- Linux divides its physical RAM (random access memory) into chucks of memory called pages. Swapping is the process whereby a page of memory is copied to the preconfigured space on the hard disk, called swap space, to free up that page of memory. The combined sizes of the physical memory and the swap space is the amount of virtual memory available.
Swap space will usually be a disk partition but can also be a file. Users may create a swap space during installation of Arch Linux or at any later time should it become necessary. Swap space is generally recommended for users with less than 1 GB of RAM, but becomes more a matter of personal preference on systems with gratuitous amounts of physical RAM (though it is required for suspend-to-disk support).
To set up a Linux swap area, the Template:Codeline command is used. For example:
# mkswap /dev/sda2
To enable the device for paging:
# swapon /dev/sda2
To enable this swap partition on boot, add an entry to fstab:
/dev/sda2 swap swap defaults 0 0
As an alternative to creating an entire partition, a swap file offers the ability to vary its size on-the-fly, and is more easily removed altogether. This may be especially desirable if disk space is at a premium (e.g. a modestly-sized SSD).
Swap file creation
As root, use Template:Codeline to create a file the size of your choosing. For example, creating a 512 MB swap file:
# dd if=/dev/zero of=/swapfile bs=1M count=512
Set the right permissions (a world-readable swap file is a huge local vulnerability)
# chmod 600 /swapfile
After creating the correctly-sized file, format it to swap:
# mkswap /swapfile
Activate the swapfile:
# swapon /swapfile
Edit Template:Filename and add an entry for the swap file:
/swapfile swap swap defaults 0 0
Ensure proper swap file size and activation with Template:Codeline:
$ free -m
Swap file removal
To remove a swap file, the current swap file must be turned off.
# swapoff -a
# rm -rf /swapfile
Resume from Swap file
Resuming the system from a swap file after hibernation requires an addition parameter to the kernel compared to resuming from a swap partition. The additional parameter is resume_offset=<Swap File Offset>.
The value of <Swap FIle Offset> can be obtained from the output of filefrag -v; The output is in a table format; the required value is located in the 'physical' column from the first row. Eg:
# filefrag -v /swapfile Filesystem type is: ef53 File size of /swapfile is 4290772992 (1047552 blocks, blocksize 4096) ext logical physical expected length flags 0 0 7546880 6144 1 6144 7557120 7553023 2048 2 8192 7567360 7559167 2048 ...
From the example <Swap FIle Offset> is 7546880.
Swap over USB
Thanks to modularity offered by Linux, we can have multiple swap partitions spread over different devices. To add a a USB device to SWAP:
First, take a USB flash and partition it with a swap partition. To do this you can use graphical tools such as Gparted or console tools like fdisk. Make sure to label the partition as SWAP before writing the partition table.
Next edit the Template:Codeline
# nano /etc/fstab
Now add a new entry, just under the current swap entry, which take the current swap partition over the new USB one
UUID=... swap swap defaults,pri=10 0 0
where UUID is taken from the output of the command
ls -l /dev/disk/by-uuid/ | grep /dev/sdc1
Just replace sdc1 with your new USB swap partition. Template:Codeline
in the original swap entry for teaching fstab to use HD swap only when USB is full
- access time is slower than traditional HD
- avoid power on HD when is in stand-by
- USB are cheaper than HD
- flash memories have limited write cycles
- another device attached to the computer
To check if the tweak works, run
and see if your new swap partition is listed.
Naturally this guide will work for other memory such as SD cards, etc.
The swappiness parameter represents the kernel's preference (or avoidance) of swap space. Swappiness can have a value between 0 and 100. Setting this parameter to a low value will reduce swapping from RAM, and is known to improve responsiveness on many systems.