This is an article detailing different methods of Arch/Windows coexistence.
Windows UEFI vs BIOS limitations
Microsoft imposes limitations on which firmware boot mode and partitioning style can be supported based on the version of Windows used:
- Windows XP both x86 32-bit and x86_64 (also called x64) (RTM and all Service Packs) versions do not support booting in UEFI mode (IA32 or x86_64) from any disk (MBR or GPT) OR in BIOS mode from GPT disk. They support only BIOS boot and only from MBR disk.
- Windows Vista or 7 x86 32-bit (RTM and all Service Packs) versions support booting in BIOS mode from MBR disks only, not from GPT disks. They do not support x86_64 UEFI or IA32 (x86 32-bit) UEFI boot. They support only BIOS boot and only from MBR disk.
- Windows Vista RTM x86_64 (only RTM) version support booting in BIOS mode from MBR disks only, not from GPT disks. It does not support x86_64 UEFI or IA32 (x86 32-bit) UEFI boot. It supports only BIOS boot and only from MBR disk.
- Windows Vista (SP1 and above, not RTM) and Windows 7 x86_64 versions support booting in x86_64 UEFI mode from GPT disk only, OR in BIOS mode from MBR disk only. They do not support IA32 (x86 32-bit) UEFI boot from GPT/MBR disk, x86_64 UEFI boot from MBR disk, or BIOS boot from GPT disk.
- Windows 8/8.1 and 10 x86 32-bit support booting in IA32 UEFI mode from GPT disk only, OR in BIOS mode from MBR disk only. They do not support x86_64 UEFI boot from GPT/MBR disk, x86_64 UEFI boot from MBR disk, or BIOS boot from GPT disk. On market, the only systems known to ship with IA32 (U)EFI are some old Intel Macs (pre-2010 models?) and Intel Atom System-on-Chip (Clover trail and Bay Trail) Windows Tablets, which boot ONLY in IA32 UEFI mode and ONLY from GPT disk.
- Windows 8/8.1 and 10 x86_64 versions support booting in x86_64 UEFI mode from GPT disk only, OR in BIOS mode from MBR disk only. They do not support IA32 UEFI boot, x86_64 UEFI boot from MBR disk, or BIOS boot from GPT disk.
- Windows 11 only supports x86_64 and a boot in UEFI mode from GPT disk.
In case of pre-installed Systems:
- All systems pre-installed with Windows XP, Vista or 7 32-bit, irrespective of Service Pack level, bitness, edition (SKU) or presence of UEFI support in firmware, boot in BIOS/MBR mode by default.
- MOST of the systems pre-installed with Windows 7 x86_64, irrespective of Service Pack level, bitness or edition (SKU), boot in BIOS/MBR mode by default. Very few recent systems pre-installed with Windows 7 are known to boot in x86_64 UEFI/GPT mode by default.
- ALL systems pre-installed with Windows 8/8.1, 10 and 11 boot in UEFI/GPT mode. Up to Windows 10, the firmware bitness matches the bitness of Windows, ie. x86_64 Windows boot in x86_64 UEFI mode and 32-bit Windows boot in IA32 UEFI mode.
The best way to detect the boot mode of Windows is to do the following:
- Boot into Windows
Win+Rkeys to start the Run dialog
- In the Run dialog type
msinfo32.exeand press Enter
- In the System Information windows, select System Summary on the left and check the value of BIOS mode item on the right
- If the value is
UEFI, Windows boots in UEFI/GPT mode. If the value is
Legacy, Windows boots in BIOS/MBR mode.
In general, Windows forces type of partitioning depending on the firmware mode used, i.e. if Windows is booted in UEFI mode, it can be installed only to a GPT disk. If Windows is booted in Legacy BIOS mode, it can be installed only to an MBR disk. This is a limitation enforced by Windows Setup, and as of April 2014 there is no officially (Microsoft) supported way of installing Windows in UEFI/MBR or BIOS/GPT configuration. Thus Windows only supports either UEFI/GPT boot or BIOS/MBR configuration.
Such a limitation is not enforced by the Linux kernel, but can depend on which boot loader is used and/or how the boot loader is configured. The Windows limitation should be considered if the user wishes to boot Windows and Linux from the same disk, since installation procedure of boot loader depends on the firmware type and disk partitioning configuration. In case where Windows and Linux dual boot from the same disk, it is advisable to follow the method used by Windows, ie. either go for UEFI/GPT boot or BIOS/MBR boot. See https://support.microsoft.com/kb/2581408 for more information.
