Improving performance

The best way to tune a system is to target bottlenecks, or subsystems which limit overall speed. The system specifications can help identify them.

• If the computer becomes slow when large applications (such as LibreOffice and Firefox) run at the same time, check if the amount of RAM is sufficient. Use the following command, and check the "available" column:

  $ free -h

• If boot time is slow, and applications take a long time to load at first launch (only), then the hard drive is likely to blame. The speed of a hard drive can be measured with the hdparm command:

  # hdparm -t /dev/sd''X''

• If CPU load is consistently high even with enough RAM available, then try to lower CPU usage by disabling running daemons and/or processes. This can be monitored in several ways, for example with , or any other system monitoring tool:
• If applications using direct rendering are slow (i.e those which use the GPU, such as video players, games, or even a window manager), then improving GPU performance should help. The first step is to verify if direct rendering is actually enabled. This is indicated by the glxinfo command, part of the mesa-utils package, which should return when used:
• When running a desktop environment, disabling (unused) visual desktop effects may reduce GPU usage. Use a more lightweight environment or create a custom environment if the current does not meet the hardware and/or personal requirements.
• Using an optimized kernel improves performance. Generally, is a good option. However, the default kernel can be tweaked as shown in certain parts of this article to perform better.

The effects of optimization are often difficult to judge. They can however be measured by benchmarking tools.

An internal hardware path describes how the storage device is connected through your motherboard. There are different ways to connect through the motherboard such as the NIC, PCIe, Firewire, Raid Card, USB, etc. By spreading your storage devices across multiple connection points you can avoid bottlenecks. The reason is that each "entry path" into the motherboard is "like a pipe", and there is a set limit to how much can go through that pipe at any one time. This can be avoided because motherboards usually have several "pipes".

A concrete example of this would be if you have two USB ports on the front of your machine, four USB ports on the back, and four disks: it will usually be faster to connect two disks on front and two on back rather than three on back and one on front. This is because most of the time the front and back ports are internally connected to separate Root USB Hubs, meaning you can send more data at the same time using both instead of one.

The following commands will help you determine the various paths on your machine.

Make sure that your partitions are properly aligned.

If you have multiple disks available, you can set them up as a software RAID for serious speed improvements.

Creating swap on a separate disk can also help quite a bit, especially if your machine swaps frequently.

If using a traditional spinning HDD, your partition layout can influence the system's performance. Sectors at the beginning of the drive (closer to the outside of the disk) are faster than those at the end. Also, a smaller partition requires less movements from the drive's head, and so speed up disk operations. Therefore, it is advised to create a small partition (15-20GiB, more or less depending on your needs) only for your system, as near to the beginning of the drive as possible. Other data (pictures, videos) should be kept on a separate partition, and this is usually achieved by separating the home directory () from the system ().

Choosing the best filesystem for a specific system is very important because each has its own strengths. The File systems article provides a short summary of the most popular ones. You can also find relevant articles in Category:File systems.

The noatime option is known to improve performance of the filesystem.

Other mount options are filesystem specific, therefore see the relevant articles for the filesystems:

• Ext3
• Ext4#Improving performance
• JFS Filesystem#Optimizations
• XFS#Performance
• Btrfs#Defragmentation, Btrfs#Compression, and btrfs(5)
• ZFS#Tuning
• NTFS#Improving performance

There are several key tunables affecting the performance of block devices, see sysctl#Virtual memory for more information.

The input/output (I/O) scheduler is the kernel component that decides in which order the block I/O operations are submitted to storage devices. It is useful to remind here some specifications of two main drive types because the goal of the I/O scheduler is to optimize the way these are able to deal with read requests:

• An HDD has spinning disks and a head that moves physically to the required location. Therefore, random latency is quite high ranging between 3 and 12ms (whether it is a high end server drive or a laptop drive and bypassing the disk controller write buffer) while sequential access provides much higher throughput. The typical HDD throughput is about 200 I/O operations per second (IOPS).

• An SSD does not have moving parts, random access is as fast as sequential one, typically under 0.1ms, and it can handle multiple concurrent requests. The typical SSD throughput is greater than 10,000 IOPS, which is more than needed in common workload situations.

If there are many processes making I/O requests to different storage parts, thousands of IOPS can be generated while a typical HDD can handle only about 200 IOPS. There is a queue of requests that have to wait for access to the storage. This is where the I/O schedulers plays an optimization role.

One way to improve throughput is to linearize access: by ordering waiting requests by their logical address and grouping the closest ones. Historically this was the first Linux I/O scheduler called elevator.

