQ-ipcH-Rvlt-5zWt-iAB2-2F0XBf
| |
| </pre> | |
|
| |
|
| Quite interesting! Did you notice? The first PV is full, the second is more or less full and the third is empty. This is due to the allocation policy used for the VG: it fills its first PV then its second PV and then its third PV (this, by the way, gives you a chance to recover from a dead physical storage if by luck none of your PE was present on it).
| | '''Create a new empty partition table''' (This ''will'' erase all data on the disk when saved): |
|
| |
|
| It is now time to create our last LV, again notice the small 'l' to specify a relative size:
| | <console> |
| | Command: ##i##o ↵ |
| | This option deletes all partitions and creates a new protective MBR. |
| | Proceed? (Y/N): ##i##y ↵ |
| | </console> |
|
| |
|
| <pre>
| | '''Create Partition 1''' (boot): |
| # lvcreate -n lvdata4 -l 100%FREE vgtest
| |
| Logical volume "lvdata4" created
| |
| # lvs
| |
| LV VG Attr LSize Origin Snap% Move Log Copy% Convert
| |
| lvdata1 vgtest -wi-a- 2.00g
| |
| lvdata2 vgtest -wi-a- 1.00g
| |
| lvdata3 vgtest -wi-a- 612.00m
| |
| lvdata4 vgtest -wi-a- 2.39g
| |
| </pre>
| |
|
| |
|
| Now the $100 question: if '''pvdisplay''' and '''vgdisplay''' commands exist, does command named '''lvdisplay''' exist as well? Yes absolutely! Indeed the command sets are coherent between abstraction levels (PV/VG/LV) and they are named in the exact same manner modulo their first 2 letters:
| | <console> |
| | Command: ##i##n ↵ |
| | Partition Number: ##i##1 ↵ |
| | First sector: ##i##↵ |
| | Last sector: ##i##+500M ↵ |
| | Hex Code: ##i##↵ |
| | </console> |
|
| |
|
| * PV: pvs/pvdisplay/pvchange....
| | '''Create Partition 2''' (swap): |
| * VG: vgs/vgdisplay/vgchange....
| |
| * LG: lvs/lvdisplay/lvchange....
| |
|
| |
|
| Back to our '''lvdisplay''' command, here is how it shows up:
| | <console> |
| | Command: ##i##n ↵ |
| | Partition Number: ##i##2 ↵ |
| | First sector: ##i##↵ |
| | Last sector: ##i##+4G ↵ |
| | Hex Code: ##i##8200 ↵ |
| | </console> |
|
| |
|
| <pre>
| | '''Create Partition 3''' (root): |
| # lvdisplay
| |
| --- Logical volume ---
| |
| LV Name /dev/vgtest/lvdata1
| |
| VG Name vgtest
| |
| LV UUID fT22is-cmSL-uhwM-zwCd-jeIe-DWO7-Hkj4k3
| |
| LV Write Access read/write
| |
| LV Status available
| |
| # open 0
| |
| LV Size 2.00 GiB
| |
| Current LE 512
| |
| Segments 2
| |
| Allocation inherit
| |
| Read ahead sectors auto
| |
| - currently set to 256
| |
| Block device 253:0
| |
|
| |
| --- Logical volume ---
| |
| LV Name /dev/vgtest/lvdata2
| |
| VG Name vgtest
| |
| LV UUID yd07wA-hj77-rOth-vxW8-rwo9-AX7q-lcyb3p
| |
| LV Write Access read/write
| |
| LV Status available
| |
| # open 0
| |
| LV Size 1.00 GiB
| |
| Current LE 256
| |
| Segments 1
| |
| Allocation inherit
| |
| Read ahead sectors auto
| |
| - currently set to 256
| |
| Block device 253:1
| |
|
| |
| --- Logical volume ---
| |
| LV Name /dev/vgtest/lvdata3
| |
| VG Name vgtest
| |
| LV UUID ocMCL2-nkcQ-Fwdx-pss4-qeSm-NtqU-J7vAXG
| |
| LV Write Access read/write
| |
| LV Status available
| |
| # open 0
| |
| LV Size 612.00 MiB
| |
| Current LE 153
| |
| Segments 1
| |
| Allocation inherit
| |
| Read ahead sectors auto
| |
| - currently set to 256
| |
| Block device 253:2
| |
|
| |
| --- Logical volume ---
| |
| LV Name /dev/vgtest/lvdata4
| |
| VG Name vgtest
| |
| LV UUID iQ2rV7-8Em8-85ts-anan-PePb-gk18-A31bP6
| |
| LV Write Access read/write
| |
| LV Status available
| |
| # open 0
| |
| LV Size 2.39 GiB
| |
| Current LE 612
| |
| Segments 2
| |
| Allocation inherit
| |
| Read ahead sectors auto
| |
| - currently set to 256
| |
| Block device 253:3
| |
| </pre>
| |
|
| |
|
| Nothing extremely useful to comment for an overview beyond showing at the exception of two things:
| | <console> |
| # '''LVs are accessed via the device mapper''' (see the lines starting by ''LV Name'' and notice how the name is composed). So '''lvdata1''' will be accessed via ''/dev/vgtest/lvdata1'', ''lvdata2'' will be accessed via ''/dev/vgtest/lvdata2'' and so on. | | Command: ##i##n ↵ |
| # just like PV are managed in sets of data chunks (the so famous Physical Extents or PEs), LVs are managed in a set of data chunks known as Logical Extents or LEs. Most of the time you don't have to worry about the existence of LEs because they fits withing a single PE although it is possible to make them smaller hence having several LE within a single PE. Demonstration: if you consider the first LV, '''lvdisplay''' says it has a size of 2 GiB and holds 512 logical extents. Dividing 2GiB by 512 gives 4 MiB as the size of a LE which is the exact same size used for PEs as seen when demonstrating the '''pvdisplay''' command some paragraphs above. So in our case we have a 1:1 match between a LE and the underlying PE. | | Partition Number: ##i##3 ↵ |
| | First sector: ##i##↵ |
| | Last sector: ##i##↵##!i## (for rest of disk) |
| | Hex Code: ##i##↵ |
| | </console> |
|
| |
|
| Oh another great point to underline: you can display the PV in relation with a LV :-) Just give a special option to '''lvdisplay''':
| | Along the way, you can type "<tt>p</tt>" and hit Enter to view your current partition table. If you make a mistake, you can type "<tt>d</tt>" to delete an existing partition that you created. When you are satisfied with your partition setup, type "<tt>w</tt>" to write your configuration to disk: |
|
| |
|
| <pre>
| | '''Write Partition Table To Disk''': |
| # lvdisplay -m
| |
| --- Logical volume ---
| |
| LV Name /dev/vgtest/lvdata1
| |
| VG Name vgtest
| |
| (...)
| |
| Current LE 512
| |
| Segments 2
| |
| (...)
| |
| --- Segments ---
| |
| Logical extent 0 to 510:
| |
| Type linear
| |
| Physical volume /dev/loop0
| |
| Physical extents 0 to 510
| |
|
| |
| Logical extent 511 to 511:
| |
| Type linear
| |
| Physical volume /dev/loop1
| |
| Physical extents 0 to 0
| |
|
| |
|
| |
| --- Logical volume ---
| |
| LV Name /dev/vgtest/lvdata2
| |
| VG Name vgtest
| |
| (...)
| |
| Current LE 256
| |
| Segments 1
| |
| (...)
| |
|
| |
| --- Segments ---
| |
| Logical extent 0 to 255:
| |
| Type linear
| |
| Physical volume /dev/loop1
| |
| Physical extents 1 to 256
| |
|
| |
|
| |
| --- Logical volume ---
| |
| LV Name /dev/vgtest/lvdata3
| |
| VG Name vgtest
| |
| (...)
| |
| Current LE 153
| |
| Segments 1
| |
| (...)
