Raspberry Pi: Difference between revisions
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Note: You should be safe using the '''armhf''' build on all versions of Raspberry Pi (including Pi Zero and Compute Modules); but it may perform less optimally on recent versions of Raspberry Pi. The '''armv7''' build is compatible with Raspberry Pi 2 Model B. The '''aarch64''' build should be compatible with Raspberry Pi 2 Model v1.2, and is compatible with Raspberry Pi 3 and Compute Module 3. | Note: You should be safe using the '''armhf''' build on all versions of Raspberry Pi (including Pi Zero and Compute Modules); but it may perform less optimally on recent versions of Raspberry Pi. The '''armv7''' build is compatible with Raspberry Pi 2 Model B. The '''aarch64''' build should be compatible with Raspberry Pi 2 Model v1.2, and is compatible with Raspberry Pi 3 and Compute Module 3. | ||
Optionally create a "usercfg.txt" file on your SD card to configure low-level system settings. Specifications can be found [https://www.raspberrypi.org/documentation/configuration/config-txt here]. Some interesting values include: | |||
* Enable audio: dtparam=audio=on | |||
* If you see black edges around your screen after booting the Pi, you can add: disable_overscan=1 | |||
=== WiFi support === | === WiFi support === | ||
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cp firmware-nonfree/brcm/* [SD card]/firmware/brcm | cp firmware-nonfree/brcm/* [SD card]/firmware/brcm | ||
</code> | </code> | ||
== Installation == | == Installation == |
Revision as of 19:00, 12 November 2019
This tutorial will help you install Alpine Linux on your Raspberry Pi.
Preparation
This section will help you format and partition your SD card:
- Download Alpine for Raspberry Pi tarball for the armhf architecture which is named as
alpine-rpi-<version>-armhf.tar.gz
. You will need version 3.2.0 or greater if you have a Raspberry Pi 2. - Mount your SD card to your workstation
- Use gnome-disks or fdisk to create a FAT32 partition. If you are using fdisk, the FAT32 partition type is called W95 FAT32 (LBA) and its ID is 0x0C.
- Mark the newly created partition as bootable and save
- If you used fdisk to create the partition you need to create a filesystem on it with mkdosfs -F 32 /dev/sdX1
- Mount the previously created partition
- Extract the tarball contents to your FAT32 partition
- Unmount the SD Card.
Note: You should be safe using the armhf build on all versions of Raspberry Pi (including Pi Zero and Compute Modules); but it may perform less optimally on recent versions of Raspberry Pi. The armv7 build is compatible with Raspberry Pi 2 Model B. The aarch64 build should be compatible with Raspberry Pi 2 Model v1.2, and is compatible with Raspberry Pi 3 and Compute Module 3.
Optionally create a "usercfg.txt" file on your SD card to configure low-level system settings. Specifications can be found here. Some interesting values include:
- Enable audio: dtparam=audio=on
- If you see black edges around your screen after booting the Pi, you can add: disable_overscan=1
WiFi support
If you need WiFi to work, perform the following before unmounting the SD card:
- Download the latest Broadcom drivers for the Raspberry Pi to your machine and
- Copy them to [SD card]/firmware/brcm/.
git clone --depth 1 https://github.com/RPi-Distro/firmware-nonfree.git
cp firmware-nonfree/brcm/* [SD card]/firmware/brcm
Installation
Alpine Linux will be installed as diskless mode, hence you need to use Alpine Local Backup (lbu) to save your modifications between reboots. Follow these steps to install Alpine Linux:
- Insert the SD card into the Raspberry Pi and turn it on
- Login into the Alpine system as root. Leave the password empty.
- Type
setup-alpine
- Once the installation is complete, commit the changes by typing
lbu commit -d
Type reboot
to verify that the installation was indeed successful.
Post Installation
Update the System
Upon installation, make sure that your system is up-to-date:
apk update apk upgrade
Don't forget to save the changes:
lbu commit -d
During the booting time, you might notice errors related to the hardware clock. The Raspberry Pi does not have a hardware clock and therefore you need to disable the hwclock daemon and enable swclock:
rc-update add swclock boot # enable the software clock rc-update del hwclock boot # disable the hardware clock
Since Raspberry Pi does not have a clock, the Alpine Linux needs to know what the time is by using a Network Time Protocol (NTP) daemon. Make sure that you a NTP daemon installed and running. If you are not sure, then you can install NTP client by running the following command:
setup-ntp
The Busybox NTP client might be the most lightweight solution. Save the changes and reboot, once the NTP software is installed and running:
lbu commit -d reboot
After reboot, make sure that the date
command outputs the correct date and time.
WiFi on boot
If you have already configured WiFi during the setup, the connection will not return on reboot. You will need to start up a service to automatically connect to the wireless access point.
- Run
rc-update add wpa_supplicant boot
to connect to the wireless access point on boot. - Run it manually with
/etc/init.d/wpa_supplicant start
.
Enable OpenGL (Raspberry Pi 3)
Remount the boot partition writeable (ie. /media/mmcblk0p1):
mount -o remount,rw /media/mmcblk0p1
Add the following lines to /media/mmcblk0p1/config.txt
dtoverlay=vc4-kms-v3d gpu_mem=128
256MB gpu_mem is also possible
Install mesa-dri-vc4:
apk add mesa-dri-vc4
Reboot:
lbu_commit -d; reboot
Persistent storage
Loopback image with overlayfs
The install is in diskless mode and forces everything into memory, if you want additional storage we need to create loop-back storage onto the SD mounted with overlayfs.