One issue with the elevator algorithm is that it is not optimal for a process doing sequential access: reading a block of data, processing it for several microseconds then reading next block and so on. The elevator scheduler does not know that the process is about to read another block nearby and, thus, moves to another request by another process at some other location. The anticipatory I/O scheduler overcomes the problem: it pauses for a few milliseconds in anticipation of another close-by read operation before dealing with another request.

While these schedulers try to improve total throughput, they might leave some unlucky requests waiting for a very long time. As an example, imagine the majority of processes make requests at the beginning of the storage space while an unlucky process makes a request at the other end of storage. This potentially infinite postponement of the process is called starvation. To improve fairness, the deadline algorithm was developed. It has a queue ordered by address, similar to the elevator, but if some request sits in this queue for too long then it moves to an "expired" queue ordered by expire time. The scheduler checks the expire queue first and processes requests from there and only then moves to the elevator queue. Note that this fairness has a negative impact on overall throughput.

The Completely Fair Queuing (CFQ) approaches the problem differently by allocating a timeslice and a number of allowed requests by queue depending on the priority of the process submitting them. It supports cgroup that allows to reserve some amount of I/O to a specific collection of processes. It is in particular useful for shared and cloud hosting: users who paid for some IOPS want to get their share whenever needed. Also, it idles at the end of synchronous I/O waiting for other nearby operations, taking over this feature from the anticipatory scheduler and bringing some enhancements. Both the anticipatory and the elevator schedulers were decommissioned from the Linux kernel replaced by the more advanced alternatives presented below.

The Budget Fair Queuing (BFQ) is based on CFQ code and brings some enhancements. It does not grant the disk to each process for a fixed time-slice but assigns a "budget" measured in number of sectors to the process and uses heuristics. It is a relatively complex scheduler, it may be more adapted to rotational drives and slow SSDs because its high per-operation overhead, especially if associated with a slow CPU, can slow down fast devices. The objective of BFQ on personal systems is that for interactive tasks, the storage device is virtually as responsive as if it was idle. In its default configuration it focuses on delivering the lowest latency rather than achieving the maximum throughput, which can sometimes greatly accelerate the startup of applications on hard drives.

Kyber is a recent scheduler inspired by active queue management techniques used for network routing. The implementation is based on "tokens" that serve as a mechanism for limiting requests. A queuing token is required to allocate a request, this is used to prevent starvation of requests. A dispatch token is also needed and limits the operations of a certain priority on a given device. Finally, a target read latency is defined and the scheduler tunes itself to reach this latency goal. The implementation of the algorithm is relatively simple and it is deemed efficient for fast devices.

While some of the early algorithms have now been decommissioned, the official Linux kernel supports a number of I/O schedulers which can be split into two categories:

• The multi-queue schedulers are available by default with the kernel. The Multi-Queue Block I/O Queuing Mechanism (blk-mq) maps I/O queries to multiple queues, the tasks are distributed across threads and therefore CPU cores. Within this framework the following schedulers are available:
  • None, where no queuing algorithm is applied.
  • mq-deadline, the adaptation of the deadline scheduler (see below) to multi-threading.
  • Kyber
  • BFQ

• The single-queue schedulers are legacy schedulers:
  • NOOP is the simplest scheduler, it inserts all incoming I/O requests into a simple FIFO queue and implements request merging. In this algorithm, there is no re-ordering of the request based on the sector number. Therefore it can be used if the ordering is dealt with at another layer, at the device level for example, or if it does not matter, for SSDs for instance.
  • Deadline
  • CFQ

Note: Single-queue schedulers were removed from kernel since Linux 5.0.

To list the available schedulers for a device and the active scheduler (in brackets):

To list the available schedulers for all devices:

To change the active I/O scheduler to bfq for device sda, use:

# echo bfq > /sys/block/sda/queue/scheduler

The process to change I/O scheduler, depending on whether the disk is rotating or not can be automated and persist across reboots. For example the udev rule below sets the scheduler to none for NVMe, mq-deadline for SSD/eMMC, and bfq for rotational drives:

Reboot or force udev#Loading new rules.

Each of the kernel's I/O scheduler has its own tunables, such as the latency time, the expiry time or the FIFO parameters. They are helpful in adjusting the algorithm to a particular combination of device and workload. This is typically to achieve a higher throughput or a lower latency for a given utilization. The tunables and their description can be found within the kernel documentation.

To list the available tunables for a device, in the example below sdb which is using deadline, use:

To improve deadline's throughput at the cost of latency, one can increase with the command:

When dealing with traditional rotational disks (HDDs) you may want to completely disable or lower power saving features, and check if the write cache is enabled.

See Hdparm#Power management configuration and Hdparm#Write cache.

Afterwards, you can make a udev rule to apply them on boot-up.