| |
|
| |
| --- Segments ---
| |
| Logical extent 0 to 152:
| |
| Type linear
| |
| Physical volume /dev/loop1
| |
| Physical extents 257 to 409
| |
|
| |
|
| |
| --- Logical volume ---
| |
| LV Name /dev/vgtest/lvdata4
| |
| VG Name vgtest
| |
| (...)
| |
| Current LE 612
| |
| Segments 2
| |
| (...)
| |
|
| |
| --- Segments ---
| |
| Logical extent 0 to 510:
| |
| Type linear
| |
| Physical volume /dev/loop2
| |
| Physical extents 0 to 510
| |
|
| |
| Logical extent 511 to 611:
| |
| Type linear
| |
| Physical volume /dev/loop1
| |
| Physical extents 410 to 510
| |
| </pre>
| |
|
| |
|
| To go one step further let's analyze a bit how the PE are used: the first LV has 512 LEs (remember: one LE fits within one PE here so 1 LE = 1 PE). Amongst those 512 LEs, 511 of them (0 to 510) are stored on /dev/loop0 and the 512th LE is on /dev/loop1. Huh? Something seems to be wrong here, '''pvdisplay''' said that /dev/loop0 was holding 512 PV so why an extent has been placed on the second storage device? Indeed its not a misbehaviour and absolutely normal: LVM uses some metadata internally with regards the PV, VG and LV thus making some of storage space unavailable for the payload. This explains why 1 PE has been "eaten" to store that metadata. Also notice the linear allocation process: ''/dev/loop0'' has been used, then when being full ''/dev/loop1'' has also been used then the turn of /''dev/loop2'' came.
| | <console> |
| | Command: ##i##w ↵ |
| | Do you want to proceed? (Y/N): ##i##Y ↵ |
| | </console> |
|
| |
|
| Now everything is in place, if you want just check again with '''vgs/pvs/vgdisplay/pvdisplay''' and will notice that the VG is now 100% full and all of the underlying PV are also 100% full.
| | The partition table will now be written to disk and <tt>gdisk</tt> will close. |
|
| |
|
| == Filesystems creation and mounting ==
| | Now, your GPT/GUID partitions have been created, and will show up as the following ''block devices'' under Linux: |
|
| |
|
| Now we have our LVs it could be fun if we could do something useful with them. In the case you missed it, LVs are accessed via the device mapper which uses a combination of the VG and LV names thus:
| | * <tt>/dev/sda1</tt>, which will be used to hold the <tt>/boot</tt> filesystem, |
| * lvdata1 is accessible via /dev/vgtest/lvdata1 | | * <tt>/dev/sda2</tt>, which will be used for swap space, and |
| * lvdata2 is accessible via /dev/vgtest/lvdata2 | | * <tt>/dev/sda3</tt>, which will hold your root filesystem. |
| * and so on!
| |
|
| |
|
| Just like any traditional storage device, the newly created LVs are seen as block devices as well just as if they were a kind of harddisk (don't worry about the "dm-..", it is just an internal block device automatically allocated by the device mapper for you):
| | ==== Creating filesystems ==== |
| <pre>
| |
| # ls -l /dev/vgtest
| |
| total 0
| |
| lrwxrwxrwx 1 root root 7 Dec 27 12:54 lvdata1 -> ../dm-0
| |
| lrwxrwxrwx 1 root root 7 Dec 27 12:54 lvdata2 -> ../dm-1
| |
| lrwxrwxrwx 1 root root 7 Dec 27 12:54 lvdata3 -> ../dm-2
| |
| lrwxrwxrwx 1 root root 7 Dec 27 12:54 lvdata4 -> ../dm-3
| |
|
| |
|
| # ls -l /dev/dm-[0-3]
| | {{Note|This section covers both BIOS ''and'' UEFI installs. Don't skip it!}} |
| brw-rw---- 1 root disk 253, 0 Dec 27 12:54 /dev/dm-0
| |
| brw-rw---- 1 root disk 253, 1 Dec 27 12:54 /dev/dm-1
| |
| brw-rw---- 1 root disk 253, 2 Dec 27 12:54 /dev/dm-2
| |
| brw-rw---- 1 root disk 253, 3 Dec 27 12:54 /dev/dm-3
| |
| </pre>
| |
|
| |
|
| So if LVs are block device a filesystem can be created on them just like if they were a real harddisk or hardisk partitions? Absolutely! Now let's create ext4 filesystems on our LVs:
| | Before your newly-created partitions can be used, the block devices need to be initialized with filesystem ''metadata''. This process is known as ''creating a filesystem'' on the block devices. After filesystems are created on the block devices, they can be mounted and used to store files. |
|
| |
|
| <pre>
| | Let's keep this simple. Are you using old-school MBR partitions? If so, let's create an ext2 filesystem on /dev/sda1: |
| # mkfs.ext4 /dev/vgtest/lvdata1
| |
|
| |
|
| mke2fs 1.42 (29-Nov-2011)
| | <console> |
| Discarding device blocks: done
| | # ##i##mkfs.ext2 /dev/sda1 |
| Filesystem label=
| | </console> |
| OS type: Linux
| |
| Block size=4096 (log=2)
| |
| Fragment size=4096 (log=2)
| |
| Stride=0 blocks, Stripe width=0 blocks
| |
| 131072 inodes, 524288 blocks
| |
| 26214 blocks (5.00%) reserved for the super user
| |
| First data block=0
| |
| Maximum filesystem blocks=536870912
| |
| 16 block groups
| |
| 32768 blocks per group, 32768 fragments per group
| |
| 8192 inodes per group
| |
| Superblock backups stored on blocks:
| |
| 32768, 98304, 163840, 229376, 294912
| |
|
| |
|
| Allocating group tables: done
| | If you're using new-school GPT partitions for UEFI, you'll want to create a vfat filesystem on /dev/sda1, because this is what UEFI is able to read: |
| Writing inode tables: done
| |
| Creating journal (16384 blocks): done
| |
| Writing superblocks and filesystem accounting information: done
| |
|
| |
|
| # mkfs.ext4 /dev/vgtest/lvdata1 | | <console> |
| (...)
| | # ##i##mkfs.vfat -F 32 /dev/sda1 |
| # mkfs.ext4 /dev/vgtest/lvdata2 | | </console> |
| (...)
| |
| # mkfs.ext4 /dev/vgtest/lvdata3 | |
| (..)
| |
| </pre> | |
|
| |
|
| Once the creation ended we must create the mount points and mount the newly created filesystems on them:
| | Now, let's create a swap partition. This partition will be used as disk-based virtual memory for your Funtoo Linux system. |
|
| |
|
| <pre> | | You will not create a filesystem on your swap partition, since it is not used to store files. But it is necessary to initialize it using the <code>mkswap</code> command. Then we'll run the <code>swapon</code> command to make your newly-initialized swap space immediately active within the live CD environment, in case it is needed during the rest of the install process: |
| # mkdir /mnt/data-01
| |
| # mkdir /mnt/data-02
| |
| # mkdir /mnt/data-03
| |
| # mkdir /mnt/data-04
| |
| # mount /dev/vgtest/lvdata1 /mnt/data01
| |
| # mount /dev/vgtest/lvdata2 /mnt/data02
| |
| # mount /dev/vgtest/lvdata3 /mnt/data03
| |
| # mount /dev/vgtest/lvdata4 /mnt/data04
| |
| </pre> | |
|
| |
|
| Finally we can check that everything is in order:
| | <console> |
| | # ##i##mkswap /dev/sda2 |
| | # ##i##swapon /dev/sda2 |
| | </console> |
|
| |
|
| <pre>
| | Now, we need to create a root filesystem. This is where Funtoo Linux will live. We generally recommend ext4 or XFS root filesystems. If you're not sure, choose ext4. Here's how to create a root ext4 filesystem: |
| # df -h
| |
| Filesystem Size Used Avail Use% Mounted on
| |
| (...)
