forked from mirrors/nixpkgs
370 lines
12 KiB
XML
370 lines
12 KiB
XML
<chapter xmlns="http://docbook.org/ns/docbook"
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xmlns:xlink="http://www.w3.org/1999/xlink"
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xml:id="ch-running">
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<title>Running NixOS</title>
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<para>This chapter describes various aspects of managing a running
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NixOS system, such as how to use the <command>systemd</command>
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service manager.</para>
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<!--===============================================================-->
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<section><title>Service management</title>
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<para>In NixOS, all system services are started and monitored using
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the systemd program. Systemd is the “init” process of the system
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(i.e. PID 1), the parent of all other processes. It manages a set of
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so-called “units”, which can be things like system services
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(programs), but also mount points, swap files, devices, targets
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(groups of units) and more. Units can have complex dependencies; for
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instance, one unit can require that another unit must be successfully
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started before the first unit can be started. When the system boots,
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it starts a unit named <literal>default.target</literal>; the
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dependencies of this unit cause all system services to be started,
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file systems to be mounted, swap files to be activated, and so
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on.</para>
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<para>The command <command>systemctl</command> is the main way to
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interact with <command>systemd</command>. Without any arguments, it
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shows the status of active units:
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<screen>
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$ systemctl
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-.mount loaded active mounted /
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swapfile.swap loaded active active /swapfile
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sshd.service loaded active running SSH Daemon
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graphical.target loaded active active Graphical Interface
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<replaceable>...</replaceable>
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</screen>
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</para>
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<para>You can ask for detailed status information about a unit, for
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instance, the PostgreSQL database service:
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<screen>
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$ systemctl status postgresql.service
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postgresql.service - PostgreSQL Server
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Loaded: loaded (/nix/store/pn3q73mvh75gsrl8w7fdlfk3fq5qm5mw-unit/postgresql.service)
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Active: active (running) since Mon, 2013-01-07 15:55:57 CET; 9h ago
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Main PID: 2390 (postgres)
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CGroup: name=systemd:/system/postgresql.service
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├─2390 postgres
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├─2418 postgres: writer process
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├─2419 postgres: wal writer process
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├─2420 postgres: autovacuum launcher process
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├─2421 postgres: stats collector process
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└─2498 postgres: zabbix zabbix [local] idle
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Jan 07 15:55:55 hagbard postgres[2394]: [1-1] LOG: database system was shut down at 2013-01-07 15:55:05 CET
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Jan 07 15:55:57 hagbard postgres[2390]: [1-1] LOG: database system is ready to accept connections
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Jan 07 15:55:57 hagbard postgres[2420]: [1-1] LOG: autovacuum launcher started
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Jan 07 15:55:57 hagbard systemd[1]: Started PostgreSQL Server.
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</screen>
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Note that this shows the status of the unit (active and running), all
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the processes belonging to the service, as well as the most recent log
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messages from the service.
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</para>
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<para>Units can be stopped, started or restarted:
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<screen>
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$ systemctl stop postgresql.service
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$ systemctl start postgresql.service
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$ systemctl restart postgresql.service
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</screen>
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These operations are synchronous: they wait until the service has
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finished starting or stopping (or has failed). Starting a unit will
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cause the dependencies of that unit to be started as well (if
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necessary).</para>
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<!-- - cgroups: each service and user session is a cgroup
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- cgroup resource management -->
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</section>
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<!--===============================================================-->
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<section><title>Rebooting and shutting down</title>
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<para>The system can be shut down (and automatically powered off) by
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doing:
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<screen>
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$ shutdown
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</screen>
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This is equivalent to running <command>systemctl
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poweroff</command>.</para>
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<para>To reboot the system, run
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<screen>
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$ reboot
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</screen>
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which is equivalent to <command>systemctl reboot</command>.