Install media limitations
Intel Atom System-on-Chip Tablets (Clover trail and Bay Trail) provide only IA32 UEFI firmware without Legacy BIOS (CSM) support (unlike most of the x86_64 UEFI systems), due to Microsoft Connected Standby Guidelines for OEMs. Due to lack of Legacy BIOS support in these systems, and the lack of 32-bit UEFI boot in Arch Official Install ISO (FS#53182), the official install media cannot boot on these systems. See Unified Extensible Firmware Interface#UEFI firmware bitness for more information and available workarounds.
Bootloader UEFI vs BIOS limitations
Most of the linux bootloaders installed for one firmware type cannot launch or chainload bootloaders of the other firmware type. That is, if Arch is installed in UEFI/GPT or UEFI/MBR mode in one disk and Windows is installed in BIOS/MBR mode in another disk, the UEFI bootloader used by Arch cannot chainload the BIOS installed Windows in the other disk. Similarly if Arch is installed in BIOS/MBR or BIOS/GPT mode in one disk and Windows is installed in UEFI/GPT in another disk , the BIOS bootloader used by Arch cannot chainload UEFI installed Windows in the other disk.
The only exceptions to this are GRUB in Apple Macs in which GRUB in UEFI mode can boot BIOS installed OS via
appleloader command (does not work in non-Apple systems), and rEFInd which technically supports booting legacy BIOS OS from UEFI systems, but does not always work in non-Apple UEFI systems as per its author Rod Smith.
However if Arch is installed in BIOS/GPT in one disk and Windows is installed in BIOS/MBR mode in another disk, then the BIOS boot loader used by Arch CAN boot the Windows in the other disk, if the boot loader itself has the ability to chainload from another disk.
- Mount ESP to
/efiand use a boot loader that has file system drivers and is capable of launching kernels that reside on other partitions.
- Expand the EFI system partition, typically either by decreasing the Recovery partition size or moving the Windows partition (UUIDs will change).
- Backup and delete unneeded fonts in
- Backup and delete unneeded language directories in
esp/EFI/Microsoft/Boot/(e.g. to only keep
- Use a higher, but slower, compression for the initramfs images. E.g.
UEFI Secure Boot
All pre-installed Windows 8/8.1, 10 and 11 systems by default boot in UEFI/GPT mode and have UEFI Secure Boot enabled by default. This is mandated by Microsoft for all OEM pre-installed systems.
Arch Linux install media does not support Secure Boot yet. See Secure Boot#Booting an installation medium.
It is advisable to disable UEFI Secure Boot in the firmware setup manually before attempting to boot Arch Linux. Windows 8/8.1, 10 and 11 SHOULD continue to boot fine even if Secure boot is disabled. The only issue with regards to disabling UEFI Secure Boot support is that it requires physical access to the system to disable secure boot option in the firmware setup, as Microsoft has explicitly forbidden presence of any method to remotely or programmatically (from within OS) disable secure boot in all Windows 8/8.1 and above pre-installed systems
- If Windows used Bitlocker and stored the key in the TPM for automatic unlock on boot, it fails to boot when Secure Boot is disabled, instead showing a Bitlocker recovery screen. This is not permanent however, and you can easily boot Windows again by simply re-enabling Secure Boot.
- On Windows 11, disabling Secure Boot prevents Windows Hello, WSM (Windows Subsystem for Android) and Windows Updates from working
Fast Startup and hibernation
There are two OSs that can be hibernated, you can hibernate Windows and boot Linux (or another OS), or you can hibernate Linux and boot Windows, or hibernate both OSs.
For the same reason, if you share one EFI System Partition between Windows and Linux, then the EFI System Partition may be damaged if you hibernate (or shutdown with Fast Startup enabled) Windows and then start Linux, or hibernate Linux and then start Windows.
safe-guard to prevent read-write mounting of hibernated NTFS filesystems, but the NTFS driver within the Linux kernel has no such safeguard.added a
Windows cannot read filesystems such as ext4 by default that are commonly used for Linux. These filesystems do not have to be considered, unless you install a Windows driver for them.
