wiki:ventana/ubuntu

Version 63 (modified by Cale Collins, 4 years ago) ( diff )

step 13 cleanup

Ubuntu on Ventana

While Gateworks cannot fully support all Linux distros, it is relatively simple to overlay a Gateworks Ventana kernel onto any non-Gateworks third party Linux distro rootfs image. For a full list of Linux BSP's for Ventana see here

This page is dedicated details regarding running Ubuntu on an Gateworks Ventana Board.

For a full Board Support Package providing building a Linux distro from source, please see the OpenWrt, Yocto, or Android BSP from the Ventana BSP page

See also:

Gateworks pre-built Ubuntu Disk Images

Gateworks provides a pre-built Ubuntu firmware images for the Ventana Family:

Login Information (default)

  • Username: root
  • Password: root

Features:

  • Ubuntu arm core (created via ubuntu-rootfs.sh debootstrap script)
  • Gateworks Ventana Linux kernel (Linux 5.4 based)
  • eth0 dhcp with a 30 second timeout
  • User: root password: root
  • Packages installed on top of core including:
  • first-boot script to grow root filesystem partition and filesystem (useful when putting disk images on removable storage devices)
  • use ifupdown tools instead of netplan (we find them easier to understand and configure)

CollapsibleStart(Old Releases) Old Releases:

  • Ubuntu 16.04 LTS (Xenial Xerus) console image
    • Important Notes:
    • A pre-built console image created using the debootstrap method for Ubuntu 16.04 (Xenial Xerus) can be downloaded:
      • xenial-ventana_normal.ubi - UBI image for 2K page size 'normal' geometry FLASH (see here to determine your flash geometry)
        • see here for info about flashing UBI images
        • sha256sum: 000c3fb814f1c0605dd904cab1b77131a5a69e72a145158685d402f0f03aedbf
      • xenial-ventana_large.ubi - UBI image for 4K page size 'large' geometry FLASH (see here to determine your flash geometry)
        • see here for info about flashing UBI images
        • sha256sum: 590b4bc6af10fd8ff07061e73479fc5511fbe718a8b20e16cc6d9051e3ae5151
      • xenial-armhf.tar.xz - tarball of rootfs you can use to image onto microSD / mSATA
        • see linux/blockdev for instructions
        • sha256sum: a03dede35c64a8e28a71279b262ae9092a29ca8fd7de0e09faba4c6cc1f1356b
    • Features:
      • Ubuntu 16.04 (from debootstrap instructions)
      • Ubuntu Xenial kernel (Linux 4.11 based) with drivers/firmware
      • custom bootscript supporting NAND/UBI, MMC, SATA, USB boot devices and root filesystems
      • extra packages: openssh-server can-utils i2c-tools usbutils pciutils
      • eth0 dhcp
      • user root passwd root

CollapsibleEnd

Building the Root Filesystem via debootstrap

A popular way to create a Ubuntu root filesystem is to use the deboostrap utility on a Debian or Ubuntu host. This tool provides a 2-stage install where the second stage is within a chroot environment using qemu-arm.

Gateworks uses a script to do this which you may find at ​http://github.com/Gateworks/ubuntu-rootfs

Requirements:

  • Linux Ubuntu or Debian System with network connection and sudo permissions
  • Linux Kernel
  • Ventana target board with bootloader
  • Boot device with 2GB+ of free space (micro-SD, USB mass storage, mSATA, 1GB/2GB NAND flash)

Important notes:

  • These steps are not always exactly what we do in our script but give you an idea of how you would go about doing it yourself if you wanted to customize something
  • We set and use target and distro env variables in step 2 and use those env variables in the remaining steps to make this tutorial more version-agnostic. Please be aware of this and do not deviate from the steps unless or until you completely understand what you are doing.
  • While operating under the qemu chroot (ie on the host system) you may encounter 'qemu: Unsupported syscall'. Note that messages from QEMU about unsupported syscalls are often harmless, because typically they only appear for relatively new syscalls which QEMU hasn't implemented yet. The guest code will have a fallback path so it works on older kernels which don't implement the syscall, so a message is printed but the application still runs. So if the guest program is failing then it is quite likely to be for an entirely unrelated reason to the missing syscalls.

