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documentation.suse.com / SUSE Linux Enterprise Micro Documentation / Deployment Guide / Installation preparation / Installation on AArch64
Applies to SUSE Linux Enterprise Micro 5.1

3 Installation on AArch64

This chapter describes the steps necessary to prepare for the installation of SUSE Linux Enterprise Micro on AArch64 computers. It introduces the steps required to prepare for various installation methods. The list of hardware requirements provides an overview of systems supported by SUSE Linux Enterprise Server. Find information about available installation methods and several common known problems. Also learn how to control the installation, provide installation media, and boot with regular methods.

3.1 Hardware requirements

The SUSE® Linux Enterprise Micro operating system can be deployed on a wide range of hardware. It is impossible to list all the different combinations of hardware SUSE Linux Enterprise Micro supports. However, to provide you with a guide to help you during the planning phase, the minimum requirements are presented here.

If you want to be sure that a given computer configuration will work, find out which platforms have been certified by SUSE. Find a list at https://www.suse.com/yessearch/.

CPU

The minimum requirement is a CPU that supports the Armv8-A instruction set architecture (ISA), for example, Arm Cortex-A53 or Cortex-A57. Refer to https://www.arm.com/products/processors/cortex-a/ for a list of available Armv8-A processors.

CPUs with the Armv8-R (realtime) and Armv8-M (microcontroller) ISA are currently not supported.

Maximum number of CPUs

The maximum number of CPUs supported by software design is 256. If you plan to use such a large system, check our hardware system certification Web page for supported devices, see https://www.suse.com/yessearch/.

Memory requirements

A minimum of 1024 MB of memory is required for a minimal installation. On machines with more than two processors, add 512 MB per CPU. For remote installations via HTTP or FTP, add another 150 MB. Note that these values are only valid for the installation of the operating system—the actual memory requirement in production depends on the system's workload. For systems running the GNOME desktop environment, a minimum of 2048 MB of memory is required and 4096  MB is recommended.

Hard disk requirements

The disk requirements depend largely on workload of your containers. Commonly, you need more space than the installation software itself needs to have a system that works properly. The minimum required value is 12 GB. The recommended value is 20 GB.

Boot methods

The computer can be booted from a USB disk or a network. A special boot server is required to boot over the network. This can be set up with SUSE Linux Enterprise Server.

3.2 Installation considerations

This section encompasses many factors that need to be considered before installing SUSE Linux Enterprise Micro on AArch64 hardware.

3.2.1 Installation on hardware or virtual machine

SUSE Linux Enterprise Micro is normally installed as an independent operating system. With virtualization it is also possible to run multiple instances of SLE Micro on the same hardware. However, the installation of the VM Host Server is performed like a typical installation with some additional packages.

3.2.2 Installation target

Most installations are to a local hard disk. Therefore, it is necessary for the hard disk controllers to be available to the installation system. If a special controller (like a RAID controller) needs an extra kernel module, provide a kernel module update disk to the installation system.

Other installation targets may be various types of block devices that provide sufficient disk space and speed to run an operating system. This includes network block devices like iSCSI or SAN. It is also possible to install on network file systems that offer the standard Unix permissions. However, it may be problematic to boot these, because they must be supported by the initramfs before the actual system can start. Such installations can be useful when you need to start the same system in different locations or you plan to use virtualization features like domain migration.

3.3 Controlling the installation

Control the installation in one of several ways. Boot the setup with one of the options listed in Section 3.4, “Booting the installation system”. To enable the different control methods refer to Section 9.3.4, “Specifying remote access”. For information about how to use each remote control method, refer to Chapter 11, Remote installation.

A brief overview of the different methods:

Local with monitor and keyboard

This is the method most frequently used to install SUSE Linux Enterprise Micro. This also requires the smallest preparation effort but requires a lot of direct interaction.

Remote via SSH

You can control the installation via SSH either in text mode or use X-forwarding for a graphical installation. For details refer to Section 11.4, “Monitoring installation via SSH”.

Remote via serial console

For this installation method you need a second computer connected by a null modem cable to the computer on which to install SUSE Linux Enterprise Micro. The installation then proceeds in text mode. For details refer to Section 11.5, “Monitoring installation via serial console”.

Remote via VNC

Use this method if you want a graphical installation without direct access to the target machine. For details refer to Section 11.3, “Monitoring installation via VNC”.

3.4 Booting the installation system

This section gives an overview of the steps required for the complete installation of SUSE® Linux Enterprise Micro.