Fast Startup is a feature in Windows 8 and above that hibernates the computer rather than actually shutting it down to speed up boot times.
There are multiple options regarding the Windows settings for Fast Startup and hibernation that are covered in the next sections.
- disable Fast Startup and disable hibernation
- disable Fast Startup and enable hibernation
- enable Fast Startup and enable hibernation
The procedure of disabling Fast Startup is described in the tutorials for Windows 8, Windows 10 and Windows 11. In any case if you disable a setting, make sure to disable the setting and then shut down Windows, before installing Linux; note that rebooting is not sufficient.
Disable Fast Startup and disable hibernation
This is the safest option, and recommended if you are unsure about the issue, as it requires the least amount of user awareness when rebooting from one OS into the other. You may share the same EFI System Partition between Windows and Linux.
Disable Fast Startup and enable hibernation
This option requires user awareness when rebooting from one OS into the other. If you want to start Linux while Windows is hibernated, which is a common use case, then
- you must use a separate EFI System Partition (ESP) for Windows and Linux, and ensure that Windows does not mount the ESP used for Linux. As there can only be one ESP per drive, the ESP used for Linux must be located on a separate drive than the ESP used for Windows. In this case Windows and Linux can still be installed on the same drive in different partitions, if you place the ESP used by linux on another drive than the Linux root partition.
- you can not read-write mount any filesystem in Linux, that is mounted by Windows while Windows is hibernated. You should be extremely careful about this, and also consider Automount behaviour.
- If you shut down Windows fully, rather than hibernating, then you can read-write mount the filesystem.
Enable Fast Startup and enable hibernation
The same considerations apply as in case "Disable Fast Startup and enable hibernation", but since Windows can not be shut down fully, only hibernated, you can never read-write mount any filesystem that was mounted by Windows while Windows is hibernated.
Windows filenames limitations
Windows is limited to filepaths being shorter than 260 characters.
Windows also puts certain characters off limits in filenames for reasons that run all the way back to DOS:
|(vertical bar or pipe)
These are limitations of Windows and not NTFS: any other OS using the NTFS partition will be fine. Windows will fail to detect these files and running
chkdsk will most likely cause them to be deleted. This can lead to potential data-loss.
The recommended way to setup a Linux/Windows dual booting system is to first install Windows, only using part of the disk for its partitions. When you have finished the Windows setup, boot into the Linux install environment where you can create and resize partitions for Linux while leaving the existing Windows partitions untouched. The Windows installation will create the EFI system partition which can be used by your Linux boot loader.
Windows before Linux
Using a Linux boot loader
You may use any multi-boot supporting BIOS boot loader.
Using the Windows Vista/7/8/8.1 boot loader
This section explains how to : install a linux bootloader on a partition instead of the MBR ; copy this bootloader to a partition readable by the windows bootloader ; use the windows bootloader to start said copy of the linux bootloader.
- When installing the boot loader, install it on your
/bootpartition rather than the MBR. For details on doing this with GRUB, see GRUB/Tips and tricks#Install to partition or partitionless disk, for Syslinux, see the note at Syslinux#Manual install, for LILO see LILO#Install to partition or partitionless disk.
- Make a copy of the VBR:
dd if=/dev/disk of=/path/to/linux.bin bs=512 count=1where
/dev/diskis the path of the partition on which your bootloader is installed and
/path/to/is the mounted filesystem on which you want the copy to be readable by the Windows bootloader.
- On Windows, the linux.bin file should now be accessible. Run cmd with administrator privileges (navigate to Start > All Programs > Accessories, right-click on Command Prompt and select Run as administrator):
bcdedit /create /d "Linux" /application BOOTSECTORBCDEdit will return a UUID for this entry. This will be refered to as
UUIDin the remaining steps.
bcdedit /set UUID device partition=c: (or the drive letter on which linux.bin is kept) bcdedit /set UUID path \path\to\linux.bin bcdedit /displayorder UUID /addlast bcdedit /timeout 30
On reboot, both Windows and Linux should now show up in the Windows bootloader.