| |
| /dev/mapper/vgtest-lvdata1 2.0G 96M 1.9G 5% /mnt/data01
| |
| /dev/mapper/vgtest-lvdata2 1022M 47M 924M 5% /mnt/data02
| |
| /dev/mapper/vgtest-lvdata3 611M 25M 556M 5% /mnt/data03
| |
| /dev/mapper/vgtest-lvdata4 2.4G 100M 2.2G 5% /mnt/data04
| |
| </pre>
| |
|
| |
|
| Did you notice the device has changed? Indeed everything is in order, mount just uses another set of symlinks which point to the exact same block devices:
| | <console> |
| | # ##i##mkfs.ext4 /dev/sda3 |
| | </console> |
|
| |
|
| <pre>
| | ...and here's how to create an XFS root filesystem, if you choose to use XFS: |
| # ls -l /dev/mapper/vgtest-lvdata[1-4]
| |
| lrwxrwxrwx 1 root root 7 Dec 28 20:12 /dev/mapper/vgtest-lvdata1 -> ../dm-0
| |
| lrwxrwxrwx 1 root root 7 Dec 28 20:13 /dev/mapper/vgtest-lvdata2 -> ../dm-1
| |
| lrwxrwxrwx 1 root root 7 Dec 28 20:13 /dev/mapper/vgtest-lvdata3 -> ../dm-2
| |
| lrwxrwxrwx 1 root root 7 Dec 28 20:13 /dev/mapper/vgtest-lvdata4 -> ../dm-3
| |
| </pre>
| |
|
| |
|
| == Renaming a volume group and its logical volumes ==
| | <console> |
| | # ##i##mkfs.xfs /dev/sda3 |
| | </console> |
|
| |
|
| So far we have four LVs named lvdata1 to lvdata4 mounted on /mnt/data01 to /mnt/data04. It would be more adequate to :
| | Your filesystems (and swap) have all now been initialized, so that that can be mounted (attached to your existing directory heirarchy) and used to store files. We are ready to begin installing Funtoo Linux on these brand-new filesystems. |
| # make the number in our LV names being like "01" instead of "1"
| |
| # rename our volume groupe to "vgdata" instead of "vgtest"
| |
|
| |
|
| To show how dynamic is the LVM world, we will rename our VG and LV on the fly using two commands: '''vgrename''' for acting at the VG level and its counterpart '''lvrename''' to act at the LV level. Starting by the VG or the LVs makes strictly no difference, you can start either way and get the same result. In our example we have chosen to start with the VG:
| | {{fancywarning|1= |
| | When deploying an OpenVZ host, please use ext4 exclusively. The Parallels development team tests extensively with ext4, and modern versions of <code>openvz-rhel6-stable</code> are '''not''' compatible with XFS, and you may experience kernel bugs. |
| | }} |
|
| |
|
| <pre>
| | ==== Mounting filesystems ==== |
| # vgrename vgtest vgdata
| |
| Volume group "vgtest" successfully renamed to "vgdata"
| |
| # lvrename vgdata/lvdata1 vgdata/lvdata01
| |
| Renamed "lvdata1" to "lvdata01" in volume group "vgdata"
| |
| # lvrename vgdata/lvdata2 vgdata/lvdata02
| |
| Renamed "lvdata2" to "lvdata02" in volume group "vgdata"
| |
| # lvrename vgdata/lvdata3 vgdata/lvdata03
| |
| Renamed "lvdata3" to "lvdata03" in volume group "vgdata"
| |
| # lvrename vgdata/lvdata4 vgdata/lvdata04
| |
| Renamed "lvdata4" to "lvdata04" in volume group "vgdata"
| |
| </pre>
| |
|
| |
|
| What happened? Simple:
| | Mount the newly-created filesystems as follows, creating <code>/mnt/funtoo</code> as the installation mount point: |
|
| |
|
| <pre> | | <console> |
| # vgs | | # ##i##mkdir /mnt/funtoo |
| VG #PV #LV #SN Attr VSize VFree
| | # ##i##mount /dev/sda3 /mnt/funtoo |
| vgdata 3 4 0 wz--n- 5.99g 0
| | # ##i##mkdir /mnt/funtoo/boot |
| # lvs | | # ##i##mount /dev/sda1 /mnt/funtoo/boot |
| LV VG Attr LSize Origin Snap% Move Log Copy% Convert
| | </console> |
| lvdata01 vgdata -wi-ao 2.00g
| |
| lvdata02 vgdata -wi-ao 1.00g
| |
| lvdata03 vgdata -wi-ao 612.00m
| |
| lvdata04 vgdata -wi-ao 2.39g
| |
| </pre> | |
|
| |
|
| Sounds good, our VG and LVs have been renamed! What a command like ''mount'' will say?
| | Optionally, if you have a separate filesystem for <code>/home</code> or anything else: |
|
| |
|
| <pre> | | <console> |
| # mount | | # ##i##mkdir /mnt/funtoo/home |
| (...)
| | # ##i##mount /dev/sda4 /mnt/funtoo/home |
| /dev/mapper/vgtest-lvdata1 on /mnt/data01 type ext4 (rw)
| | </console> |
| /dev/mapper/vgtest-lvdata2 on /mnt/data02 type ext4 (rw)
| |
| /dev/mapper/vgtest-lvdata3 on /mnt/data03 type ext4 (rw) | |
| /dev/mapper/vgtest-lvdata4 on /mnt/data04 type ext4 (rw)
| |
| </pre> | |
|
| |
|
| Ooops... It is not exactly a bug, mount still shows the symlinks used at the time the LVs were mounted in the VFS and has not updated its information. However once again everything is correct because the underlying block devices (/dev/dm-0 to /dev/dm-3) did not changed at all. To see the right information the LVs must be unmounted and mounted again:
| | If you have <code>/tmp</code> or <code>/var/tmp</code> on a separate filesystem, be sure to change the permissions of the mount point to be globally-writeable after mounting, as follows: |
|
| |
|
| <pre> | | <console> |
| # umount /mnt/data01 | | # ##i##chmod 1777 /mnt/funtoo/tmp |
| (...)
| | </console> |
| # umount /mnt/data04 | |
| # mount /dev/vgdata/lvdata01 /mnt/data01 | |
| (...)
| |
| # mount /dev/vgdata/lvdata04 /mnt/data04 | |
| # mount | |
| /dev/mapper/vgdata-lvdata01 on /mnt/data01 type ext4 (rw)
| |
| /dev/mapper/vgdata-lvdata02 on /mnt/data02 type ext4 (rw)
| |
| /dev/mapper/vgdata-lvdata03 on /mnt/data03 type ext4 (rw)
| |
| /dev/mapper/vgdata-lvdata04 on /mnt/data04 type ext4 (rw)
| |
| </pre>
| |
| | |
| {{fancynote|Using /dev/''volumegroup''/''logicalvolume'' or /dev/''volumegroup''-''logicalvolume'' makes no difference at all, those are two sets of symlinks pointing on the '''exact''' same block device. }}
| |
| | |
| = Expanding and shrinking the storage space =
| |
| | |
| Did you notice in the previous section we have never talked on topic like "create this partition at the beginning" or "allocate 10 sectors more". In LVM you do not have to worry about that kind of problematics: your only concern is more "Do I have the space to allocate a new LV or how can I extend an existing LV?". '''LVM takes cares of the low levels aspects for you, just focus on what you want to do with your storage space.'''
| |
| | |
| The most common problem with computers is the shortage of space on a volume, most of the time production servers can run months or years without requiring a reboot for various reasons (kernel upgrade, hardware failure...) however they regularly requires to extend their storage space because we do generate more and more data as the time goes. With "traditional" approach like fiddling directly with hard drives partitions, storage space manipulation can easily become a headache mainly because it requires coherent copy to be made and thus application downtimes. Don't expect the situation to be more enjoyable with a SAN storage rather a directly attached storage device... Basically the problems remains the same.