For a full description of how to install and configure the system with YaST, refer to Part III, “Manual installation”.

In case of the manual installation, an overview of booting the installation system is provided by the following procedure:

  1. Prepare the installation media.

    USB Flash Drive

    In case of the manual installation from an ISO, creating a bootable flash disk is the easiest way to start the installation. You need to copy the ISO to the device using the dd. The flash disk must not be mounted, and all data on the device will be erased.

    # dd if=PATH_TO_ISO_IMAGE of=USB_STORAGE_DEVICE bs=4M

    If you are deploying raw images, you need to prepare the configuration device. For details refer to Chapter 6, Deploying raw images.

    Network booting

    If the target computer's firmware supports it, you can boot the computer from the network and install from a server. This booting method requires a boot server that provides the needed boot images over the network. The exact protocol depends on your hardware. Commonly you need several services, such as TFTP and DHCP or PXE boot.

    It is possible to install from many common network protocols, such as NFS, HTTP, FTP, or SMB. For more information on how to perform such an installation, refer to Chapter 11, Remote installation.

  2. Configure the target system firmware to boot the medium you chose. Refer to the documentation of your hardware vendor about how to configure the correct boot order.

  3. Set the boot parameters required for your installation control method. An overview of the different methods is provided in Section 3.3, “Controlling the installation”. A list of boot parameters is available in Chapter 9, Boot parameters.

  4. Perform the installation as described in Chapter 10, Installation steps. The system needs to restart after the installation is finished.

  5. Optional: Change the boot order of the system to directly boot from the medium to which SUSE Linux Enterprise Micro has been installed. If the system boots from the installation medium, the first boot parameter will be to boot the installed system.

For the deployment of raw images, the procedure is the following:

  1. Prepare the raw image, for details refer to Procedure 6.1, “Preparing the raw disk image”.

  2. Prepare the configuration media, for details refer to Procedure 6.2, “Preparing the configuration device.”.

  3. Configure the target system firmware to boot the medium where you copied the raw image. Refer to the documentation of your hardware vendor about how to configure the correct boot order.

  4. Perform the installation as described in Chapter 6, Deploying raw images. The system needs to restart after the installation is finished.

3.5 Dealing with boot and installation problems

Although SUSE® Linux Enterprise Micro undergoes an extensive test program, problems may occasionally occur during boot or installation.

3.5.1 Problems booting

Boot problems may prevent the YaST installer from starting on your system. Another symptom is failure to boot after the installation has been completed.

Installed system boots, not media

Change your computer's firmware so that the boot sequence is correct. To do this, consult the manual for your hardware.

The computer hangs

Change the console on your computer so that the kernel outputs are visible. Be sure to check the last few lines of output. This is normally done by pressing CtrlAltF10. If you cannot resolve the problem, consult the SUSE Linux Enterprise Micro support staff. To log all system messages at boot time, use a serial connection as described in Section 2.3, “Controlling the installation”.

Boot disk

The boot disk is a useful interim solution for boot issues. If you have difficulties setting the other configurations, or if you want to postpone the decision regarding the final boot mechanism, use a boot disk.

3.5.2 Problems installing

If an unexpected problem occurs during installation, information is needed to determine the cause of the problem. Use the following directions to help with troubleshooting:

  • Check the outputs on the various consoles. You can switch consoles with the key combination CtrlAltFn. For example, obtain a shell in which to execute various commands by pressing CtrlAltF2.

  • Try launching the installation with Safe Settings (press F5 on the installation screen and choose Safe Settings). If the installation works without problems in this case, there is an incompatibility that causes either ACPI or APIC to fail. In some cases, a firmware update fixes this problem.

  • Check the system messages on a console in the installation system by entering the command dmesg -T.

3.5.3 Redirecting the boot source to the boot DVD

To simplify the installation process and avoid accidental installations, the default setting on the installation DVD for SUSE Linux Enterprise Micro is that your system is booted from the first hard disk. At this point, an installed boot loader normally takes over control of the system. This means that the boot DVD can stay in the drive during an installation. To start the installation, choose one of the installation possibilities in the boot menu of the media.