For more details, see https://www.iceflatline.com/2009/09/how-to-dual-boot-windows-7-and-linux-using-bcdedit/
If you already have Windows installed, it will already have created some partitions on a GPT-formatted disk:
- a Windows Recovery Environment partition, generally of size 499 MiB, containing the files required to boot Windows (i.e. the equivalent of Linux's
- an EFI system partition with a FAT32 filesystem,
- a Microsoft Reserved Partition, generally of size 128 MiB,
- a Microsoft basic data partition with a NTFS filesystem, which corresponds to
- potentially system recovery and backup partitions and/or secondary data partitions (corresponding often to
Using the Disk Management utility in Windows, check how the partitions are labelled and which type gets reported. This will help you understand which partitions are essential to Windows, and which others you might repurpose. The Windows Disk Management utility can also be used to shrink Windows (NTFS) partitions to free up disk space for additional partitions for Linux.
You can then proceed with partitioning, depending on your needs. The boot loader needs to support chainloading other EFI applications to dual boot Windows and Linux. An additional EFI system partition should not be created, as it may prevent Windows from booting.
Simply mount the existing partition.
- rEFInd and systemd-boot will autodetect Windows Boot Manager (
\EFI\Microsoft\Boot\bootmgfw.efi) and show it in their boot menu automatically. For GRUB follow either GRUB#Windows installed in UEFI/GPT mode to add boot menu entry manually or GRUB#Detecting other operating systems for a generated configuration file.
- To save space on the EFI system partition, especially for multiple kernels, increase the initramfs compression.
Computers that come with newer versions of Windows often have Secure Boot enabled. You will need to take extra steps to either disable Secure Boot or to make your installation media compatible with secure boot (see above and in the linked page).
Linux before Windows
Even though the recommended way to setup a Linux/Windows dual booting system is to first install Windows, it can be done the other way around. In contrast to installing Windows before Linux, you will have to set aside a partition for Windows, say 40GB or larger, in advance. Or have some unpartitioned disk space, or create and resize partitions for Windows from within the Linux installation, before launching the Windows installation.
Windows will use the already existing EFI system partition. In contrast to what was stated earlier, it is unclear if a single partition for Windows, without the Windows Recovery Environment and without Microsoft Reserved Partition, will not do.
Follows an outline, assuming Secure Boot is disabled in the firmware.
- Boot into windows installation. Watch to let it use only the intended partition, but otherwise let it do its work as if there is no Linux installation.
- Follow the #Fast Startup and hibernation section.
- Fix the ability to load Linux at start up, perhaps by following #Cannot boot Linux after installing Windows. It was already mentioned in #UEFI systems that some Linux boot managers will autodetect Windows Boot Manager. Even though newer Windows installations have an advanced restart option, from which you can boot into Linux, it is advised to have other means to boot into Linux, such as an arch installation media or a live CD.
Windows 10 with GRUB
The following assumes GRUB is used as a boot loader (although the process is likely similar for other boot loaders) and that Windows 10 will be installed on a GPT block device with an existing EFI system partition (see the "System partition" section in the Microsoft documentation for more information).
Create with program
gdisk on the block device the following three new partitions. See  for more precise partition sizes.
|Min size||Code||Name||File system|
|16 MB||0C01||Microsoft reserved||N/A|
|~40 GB||0700||Microsoft basic data||NTFS|
|300 MB||2700||Windows RE||NTFS|
Create NTFS file systems on the new Microsoft basic data and Windows RE (recovery) partitions using the mkntfs program from package.
Reboot the system into a Windows 10 installation media. When prompted to install select the custom install option and install Windows on the Microsoft basic data partition created earlier. This should also install Microsoft EFI files in the EFI partition.
After installation (set up of and logging into Windows not required), reboot into Linux and generate a GRUB configuration for the Windows boot manager to be available in the GRUB menu on next boot.
Couldn't create a new partition or locate an existing one
Cannot boot Linux after installing Windows
Restoring a Windows boot record
By convention (and for ease of installation), Windows is usually installed on the first partition and installs its partition table and reference to its bootloader to the first sector of that partition. If you accidentally install a bootloader like GRUB to the Windows partition or damage the boot record in some other way, you will need to use a utility to repair it. Microsoft includes a boot sector fix utility
FIXBOOT and an MBR fix utility called
FIXMBR on their recovery discs, or sometimes on their install discs. Using this method, you can fix the reference on the boot sector of the first partition to the bootloader file and fix the reference on the MBR to the first partition, respectively. After doing this you will have to reinstall GRUB to the MBR as was originally intended (that is, the GRUB bootloader can be assigned to chainload the Windows bootloader).