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Alternatively, you can quickly reboot the system using
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<literal>kexec</literal>, which bypasses the BIOS by directly loading
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the new kernel into memory:
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<screen>
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$ systemctl kexec
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</screen>
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</para>
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<para>The machine can be suspended to RAM (if supported) using
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<command>systemctl suspend</command>, and suspended to disk using
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<command>systemctl hibernate</command>.</para>
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<para>These commands can be run by any user who is logged in locally,
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i.e. on a virtual console or in X11; otherwise, the user is asked for
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authentication.</para>
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</section>
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<!--===============================================================-->
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<section><title>User sessions</title>
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<para>Systemd keeps track of all users who are logged into the system
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(e.g. on a virtual console or remotely via SSH). The command
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<command>loginctl</command> allows querying and manipulating user
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sessions. For instance, to list all user sessions:
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<screen>
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$ loginctl
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SESSION UID USER SEAT
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c1 500 eelco seat0
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c3 0 root seat0
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c4 500 alice
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</screen>
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This shows that two users are logged in locally, while another is
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logged in remotely. (“Seats” are essentially the combinations of
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displays and input devices attached to the system; usually, there is
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only one seat.) To get information about a session:
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<screen>
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$ loginctl session-status c3
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c3 - root (0)
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Since: Tue, 2013-01-08 01:17:56 CET; 4min 42s ago
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Leader: 2536 (login)
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Seat: seat0; vc3
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TTY: /dev/tty3
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Service: login; type tty; class user
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State: online
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CGroup: name=systemd:/user/root/c3
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├─ 2536 /nix/store/10mn4xip9n7y9bxqwnsx7xwx2v2g34xn-shadow-4.1.5.1/bin/login --
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├─10339 -bash
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└─10355 w3m nixos.org
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</screen>
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This shows that the user is logged in on virtual console 3. It also
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lists the processes belonging to this session. Since systemd keeps
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track of this, you can terminate a session in a way that ensures that
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all the session’s processes are gone:
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<screen>
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$ loginctl terminate-session c3
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</screen>
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</para>
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</section>
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<!--===============================================================-->
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<section><title>Control groups</title>
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<para>To keep track of the processes in a running system, systemd uses
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<emphasis>control groups</emphasis> (cgroups). A control group is a
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set of processes used to allocate resources such as CPU, memory or I/O
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bandwidth. There can be multiple control group hierarchies, allowing
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each kind of resource to be managed independently.</para>
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<para>The command <command>systemd-cgls</command> lists all control
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groups in the <literal>systemd</literal> hierarchy, which is what
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systemd uses to keep track of the processes belonging to each service
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or user session:
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<screen>
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$ systemd-cgls
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├─user
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│ └─eelco
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│ └─c1
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│ ├─ 2567 -:0
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│ ├─ 2682 kdeinit4: kdeinit4 Running...
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│ ├─ <replaceable>...</replaceable>
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│ └─10851 sh -c less -R
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└─system
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├─httpd.service
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│ ├─2444 httpd -f /nix/store/3pyacby5cpr55a03qwbnndizpciwq161-httpd.conf -DNO_DETACH
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│ └─<replaceable>...</replaceable>
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├─dhcpcd.service
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│ └─2376 dhcpcd --config /nix/store/f8dif8dsi2yaa70n03xir8r653776ka6-dhcpcd.conf
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└─ <replaceable>...</replaceable>
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</screen>
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Similarly, <command>systemd-cgls cpu</command> shows the cgroups in
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the CPU hierarchy, which allows per-cgroup CPU scheduling priorities.