3.6 Raspberry Pi

SUSE® Linux Enterprise Server is the first enterprise Linux distribution to support the inexpensive Raspberry Pi* single-board computer. SUSE Linux Enterprise Micro 5.1 supports the following models:

  • Raspberry Pi 3 Model A+

  • Raspberry Pi 3 Model B

  • Raspberry Pi 3 Model B+

  • Raspberry Pi 4 Model B

  • Raspberry Pi Compute Module 3

  • Raspberry Pi Compute Module 3+

  • Raspberry Pi Compute Module 4

The Raspberry Pi differs from more conventional server machines in several ways. First and foremost, it does not come with a boot loader capable of loading operating systems. SUSE Linux Enterprise Micro therefore ships additional boot loader software to fill that gap.

3.6.1 Boot process

The primary processor on the Raspberry Pi's System-on-Chip (SoC) is the Broadcom VideoCore Graphics Processing Unit (GPU), not the Arm Central Processing Unit (CPU). It is the GPU which starts initializing the hardware from a first-stage boot loader in the on-chip Boot Read-Only Memory (Boot ROM). Only a few configuration options can influence the Boot ROM; see Section 3.6.1.2, “OTP memory”.

The Raspberry Pi 3 hardware does not have any built-in firmware. Instead, its second-stage boot loader firmware bootcode.bin is loaded from the boot medium every time the machine is powered on. It in turn loads the third-stage boot loader start.elf.

The Raspberry Pi 4 hardware has a small Electrically Erasable Programmable Read-Only Memory (EEPROM) for the second-stage boot loader. Apart from that, its boot sequence is similar to that of the Raspberry Pi 3, loading the third-stage boot loader start4.elf from the boot medium.

Warning
Warning: EEPROM update on Raspberry Pi 4

An update of the second-stage boot loader can be performed by booting from a specially prepared microSD card.

Only insert boot media that you trust, and verify that no file called recovery.bin is unintentionally present.

If an armstub8.bin file is present, it will be loaded as a fourth-stage boot loader at AArch64 Exception Level 3 (EL3). Otherwise, a minimal integrated stub will be used.

Note
Note: EL3 security considerations

Code loaded for EL3 (often called BL31) will reside in memory, and Linux may attempt hypercalls into EL3 throughout its runtime.

Verify that your boot media have no armstub8.bin file unintentionally present. SUSE Linux Enterprise Micro 5.1 does not include it.

Beware that the Raspberry Pi's SoC does not provide TrustZone secure memory. Both the OS on the CPU and any software on the GPU may access its RAM. It is therefore unsuited for cryptographic EL0-s applications. SUSE Linux Enterprise Micro does not provide an EL1-s Trusted Execution Environment (TEE) for that reason.

SUSE Linux Enterprise Micro for the Raspberry Pi is configured to load a fifth-stage boot loader called Das U-Boot.

3.6.1.1 Config.txt

There is no non-volatile memory to hold configuration information. This means there are no conventional settings to adjust for boot device order, time and date, and so on.

Instead, the boot loader reads a configuration file config.txt from the boot medium. The config.txt provided by SUSE should not be modified. It allows the user to optionally provide an extraconfig.txt file, which can override any setting from config.txt if needed. This permits SUSE Linux Enterprise Micro to update the config.txt file when needed, without overwriting any user settings.

3.6.1.2 OTP memory

The SoC also has a very small amount of One-Time Programmable Memory (OTP memory). This can be used to configure some settings, such as whether the Boot ROM should attempt to boot from USB devices or over Ethernet.

This OTP memory is described on the Raspberry Pi Foundation Web site: https://www.raspberrypi.org/documentation/hardware/raspberrypi/otpbits.md

Warning
Warning: One-time programmable only

Configuration settings written into OTP memory cannot be reversed.

The most common use case for OTP memory will be enabling USB boot on Raspberry Pi 3 Model B or Compute Module 3.

3.6.1.3 Enabling USB boot mode for Raspberry Pi 3 Model B

To permanently allow booting from connected USB mass storage devices on Raspberry Pi 3 Model B, and from its on-board USB Ethernet, prepare a microSD card as described in Section 3.6.3, “Deploying an appliance image”. Before unmounting or ejecting the card and booting from it, add to its FAT partition a text file extraconfig.txt (Section 3.6.1.1, “Config.txt”) with the following setting:

program_usb_boot_mode=1

Then continue to boot from the modified microSD card as usual. Once you see output from the U-Boot or GRUB boot loaders or the Linux kernel, you can remove power and then the microSD card. Your device should now be able to boot from USB (Section 3.6.4, “Installation from USB media”).

Note that once USB boot mode has been enabled for Raspberry Pi 3 Model B, USB boot mode cannot be disabled again (Section 3.6.1.2, “OTP memory”).