Host specific notes:

  • Ubuntu 16.04:
    • qemu: Unsupported syscall: 373: an update to initramfs-tools adds a 'sync -f' which isn't supported on qemu-2.5 used by Xenial 16.04. This is fixed in qemu-2.11 (used on Ubuntu 18.04 and beyond). This will cause initramfs updates to fail which may be used if you are trying to use a kernel needing an initramfs. To work around the issue you can comment out the 'sync -f' call in update-initramfs:
      sed -i 's/sync/#sync/' /usr/sbin/update-initramfs
      dpkg --configure -a # re-run any halted postinst scripts
      

Steps:

  1. Install pre-requisites:
    sudo apt-get install qemu-user-static debootstrap binfmt-support
    
  1. Perform first stage install of minimal filesystem:
    target=rootfs
    distro=focal
    sudo debootstrap --arch=armhf --foreign $distro $target
    # copy qemu-arm-static binary for the binfmt packages to find it and copy in resolv.conf from host
    sudo cp /usr/bin/qemu-arm-static $target/usr/bin
    
    • See http://ports.ubuntu.com/ubuntu-ports/dists/ and https://wiki.ubuntu.com/Releases for a list of Ubuntu releases. For example: 20.04=focal (latest LTS)
    • this minimal rootfs is still missing some core packages and configuration before it can be booted. These steps are taken care of in a 2nd stage install within a chroot shell
    • the chroot shell below will provide network support (inherited from the host)
  1. we now have a minimal Ubuntu rootfs - chroot to it and perform the 2nd stage install:
    sudo chroot $target
    # now we are in the chroot
    distro=focal
    export LANG=C
    # setup second stage
    /debootstrap/debootstrap --second-stage
    
    • this is the most minimal rootfs we would recommend
  1. (optional) add additional apt package repos:
    cat <<EOT > /etc/apt/sources.list
    deb http://ports.ubuntu.com/ubuntu-ports $distro main restricted universe multiverse
    deb http://ports.ubuntu.com/ubuntu-ports $distro-updates main restricted universe multiverse
    deb http://ports.ubuntu.com/ubuntu-ports $distro-security main restricted universe multiverse
    EOT
    
    • you may want to customize the above list, depending on your needs. See below for more detail on Ubuntu package feeds
  1. (optional) update package database and setup locales (do not skip this step if you are needing to install any packages for the steps below or otherwise)
    apt-get update
    apt-get -f install # fixup missing package dependencies
    apt-get install locales dialog
    dpkg-reconfigure locales
    
  1. set hostname:
    echo ${distro}-armhf > /etc/hostname
    
  1. create a default fstab:
    cat <<EOT > /etc/fstab
    /dev/root            /                    auto       defaults              1  1
    EOT
    
    • Note that this not required if you pass in 'rw' on the kernel cmdline. However while that is the default for the Ventana bootscripts for removeable storage it is not for NAND boot, therefore we will add a default fstab that will re-mount the kernel mounted rootfs as read-write
    • /dev/root in /etc/fstab will refer to the rootfs mounted by the kernel, thus the above entry simply re-mounts rootfs as read-write
  1. set a root passwd so you can login
    passwd
    
    • or consider adding a user via adduser:
      adduser myuser
      usermod -a -G tty myuser # add to tty group for tty access
      usermod -a -G dialout myuser # add to dialout group for UART access
      usermod -a -G sudo myuser # add to sudo group for root access
      
  1. (optional) configure networking:
    • wired ethernet with DHCP on eth0
      apt-get install net-tools ifupdown
      cat <<EOF >> /etc/network/interfaces
      allow-hotplug eth0
      auto eth0
      iface eth0 inet dhcp
      
