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490 lines
16 KiB
490 lines
16 KiB
#!/bin/perl |
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# |
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# This script is designed to identify hard drives and decide where and how to partition it for installation |
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# during a kickstart install. |
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# |
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# Exit codes; |
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# 0 - Success |
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# 1 - Target type not specified. |
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# 2 - Failed to find a drive to install on. |
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# |
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# NOTE: This is restricted to what is available during an anaconda install session. That is to say, bare |
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# minimum. |
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# TODO: If multiple matching drives are found (same medium and size, build an appropriate RAID array. |
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# TODO: in pre, wipefs on all disks to clear old LVM and DRBD data |
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# |
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|
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use strict; |
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use warnings; |
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|
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# Set to '1' for verbose output |
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my $debug = 0; |
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|
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### NOTE: This must be set to 'striker', 'node' or 'dr'! Wither set '$type' or use the appropriate argument. |
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my $type = ""; |
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if ((defined $ARGV[0]) && ((lc($ARGV[0]) eq "striker") or (lc($ARGV[0]) eq "node") or (lc($ARGV[0]) eq "dr"))) |
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{ |
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$type = $ARGV[0]; |
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} |
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if ($type =~ /striker/i) |
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{ |
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print "-=] Finding install drive(s) for a Striker dashboard.\n"; |
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$type = "striker"; |
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} |
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elsif ($type =~ /node/i) |
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{ |
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print "-=] Finding install drive(s) for an Anvil! node.\n"; |
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$type = "node"; |
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} |
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elsif ($type =~ /dr/i) |
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{ |
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print "-=] Finding install drive(s) for a DR (disaster recovery) host.\n"; |
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$type = "dr"; |
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} |
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else |
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{ |
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print " |
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[ Error ] - Target type not specified! |
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Usage: ".$0." {striker,node,dr} |
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"; |
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exit(1); |
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} |
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my $device = {}; |
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|
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# We might want to add HCTL (Host:Channel:Target:Lun for SCSI) and/or SUBSYSTEMS later |
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my $drives = {}; |
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my $target = ""; |
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my $lsblk = system_call("/bin/lsblk --bytes --paths --pairs --output NAME,RM,HOTPLUG,TYPE,SIZE,TRAN,ROTA"); |
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foreach my $line (split/\n/, $lsblk) |
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{ |
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### NOTE: If a drive has no transport, is not removable, but is hotplugable and the device path is |
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### mmcblk0, it is probably an SDCard. It doesn't seem to be a directly divinable state. We |
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### don't currently plan to use them, but it might come to pass later. |
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print __LINE__."; [ Debug ] - lsblk: [".$line."]\n" if $debug; |
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my ($path, $removable, $hotplug, $type, $size, $transport, $rotational) = ($line =~ /NAME="(.*?)" RM="(\d)" HOTPLUG="(\d)" TYPE="(.*?)" SIZE="(\d+)" TRAN="(.*?)" ROTA="(\d)"/); |
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print __LINE__."; [ Debug ] - Device: [".$path."], type: [".$type."], remvoable? [".$removable."], hotplug? [".$hotplug."], rotational? [".$rotational."], transport: [".$transport."], size: [".$size."]\n" if $debug; |
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# Skip 'zramX' devices |
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next if ($path =~ /^\/dev\/zram\d/); |
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# Skip removable disks and anything that just isn't a disk at all. |
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next if (($removable) or ($hotplug) or ($type ne "disk")); |
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$device->{$path} = { |
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type => $type, |
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size => $size, |
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transport => $transport, |
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rotational => $rotational, |
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}; |
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my $hr_size = hr_size($device->{$path}{size}); |
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$device->{$path}{hr_size} = $hr_size; |
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if ($device->{$path}{rotational}) |
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{ |
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if (not $device->{$path}{transport}) |
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{ |
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print "Analyzing platter or virtual drive: [".$path."] of the size: [".$device->{$path}{size}." (".$device->{$path}{hr_size}.")]\n"; |
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} |
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else |
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{ |
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print "Analyzing platter drive: [".$path."], using the transport: [".$device->{$path}{transport}."], of the size: [".$device->{$path}{size}." (".$device->{$path}{hr_size}.")]\n"; |
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} |
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} |
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else |
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{ |
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print "Analyzing solid-state drive: [".$path."], using the transport: [".$device->{$path}{transport}."], of the size: [".$device->{$path}{size}." (".$device->{$path}{hr_size}.")]\n"; |
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} |