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By default, every systemd service gets its own CPU cgroup, while all
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user sessions are in the top-level CPU cgroup. This ensures, for
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instance, that a thousand run-away processes in the
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<literal>httpd.service</literal> cgroup cannot starve the CPU for one
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process in the <literal>postgresql.service</literal> cgroup. (By
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contrast, it they were in the same cgroup, then the PostgreSQL process
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would get 1/1001 of the cgroup’s CPU time.) You can limit a service’s
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CPU share in <filename>configuration.nix</filename>:
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<programlisting>
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systemd.services.httpd.serviceConfig.CPUShares = 512;
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</programlisting>
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By default, every cgroup has 1024 CPU shares, so this will halve the
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CPU allocation of the <literal>httpd.service</literal> cgroup.</para>
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<para>There also is a <literal>memory</literal> hierarchy that
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controls memory allocation limits; by default, all processes are in
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the top-level cgroup, so any service or session can exhaust all
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available memory. Per-cgroup memory limits can be specified in
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<filename>configuration.nix</filename>; for instance, to limit
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<literal>httpd.service</literal> to 512 MiB of RAM (excluding swap)
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and 640 MiB of RAM (including swap):
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<programlisting>
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systemd.services.httpd.serviceConfig.MemoryLimit = "512M";
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systemd.services.httpd.serviceConfig.ControlGroupAttribute = [ "memory.memsw.limit_in_bytes 640M" ];
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</programlisting>
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</para>
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<para>The command <command>systemd-cgtop</command> shows a
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continuously updated list of all cgroups with their CPU and memory
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usage.</para>
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</section>
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<!--===============================================================-->
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<section><title>Logging</title>
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<para>System-wide logging is provided by systemd’s
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<emphasis>journal</emphasis>, which subsumes traditional logging
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daemons such as syslogd and klogd. Log entries are kept in binary
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files in <filename>/var/log/journal/</filename>. The command
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<literal>journalctl</literal> allows you to see the contents of the
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journal. For example,
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<screen>
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$ journalctl -b
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</screen>
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shows all journal entries since the last reboot. (The output of
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<command>journalctl</command> is piped into <command>less</command> by
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default.) You can use various options and match operators to restrict
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output to messages of interest. For instance, to get all messages
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from PostgreSQL:
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<screen>
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$ journalctl -u postgresql.service
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-- Logs begin at Mon, 2013-01-07 13:28:01 CET, end at Tue, 2013-01-08 01:09:57 CET. --
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...
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Jan 07 15:44:14 hagbard postgres[2681]: [2-1] LOG: database system is shut down
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-- Reboot --
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Jan 07 15:45:10 hagbard postgres[2532]: [1-1] LOG: database system was shut down at 2013-01-07 15:44:14 CET
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Jan 07 15:45:13 hagbard postgres[2500]: [1-1] LOG: database system is ready to accept connections
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</screen>
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Or to get all messages since the last reboot that have at least a
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“critical” severity level:
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<screen>
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$ journalctl -b -p crit
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Dec 17 21:08:06 mandark sudo[3673]: pam_unix(sudo:auth): auth could not identify password for [alice]
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Dec 29 01:30:22 mandark kernel[6131]: [1053513.909444] CPU6: Core temperature above threshold, cpu clock throttled (total events = 1)
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</screen>
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</para>
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<para>The system journal is readable by root and by users in the
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<literal>wheel</literal> and <literal>systemd-journal</literal>
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groups. All users have a private journal that can be read using
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<command>journalctl</command>.</para>
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</section>
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<!--===============================================================-->
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<section><title>Cleaning up the Nix store</title>
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<para>Nix has a purely functional model, meaning that packages are
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never upgraded in place. Instead new versions of packages end up in a
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different location in the Nix store (<filename>/nix/store</filename>).
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You should periodically run Nix’s <emphasis>garbage
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collector</emphasis> to remove old, unreferenced packages. This is
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easy:
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<screen>
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$ nix-collect-garbage
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</screen>
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Alternatively, you can use a systemd unit that does the same in the
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background:
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<screen>
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$ systemctl start nix-gc.service
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</screen>
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You can tell NixOS in <filename>configuration.nix</filename> to run
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this unit automatically at certain points in time, for instance, every
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night at 03:15:
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<programlisting>
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nix.gc.automatic = true;
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nix.gc.dates = "03:15";
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</programlisting>
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</para>
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<para>The commands above do not remove garbage collector roots, such
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as old system configurations. Thus they do not remove the ability to
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roll back to previous configurations. The following command deletes
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old roots, removing the ability to roll back to them:
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<screen>
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$ nix-collect-garbage -d
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</screen>
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You can also do this for specific profiles, e.g.
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<screen>
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$ nix-env -p /nix/var/nix/profiles/per-user/eelco/profile --delete-generations old
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</screen>
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Note that NixOS system configurations are stored in the profile
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<filename>/nix/var/nix/profiles/system</filename>.</para>
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<para>Another way to reclaim disk space (often as much as 40% of the
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size of the Nix store) is to run Nix’s store optimiser, which seeks
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out identical files in the store and replaces them with hard links to
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a single copy.
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<screen>
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$ nix-store --optimise
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</screen>
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Since this command needs to read the entire Nix store, it can take
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quite a while to finish.</para>
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</section>
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</chapter>
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