      EOF
      
    • or static IP:
      apt-get install net-tools ifupdown
      cat <<EOF >> /etc/network/interfaces
      allow-hotplug eth0
      auto eth0
      iface eth0 inet static
      address 192.168.1.1
      netmask 255.255.255.0
      gateway 192.168.1.254
      
      EOF
      
    • or wireless (requires ~3MB of additional packages):
      apt-get install wpasupplicant iw
      cat << EOF >> /etc/network/interfaces
      # Wireless interface
      auto wlan0
      iface wlan0 inet dhcp
              wireless_mode managed
              wireless_essid any
              wpa-driver nl80211
              wpa-conf /etc/wpa_supplicant.conf
      
      EOF
      wpa_passphrase <myssid> <mypass> >> /etc/wpa_supplicant.conf
      
  1. (optional) install some useful packages
    apt-get install openssh-server # ssh server for remote access
    apt-get install can-utils i2c-tools usbutils pciutils # cmdline tools for various Ventana hardware support
    
    • Note that by default root ssh access is disabled for security. See this link for info on enabling it
  1. install a kernel and kernel support (kernel+dtbs+modules+firmware+initrd). You have several options here (see above for more details). Gateworks recomends using a Gateworks pre-built kernel:
    1. (recommended) Gateworks Pre-built kernel (includes the same kernel drivers typically found on Ubuntu kernels including video capture/display and is built by Gateworks):
      cd /
      wget http://dev.gateworks.com/ventana/images/linux-ventana.tar.xz
      tar -xvf linux-ventana.tar.xz --keep-directory-symlink
      depmod $(ls /lib/modules/) # create module dependencies
      rm linux-ventana.tar.xz
      
      • the depmod trick above is to run depmod with the exact kernel version (which will be the subdir in /lib/modules). An alternative is to run depmod after the first boot
      • this kernel is recommended over the Ubuntu built kernel because it a) enables some drivers/features that Ubuntu leaves out, such as video capture b) may have patches for features that are not yet in mainline linux c) enables everything needed to boot from a Gateworks board static so that you do not need an initrd.
    2. Build your own kernel and install it as above with proper bootscript - see linux/kernel for more info (you can do this on a development host with a cross-toolchain or even even install development tools via the build-essential meta-package and build and install sources such as the kernel below (adds appx 180MB))
    3. Ubuntu Pre-built kernel (includes the most kernel drivers and is built by and supported by Ubuntu):
      # disable flash-kernel as its not needed and will otherwise error out
      echo "FLASH_KERNEL_SKIP=1" >> /etc/environment
      export FLASH_KERNEL_SKIP=1 # and export it for current operations
      # install kernel/firmware/headers
      apt-get install linux-generic
      # install mkimage
      apt-get install u-boot-tools
      # create u-boot image for kernel
      mkimage -A arm -O linux -T kernel -C none \
        -a 0x10008000 -e 0x10008000 -n "linux" \
        -d /boot/vmlinuz-*-generic /boot/uImage
      # install device-tree blobs
      cp /lib/firmware/*-generic/device-tree/imx6*-gw*.dtb /boot
      #blacklist imx rtc driver, Gateworks board uses GSC RTC, and does not use imx RTC
      echo "blacklist rtc_snvs" > /etc/modprobe.d/blacklist-rtc.conf
      
  1. exit the chroot shell and remove files we no longer need
    exit
    sudo rm $target/usr/bin/qemu-arm-static
    
    • You may wish to move this file else place for later use should you wish to chroot again.
  1. Now that the rootfs has been created, use one of the following options:
  1. Create a tarball of the rootfs
    sudo tar --keep-directory-symlink -cvJf $distro-ventana.tar.xz -C $target .
    
