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Difference between revisions of "Install/Prepare Disk"

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(→‎The first rule of funtoo is funtoo rules.: explain why 2 rules for nvme and mmc.)
 
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== Prepare Disk == <!--T:23-->
== Prepare Disk == <!--T:23-->
</includeonly><noinclude><languages/>
</includeonly><noinclude><languages/>
== Install Guide: Prepare Disk ==
= Install Guide: Prepare Disk =  
   
   
{{InstallNavigation|num=2|prev=Download LiveCD|next=MBR Partitioning}}</noinclude>
{{InstallNavigation|num=2|prev=Download LiveCD|next=MBR Partitioning}}</noinclude>


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In this section, you will need to choose a disk format to use for booting and partitioning -- either MBR or UEFI/GPT. If you are not familiar with the differences between these options, please review our [[Install/Disk Formats|Disk Formats]] page for an overview of each option and the trade-offs. Generally, it's usually safe to pick the GPT method with a BIOS Boot partition to enable legacy booting, and install UEFI.
In this section, you will need to choose a disk format to use for booting and partitioning -- either MBR or UEFI.
 
<!--T:31-->
MBR is the traditional way of booting a PC. It works by installing executable code on the boot sector of your hard drive, which starts the boot process. When you use MBR to boot, you must have BIOS booting enabled in your BIOS, use traditional MBR partitions on your disk which are created using the {{c|fdisk}} tool.
 
<!--T:32-->
UEFI is the more modern way to boot a PC. It works using a boot loader that is built into your computer. Boot entries are created and stored in your computer's non-volatile memory. When you use UEFI to boot, you must have UEFI enabled in your BIOS, and use more modern GPT partitions which are created using the {{c|gdisk}} tool.
 
<!--T:33-->
Generally, it's usually safe to pick the legacy MBR method for system disks under 2TB in size and most modern PC systems support MBR as well as UEFI booting.
 
<!--T:34-->
{{note|For more information on differences between MBR and UEFI, see our [[Install/Disk Formats|Disk Formats]] page for an overview of each option and the trade-offs.}}


==== But First... ==== <!--T:25-->
==== But First... ==== <!--T:25-->
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{{console|body=
{{console|body=
# ##i##spaceball-1 ~ # lsblk -o model,name,size,label,partlabel
# ##i##lsblk
MODEL            NAME     SIZE LABEL                    PARTLABEL
NAME         MAJ:MIN RM  SIZE RO TYPE MOUNTPOINT
ST31000340AS    sda    931.5G                         
sda             8:0   0  1.8T  0 disk
                └─sda1 931.5G HOME                   
├─sda1          8:1    0  512M 0 part
PNY CS900 120GB sdb    111.8G                         
├─sda2          8:2   0   8G 0 part [SWAP]
                ├─sdb1    1M                          BIOS Boot
└─sda3          8:3   0  1.8T 0 part
                ├─sdb2  256M BOOTF                    BOOTF
   ├─main-root 254:0    0  500G  0 lvm  /
                └─sdb3 111.6G FUNTOOL                  FUNTOOL
  └─main-data 254:1    0  1.3T  0 lvm  /home
USB 2.0 FD      sdc      3.8G Ubuntu 20.04.1 LTS amd64
                ├─sdc1  2.6G Ubuntu 20.04.1 LTS amd64
                └─sdc2  3.9M                         
Portable        sdd      1.8T                        
                └─sdd1   1.8T Seagate Portable Drive 
}}
}}


<!--T:30-->
<!--T:30-->
Now that we know what drive we're targeting to install, we will set udev rules to alias the drive as /dev/funtoo, and partitions as /dev/funtoo1 /dev/funtoo2 etc.  undead usb uses the second official partitioning scheme, which is swapless, the official install guide uses the first official partitioning scheme with a swap partition to avoid the performance hit from mounting swap by file.
{{Note|If you're not sure which disks are which, you can use {{c|lsblk -o MODEL,NAME,SIZE}} to show the device models matching the {{c|/dev/sd?}} names.}}


<!--T:28-->
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====The first rule of funtoo is funtoo rules.====
Make sure you will not be overwriting any important data and that you have chosen the correct {{c|/dev/sd?}} device. Above, you can see that SATA disk {{c|sda}} contains three partitions, {{c|sda1}}, {{c|sda2}} and {{c|sda3}}, and that {{c|sda3}} contains LVM volumes. If you are using an NVME disk, then you may see {{c|nvme0n1}} as your disk, and your partitions (if any exist yet) will be named {{c|nvme0n1p1}}, {{c|nvme0n1p2}}, etc. If you are installing on microSD Card for Raspberry Pi, your disk will likely be {{c|mmcblk0}} and partitions will have suffixes {{c|p1}}, {{c|p2}}, etc.
 