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if (not exists $drives->{by_hr_size}{$hr_size}) |
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{ |
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$drives->{by_hr_size}{$hr_size} = []; |
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} |
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push @{$drives->{by_hr_size}{$hr_size}}, $path; |
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} |
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|
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### Usage selection priority |
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# on Striker, we'll simply use whatever is the biggest avalable drive. |
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# on Node and DR, we'll prefer slowest first (rotational, sata before nvme/scsi), and smallest second. |
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my $use_drive = ""; |
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if ($type eq "striker") |
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{ |
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my $biggest_size = 0; |
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foreach my $path (sort {$a cmp $b} keys %{$device}) |
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{ |
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print __LINE__."; [ Debug ] - path: [".$path."], ${path}::size: [".$device->{$path}{size}." (".hr_size($device->{$path}{size}).")] < biggest_size: [".$biggest_size." (".hr_size($biggest_size).")]\n" if $debug; |
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if ($device->{$path}{size} > $biggest_size) |
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{ |
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$biggest_size = $device->{$path}{size}; |
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$use_drive = $path; |
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print __LINE__."; [ Debug ] - use_drive: [".$use_drive."], biggest_size: [".$biggest_size." (".hr_size($biggest_size).")]\n" if $debug; |
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} |
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} |
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if ($use_drive) |
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{ |
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print "Selected the largest disk: [".$use_drive."], which has a capacity of: [".hr_size($device->{$use_drive}{size})."]\n"; |
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} |
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} |
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else |
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{ |
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# Node and DR are handled the same |
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my $first_disk_seen = 0; |
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my $smallest_size = 0; |
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my $selected_is_platter = 0; |
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foreach my $path (sort {$a cmp $b} keys %{$device}) |
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{ |
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print __LINE__."; [ Debug ] - first_disk_seen: [".$first_disk_seen."], path: [".$path."], ${path}::rotational: [".$device->{$path}{rotational}."]\n" if $debug; |
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if (not $first_disk_seen) |
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{ |
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# Select this one |
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$first_disk_seen = 1; |
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$use_drive = $path; |
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$smallest_size = $device->{$path}{size}; |
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$selected_is_platter = $device->{$path}{rotational}; |
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print __LINE__."; [ Debug ] - first_disk_seen: [".$first_disk_seen."], use_drive: [".$use_drive."], selected_is_platter: [".$selected_is_platter."], smallest_size: [".$smallest_size." (".hr_size($smallest_size).")]\n" if $debug; |
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} |
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elsif ($device->{$path}{rotational}) |
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{ |
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# This takes priority |
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print __LINE__."; [ Debug ] - selected_is_platter: [".$selected_is_platter."]\n" if $debug; |
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if ($selected_is_platter) |
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{ |
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# Was the previously seen drive bigger? |
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print __LINE__."; [ Debug ] - ".$path."::size: [".$first_disk_seen." (".hr_size($first_disk_seen).")], smallest_size: [".$smallest_size." (".hr_size($smallest_size).")]\n" if $debug; |
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if ($device->{$path}{size} < $smallest_size) |
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{ |
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# This is smaller, use it. |
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$use_drive = $path; |
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$smallest_size = $device->{$path}{size}; |
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print __LINE__."; [ Debug ] - use_drive: [".$use_drive."], smallest_size: [".$smallest_size." (".hr_size($smallest_size).")]\n" if $debug; |
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} |
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} |
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else |
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{ |
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# The previous drive is an SSD, so use this one regardless |
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$use_drive = $path; |
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$smallest_size = $device->{$path}{size}; |
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$selected_is_platter = $device->{$path}{rotational}; |
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print __LINE__."; [ Debug ] - use_drive: [".$use_drive."], selected_is_platter: [".$selected_is_platter."], smallest_size: [".$smallest_size." (".hr_size($smallest_size).")]\n" if $debug; |
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} |
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} |
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elsif (not $selected_is_platter) |
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{ |
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# This is an SSD, but we haven't seen a platter drive yet, so use it if it is |
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# smaller. |
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print __LINE__."; [ Debug ] - ".$path."::size: [".$first_disk_seen." (".hr_size($first_disk_seen).")], smallest_size: [".$smallest_size." (".hr_size($smallest_size).")]\n" if $debug; |
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if ($device->{$path}{size} < $smallest_size) |
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{ |
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# This is smaller, use it. |
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$use_drive = $path; |
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$smallest_size = $device->{$path}{size}; |
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print __LINE__."; [ Debug ] - use_drive: [".$use_drive."], smallest_size: [".$smallest_size." (".hr_size($smallest_size).")]\n" if $debug; |
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} |
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} |
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} |
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# Did we find a drive? |
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if ($use_drive) |
