depot/third_party/nixpkgs/nixos/modules/virtualisation/amazon-image.nix

179 lines
6.5 KiB
Nix
Raw Normal View History

# Configuration for Amazon EC2 instances. (Note that this file is a
# misnomer - it should be "amazon-config.nix" or so, not
# "amazon-image.nix", since it's used not only to build images but
# also to reconfigure instances. However, we can't rename it because
# existing "configuration.nix" files on EC2 instances refer to it.)
{ config, lib, pkgs, ... }:
with lib;
let
cfg = config.ec2;
metadataFetcher = import ./ec2-metadata-fetcher.nix {
inherit (pkgs) curl;
targetRoot = "$targetRoot/";
wgetExtraOptions = "-q";
};
in
{
imports = [
../profiles/headless.nix
# Note: While we do use the headless profile, we also explicitly
# turn on the serial console on ttyS0 below. This is because
# AWS does support accessing the serial console:
# https://docs.aws.amazon.com/AWSEC2/latest/UserGuide/configure-access-to-serial-console.html
./ec2-data.nix
./amazon-init.nix
];
config = {
assertions = [
{ assertion = cfg.hvm;
message = "Paravirtualized EC2 instances are no longer supported.";
}
{ assertion = cfg.efi -> cfg.hvm;
message = "EC2 instances using EFI must be HVM instances.";
}
{ assertion = versionOlder config.boot.kernelPackages.kernel.version "5.17";
message = "ENA driver fails to build with kernel >= 5.17";
}
];
boot.growPartition = cfg.hvm;
fileSystems."/" = mkIf (!cfg.zfs.enable) {
device = "/dev/disk/by-label/nixos";
fsType = "ext4";
autoResize = true;
};
fileSystems."/boot" = mkIf (cfg.efi || cfg.zfs.enable) {
# The ZFS image uses a partition labeled ESP whether or not we're
# booting with EFI.
device = "/dev/disk/by-label/ESP";
fsType = "vfat";
};
services.zfs.expandOnBoot = mkIf cfg.zfs.enable "all";
boot.zfs.devNodes = mkIf cfg.zfs.enable "/dev/";
boot.extraModulePackages = [
config.boot.kernelPackages.ena
];
boot.initrd.kernelModules = [ "xen-blkfront" "xen-netfront" ];
boot.initrd.availableKernelModules = [ "ixgbevf" "ena" "nvme" ];
boot.kernelParams = mkIf cfg.hvm [ "console=ttyS0,115200n8" "random.trust_cpu=on" ];
# Prevent the nouveau kernel module from being loaded, as it
# interferes with the nvidia/nvidia-uvm modules needed for CUDA.
# Also blacklist xen_fbfront to prevent a 30 second delay during
# boot.
boot.blacklistedKernelModules = [ "nouveau" "xen_fbfront" ];
# Generate a GRUB menu. Amazon's pv-grub uses this to boot our kernel/initrd.
boot.loader.grub.version = if cfg.hvm then 2 else 1;
boot.loader.grub.device = if (cfg.hvm && !cfg.efi) then "/dev/xvda" else "nodev";
boot.loader.grub.extraPerEntryConfig = mkIf (!cfg.hvm) "root (hd0)";
boot.loader.grub.efiSupport = cfg.efi;
boot.loader.grub.efiInstallAsRemovable = cfg.efi;
boot.loader.timeout = 1;
boot.loader.grub.extraConfig = ''
serial --unit=0 --speed=115200 --word=8 --parity=no --stop=1
terminal_output console serial
terminal_input console serial
'';
boot.initrd.network.enable = true;
# Mount all formatted ephemeral disks and activate all swap devices.
# We cannot do this with the fileSystems and swapDevices options
# because the set of devices is dependent on the instance type
# (e.g. "m1.small" has one ephemeral filesystem and one swap device,
# while "m1.large" has two ephemeral filesystems and no swap
# devices). Also, put /tmp and /var on /disk0, since it has a lot
# more space than the root device. Similarly, "move" /nix to /disk0
# by layering a unionfs-fuse mount on top of it so we have a lot more space for
# Nix operations.
boot.initrd.postMountCommands =
''
${metadataFetcher}
diskNr=0
diskForUnionfs=
for device in /dev/xvd[abcde]*; do
if [ "$device" = /dev/xvda -o "$device" = /dev/xvda1 ]; then continue; fi
fsType=$(blkid -o value -s TYPE "$device" || true)
if [ "$fsType" = swap ]; then
echo "activating swap device $device..."
swapon "$device" || true
elif [ "$fsType" = ext3 ]; then
mp="/disk$diskNr"
diskNr=$((diskNr + 1))
if mountFS "$device" "$mp" "" ext3; then
if [ -z "$diskForUnionfs" ]; then diskForUnionfs="$mp"; fi
fi
else
echo "skipping unknown device type $device"
fi
done
if [ -n "$diskForUnionfs" ]; then
mkdir -m 755 -p $targetRoot/$diskForUnionfs/root
mkdir -m 1777 -p $targetRoot/$diskForUnionfs/root/tmp $targetRoot/tmp
mount --bind $targetRoot/$diskForUnionfs/root/tmp $targetRoot/tmp
if [ "$(cat "$metaDir/ami-manifest-path")" != "(unknown)" ]; then
mkdir -m 755 -p $targetRoot/$diskForUnionfs/root/var $targetRoot/var
mount --bind $targetRoot/$diskForUnionfs/root/var $targetRoot/var
mkdir -p /unionfs-chroot/ro-nix
mount --rbind $targetRoot/nix /unionfs-chroot/ro-nix
mkdir -m 755 -p $targetRoot/$diskForUnionfs/root/nix
mkdir -p /unionfs-chroot/rw-nix
mount --rbind $targetRoot/$diskForUnionfs/root/nix /unionfs-chroot/rw-nix
unionfs -o allow_other,cow,nonempty,chroot=/unionfs-chroot,max_files=32768 /rw-nix=RW:/ro-nix=RO $targetRoot/nix
fi
fi
'';
boot.initrd.extraUtilsCommands =
''
# We need swapon in the initrd.
copy_bin_and_libs ${pkgs.util-linux}/sbin/swapon
'';
# Allow root logins only using the SSH key that the user specified
# at instance creation time.
services.openssh.enable = true;
services.openssh.permitRootLogin = "prohibit-password";
# Enable the serial console on ttyS0
systemd.services."serial-getty@ttyS0".enable = true;
# Creates symlinks for block device names.
services.udev.packages = [ pkgs.amazon-ec2-utils ];
# Force getting the hostname from EC2.
networking.hostName = mkDefault "";
# Always include cryptsetup so that Charon can use it.
environment.systemPackages = [ pkgs.cryptsetup ];
boot.initrd.supportedFilesystems = [ "unionfs-fuse" ];
# EC2 has its own NTP server provided by the hypervisor
networking.timeServers = [ "169.254.169.123" ];
# udisks has become too bloated to have in a headless system
# (e.g. it depends on GTK).
services.udisks2.enable = false;
};
}