{ platform ? __currentSystem , stage2Init ? "" , configuration }: rec { # Make a configuration object from which we can retrieve option # values. config = import ./config.nix pkgs.library configuration; pkgs = import ../pkgs/top-level/all-packages.nix {system = platform;}; pkgsDiet = import ../pkgs/top-level/all-packages.nix { system = platform; bootStdenv = pkgs.useDietLibC pkgs.stdenv; }; pkgsStatic = import ../pkgs/top-level/all-packages.nix { system = platform; bootStdenv = pkgs.makeStaticBinaries pkgs.stdenv; }; stdenvLinuxStuff = import ../pkgs/stdenv/linux { system = pkgs.stdenv.system; allPackages = import ../pkgs/top-level/all-packages.nix; }; nix = pkgs.nixUnstable; # we need the exportReferencesGraph feature # Splash configuration. splashThemes = import ./splash-themes.nix { inherit (pkgs) fetchurl; }; # Determine the set of modules that we need to mount the root FS. modulesClosure = import ../helpers/modules-closure.nix { inherit (pkgs) stdenv kernel module_init_tools; rootModules = ["ide-cd" "ide-disk" "ide-generic"]; }; # Some additional utilities needed in stage 1, notably mount. We # don't want to bring in all of util-linux, so we just copy what we # need. extraUtils = pkgs.runCommand "extra-utils" { buildInputs = [pkgs.nukeReferences]; inherit (pkgsStatic) utillinux; inherit (pkgs) splashutils; e2fsprogs = pkgs.e2fsprogsDiet; } " ensureDir $out/bin cp $utillinux/bin/mount $utillinux/bin/umount $utillinux/sbin/pivot_root $out/bin cp -p $e2fsprogs/sbin/fsck* $e2fsprogs/sbin/e2fsck $out/bin cp $splashutils/bin/splash_helper $out/bin nuke-refs $out/bin/* "; # The init script of boot stage 1 (loading kernel modules for # mounting the root FS). bootStage1 = import ../boot/boot-stage-1.nix { inherit (pkgs) substituteAll; inherit (pkgsDiet) module_init_tools; inherit extraUtils; autoDetectRootDevice = config.get ["boot" "autoDetectRootDevice"]; rootDevice = config.get ["boot" "rootDevice"]; rootLabel = config.get ["boot" "rootLabel"]; inherit stage2Init; modules = modulesClosure; staticShell = stdenvLinuxStuff.bootstrapTools.bash; staticTools = stdenvLinuxStuff.staticTools; }; # The closure of the init script of boot stage 1 is what we put in # the initial RAM disk. initialRamdisk = import ../boot/make-initrd.nix { inherit (pkgs) stdenv cpio; contents = [ { object = bootStage1; symlink = "/init"; } { object = extraUtils; suffix = "/bin/splash_helper"; symlink = "/sbin/splash_helper"; } { object = import ../helpers/unpack-theme.nix { inherit (pkgs) stdenv; theme = splashThemes.splashScreen; }; symlink = "/etc/splash"; } ]; }; # The installer. nixosInstaller = import ../installer/nixos-installer.nix { inherit (pkgs) stdenv runCommand substituteAll; inherit nix; }; # The services (Upstart) configuration for the system. upstartJobs = import ./upstart.nix { inherit pkgs nix splashThemes; }; # The static parts of /etc. etc = import ./etc.nix { inherit pkgs upstartJobs; }; # The wrapper setuid programs (since we can't have setuid programs # in the Nix store). setuidWrapper = import ../helpers/setuid { inherit (pkgs) stdenv; wrapperDir = "/var/setuid-wrappers"; }; # The packages you want in the boot environment. fullPath = [ pkgs.bash pkgs.bzip2 pkgs.coreutils pkgs.cpio pkgs.curl pkgs.e2fsprogs pkgs.findutils pkgs.gnugrep pkgs.gnused pkgs.gnutar pkgs.grub pkgs.gzip pkgs.iputils pkgs.less pkgs.module_init_tools pkgs.nano pkgs.netcat pkgs.nettools pkgs.perl pkgs.procps pkgs.pwdutils pkgs.rsync pkgs.strace pkgs.sysklogd pkgs.udev pkgs.upstart pkgs.utillinux # pkgs.vim nix nixosInstaller setuidWrapper ]; # The script that activates the configuration, i.e., it sets up # /etc, accounts, etc. It doesn't do anything that can only be done # at boot time (such as start `init'). activateConfiguration = pkgs.substituteAll { src = ./activate-configuration.sh; isExecutable = true; inherit etc; inherit (pkgs) kernel; readOnlyRoot = config.get ["boot" "readOnlyRoot"]; hostName = config.get ["networking" "hostname"]; wrapperDir = setuidWrapper.wrapperDir; accounts = ../helpers/accounts.sh; path = [pkgs.coreutils pkgs.gnugrep pkgs.findutils]; # We don't want to put all of `startPath' and `path' in $PATH, since # then we get an embarrassingly long $PATH. So use the user # environment builder to make a directory with symlinks to those # packages. fullPath = pkgs.buildEnv { name = "boot-stage-2-path"; paths = fullPath; pathsToLink = ["/bin" "/sbin" "/man/man1" "/share/man/man1"]; ignoreCollisions = true; }; }; # The init script of boot stage 2, which is supposed to do # everything else to bring up the system. bootStage2 = import ../boot/boot-stage-2.nix { inherit (pkgs) substituteAll coreutils utillinux kernel udev upstart; inherit activateConfiguration; readOnlyRoot = config.get ["boot" "readOnlyRoot"]; upstartPath = [ pkgs.coreutils pkgs.findutils pkgs.gnugrep pkgs.gnused pkgs.upstart ]; }; # Script to build the Grub menu containing the current and previous # system configurations. grubMenuBuilder = pkgs.substituteAll { src = ../installer/grub-menu-builder.sh; isExecutable = true; inherit (pkgs) bash; path = [pkgs.coreutils pkgs.gnused pkgs.gnugrep]; }; # Putting it all together. This builds a store object containing # symlinks to the various parts of the built configuration (the # kernel, the Upstart services, the init scripts, etc.) as well as a # script `switch-to-configuration' that activates the configuration # and makes it bootable. system = pkgs.stdenvNew.mkDerivation { name = "system"; builder = ./system.sh; switchToConfiguration = ./switch-to-configuration.sh; inherit (pkgs) grub coreutils gnused gnugrep diffutils findutils; grubDevice = config.get ["boot" "grubDevice"]; kernelParams = (config.get ["boot" "kernelParams"]) ++ (config.get ["boot" "extraKernelParams"]); inherit bootStage2; inherit activateConfiguration; inherit grubMenuBuilder; inherit etc; kernel = pkgs.kernel + "/vmlinuz"; initrd = initialRamdisk + "/initrd"; # Most of these are needed by grub-install. path = [pkgs.coreutils pkgs.gnused pkgs.gnugrep pkgs.findutils pkgs.diffutils]; }; }