| |
| | |
| == Expanding a storage space ==
| |
| | |
| The most common task for a system administrator is to expand the available storage space. In the LVM world this implies:
| |
| * Creating a new PV
| |
| * Adding the PV to the VG (thus extending the VG capacity)
| |
| * Extending the existing LVs or create new ones
| |
| * Extending the structures of the filesystems located on a LV in the case a LV is extended (Not all of the filesystems around support that capability).
| |
| | |
| === Bringing a new PV in the VG ===
| |
| | |
| In the exact same manner we have created our first PV let's create our additional storage device, associate it to a loopback device and then create a PV on it:
| |
| | |
| <pre>
| |
| # dd if=/dev/zero of=/tmp/hdd4.img bs=2G count=1
| |
| # losetup /dev/loop3 /tmp/hdd4.img
| |
| # pvcreate /dev/loop3
| |
| </pre>
| |
| | |
| A '''pvs''' should report the new PV with 2 GB of free space:
| |
| | |
| <pre>
| |
| # pvs
| |
| PV VG Fmt Attr PSize PFree
| |
| /dev/loop0 vgdata lvm2 a- 2.00g 0
| |
| /dev/loop1 vgdata lvm2 a- 2.00g 0
| |
| /dev/loop2 vgdata lvm2 a- 2.00g 0
| |
| /dev/loop3 lvm2 a- 2.00g 2.00g
| |
| </pre>
| |
| | |
| Excellent! The next step consist of adding this newly created PV inside our VG ''vgdata'', this is where the '''vgextend''' command comes at our rescue:
| |
| | |
| <pre>
| |
| # vgextend vgdata /dev/loop3
| |
| Volume group "vgdata" successfully extended
| |
| # vgs
| |
| VG #PV #LV #SN Attr VSize VFree
| |
| vgdata 4 4 0 wz--n- 7.98g 2.00g
| |
| </pre>
| |
| | |
| Great, ''vgdata'' is now 8 GB large instead of 6 GB and have 2 GB of free space to allocate to either new LVs either existing LVs.
| |
| | |
| === Extending the LV and its filesystem ===
| |
| | |
| Bringing new LV would demonstrate nothing more nevertheless extending our existing LVs is much more interesting. How can we use our 2GB extra free space? We can, for example, split it in two allocating a 50% to our first (''lvdata01'') and third (''lvdata03'') LV adding 1GB of space to both. The best of the story is that operation is very simple and is realized with a command named '''lvextend''':
| |
| | |
| <pre>
| |
| # lvextend vgdata/lvdata01 -l +50%FREE
| |
| Extending logical volume lvdata01 to 3.00 GiB
| |
| Logical volume lvdata01 successfully resized
| |
| # lvextend vgdata/lvdata03 -l +50%FREE
| |
| Extending logical volume lvdata03 to 1.10 GiB
| |
| Logical volume lvdata03 successfully resized
| |
| </pre>
| |
| | |
| Ouaps!! We did a mistake there: lvdata01 has the expected size (2GB + 1GB for a grand total of 3 GB) but lvdata03 only grown of 512 MB (for a grand total size of 1.1 GB). Our mistake was obvious: once the first gigabyte (50% of 2GB) of extra space has been given to lvdata01, only one gigabyte remained free on the VG thus when we said "allocate 50% of the remaining gigabyte to ''lvdata03''" LVM added only 512 MB leaving the other half of this gigabyte unused. The '''vgs''' command can confirm this:
| |
| | |
| <pre>
| |
| # vgs
| |
| VG #PV #LV #SN Attr VSize VFree
| |
| vgdata 4 4 0 wz--n- 7.98g 512.00m
| |
| </pre> | |
| | |
| Nevermind about that voluntary mistake we will keep that extra space for a later paragraph :-) What happened to the storage space visible from the operating system?
| |
| | |
| <pre>
| |
| # df -h | grep lvdata01
| |
| /dev/mapper/vgdata-lvdata01 2.0G 96M 1.9G 5% /mnt/data01
| |
| </pre>
| |
| | |
| Obviously resizing a LV does not "automagically" resize the filesystem structures to take into account the new LV size making that step part of our duty. Happily for us, ext3 can be resized and better it can be grown when mounted in the VFS. This is known as ''online resizing'' and a few others filesystems supports that capability, among them we can quote ext2 (ext3 without a journal), ext4 (patches integrated very recently as of Nov/Dec 2011), XFS, ResiserFS and BTRFS. To our knowledge, only BTRFS support both online resizing '''and''' online shrinking as of Decembrer 2011, all of the others require a filesystem to be unmounted first before being shrunk.
| |
| | |
| {{fancynote|Consider using the option -r when invoking lvextend, it asks the command to perform a filesystem resize.}}
| |
| | |
| Now let's extend (grow) the ext3 filesystem located on lvdata01. As said above, ext3 support online resizing hence we do not need to kick it out of the VFS first:
| |
| | |
| <pre>
| |
| # resize2fs /dev/vgdata/lvdata01
| |
| resize2fs 1.42 (29-Nov-2011)
| |
| Filesystem at /dev/vgdata/lvdata01 is mounted on /mnt/data01; on-line resizing required
| |
| old_desc_blocks = 1, new_desc_blocks = 1
| |
| Performing an on-line resize of /dev/vgdata/lvdata01 to 785408 (4k) blocks.
| |
| The filesystem on /dev/vgdata/lvdata01 is now 785408 blocks long.
| |
| | |
| # df -h | grep lvdata01
| |
| /dev/mapper/vgdata-lvdata01 3.0G 96M 2.8G 4% /mnt/data01
| |
| </pre>
| |
| | |
| ''Et voila!'' Our LV has now plenty of new space usable :-) '''We do not bother about ''how'' the storage is organized by LVM amongst the underlying storage devices and it is not our problem after all. We only worry about having our storage requirements being satisfied without any further details. From our point of view everything is seen just as if we were manipulating a single storage device subdivided in several partitions of a dynamic size and always organized in a set of contiguous blocks.'''
| |
| | |
| Now let's shuffle the cards a bit more: when we examined how the LEs of our LVs were allocated, we saw that ''lvdata01'' (named lvdata1 at this time) consisted of 512 LEs or 512 PEs (because of the 1:1 mapping between those) spread over two PVs. As we have extended it to use an additional PV, we should see it using 3 segments:
| |
| | |
| * Segment 1: located on the PV stored on /dev/loop0 (LE/PE #0 to #510)
| |
| * Segment 2: located on the PV stored on /dev/loop1 (LE/PE #511)
| |
| * Segment 3: located on the PV stored on /dev/loop1 (LE/PE #512 and followers)
| |
| | |
| Is it the case? Let's check:
| |
| | |
| <pre>
| |
| # lvdisplay -m vgdata/lvdata01
| |
| --- Logical volume ---
| |
| LV Name /dev/vgdata/lvdata01
| |
| VG Name vgdata
| |
| LV UUID fT22is-cmSL-uhwM-zwCd-jeIe-DWO7-Hkj4k3
| |
| LV Write Access read/write
| |
| LV Status available
| |
| # open 1
| |
| LV Size 3.00 GiB
| |
| Current LE 767
| |
| Segments 3
| |
| Allocation inherit
| |
| Read ahead sectors auto
| |
| - currently set to 256
| |
| Block device 253:0
| |
|
| |
| --- Segments ---
| |
| Logical extent 0 to 510:
| |
| Type linear
| |
| Physical volume /dev/loop0
| |
| Physical extents 0 to 510
| |
|
| |
| Logical extent 511 to 511:
| |
| Type linear
| |
| Physical volume /dev/loop1
| |
| Physical extents 0 to 0
| |
|
| |
| Logical extent 512 to 766:
| |
| Type linear
| |
| Physical volume /dev/loop3
| |
| Physical extents 0 to 254
| |
| </pre>
| |
| | |
| Bingo! Note that if it is true here (LVM uses linear allocation) would not be true in the general case.