If you wish to revert back to using Windows, you can use the
FIXBOOT command which chains from the MBR to the boot sector of the first partition to restore normal, automatic loading of the Windows operating system.
Of note, there is a Linux utility called
ms-sys (package AUR in AUR) that can install MBR's. However, this utility is only currently capable of writing new MBRs (all OS's and file systems supported) and boot sectors (a.k.a. boot record; equivalent to using
FIXBOOT) for FAT file systems. Most LiveCDs do not have this utility by default, so it will need to be installed first, or you can look at a rescue CD that does have it, such as Parted Magic.
First, write the partition info (table) again by:
# ms-sys --partition /dev/sda1
Next, write a Windows 2000/XP/2003 MBR:
# ms-sys --mbr /dev/sda # Read options for different versions
Then, write the new boot sector (boot record):
# ms-sys -(1-6) # Read options to discover the correct FAT record type
ms-sys can also write Windows 98, ME, Vista, and 7 MBRs as well, see
Restoring an accidentally deleted EFI partition
If you have a GPT-partitioned disk and erased (e.g. with
mkfs.fat -F32 /dev/sdx) the EFI partition, you will notice that Windows Boot Manager will either disappear from your boot options, or selecting it will send you back to the UEFI.
To remedy it, boot with a Windows installation media, press
Shift+F10 to open the console (or click NEXT > Repair Computer > Troubleshoot... > Advanced > Command Prompt), then start the diskpart utility:
X:\Sources> diskpart DISKPART> list disk
Select the appropriate hard drive by typing:
DISKPART> select disk number
Make sure that there is a partition of type system (the EFI partition):
DISKPART> list partition
Select this partition:
DISKPART> select partition number
and assign a temporary drive letter to it:
DISKPART> assign letter=G:
DiskPart successfully assigned the drive letter or mount point.
To make sure that drive letter is correctly assigned:
DISKPART> list vol
Volume ### Ltr Label Fs Type Size Status Info ---------- --- ----------- ----- ---------- ------- --------- -------- Volume 0 E DVD-ROM 0 B No Media Volume 1 C NTFS Partition 195 GB Healthy Boot Volume 2 WINRE NTFS Partition 400 MB Healthy Hidden Volume 3 G FAT32 Partition 499 MB Healthy System
C:\ (or what your system drive letter is):
X:\Sources> cd /d C:\
Next is the "magic" command, which recreate the BCD store (with
/s for the mount point,
/f for firmware type, optionally add
/v for verbose):
C:\> bcdboot C:\Windows /s G: /f UEFI
Ctrl+c. This happens sometimes, but you will get a message like
boot files successfully createdand it will have worked just fine.
You should now have Windows Boot Manager working as a boot option, and thus have access to Windows. Just make sure to never format your EFI partition again!
The EFI system partition created by Windows Setup is too small
Windows Setup creates a 100 MiB EFI system partition (except for Advanced Format 4K native drives where it creates a 300 MiB ESP). This is generally too small to fit everything you need. You can try different tools to resize this partition, but there are usually other partitions in the way, making it, at the very least, difficult. One option is to use the Arch install media to create a single EFI system partition of your preferred size before you install Windows on the drive. Windows Setup will use the EFI system partition you made instead of creating its own.
- Recommended: Set both Arch Linux and Windows to use UTC, following System time#UTC in Microsoft Windows. Some versions of Windows revert the hardware clock back to localtime if they are set to synchronize the time online. This issue appears to be fixed in Windows 10.
- Not recommended: Set Arch Linux to localtime and disable all time synchronization daemons. This will let Windows take care of hardware clock corrections and you will need to remember to boot into Windows at least two times a year (in Spring and Autumn) when DST kicks in. So please do not ask on the forums why the clock is one hour behind or ahead if you usually go for days or weeks without booting into Windows.
When it comes to pairing Bluetooth devices with both the Linux and Windows installation, both systems have the same MAC address, but will use different link keys generated during the pairing process. This results in the device being unable to connect to one installation, after it has been paired with the other. To allow a device to connect to either installation without re-pairing, follow Bluetooth#Dual boot pairing.