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{ |
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if ($selected_is_platter) |
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{ |
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print "Selected the smallest platter drive: [".$use_drive."], which has a capacity of: [".hr_size($device->{$use_drive}{size})."]\n"; |
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} |
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else |
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{ |
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print "Selected the smallest solid-state drive: [".$use_drive."], which has a capacity of: [".hr_size($device->{$use_drive}{size})."] (no platter drives found)\n"; |
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} |
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} |
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} |
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# Did we find a disk to use? |
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if (not $use_drive) |
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{ |
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print "[ Error ] - Failed to find any fixed drives (platter or USB, not removable) to install onto. Unable to proceed.\n"; |
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exit(2); |
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} |
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# Pick up a bit of a UUID to add to the volume group name. |
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my $id = time; |
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if ((-e "/sys/class/dmi/id/product_uuid") && (-r "/sys/class/dmi/id/product_uuid")) |
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{ |
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# We should be able to read the system UUID. If so, we'll take the starting part of the string for |
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# the short ID. |
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my $uuid = ""; |
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my $shell_call = "/sys/class/dmi/id/product_uuid"; |
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print __LINE__."; [ Debug ] - shell_call: [".$shell_call."]\n" if $debug; |
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open (my $file_handle, "<", $shell_call) or die "Failed to read: [".$shell_call."], the error was: ".$!."\n"; |
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while(<$file_handle>) |
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{ |
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chomp; |
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$uuid = $_; |
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print __LINE__."; [ Debug ] - uuid: [".$uuid."]\n" if $debug; |
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} |
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close $file_handle; |
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if ($uuid =~ /^(\w+)-/) |
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{ |
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$id = $1; |
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print __LINE__."; [ Debug ] - id: [".$id."]\n" if $debug; |
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} |
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} |
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### NOTE: RAID 0 is not RAID (literally or in this case). So '0' means 'no raid' |
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# If I have 2+ drives of the same size as 'use_drive', I will create a RAID array. |
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my $raid_level = 0; |
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my $hr_size = $device->{$use_drive}{hr_size}; |
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my $count = @{$drives->{by_hr_size}{$hr_size}}; |
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print __LINE__."; [ Debug ] - Drives of size: [".$hr_size."]: [".$count."].\n" if $debug; |
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if ($count == 0) |
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{ |
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$raid_level = 0; |
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} |
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elsif ($count == 2) |
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{ |
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$raid_level = 1; |
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} |
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elsif ($count == 4) |
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{ |
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$raid_level = 10; |
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} |
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elsif (($count == 3) or ($count == 5)) |
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{ |
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$raid_level = 5; |
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} |
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elsif ($count > 5) |
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{ |
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$raid_level = 6; |
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} |
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my $say_use_drive = $use_drive; |
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if (not $raid_level) |
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{ |
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print "Building a standard partition layout for: [".$use_drive."] which is: [".$hr_size."]\n"; |
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} |
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else |
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{ |
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print "Building a software RAID level: [".$raid_level."] array using the: [".$count."x] [".$hr_size."] drives;\n"; |
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$say_use_drive = ""; |
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foreach my $path (sort {$a cmp $b} @{$drives->{by_hr_size}{$hr_size}}) |
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{ |
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print "- ".$path."\n"; |
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$say_use_drive .= $path.","; |
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} |
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$say_use_drive =~ s/,$//; |
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} |
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### NOTE: kickstart sizes are in MiB |
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# Prepare some variables |
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my $swap_size = 8192; |
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my $root_size = 0; |
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my $vg_name = $type."_".$id; |
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# If this machine has a small size, we'll cut back the swap and root sizes. |
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my $per_disk_space = sprintf("%.2f", ($device->{$use_drive}{size} /= (2 ** 20))); |
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my $available_space = $per_disk_space; |
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print __LINE__."; [ Debug ] - per_disk_space: [".$per_disk_space." (".hr_size($per_disk_space * (2**20)).")], available_space: [".$available_space." (".hr_size($available_space * (2**20)).")]\n" if $debug; |
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if ($raid_level == 10) |
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{ |
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# Total == 2 x single disk |
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$available_space *= 2; |
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print __LINE__."; [ Debug ] - available_space: [".$available_space."]\n" if $debug; |
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} |