| |
| | |
| {{fancywarning|'''Never mix a local storage device with a SAN disk within the same volume group''' and especially if that later is your system volume. It will bring you a lot of troubles if the SAN disk goes offline or bring weird performance fluctuations as PEs allocated on the SAN will get faster response times than those located on a local disk. }}
| |
| | |
| == Shrinking a storage space ==
| |
| | |
| On some occasions it can be useful to reduce the size of a LV or the size of the VG itself. The principle is similar to what has been demonstrated in the previous section:
| |
| | |
| # umount the filesystem belong to the LV to be processed (if your filesystem does not support online shrinking)
| |
| # reduce the filesystem size (if the LV is not to be flushed)
| |
| # reduce the LV size - OR - remove the LV
| |
| # remove a PV from the volume group if no longer used to store extents
| |
| | |
| The simplest case to start with is how a LV can be removed: a good candidate for removal is ''lvdata03'', we failed to resize it and the better would be to scrap it. First unmount it:
| |
| | |
| <pre>
| |
| # lvs
| |
| LV VG Attr LSize Origin Snap% Move Log Copy% Convert
| |
| lvdata01 vgdata -wi-ao 3.00g
| |
| lvdata02 vgdata -wi-ao 1.00g
| |
| lvdata03 vgdata -wi-ao 1.10g
| |
| lvdata04 vgdata -wi-ao 2.39g
| |
| # umount /dev/vgdata/lvdata03
| |
| # lvs
| |
| LV VG Attr LSize Origin Snap% Move Log Copy% Convert
| |
| lvdata01 vgdata -wi-ao 3.00g
| |
| lvdata02 vgdata -wi-ao 1.00g
| |
| lvdata03 vgdata -wi-a- 1.10g
| |
| lvdata04 vgdata -wi-ao 2.39g
| |
| </pre>
| |
| | |
| Noticed the little change with '''lvs'''? It lies in the ''Attr'' field: once the ''lvdata03'' has been unmounted, '''lvs''' tells us the LV is not '''o'''pened anymore (the little o at the rightmost position has been replaced by a dash). The LV still exists but nothing is using it.
| |
| | |
| To remove ''lvdata03'' use the command '''lvremove''' and confirm the removal by entering 'y' when asked:
| |
| | |
| <pre>
| |
| # lvremove vgdata/lvdata03
| |
| Do you really want to remove active logical volume lvdata03? [y/n]: y
| |
| Logical volume "lvdata03" successfully removed
| |
| # lvs
| |
| LV VG Attr LSize Origin Snap% Move Log Copy% Convert
| |
| lvdata01 vgdata -wi-ao 3.00g
| |
| lvdata02 vgdata -wi-ao 1.00g
| |
| lvdata04 vgdata -wi-ao 2.39g
| |
| # vgs
| |
| VG #PV #LV #SN Attr VSize VFree
| |
| vgdata 4 3 0 wz--n- 7.98g 1.60g
| |
| </pre>
| |
| | |
| Notice the 1.60 of space has been freed in the VG. What can we do next? Shrinking ''lvdata04'' by 50% giving roughly 1.2GB or 1228MB (1.2*1024) of its size could be a good idea so here we go. First we need to umount the filesystem from the VFS because ext3 '''does not support''' online shrinking.
| |
| | |
| <pre>
| |
| # umount /dev/vgdata/lvdata04
| |
| # e2fsck -f /dev/vgdata/lvdata04
| |
| e2fsck 1.42 (29-Nov-2011)
| |
| Pass 1: Checking inodes, blocks, and sizes
| |
| Pass 2: Checking directory structure
| |
| Pass 3: Checking directory connectivity
| |
| Pass 4: Checking reference counts
| |
| Pass 5: Checking group summary information
| |
| /dev/vgdata/lvdata04: 11/156800 files (0.0% non-contiguous), 27154/626688 blocks
| |
| # resize2fs -p /dev/vgdata/lvdata04 -L 1228M
| |
| # lvreduce /dev/vgdata/lvdata04 -L 1228
| |
| WARNING: Reducing active logical volume to 1.20 GiB
| |
| THIS MAY DESTROY YOUR DATA (filesystem etc.)
| |
| Do you really want to reduce lvdata04? [y/n]: y
| |
| Reducing logical volume lvdata04 to 1.20 GiB
| |
| Logical volume lvdata04 successfully resized
| |
| oxygen ~ # e2fsck -f /dev/vgdata/lvdata04
| |
| e2fsck 1.42 (29-Nov-2011)
| |
| Pass 1: Checking inodes, blocks, and sizes
| |
| Pass 2: Checking directory structure
| |
| Pass 3: Checking directory connectivity
| |
| Pass 4: Checking reference counts
| |
| Pass 5: Checking group summary information
| |
| /dev/vgdata/lvdata04: 11/78400 files (0.0% non-contiguous), 22234/314368 blocks
| |
| </pre>
| |
| | |
| Not very practical indeed, we can tell '''lvreduce''' to handle the underlying filesystem shrinkage for us. Let's shrink again this time giving a 1 GB volume (1024 MB) in absolute size:
| |
| | |
| <pre>
| |
| # lvreduce /dev/vgdata/lvdata04 -r -L 1024
| |
| fsck from util-linux 2.20.1
| |
| /dev/mapper/vgdata-lvdata04: clean, 11/78400 files, 22234/314368 blocks
| |
| resize2fs 1.42 (29-Nov-2011)
| |
| Resizing the filesystem on /dev/mapper/vgdata-lvdata04 to 262144 (4k) blocks.
| |
| The filesystem on /dev/mapper/vgdata-lvdata04 is now 262144 blocks long.
| |
| | |
| Reducing logical volume lvdata04 to 1.00 GiB
| |
| Logical volume lvdata04 successfully resized
| |
| # lvs
| |
| LV VG Attr LSize Origin Snap% Move Log Copy% Convert
| |
| lvdata01 vgdata -wi-ao 3.00g
| |
| lvdata02 vgdata -wi-ao 1.00g
| |
| lvdata04 vgdata -wi-a- 1.00g
| |
| </pre>
| |
| | |
| {{fancynote|Notice the number of 4k blocks shown: 4096*262144/1024^2 gives 1,073,741,824 bytes either 1 GB.}}
| |
| | |
| Time to mount the volume again:
| |
| | |
| <pre>
| |
| # mount /dev/vgdata/lvdata04 /mnt/data04
| |
| # df -h | grep lvdata04
| |
| /dev/mapper/vgdata-lvdata04 1021M 79M 891M 9% /mnt/data04
| |
| </pre>
| |
| | |
| And what is going on at the VG level?
| |
| | |
| <pre>
| |
| # vgs
| |
| VG #PV #LV #SN Attr VSize VFree
| |
| vgdata 4 3 0 wz--n- 7.98g 2.99g
| |
| </pre>
| |
| | |
| Wow, we have near 3 GB of free space inside, a bit more than one of our PV. It could be great if we can free one of the those and of course LVM gives you the possibility to do that. Before going further, let's check what happened at the PVs level:
| |
| | |
| <pre>
| |
| # pvs
| |
| PV VG Fmt Attr PSize PFree
| |
| /dev/loop0 vgdata lvm2 a- 2.00g 0
| |
| /dev/loop1 vgdata lvm2 a- 2.00g 1016.00m
| |
| /dev/loop2 vgdata lvm2 a- 2.00g 1020.00m
| |
| /dev/loop3 vgdata lvm2 a- 2.00g 1.00g
| |
| </pre>
| |
| | |
| Did you noticed? 1 GB of space has been freed on the last PV (/dev/loop3) since ''lvdata04'' has been shrunk not counting the space freed on ''/dev/loop1'' and ''/dev/loop2'' after the removal of lvdata02.
| |
| | |
| | |
| Next steo: can we remove a PV directly (the command to remove a PV from a VG is '''vgreduce''')?