Avoiding unnecessary access to slow storage drives is good for performance and also increasing lifetime of the devices, although on modern hardware the difference in life expectancy is usually negligible.

The package can sort by disk writes, and show how much and how frequently programs are writing to the disk. See iotop(8) for details.

Relocate files, such as your browser profile, to a tmpfs file system, for improvements in application response as all the files are now stored in RAM:

• Refer to Profile-sync-daemon for syncing browser profiles. Certain browsers might need special attention, see e.g. Firefox on RAM.
• Refer to Anything-sync-daemon for syncing any specified folder.
• Refer to Makepkg#Improving compile times for improving compile times by building packages in tmpfs.

Refer to corresponding file system page in case there were performance improvements instructions, e.g. Ext4#Improving performance and XFS#Performance.

See Swap#Performance.

See Sysctl#Virtual memory for details.

Many tasks such as backups do not rely on a short storage I/O delay or high storage I/O bandwidth to fulfil their task, they can be classified as background tasks. On the other hand quick I/O is necessary for good UI responsiveness on the desktop. Therefore it is beneficial to reduce the amount of storage bandwidth available to background tasks, whilst other tasks are in need of storage I/O. This can be achieved by making use of the linux I/O scheduler CFQ, which allows setting different priorities for processes.

The I/O priority of a background process can be reduced to the "Idle" level by starting it with

# ionice -c 3 command

See a short introduction to ionice and for more information.

Overclocking improves the computational performance of the CPU by increasing its peak clock frequency. The ability to overclock depends on the combination of CPU model and motherboard model. It is most frequently done through the BIOS. Overclocking also has disadvantages and risks. It is neither recommended nor discouraged here.

Many Intel chips will not correctly report their clock frequency to acpi_cpufreq and most other utilities. This will result in excessive messages in dmesg, which can be avoided by unloading and blacklisting the kernel module . To read their clock speed use i7z from the package. To check for correct operation of an overclocked CPU, it is recommended to do stress testing.

See CPU frequency scaling.

The default CPU scheduler in the mainline Linux kernel is CFS.

The upstream default settings are tweaked for high throughput which make the desktop applications unresponsive under heavy CPU loads.

The package contains a script that sets up the CFS to use the same settings as the kernel. To run the script on startup, enable/start .

• Project C — Cross-project for refactoring BMQ into Project C, with re-creation of PDS based on the Project C code base. So it is a merge of the two projects, with a subsequent update of the PDS as Project C. Recommended as a more recent development.

https://cchalpha.blogspot.com/ ||

Some applications such as running a TV tuner card at full HD resolution (1080p) may benefit from using a realtime kernel.

See also nice(1) and .

Ananicy is a daemon, available as or , for auto adjusting the nice levels of executables. The nice level represents the priority of the executable when allocating CPU resources.

See cgroups.

Cpulimit is a program to limit the CPU usage percentage of a specific process. After installing , you may limit the CPU usage of a processes' PID using a scale of 0 to 100 times the number of CPU cores that the computer has. For example, with eight CPU cores the percentage range will be 0 to 800. Usage:

$ cpulimit -l 50 -p 5081

The purpose of is distribute hardware interrupts across processors on a multiprocessor system in order to increase performance. It can be controlled by the provided .

Turning off CPU exploit mitigations may improve performance. Use below kernel parameter to disable them all:

mitigations=off

The explanations of all the switches it toggles are given at kernel.org. You can use or (from ) for vulnerability check.

Graphics performance may depend on the settings in ; see the NVIDIA, ATI, AMDGPU and Intel articles. Improper settings may stop Xorg from working, so caution is advised.

The performance of the Mesa drivers can be configured via drirc. GUI configuration tools are available:

• adriconf (Advanced DRI Configurator) — GUI tool to configure Mesa drivers by setting options and writing them to the standard drirc file.

https://gitlab.freedesktop.org/mesa/adriconf/ || adriconf

Hardware video acceleration makes it possible for the video card to decode/encode video.

As with CPUs, overclocking can directly improve performance, but is generally recommended against. There are several packages, such as (ATI cards), (recent AMD cards), nvclock^AUR (old NVIDIA - up to Geforce 9), and for recent NVIDIA cards.

See AMDGPU#Overclocking or NVIDIA/Tips and tricks#Enabling overclocking.

The PCI specification allows larger Base Address Registers to be used for exposing PCI devices memory to the PCI Controller. This can result in a performance increase for video cards. Having access to the the full video memory improves performance, but also enables optimizations in the graphics driver. The combination of resizable BAR, above 4G decoding and these driver optimizations are what AMD calls AMD Smart Access Memory, available at first on AMD Series 500 chipset motherboards, later expanded to AMD Series 400 and Intel Series 300 and later through UEFI updates. This setting may not be available on all motherboards, and is known to sometimes cause boot problems on certain boards.