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elsif ($raid_level == 5) |
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{ |
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# Total == count x Disks - 1 |
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$available_space = ($per_disk_space * $count) - $per_disk_space; |
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print __LINE__."; [ Debug ] - available_space: [".$available_space."]\n" if $debug; |
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} |
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elsif ($raid_level == 6) |
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{ |
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# Total == count x Disks - 2 |
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$available_space = ($per_disk_space * $count) - ($per_disk_space * 2); |
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print __LINE__."; [ Debug ] - available_space: [".$available_space."]\n" if $debug; |
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} |
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# Now, how much space is available after taking some for BIOSBOOT and /boot ? |
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$available_space -= 2; |
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print __LINE__."; [ Debug ] - available_space: [".$available_space." (".hr_size($available_space * (2**20)).")]\n" if $debug; |
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if ($available_space < 40960) |
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{ |
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# Not enough space for the standard layout. |
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$swap_size = 4096; |
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print __LINE__."; [ Debug ] - swap_size: [".$swap_size."]\n" if $debug; |
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} |
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# The left over space is for '/' (we'll shorten this up to 40GiB for nodes and DR hosts next) |
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$root_size = $available_space - $swap_size; |
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print __LINE__."; [ Debug ] - root_size: [".$root_size."]\n" if $debug; |
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print __LINE__."; [ Debug ] - type: [".$type."], root_size: [".$root_size."]\n" if $debug; |
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if (($type ne "striker") && ($root_size > 40960)) |
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{ |
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$root_size = 40960; |
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print __LINE__."; [ Debug ] - root_size: [".$root_size."]\n" if $debug; |
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} |
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# Round down to an event integer. |
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$root_size =~ s/\.\d+$//; |
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print __LINE__."; Assigning: [".hr_size($swap_size * (2**20))." (".$swap_size." MiB)], root_size: [".hr_size($root_size * (2**20))." (".$root_size.") MiB]\n" if $debug; |
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# Build the partition file. |
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my $partition_file = "/tmp/plan_partitions.out"; |
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my $partition_body = "zerombr |
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clearpart --all --drives=".$say_use_drive." |
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ignoredisk --only-use=".$say_use_drive." |
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bootloader --location=mbr --driveorder=".$say_use_drive." --boot-drive=".$use_drive; |
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if (not $raid_level) |
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{ |
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# Finally, we've got our output. |
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$partition_body .= " |
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# Partitions |
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part biosboot --fstype=biosboot --size=2 |
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part pv.01 --fstype=lvmpv --size=100 --ondisk=".$use_drive." --grow |
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# LVM Volume groups |
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volgroup ".$vg_name." --pesize=4096 pv.01 |
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# LVM logical volumes |
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logvol swap --fstype=swap --size=".$swap_size." --name=lv_swap --vgname=".$vg_name." |
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logvol / --fstype=xfs --size=100 --grow --maxsize=".$root_size." --name=lv_root --vgname=".$vg_name." |
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"; |
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} |
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else |
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{ |
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$partition_body .= " |
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# biosboot |
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"; |
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for (my $i = 0; $i < $count; $i++) |
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{ |
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$partition_body .= "part biosboot --fstype=biosboot --size=2 --ondisk=".$drives->{by_hr_size}{$hr_size}->[$i]."\n"; |
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} |
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$partition_body .= " |
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# LVM PV |
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"; |
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my $say_raid = ""; |
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for (my $i = 0; $i < $count; $i++) |
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{ |
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my $disk_number = $i + 1; |
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$partition_body .= "part raid.1".$disk_number." --size 100 --grow --ondisk=".$drives->{by_hr_size}{$hr_size}->[$i]."\n"; |
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$say_raid .= "raid.1".$disk_number." "; |
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} |
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$partition_body .= "raid pv.01 --fstype=xfs --device=pv.01 --level=RAID".$raid_level." ".$say_raid." |
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# LVM Volume groups |
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volgroup ".$vg_name." pv.01 |
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|
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# LVM logical volumes |
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logvol swap --fstype=swap --size=".$swap_size." --name=lv_swap --vgname=".$vg_name." |
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logvol / --fstype=xfs --size=100 --grow --maxsize=".$root_size." --name=lv_root --vgname=".$vg_name." |
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"; |
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} |
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|
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### NOTE: This shouldn't be needed... See: https://bugzilla.redhat.com/show_bug.cgi?id=1654902 |
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# Wipe out the start of each disk so that the install doesn't puke if it sees, for example, an mdadm |
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# signature on the sole disk being used as an install target. |
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foreach my $path (split/,/, $say_use_drive) |
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{ |
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print "[ NOTE ] - Wiping the boot sector of: [".$path."] and configuring it for a GPT label.\n"; |