  1. install to bootable media:
    • For a removable block storage device supported by your board such as a USB Mass Storage device, a microSD, an mSATA SSD the example below will create a single ext4 rootfs partition on a removable block storage device. Ensure you set DEVICE properly for your system.
      DEVICE=/dev/sdc # adjust per your system!
      MNT=/mnt # adjust per your system!
      # unmount all auto-mounted partitions for this device
      sudo umount ${DEVICE}?
      # partition disk - single ext partition
      printf ",,L,,\n" | sudo sfdisk -uS ${DEVICE}
      sync
      sudo mkfs.ext4 -O ^64bit -L rootfs ${DEVICE}1
      # mount partition
      sudo mount ${DEVICE}1 $MNT
      # copy the root filesystem
      sudo cp -rupv $target/*  $MNT/
      # unmount the disk
      sudo umount ${DEVICE}1
      
  2. Create a ubifs filesystem image and ubi image for flashing onto raw NAND see linux/ubi

Hardware Accelerated Desktop UI

While it is not typical to use an embedded system as an Ubuntu desktop we often are asked how to do it.

With the Ubuntu Focal (20.04) all the software is in place to give you 2D and 3D hardware acceleration with the IMX6 with a modern kernel such as the Linux 5.4 kernel we use in our pre-built images.

Here are the steps to add a desktop UI:

  1. Install gnome desktop:
    # add packages
    apt install gnome-session gnome-terminal
    # add a non-root user (required to login)
    adduser gateworks
    # sync the filesystem and reboot
    sync
    reboot
    
    • you'll notice dragging opaque windows around is fairly smooth as it is using hardware 2D acceleration
    • Network manager will not allow access to interfaces in the GUI with "ifupdown" installed. If you plan to use network functions within the GUI you will need to remove/purge this package first. All network settings must be configured using the terminal.
  2. 3D opengl hardware acceleration:
    apt install mesa-utils glmark2
    # from gnome-terminal running on display from above:
    glxgears # 75fps on IMX6Q displaying HDMI 1080p60hz
    glmark2 # another test that renders via opengl
    
  3. GStreamer Video display
    apt-get install gstreamer1.0-x gstreamer1.0-tools libgstreamer1.0-0 \
      gstreamer1.0-plugins-base gstreamer1.0-plugins-good gstreamer1.0-plugins-bad gstreamer1.0-plugins-ugly \
      gstreamer1.0-libav gstreamer1.0-alsa gstreamer1.0-gl gstreamer1.0-gtk3 gstreamer1.0-qt5 gstreamer1.0-pulseaudio \
      v4l-utils alsa-utils
    # using waylandsink will render 'within' GUI
    gst-launch-1.0 videotestsrc ! waylandsink # renders 'within' gui
    
    • Note: This pipeline is intended to be run in a terminal within the GUI. Executing this pipeline as "root" or using the command "sudo" will result in an error.
    • See gstreamer wiki page for information on hardware accelerated encode/decode

Kernel

While a kernel is not specifically part of a root filesystem it usually resides on the root filesystem. There are several kernel sources you can choose from:

  • Gateworks pre-built 5.4 kernel (recommended)
  • Ubuntu built kernel
  • Kernel built by hand

Gateworks built kernel

Gateworks periodically updates their pre-built IMX6 kernel release and it is easy to install on a running system:

wget http://dev.gateworks.com/ventana/images/linux-ventana.tar.xz
tar -C / -xvf linux-ventana.tar.xz --keep-directory-symlink
rm linux-ventana.tar.xz

If you want to clean out old kernels no longer used, you can remove the directory of modules in /lib/modules/<kernel-version>

Benefits of using the Gateworks kernel:

  • contains all drivers 'static' required to boot off boot devices supported by Gateworks boards (ie NAND, SATA, MMC, USB Mass storage all static in kernel) removing requirement for an 'inital ramdisk' (initrd) that Ubuntu Built kernels require
  • contains kernel patches that may not be in mainline yet
  • tested and supported by Gateworks

Ubuntu built kernel

Ubuntu releases are based on a specific major kernel version. However over time the Ubuntu team releases new major kernel version updates for specific distro versions. An apt-get install linux-image will not change the kernel major version and you have to specifically install a new major version to switch to it.