| |
| | |
| <pre>
| |
| # vgreduce vgdata /dev/loop0
| |
| Physical volume "/dev/loop0" still in use
| |
| </pre>
| |
| | |
| Of course not, all of our PVs supports the content of our LVs and we must find a manner to move all of the PE (physical extents) actually hold by the PV /dev/loop0 elsewhere withing the VG. But wait a minute, the victory is there yet: we do have some free space in the /dev/loop0 and we will get more and more free space in it as the displacement process will progress. What is going to happen if, from a concurrent session, we create others LV in ''vgdata'' at the same time the content of /dev/loop0 is moved? Simple: it can be filled again with the PEs newly allocated.
| |
| | |
| So before proceeding to the displacement of what ''/dev/loop0'' contents, we must say to LVM: "please don't allocate anymore PEs on ''/dev/loop0''". This is achieved via the parameter ''-x'' of the command '''pvchange''':
| |
| <pre>
| |
| # pvchange -x n /dev/loop0
| |
| Physical volume "/dev/loop0" changed
| |
| 1 physical volume changed / 0 physical volumes not changed
| |
| </pre>
| |
| | |
| The value ''n'' given to ''-x'' marks the PV as ''unallocable'' (i.e. not usable for future PE allocations). Let's check again the PVs with '''pvs''' and '''pvdisplay''':
| |
| | |
| <pre>
| |
| # pvs
| |
| PV VG Fmt Attr PSize PFree
| |
| /dev/loop0 vgdata lvm2 -- 2.00g 0
| |
| /dev/loop1 vgdata lvm2 a- 2.00g 1016.00m
| |
| /dev/loop2 vgdata lvm2 a- 2.00g 1020.00m
| |
| /dev/loop3 vgdata lvm2 a- 2.00g 1.00g
| |
| | |
| # pvdisplay /dev/loop0
| |
| --- Physical volume ---
| |
| PV Name /dev/loop0
| |
| VG Name vgdata
| |
| PV Size 2.00 GiB / not usable 4.00 MiB
| |
| Allocatable NO
| |
| PE Size 4.00 MiB
| |
| Total PE 511
| |
| Free PE 0
| |
| Allocated PE 511
| |
| PV UUID b9i1Hi-llka-egCF-2vU2-f7tp-wBqh-qV4qEk
| |
| </pre>
| |
| | |
| Great news here, the ''Attrs'' field shows a dash instead of 'a' at the leftmost position meaning the PV is effectively ''not allocatable''. However '''marking a PV not allocatable does not wipe the existing PEs stored on it'''. In other words, it means that data present on the PV remains '''absolutely intact'''. Another positive point lies the remaining capacities of the PVs composing ''vgdata'': the sum of free space available on ''/dev/loop1'', ''/dev/loop2'' and ''/dev/loop3'' is 3060MB (1016MB + 1020MB + 1024MB) so largely sufficient to hold the 2048 MB (2 GB) actually stored on the PV ''/dev/loop0''.
| |
| | |
| Now we have frozen the allocation of PEs on /dev/loop0 we can make LVM move all of PEs located in this PV on the others PVs composing the VG ''vgdata''. Again, we don't have to worry about the gory details like where LVM will precisely relocate the PEs actually hold by ''/dev/loop0'', our '''only''' concerns is to get all of them moved out of ''/dev/loop0''. That job gets done by:
| |
| | |
| <pre>
| |
| # pvmove /dev/loop0
| |
| /dev/loop0: Moved: 5.9%
| |
| /dev/loop0: Moved: 41.3%
| |
| /dev/loop0: Moved: 50.1%
| |
| /dev/loop0: Moved: 100.0%
| |
| </pre>
| |
| | |
| We don't have to tell LVM the VG name because it already knows that ''/dev/loop0'' belongs to ''vgdata'' and what are the others PVs belonging to that VG usable to host the PEs coming from ''/dev/loop0''. It is absolutely normal for the process to takes some minutes (real life cases can go up to several hours even with SAN disks located on high-end storage hardware which is much more faster than local SATA or even SAS drive).
| |
| | |
| At the end of the moving process, we can see that the PV ''/dev/loop0'' is totally free:
| |
| | |
| <pre>
| |
| # pvs
| |
| PV VG Fmt Attr PSize PFree
| |
| /dev/loop0 vgdata lvm2 a- 2.00g 2.00g
| |
| /dev/loop1 vgdata lvm2 a- 2.00g 1016.00m
| |
| /dev/loop2 vgdata lvm2 a- 2.00g 0
| |
| /dev/loop3 vgdata lvm2 a- 2.00g 0
| |
| | |
| # pvdisplay /dev/loop0
| |
| --- Physical volume ---
| |
| PV Name /dev/loop0
| |
| VG Name vgdata
| |
| PV Size 2.00 GiB / not usable 4.00 MiB
| |
| Allocatable yes
| |
| PE Size 4.00 MiB
| |
| Total PE 511
| |
| Free PE 511
| |
| Allocated PE 0
| |
| PV UUID b9i1Hi-llka-egCF-2vU2-f7tp-wBqh-qV4qEk
| |
| </pre>
| |
| | |
| 511 PEs free out of a maximum 511 PEs so all of its containt has been successfully spread on the others PVs (the volume is also still marked as "unallocatable", this is normal). Now it is ready to be detached from the VG ''vgdata'' with the help of '''vgreduce''' :
| |
| | |
| <pre>
| |
| # vgreduce vgdata /dev/loop0
| |
| Removed "/dev/loop0" from volume group "vgdata"
| |
| </pre>
| |
| | |
| What happened to ''vgdata''?
| |
| <pre>
| |
| # vgs
| |
| VG #PV #LV #SN Attr VSize VFree
| |
| vgdata 3 3 0 wz--n- 5.99g 1016.00m
| |
| </pre>
| |
| | |
| Its storage space falls to ~6GB! What would tell '''pvs'''?
| |
| | |
| <pre>
| |
| # pvs
| |
| PV VG Fmt Attr PSize PFree
| |
| /dev/loop0 lvm2 a- 2.00g 2.00g
| |
| /dev/loop1 vgdata lvm2 a- 2.00g 1016.00m
| |
| /dev/loop2 vgdata lvm2 a- 2.00g 0
| |
| /dev/loop3 vgdata lvm2 a- 2.00g 0
| |
| </pre>
| |
| | |
| ''/dev/loop0'' is now a standalone device detached from any VG. However it still contains some LVM metadata that remains to be wiped with the help of the '''pvremove''' command:
| |
| | |
| {{fancywarning|pvremove/pvmove '''do not destroy the disk content'''. Please *do* a secure erase of the storage device with ''shred'' or any similar tool before disposing of it. }}
| |
| | |
| <pre>
| |
| # pvdisplay /dev/loop0
| |
| "/dev/loop0" is a new physical volume of "2.00 GiB"
| |
| --- NEW Physical volume ---
| |
| PV Name /dev/loop0
| |
| VG Name
| |
| PV Size 2.00 GiB
| |
| Allocatable NO
| |
| PE Size 0
| |
| Total PE 0
| |
| Free PE 0
| |
| Allocated PE 0
| |
| PV UUID b9i1Hi-llka-egCF-2vU2-f7tp-wBqh-qV4qEk
| |
| | |
| # pvremove /dev/loop0
| |
| Labels on physical volume "/dev/loop0" successfully wiped
| |
| # pvdisplay /dev/loop0
| |
| No physical volume label read from /dev/loop0
| |
| Failed to read physical volume "/dev/loop0"
| |
| </pre>
| |
| | |
| Great! Things are just simple than that. In their day to day reality, system administrators drive their show in a extremely close similar manner: they do additional tasks like taking backups of data located on the LVs before doing any risky operation or plan applications shutdown periods prior starting a manipulation with a LVM volume to take extra precautions.