*ide drive #3 example:
{{console|body=
###i## echo 'KERNEL=="hdd*", SYMLINK+="funtoo%n"' > /etc/udev/rules.d/01-funtoo.rules
}}
 
*sata drive #2 example:
{{console|body=
###i## echo 'KERNEL=="sdc*", SYMLINK+="funtoo%n"' > /etc/udev/rules.d/01-funtoo.rules
}}
nvme & mmc require two rules, 1 for the drive location, and the other for the drive location, and partition number.
 
*nvme nvme drive 1 example:
{{console|body=
###i## echo 'KERNEL=="nvme1n1", SYMLINK+="funtoo"' > /etc/udev/rules.d/01-funtoo.rules
###i## echo 'KERNEL=="nvme1n1p*", SYMLINK+="funtoo%n"' >> /etc/udev/rules.d/01-funtoo.rules
}}
 
*mmc drive 0 example:
{{console|body=
###i## echo 'KERNEL=="mmcblk0", SYMLINK+="funtoo"' > /etc/udev/rules.d/01-funtoo.rules
###i## echo 'KERNEL=="mmcblk0p*", SYMLINK+="funtoo%n"' >> /etc/udev/rules.d/01-funtoo.rules
}}
 
{{console|body=
###i## udevadm control --reload-rules && udevadm trigger
}}


<!--T:29-->
<!--T:29-->
I need to mount the 1.8tb usb drive today, notice I leave the star for /dev/funtoo2 to point to /dev/sdd2
Once you've double-checked your target block device and made sure you'll be partitioning the correct disk, proceed to the next step.
*sata drive #2 example modified to load /dev/sdd:
{{console|body=
###i## echo 'KERNEL=="sdd*", SYMLINK+="funtoo%n"' > /etc/udev/rules.d/01-funtoo.rules
###i## udevadm control --reload-rules && udevadm trigger
}}
Now running {{c|ls -al /dev/funtoo}} will point to my drive that I am targeting to install. {{c|/dev/funtoo -> sdd}}
*you can think of /dev/funtoo as /dev/sdX install instructions, but were mounting our drive were installing to /dev/sdX so everything on the install is copy paste, and safely pointed away from drives you might care about.
</translate>
</translate>
<noinclude>{{InstallNavigation|num=2|prev=Download LiveCD|next=MBR Partitioning|align=right}}</noinclude>
<noinclude>{{InstallNavigation|num=2|prev=Download LiveCD|next=MBR Partitioning|align=right}}</noinclude>

Latest revision as of 16:30, March 21, 2024

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Install Guide: Prepare Disk

Install Guide, Chapter 2 < Prev Next >

In this section, you will need to choose a disk format to use for booting and partitioning -- either MBR or UEFI.

MBR is the traditional way of booting a PC. It works by installing executable code on the boot sector of your hard drive, which starts the boot process. When you use MBR to boot, you must have BIOS booting enabled in your BIOS, use traditional MBR partitions on your disk which are created using the fdisk tool.

UEFI is the more modern way to boot a PC. It works using a boot loader that is built into your computer. Boot entries are created and stored in your computer's non-volatile memory. When you use UEFI to boot, you must have UEFI enabled in your BIOS, and use more modern GPT partitions which are created using the gdisk tool.

Generally, it's usually safe to pick the legacy MBR method for system disks under 2TB in size and most modern PC systems support MBR as well as UEFI booting.

   Note

For more information on differences between MBR and UEFI, see our Disk Formats page for an overview of each option and the trade-offs.

But First...

Before doing anything to your disks, make sure you are partitioning the right one. Use the lsblk command to view a list of all block devices on your system, as well as partitions on these block devices:

root # lsblk
NAME          MAJ:MIN RM  SIZE RO TYPE MOUNTPOINT
sda             8:0    0  1.8T  0 disk 
├─sda1          8:1    0  512M  0 part 
├─sda2          8:2    0    8G  0 part [SWAP]
└─sda3          8:3    0  1.8T  0 part 
  ├─main-root 254:0    0  500G  0 lvm  /
  └─main-data 254:1    0  1.3T  0 lvm  /home
   Note

If you're not sure which disks are which, you can use lsblk -o MODEL,NAME,SIZE to show the device models matching the /dev/sd? names.

Make sure you will not be overwriting any important data and that you have chosen the correct /dev/sd? device. Above, you can see that SATA disk sda contains three partitions, sda1, sda2 and sda3, and that sda3 contains LVM volumes. If you are using an NVME disk, then you may see nvme0n1 as your disk, and your partitions (if any exist yet) will be named nvme0n1p1, nvme0n1p2, etc. If you are installing on microSD Card for Raspberry Pi, your disk will likely be mmcblk0 and partitions will have suffixes p1, p2, etc.

Once you've double-checked your target block device and made sure you'll be partitioning the correct disk, proceed to the next step.

Install Guide, Chapter 2 < Prev Next >