It is recommended that you use the Gateworks kernel above for the following reasons:

  • Ubuntu built kernels can require initrd for some boot devices complicating things (ie NAND and USB Mass Storage are kernel modules)
  • Ubuntu built kernels may be configured in ways not appropriate for Gateworks boards (ie the DS1672 RTC driver is not static which complicates restoring system time on boot from the GSC provided RTC)

If you wish to use an Ubuntu built kernel here are some notes but Gateworks can not support you if you run into issues as we don't maintain this kernel.

To install a specific kernel image search for available packages and pick the version you want. For example if wanting the 4-15.0-34-generic kernel:

apt-get update
apt-get install linux-image-4.15.0-34-generic
# install mkimage
apt-get install u-boot-tools
# create u-boot image for kernel
mkimage -A arm -O linux -T kernel -C none \
  -a 0x10008000 -e 0x10008000 -n "linux" \
  -d /boot/vmlinuz-4.15.0-34-generic /boot/uImage
# install device-tree blobs
cp /lib/firmware/4.15.0-34-generic/device-tree/imx6*-gw*.dtb /boot
#blacklist imx rtc driver, Gateworks board uses GSC RTC, and does not use imx RTC
echo "blacklist rtc_snvs" > /etc/modprobe.d/blacklist-rtc.conf
# create u-boot image for initrd
mkimage -A arm -O linux -T ramdisk \
  -a 0x0 -e 0x0 -n "initrd" \
  -d /boot/initrd.img-4.15.0-34-generic /boot/uramdisk
  • use apt-cache search linux-image to determine what Ubuntu kernel versions are available

If you want to clean out old kernels no longer used you can use apt list --installed | grep linux to list installed packages and remove them (remove linux-headers, linux-image, linux-modules for example). For example if you want to remove the 4.15.0-42-generic packages:

apt purge linux-image-4.15.0-42-generic linux-modules-4.15.0-42-generic linux-headers-4.15.0-42
  • modify the above to remove the specific version(s) you want to remove

If booting from boot media that requires kernel modules you need to create an initrd:

  • The default Ubuntu kernel supports booting a microSD/SATA rootfs directly, but lacks nand/ubifs/ubi/usb-storage support. If you need that (and have a large enough flash to boot from that) you will need to use the Ubuntu initrd:
    • add NAND/ubifs/usb-storage modules to the initrd:
      cat << EOF >> /etc/initramfs-tools/modules
      # for NAND/ubi
      gpmi_nand
      ubi mtd=2
      ubifs
      
      # for usb-storage
      ci_hdrc_imx
      usb-storage
      EOF
      update-initramfs -u # press 'Enter' when prompted
      # create u-boot image for initrd
      mkimage -A arm -O linux -T ramdisk \
        -a 0x0 -e 0x0 -n "initrd" \
        -d /boot/initrd.img-*-generic /boot/uramdisk
      

You will need to create a boot script that sets kernel cmdline properly based on boot device and loads the Ubuntu initrd if needed. You can do this on the target board:

# The Gateworks bootscript is a good starting point
wget https://raw.githubusercontent.com/Gateworks/linux-imx6/gateworks_5.4.45/gwventana_bootscript -O /boot/6x_bootscript-ventana.txt
# re-enable ramdisk when its needed
sed -i 's/^setenv rd_addr$/#setenv rd_addr/' /boot/6x_bootscript-ventana.txt 
mkimage -A arm -O linux -T script -n bootscript -d /boot/6x_bootscript-ventana.txt /boot/6x_bootscript-ventana
Note: See TracWiki for help on using the wiki.