| |
| | |
| == Replacing a PV (storage device) by another ==
| |
| | |
| The principle a mix of what has been said in the above sections. The principle is basically:
| |
| # Create a new PV
| |
| # Associate it to the VG
| |
| # Move the contents of the PV to be removed on the remaining PVs composing the VG
| |
| # Remove the PV from the VG and wipe it
| |
| | |
| The strategy in this paragraph is to reuse ''/dev/loop0'' and make it replace ''/dev/loop2'' (both devices are of the same size, however we also could have used a bigger ''/dev/loop0'' as well).
| |
| | |
| Here we go! First we need to (re-)create the LVM metadata to make ''/dev/loop0'' usable by LVM:
| |
| | |
| <pre>
| |
| # pvcreate /dev/loop0
| |
| Physical volume "/dev/loop0" successfully created
| |
| </pre>
| |
| | |
| Then this brand new PV is added to the VG ''vgdata'' thus increasing its size of 2 GB:
| |
| | |
| <pre>
| |
| # vgextend vgdata /dev/loop0
| |
| Volume group "vgdata" successfully extended
| |
| # vgs
| |
| VG #PV #LV #SN Attr VSize VFree
| |
| vgdata 4 3 0 wz--n- 7.98g 2.99g
| |
| # pvs
| |
| PV VG Fmt Attr PSize PFree
| |
| /dev/loop0 vgdata lvm2 a- 2.00g 2.00g
| |
| /dev/loop1 vgdata lvm2 a- 2.00g 1016.00m
| |
| /dev/loop2 vgdata lvm2 a- 2.00g 0
| |
| /dev/loop3 vgdata lvm2 a- 2.00g 0
| |
| </pre>
| |
| | |
| Now we have to suspend the allocation of PEs on ''/dev/loop2'' prior to moving its PEs (and freeing some space on it):
| |
| | |
| <pre>
| |
| # pvchange -x n /dev/loop2
| |
| Physical volume "/dev/loop2" changed
| |
| 1 physical volume changed / 0 physical volumes not changed
| |
| # pvs
| |
| PV VG Fmt Attr PSize PFree
| |
| /dev/loop0 vgdata lvm2 a- 2.00g 2.00g
| |
| /dev/loop1 vgdata lvm2 a- 2.00g 1016.00m
| |
| /dev/loop2 vgdata lvm2 -- 2.00g 0
| |
| /dev/loop3 vgdata lvm2 a- 2.00g 0
| |
| </pre>
| |
| | |
| Then we move all of the the PEs on ''/dev/loop2'' to the rest of the VG:
| |
| | |
| <pre>
| |
| # pvmove /dev/loop2
| |
| /dev/loop2: Moved: 49.9%
| |
| /dev/loop2: Moved: 100.0%
| |
| # pvs
| |
| PV VG Fmt Attr PSize PFree
| |
| /dev/loop0 vgdata lvm2 a- 2.00g 0
| |
| /dev/loop1 vgdata lvm2 a- 2.00g 1016.00m
| |
| /dev/loop2 vgdata lvm2 -- 2.00g 2.00g
| |
| /dev/loop3 vgdata lvm2 a- 2.00g 0
| |
| </pre>
| |
| | |
| Then we remove ''/dev/loop2'' from the VG and we wipe its LVM metadata:
| |
| | |
| <pre>
| |
| # vgreduce vgdata /dev/loop2
| |
| Removed "/dev/loop2" from volume group "vgdata"
| |
| # pvremove /dev/loop2
| |
| Labels on physical volume "/dev/loop2" successfully wiped
| |
| </pre>
| |
| | |
| Final state of the PVs composing ''vgdata'':
| |
| <pre>
| |
| # pvs
| |
| PV VG Fmt Attr PSize PFree
| |
| /dev/loop0 vgdata lvm2 a- 2.00g 0
| |
| /dev/loop1 vgdata lvm2 a- 2.00g 1016.00m
| |
| /dev/loop3 vgdata lvm2 a- 2.00g 0
| |
| </pre>
| |
| | |
| ''/dev/loop0'' took the place of ''/dev/loop2'' :-)
| |
| | |
| = More advanced topics =
| |
| | |
| == Backing up the layout ==
| |
| | |
| == Freezing a VG ==
| |
| | |
| == LVM snapshots ==
| |
| | |
| == Linear/Stripped/Mirrored Logical volumes ==
| |
| | |
| = LVM and Funtoo =
| |
| | |
| | |
| [[Category:Labs]]
| |
| [[Category:Filesystems]]
| |
| [[Category:Articles]]
| |
| {{ArticleFooter}}
| |
Note
This is a template that is used as part of the Installation instructions which covers: процесс разбиения диска и создания файловых систем. Templates are being used to allow multiple variant install guides that use most of the same re-usable parts.
Подготовка жесткого диска
В этой части мы научимся различным способам установки Funtoo Linux -- и загрузки с -- жесткий диск.
Введение
В прежние времена существовал лишь один способ загрузить PC-совместимый компьютер. Все наши дектопы и сервера имели стандартный PC BIOS, все наши харды использовали MBR и были разбиты используя схему разбивки MBR. Вот как это все было и нам это нравилось!
Затем появились EFI и UEFI, встроенные программы нового образца наряду со схемой разбивки GPT, поддерживающая диски размером более 2.2TБ. Неожиданно, нам стали доступны различные способы установки и загрузки Линукс систем . То, что было единым методом, стало чем-то более сложным.
Let's take a moment to review the options available to you for configuring a hard drive to boot Funtoo Linux. This Install Guide uses, and recommends, the old-school method of BIOS booting and using an MBR. It works and (except for rare cases) is universally supported. There's nothing wrong with it. If your system disk is 2TB or smaller in size, it won't prevent you from using all of your disk's capacity, either.
But, there are some situations where the old-school method isn't optimal. If you have a system disk >2TB in size, then MBR partitions won't allow you to access all your storage. So that's one reason. Another reason is that there are some so-called "PC" systems out there that don't support BIOS booting anymore, and force you to use UEFI to boot. So, out of compassion for people who fall into this predicament, this Install Guide documents UEFI booting too.
Our recommendation is still to go old-school unless you have reason not to. The boot loader we will be using to load the Linux kernel in this guide is called GRUB, so we call this method the BIOS + GRUB (MBR) method. It's the traditional method of setting up a PC-compatible system to boot Linux.
If you need to use UEFI to boot, we recommend not using the MBR at all for booting, as some systems support this, but others don't. Instead, we recommend using UEFI to boot GRUB, which in turn will load Linux. We refer to this method as the UEFI + GRUB (GPT) method.
And yes, there are even more methods, some of which are documented on the Boot Methods page. We used to recommend a BIOS + GRUB (GPT) method but it is not consistently supported across a wide variety of hardware.
The big question is -- which boot method should you use? Here's how to tell.
- Principle 1 - Old School
- If you can reliably boot System Rescue CD and it shows you an initial light blue menu, you are booting the CD using the BIOS, and it's likely that you can thus boot Funtoo Linux using the BIOS. So, go old-school and use BIOS booting, unless you have some reason to use UEFI, such as having a >2.2TB system disk. In that case, see Principle 2, as your system may also support UEFI booting.
- Principle 2 - New School
- If you can reliably boot System Rescue CD and it shows you an initial black and white menu -- congratulations, your system is configured to support UEFI booting. This means that you are ready to install Funtoo Linux to boot via UEFI. Your system may still support BIOS booting, but just be trying UEFI first. You can poke around in your BIOS boot configuration and play with this.
- What's the Big Difference between Old School and New School?
- Here's the deal. If you go with old-school MBR partitions, your
/boot partition will be an ext2 filesystem, and you'll use fdisk to create your MBR partitions. If you go with new-school GPT partitions and UEFI booting, your /boot partition will be a vfat filesystem, because this is what UEFI is able to read, and you will use gdisk to create your GPT partitions. And you'll install GRUB a bit differently. That's about all it comes down to, in case you were curious.
