Improving performance/Boot process

Improving the boot performance of a system can provide reduced boot wait times and serves as a means to learn more about how certain system files and scripts interact with one another. This article attempts to aggregate methods on how to improve the boot performance of an Arch Linux system.

Analyzing the boot process

Using systemd-analyze

systemd provides a tool called systemd-analyze that can be used to show timing details about the boot process, including an svg plot showing units waiting for their dependencies. You can see which unit files are causing your boot process to slow down. You can then optimize your system accordingly.

To see how much time was spent in kernelspace and userspace on boot, simply use:

$ systemd-analyze

To list the started unit files, sorted by the time each of them took to start up:

$ systemd-analyze blame

At some points of the boot process, things can not proceed until a given unit succeeds. To see which units find themselves at these critical points in the startup chain, do:

$ systemd-analyze critical-chain

You can also create an SVG file which describes your boot process graphically, similar to Bootchart:

$ systemd-analyze plot > plot.svg

See systemd-analyze(1) for details.

Using bootchart2

You could also use a version of Bootchart to visualize the boot sequence. Since you are not able to put a second init into the kernel command line you will not be able to use any of the standard Bootchart setups. However the bootchart2^AUR package from AUR comes with an undocumented systemd service. After you have installed bootchart2, enable bootchart2.service.

You can visualize the results by opening /var/log/bootchart.png, or if you would like more features by launching:

$ pybootchartgui -i

Read the bootchart2 documentation for further details on using this version of Bootchart.

Using systemd instead of busybox on early init

By default, the Mkinitcpio configuration uses the base and udev hooks for building the initramfs. Faster boot times can be achieved by replacing them with systemd.

See Mkinitcpio#Common hooks for more details. See also Fsck#Boot time checking if replacing the fsck hook.

Compiling a custom kernel

Compiling a custom kernel can reduce boot time and memory usage. Though with the standardization of the 64-bit architecture and the modular nature of the Linux kernel, these benefits may not be as great as expected. See Kernel#Compilation for more info.

Initramfs

In a similar approach to #Compiling a custom kernel, the initramfs can be slimmed down. A simple way is to include the mkinitcpio autodetect hook. If you want to go further than that, see Minimal initramfs.

Depending on your hardware (processor and storage speed), using lz4 instead of the default zstd compression option may be quicker since the faster decompression speed at boot time usually offsets the slightly larger size of the initramfs that has to be read from disk. See Mkinitcpio#COMPRESSION.

Early start for services

One central feature of systemd is D-Bus and socket activation. This causes services to be started when they are first accessed and is generally a good thing. However, if you know that a service (like upower) will always be started during boot, then the overall boot time might be reduced by starting it as early as possible. This can be achieved (if the service file is set up for it, which in most cases it is) by issuing:

# systemctl enable upower

This will cause systemd to start UPower as soon as possible, without causing races with the socket or D-Bus activation.

Staggered spin-up

Some hardware implements staggered spin-up, which causes the OS to probe ATA interfaces serially, which can spin up the drives one-by-one and reduce the peak power usage. This slows down the boot speed, and on most consumer hardware provides no benefits at all since the drives will already spin-up immediately when the power is turned on. To check if SSS is being used:

# dmesg | grep SSS

If it was not used during boot, there will be no output.

To disable it, add libahci.ignore_sss=1 kernel parameter.

Filesystem mounts

Thanks to mkinitcpio's fsck hook, you can avoid a possibly costly remount of the root partition by changing ro to rw on the kernel line: options can be set with rootflags=rw,other_mount_options. The entry must be removed from the /etc/fstab file, otherwise the systemd-remount-fs.service will continue to try applying these settings. Alternatively, one could try to mask that unit.

If Btrfs is in use for the root filesystem, there is no need for a fsck on every boot like other filesystems. If this is the case, mkinitcpio's fsck hook can be removed. You may also want to mask the systemd-fsck-root.service, or tell it not to fsck the root filesystem from the kernel command line using fsck.mode=skip. Without mkinitcpio's fsck hook, systemd will still fsck any relevant filesystems with the systemd-fsck@.service

You can also remove API filesystems from /etc/fstab, as systemd will mount them itself (see pacman -Ql systemd | grep '\.mount$' for a list). It is not uncommon for users to have a /tmp entry carried over from sysvinit, but you may have noticed from the command above that systemd already takes care of this. Ergo, it may be safely removed.

Other filesystems, like /home or EFI system partition, can be mounted with custom mount units. Adding noauto,x-systemd.automount to mount options will buffer all access to that partition, and will fsck and mount it on first access, reducing the number of filesystems it must fsck/mount during the boot process.

Less output during boot

For some systems, particularly those with an SSD, the slow performance of the TTY is actually a bottleneck, and so less output means faster booting. See the Silent boot article for suggestions.

Changing bootloader

If your setup allows it, try changing your bootloader or even not using any with EFISTUB.

Suspend to RAM

The best way to reduce boot time is not booting at all. Consider suspending your system to RAM instead.