For more details, refer to the Raspberry Pi Foundation Web site: https://www.raspberrypi.org/documentation/hardware/raspberrypi/bootmodes/msd.md

For the Raspberry Pi Compute Module 3, the setting required is the same, but the deployment of the modified image is a little more complicated.

3.6.2 Lack of a real-time clock

There is no battery-backed Real-Time Clock (RTC) on the Raspberry Pi itself.

Note
Note: Time synchronization

The lack of a Real-Time Clock means that Raspberry Pi devices need to be configured to fetch the time from a network server by Network Time Protocol.

However, base boards for the Raspberry Pi Compute Modules may feature an RTC.

It is also possible to connect an RTC via the GPIO connector, using Hardware Attached on Top (HATs) or other expansion boards.

Either way, check whether the respective RTC chipset is supported by SUSE Linux Enterprise Micro. The connected RTC will need to be described to the operating system via a Device Tree Overlay (Section 3.6.1.1, “Config.txt”). For example, the MyPi base board might use:

dtparam=i2c1=on
dtoverlay=i2c-rtc,ds1307

3.6.3 Deploying an appliance image

The most common method to deploy an operating system onto Raspberry Pi hardware is to copy a pre-installed system image onto a boot medium, usually a microSD card. This is the simplest and easiest method.

SUSE provides a preconfigured bootable image of SUSE Linux Enterprise Micro for Raspberry Pi hardware. This comes with the Btrfs file system, with compression enabled to improve performance and reduce wear on microSD media.

A microSD card with a minimum size of 8 GB is recommended. Faster cards will give better system performance. On the first boot, the operating system automatically expands the file system to fill the card. This means that the first boot will be substantially slower than subsequent boots.

The process of writing the card image onto microSD media is described in the Raspberry Pi Quick Start.

3.6.4 Installation from USB media

Some models of Raspberry Pi allow booting from USB mass storage devices. This will then allow deploying SUSE Linux Enterprise Micro on Raspberry Pi similar to server platforms.

Installation can be performed from a removable USB medium, such as a memory stick, onto a microSD card in the machine's internal slot. Alternatively, it can be performed from a removable USB medium onto another USB medium, such as a USB-connected hard disk.

Note
Note: USB bandwidth limitations

Note that the Ethernet controller on the Raspberry Pi 3 is connected to the device's on-board USB 2.0 bus.

Therefore an operating system running from a disk attached via USB must share the total 480 Mbps bandwidth of the USB 2.0 controller. This will limit performance, and could significantly impact network performance.

This limitation does not apply to the Raspberry Pi 4.

Newer models of Raspberry Pi 3 with BCM2837 B0 silicon (silver instead of black chip), including Raspberry Pi 3 Model B+ and Compute Module 3+, allow booting from USB-connected storage devices by default.

On older models, such as Raspberry Pi 3 Model B or Compute Module 3, USB boot can be enabled by booting from a specially prepared microSD card once. See Section 3.6.1.2, “OTP memory” for instructions.

3.6.5 Installation from network

Because of the hardware's lack of on-board firmware (Section 3.6.1, “Boot process”), network-booting the Raspberry Pi using PXE is more complex than with more conventional computers.

The process of setting up a PXE boot server for x86 and Arm is described in the SUSE Best Practices document How to Set Up a Multi-PXE Installation Server.

The Raspberry Pi Foundation publishes information on how to boot using PXE one Raspberry Pi from another Raspberry Pi: https://www.raspberrypi.org/documentation/hardware/raspberrypi/bootmodes/net_tutorial.md

3.6.6 More information

For more information, consult the following resources:

SUSE Linux Enterprise Server 15 SP3 Release Notes

For more information about hardware compatibility, supported options and functionality when running on Raspberry Pi hardware, consult the Boot and Driver Enablement for Raspberry Pi section of the SUSE Linux Enterprise Server Release Notes:

https://www.suse.com/releasenotes/aarch64/SUSE-SLES/15-SP3/#aarch64-rpi

Raspberry Pi Quick Start

https://documentation.suse.com/sles-15/html/SLES-rpi-quick/art-rpiquick.html

openSUSE Hardware Compatibility List: Raspberry Pi 3

The openSUSE project also has information about installing and configuring Raspberry Pi hardware. Much of this also applies to SUSE Linux Enterprise.

See https://en.opensuse.org/HCL:Raspberry_Pi3.

Das U-Boot

More information about Das U-Boot boot loader can be found on the project's GitHub page at https://github.com/u-boot/u-boot.