First make the SD card writable again and change fstab to always do so:
mount /media/mmcblk0p1 -o rw,remount sed -i 's/vfat\ ro,/vfat\ rw,' /etc/fstab
Create the loop-back file, this example is 1 GB:
dd if=/dev/zero of=/media/mmcblk0p1/persist.img bs=1024 count=0 seek=1048576
Install the ext utilities:
apk add e2fsprogs
Format the loop-back file:
mkfs.ext4 /media/mmcblk0p1/persist.img
Mount the storage:
echo "/media/mmcblk0p1/persist.img /media/persist ext4 rw,relatime,errors=remount-ro 0 0" >> /etc/fstab mkdir /media/persist mount -a
Make the overlay folders, we are doing /usr here, but you can do /home or anything else:
mkdir /media/persist/usr mkdir /media/persist/.work echo "overlay /usr overlay lowerdir=/usr,upperdir=/media/persist/usr,workdir=/media/persist/.work 0 0" >> /etc/fstab mount -a
Your /etc/fstab should look something like this:
/dev/cdrom /media/cdrom iso9660 noauto,ro 0 0 /dev/usbdisk /media/usb vfat noauto,ro 0 0 /dev/mmcblk0p1 /media/mmcblk0p1 vfat rw,relatime,fmask=0022,dmask=0022,errors=remount-ro 0 0 /media/mmcblk0p1/persist.img /media/persist ext4 rw,relatime,errors=remount-ro 0 0 overlay /usr overlay lowerdir=/usr,upperdir=/media/persist/usr,workdir=/media/persist/.work 0 0
Now commit the changes: (optionally remove the e2fsprogs, but it does contain repair tools)
lbu_commit -d
Remember with this setup, if you install things and you have done this overlay for /usr, you must not commit the 'apk add', otherwise while it boots it will try and install it to memory and not to the persist storage.
If you do want to install something small at boot you can use `apk add` and `lbu commit -d`.
If it is something a bit bigger then you can use `apk add` but then not commit it, it will be persistent (in /user), but do check everything you need is in that directory and not in folders you have not made persistent.
Traditional disk-based (sys) installation
It is also possible to switch to a fully disk-based installation: this is not yet formally supported, but can be done somewhat manually. This frees all the memory otherwise needed for the root filesystem, allowing more installed packages.
Split your SD card into two partitions: the FAT32 boot partition described above (in this example it'll be mmcblk0p1
) , and a second partition to hold the root filesystem (here it'll be mmcblk0p2
). Boot and configure your diskless system as above, then create a root filesystem:
apk add e2fsprogs mkfs.ext4 /dev/mmcblk0p2
Now do a disk install via a mountpoint. The setup-disk
script will give some errors about syslinux/extlinux, but you can ignore these: the Raspberry Pi doesn't need this to boot anyway.
mkdir /stage mount /dev/mmcblk0p2 /stage setup-disk -o /media/mmcblk0p1/MYHOSTNAME.apkovl.tar.gz /stage # (ignore errors about syslinux/extlinux)
Add a line to /stage/etc/fstab
to mount the Pi's boot partition again:
/dev/mmcblk0p1 /media/mmcblk0p1 vfat defaults 0 0
Now add a root=/dev/mmcblk0p2
parameter to the Pi's boot command line, either cmdline-rpi2.txt
or cmdline-rpi.txt
depending on model:
mount -o remount,rw /media/mmcblk0p1 sed -i '$ s/$/ root=\/dev\/mmcblk0p2/' /media/mmcblk0p1/cmdline-rpi2.txt
You might also consider overlaytmpfs=yes
here, which will cause the underlying SD card root filesystem to be mounted read-only, with an overlayed tmpfs for modifications which will be discarded on shutdown.
Beware, though, that the contents of /boot will be ignored when the Pi boots: it will use the kernel, initramfs, and modloop images from the FAT32 boot partition. To update the kernel, initfs or modules, you will need to manually (generate and) copy these to the boot partition or you could use bind mount so that manually copy the files to boot partition is not needed.
echo /media/mmcblk0p1/boot /boot none defaults,bind 0 0 >> /etc/fstab
Persistent Installation on Raspberry Pi 3
See this page : https://wiki.alpinelinux.org/wiki/Classic_install_or_sys_mode_on_Raspberry_Pi
See https://web.archive.org/web/20171125115835/https://forum.alpinelinux.org/comment/1084#comment-1084
Troubleshooting
Long boot time when running headless
If no peripherals are connected the system might hang for an exceptionally long period of time while it attempts to accumulate entropy.
If this is the case simply plugging in any USB device should work around this issue.
apk indicating 'No space left on device'
Note some models of the Raspberry Pi such as the 3A+ only have 512M of RAM, which on fresh Alpine deployment will only leave around 200M for tmpfs root. It's important to keep this limitation in mind when using these boards.
See Also
- Classic install or sys mode on Raspberry Pi - a variant.
- Raspberry Pi 3 - Setting Up Bluetooth
- Raspberry Pi 3 - Configuring it as wireless access point -AP Mode
- Linux Router with VPN on a Raspberry Pi
- Create a bootable SDHC from a Mac
- Build custom Raspberry Pi images based on Alpine via Pieman