- Also Note
- To install Funtoo Linux to boot via the New School UEFI method, you must boot System Rescue CD using UEFI -- and see an initial black and white screen. Otherwise, UEFI will not be active and you will not be able to set it up!
Note
Some motherboards may appear to support UEFI, but don't. Do your research. For example, the Award BIOS in my Gigabyte GA-990FXA-UD7 rev 1.1 has an option to enable UEFI boot for CD/DVD. This is not sufficient for enabling UEFI boot for hard drives and installing Funtoo Linux. UEFI must be supported for both removable media (so you can boot System Rescue CD using UEFI) as well as fixed media (so you can boot your new Funtoo Linux installation.) It turns out that later revisions of this board (rev 3.0) have a new BIOS that fully supports UEFI boot. This may point to a third principle -- know thy hardware.
Old-School (BIOS/MBR) Method
Note
Use this method if you are booting using your BIOS, and if your System Rescue CD initial boot menu was light blue. If you're going to use the new-school method, click here to jump down to UEFI/GPT.
Preparation
First, it's a good idea to make sure that you've found the correct hard disk to partition. Try this command and verify that /dev/sda is the disk that you want to partition:
root # fdisk -l /dev/sda
Disk /dev/sda: 640.1 GB, 640135028736 bytes, 1250263728 sectors
Units = sectors of 1 * 512 = 512 bytes
Sector size (logical/physical): 512 bytes / 512 bytes
I/O size (minimum/optimal): 512 bytes / 512 bytes
Disk label type: gpt
root # Start End Size Type Name
1 2048 1250263694 596.2G Linux filesyste Linux filesystem
Now, it's recommended that you erase any existing MBR or GPT partition tables on the disk, which could confuse the system's BIOS at boot time. We do this using sgdisk:
Warning
This will make any existing partitions inaccessible! You are strongly cautioned and advised to backup any critical data before proceeding.
root # sgdisk --zap-all /dev/sda
Creating new GPT entries.
GPT data structures destroyed! You may now partition the disk using fdisk or
other utilities.
This output is also nothing to worry about, as the command still succeded:
***************************************************************
Found invalid GPT and valid MBR; converting MBR to GPT format
in memory.
***************************************************************
Partitioning
Now we will use fdisk to create the MBR partition table and partitions:
root # fdisk /dev/sda
Within fdisk, follow these steps:
Empty the partition table:
Command (m for help): o ↵
Create Partition 1 (boot):
Command (m for help): n ↵
Partition type (default p): ↵
Partition number (1-4, default 1): ↵
First sector: ↵
Last sector: +128M ↵
Create Partition 2 (swap):
Command (m for help): n ↵
Partition type (default p): ↵
Partition number (2-4, default 2): ↵
First sector: ↵
Last sector: +2G ↵
Command (m for help): t ↵
Partition number (1,2, default 2): ↵
Hex code (type L to list all codes): 82 ↵
Create the root partition:
Command (m for help): n ↵
Partition type (default p): ↵
Partition number (3,4, default 3): ↵
First sector: ↵
Last sector: ↵
Verify the partition table:
Command (m for help): p
Disk /dev/sda: 298.1 GiB, 320072933376 bytes, 625142448 sectors
Units: sectors of 1 * 512 = 512 bytes
Sector size (logical/physical): 512 bytes / 512 bytes
I/O size (minimum/optimal): 512 bytes / 512 bytes
Disklabel type: dos
Disk identifier: 0x82abc9a6
Device Boot Start End Blocks Id System
/dev/sda1 2048 264191 131072 83 Linux
/dev/sda2 264192 4458495 2097152 82 Linux swap / Solaris
/dev/sda3 4458496 625142447 310341976 83 Linux
Write the parition table to disk:
Command (m for help): w
Your new MBR partition table will now be written to your system disk.
New-School (UEFI/GPT) Method
Note
Use this method if you are booting using UEFI, and if your System Rescue CD initial boot menu was black and white. If it was light blue, this method will not work.
The gdisk commands to create a GPT partition table are as follows. Adapt sizes as necessary, although these defaults will work for most users. Start gdisk:
root # gdisk
Within gdisk, follow these steps:
Create a new empty partition table (This will erase all data on the disk when saved):
Command: o ↵
This option deletes all partitions and creates a new protective MBR.
Proceed? (Y/N): y ↵
Create Partition 1 (boot):
Command: n ↵
Partition Number: 1 ↵
First sector: ↵
Last sector: +500M ↵
Hex Code: ↵
Create Partition 2 (swap):
Command: n ↵
Partition Number: 2 ↵
First sector: ↵
Last sector: +4G ↵
Hex Code: 8200 ↵
Create Partition 3 (root):
Command: n ↵
Partition Number: 3 ↵
First sector: ↵
Last sector: ↵ (for rest of disk)
Hex Code: ↵
Along the way, you can type "p" and hit Enter to view your current partition table. If you make a mistake, you can type "d" to delete an existing partition that you created. When you are satisfied with your partition setup, type "w" to write your configuration to disk:
Write Partition Table To Disk:
Command: w ↵
Do you want to proceed? (Y/N): Y ↵
The partition table will now be written to disk and gdisk will close.
Now, your GPT/GUID partitions have been created, and will show up as the following block devices under Linux:
- /dev/sda1, which will be used to hold the /boot filesystem,
- /dev/sda2, which will be used for swap space, and
- /dev/sda3, which will hold your root filesystem.
Creating filesystems
Note
This section covers both BIOS and UEFI installs. Don't skip it!
Before your newly-created partitions can be used, the block devices need to be initialized with filesystem metadata. This process is known as creating a filesystem on the block devices. After filesystems are created on the block devices, they can be mounted and used to store files.
Let's keep this simple. Are you using old-school MBR partitions? If so, let's create an ext2 filesystem on /dev/sda1:
root # mkfs.ext2 /dev/sda1
If you're using new-school GPT partitions for UEFI, you'll want to create a vfat filesystem on /dev/sda1, because this is what UEFI is able to read:
root # mkfs.vfat -F 32 /dev/sda1
Now, let's create a swap partition. This partition will be used as disk-based virtual memory for your Funtoo Linux system.
You will not create a filesystem on your swap partition, since it is not used to store files. But it is necessary to initialize it using the mkswap command. Then we'll run the swapon command to make your newly-initialized swap space immediately active within the live CD environment, in case it is needed during the rest of the install process:
root # mkswap /dev/sda2
root # swapon /dev/sda2
Now, we need to create a root filesystem. This is where Funtoo Linux will live. We generally recommend ext4 or XFS root filesystems. If you're not sure, choose ext4. Here's how to create a root ext4 filesystem:
root # mkfs.ext4 /dev/sda3
...and here's how to create an XFS root filesystem, if you choose to use XFS:
root # mkfs.xfs /dev/sda3
Your filesystems (and swap) have all now been initialized, so that that can be mounted (attached to your existing directory heirarchy) and used to store files. We are ready to begin installing Funtoo Linux on these brand-new filesystems.
Warning
When deploying an OpenVZ host, please use ext4 exclusively. The Parallels development team tests extensively with ext4, and modern versions of openvz-rhel6-stable are not compatible with XFS, and you may experience kernel bugs.
Mounting filesystems
Mount the newly-created filesystems as follows, creating /mnt/funtoo as the installation mount point:
root # mkdir /mnt/funtoo
root # mount /dev/sda3 /mnt/funtoo
root # mkdir /mnt/funtoo/boot
root # mount /dev/sda1 /mnt/funtoo/boot
Optionally, if you have a separate filesystem for /home or anything else:
root # mkdir /mnt/funtoo/home
root # mount /dev/sda4 /mnt/funtoo/home
If you have /tmp or /var/tmp on a separate filesystem, be sure to change the permissions of the mount point to be globally-writeable after mounting, as follows:
root # chmod 1777 /mnt/funtoo/tmp