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my $dd_out = system_call("/bin/dd bs=5120 count=1 if=/dev/zero of=".$path." oflag=dsync"); |
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print __LINE__."; [ Debug ] - dd output: |
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================================================================================ |
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".$dd_out." |
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================================================================================\n" if $debug; |
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my $partprobe_out = system_call("/sbin/partprobe --summary ".$path); |
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print __LINE__."; [ Debug ] - partprobe summary. |
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================================================================================ |
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".$partprobe_out." |
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================================================================================\n" if $debug; |
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my $partx_out = system_call("/sbin/partx --update --verbose ".$path); |
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print __LINE__."; [ Debug ] - parted print output showing new layout. |
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================================================================================ |
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".$partx_out." |
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================================================================================\n" if $debug; |
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} |
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# Flush things out. The article says to blindly sleep 30, but it says to do so to make sure udev, partx and |
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# others have updated. We're forcing the issue, which should be faster and safer. |
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system_call("/bin/sync"); |
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system_call("/sbin/udevadm settle"); |
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# Write out the file. |
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print __LINE__."; [ Debug ] - partition_body: |
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================================================================================ |
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".$partition_body." |
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================================================================================\n"; |
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print "Writing out the partition plan to: [".$partition_file."]\n"; |
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|
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# Write it to the temp file that the kickstart's %include will look for. |
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my $shell_call = $partition_file; |
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print __LINE__."; [ Debug ] - shell_call: [".$shell_call."]\n" if $debug; |
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open (my $file_handle, ">", $shell_call) or die "Failed to write: [".$shell_call."], the error was: ".$!."\n"; |
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print $file_handle $partition_body; |
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close $file_handle; |
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print "Completed successfully, exiting.\n"; |
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# We're done. |
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exit(0); |
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|
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|
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### Functions |
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# Make the size easier to read for users |
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sub hr_size |
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{ |
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my ($size) = @_; |
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|
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my $hr_size = $size; |
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|
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if ($size < 1023) |
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{ |
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# Bytes |
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$hr_size .= " B"; |
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} |
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elsif ($size < (2 ** 20)) |
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{ |
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# Kibibyte |
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$hr_size = sprintf("%.1f", ($size /= (2 ** 10)))." KiB"; |
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} |
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elsif ($size < (2 ** 30)) |
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{ |
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# Mebibyte |
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$hr_size = sprintf("%.2f", ($size /= (2 ** 20)))." MiB"; |
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} |
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elsif ($size < (2 ** 40)) |
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{ |
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# Gibibyte |
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$hr_size = sprintf("%.2f", ($size /= (2 ** 30)))." GiB"; |
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} |
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elsif ($size < (2 ** 50)) |
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{ |
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# Tebibyte |
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$hr_size = sprintf("%.2f", ($size /= (2 ** 40)))." TiB"; |
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} |
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else |
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{ |
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# Pebibyte or higher |
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$hr_size = sprintf("%.3f", ($size /= (2 ** 40)))." PiB"; |
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} |
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|
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return($hr_size); |
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} |
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|
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sub system_call |
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{ |
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my ($command) = @_; |
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my $output = ""; |
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open (my $file_handle, $command." 2>&1 |") or die "Failed to call: [".$command."], error was: [".$!."]\n"; |
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while (<$file_handle>) |
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{ |
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chomp; |
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my $line = $_; |
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$line =~ s/\n$//; |
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$line =~ s/\r$//; |
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$output .= $line."\n"; |
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} |
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close $file_handle; |
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$output =~ s/\n$//s; |
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|
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return($output); |
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}
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