If the BAR has a 256M size, the feature is not enabled or not supported:

To enable it, enable the setting named "Above 4G Decode" or ">4GB MMIO" in your motherboard settings. Verify that the BAR is now larger:

RAM can run at different clock frequencies and timings, which can be configured in the BIOS. Memory performance depends on both values. Selecting the highest preset presented by the BIOS usually improves the performance over the default setting. Note that increasing the frequency to values not supported by both motherboard and RAM vendor is overclocking, and similar risks and disadvantages apply, see #Overclocking.

If running off a slow writing medium (USB, spinning HDDs) and storage requirements are low, the root may be run on a RAM overlay ontop of read only root (on disk). This can vastly improve performance at the cost of a limited writable space to root. See .

The zram kernel module (previously called compcache) provides a compressed block device in RAM. If you use it as swap device, the RAM can hold much more information but uses more CPU. Still, it is much quicker than swapping to a hard drive. If a system often falls back to swap, this could improve responsiveness. Using zram is also a good way to reduce disk read/write cycles due to swap on SSDs.

Similar benefits (at similar costs) can be achieved using zswap rather than zram. The two are generally similar in intent although not operation: zswap operates as a compressed RAM cache and neither requires (nor permits) extensive userspace configuration. See zswap for more details on the differences between the two.

Since it is enabled by default, disable zswap if you decide to use zram to avoid zswap acting as a swap cache in front of it. Having both enabled also results in incorrect statistics as zram remains mostly unused; this is because zswap intercepts and compresses memory pages being swapped out before they can reach zram.

Example: To set up one lz4 compressed zram device with 32GiB capacity and a higher-than-normal priority (only for the current session):

# modprobe zram
# echo lz4 > /sys/block/zram0/comp_algorithm
# echo 32G > /sys/block/zram0/disksize
# mkswap --label zram0 /dev/zram0
# swapon --priority 100 /dev/zram0

To disable it again, either reboot or run

# swapoff /dev/zram0
# rmmod zram

A detailed explanation of all steps, options and potential problems is provided in the official documentation of the zram module.

The zram-generator package provides a unit to automatically initialize zram devices without users needing to enable/start the template or its instances. The following resources provide information on how to use it:

• zram-generator.conf(5)
• https://github.com/systemd/zram-generator#readme

"The generator will be invoked by systemd early at boot", so usage is as simple as creating the appropriate configuration file(s) and rebooting. A sample configuration is provided in /usr/share/doc/zram-generator/zram-generator.conf.example. You can also check the swap status of your configured devices by checking the unit status of the instance(s).

The package provides an automated script for setting up a swap with a higher priority and a default size of 20% of the RAM size of your system. To do this automatically on every boot, enable .

Alternatively, the package allows to setup zram automatically using zstd compression by default, its configuration can be changed at . It can be started at boot by enabling the zramd.service unit.

The example below describes how to set up swap on zram automatically at boot with a single udev rule. No extra package should be needed to make this work.

Explicitly load the module at boot:

Configure the number of nodes you need:

Create the udev rule as shown in the example:

Add to your fstab.

In the unlikely case that you have very little RAM and a surplus of video RAM, you can use the latter as swap. See Swap on video RAM.

On traditional GNU/Linux system, especially for graphical workstations, when allocated memory is overcommitted, the overall system's responsiveness may degrade to a nearly unusable state before either triggering the in-kernel OOM-killer or a sufficient amount of memory got free (which is unlikely to happen quickly when the system is unresponsive, as you can hardly close any memory-hungry applications which may continue to allocate more memory). The behaviour also depends on specific setups and conditions, returning to a normal responsive state may take from a few seconds to more than half an hour, which could be a pain to wait in serious scenario like during a conference presentation.

While the behaviour of the kernel as well as the userspace things under low-memory conditions may improve in the future as discussed on kernel and Fedora mailing lists, users can use more feasible and effective options than hard-resetting the system or tuning the vm.overcommit_* sysctl parameters:

• Manually trigger the kernel OOM-killer with Magic SysRq key, namely .
• Use a userspace OOM daemon to tackle these automatically (or interactively).

Sometimes a user may prefer OOM daemon to SysRq because with kernel OOM-killer you cannot prioritize the process to (or not) terminate. To list some OOM daemons:

• nohang — Sophisticated OOM handler written in Python, with optional PSI support, more configurable than earlyoom.

https://github.com/hakavlad/nohang || nohang-git^AUR