Cubox-i

Goal
The goal of these instructions is to have a running installation of Gentoo on a Cubox-i (this should also work on a SolidRun Hummingboard also), with a kernel up-to-date enough to run a current btrfs root filesystem.

Prerequisite

 * Cubox-i
 * if you want to configure over a serial console you need a CuBox-i2ultra or a CuBox-i4pro
 * otherwise you need an hdmi display and an usb keyboard
 * git
 * sd-card (with enough space, boot partition, rootfs with a git kernel and gentoo, 4GB+)
 * network cable for an internet connection (the wifi driver needs a firmware that can be installed later)
 * another (Linux) computer with a cross compiler for arm installed (the installation for Gentoo is documented here)

Optional
If you want you can install the "Ignition" image of solid-run to see if your machine is working with the serial connection (or the connected keyboard and display). This will overwrite the u-boot installation!
 * tftp server
 * u-boot-tools
 * Ignition

Installation
The install consists of installing crossdev, partitioning and formatting, the sd-card. Copying over a stage3 tarball, configuring it so that it can boot and it can be accessed. Creating a kernel. Booting the kernel on the machine. Installing the kernel for an automatic boot. Continue a default Gentoo installation.

Installing Crossdev
This is necessary to build u-boot and the kernel on your desktop system.

Details and troubleshooting are at the Embedded Handook, Chapter 2 (see below).

Setup U-Boot
SolidRun provides a custom U-Boot, this is a fork from the upstream and patched by Jon Nettelton. Main feature is addition of console on HDMI support, and the SPL support for Cubox-i. To build the bootloader, do:

A successful build will create two files in the source tree directory, SPL and u-boot.img


 * SPL file is the actual machine detection and initialization and must be flashed on offset 1KByte of the boot micro SD.
 * u-boot.img is the second stage bootloader; it can be flashed at offset 42KByte from the starting of the boot micro SD; or alternatively can be put as-is on the first partition of the micro SD if the partition has a FAT filesystem.

More informations: http://wiki.solid-run.com/doku.php?id=products:imx6:software:development:u-boot

Warning: SolidRun's u-boot currently broken for some models
At the time of this writing (and since june 3 2016), u-boot's latest commit on master make some models such as the i4pro report 4GB of RAM when it has 2. This results in a highly unstable system. It can boot, but it's going to crash as soon as it tries to access its "phantom" memory. It's recommended that you use the previous commit when compiling u-boot.

Setup serial console
If the model is a CuBox-i2ultra or a CuBox-i4pro it can be connected direclty with your other computer. If not you need to attach it to an hdmi display and connect a usb keyboard.

For the serial console you can install minicom. Make sure that you have the following config in your kernel activated:

You can find it here: Device Drivers -> USB support -> USB Serial Converter support -> USB FTDI Single Port Serial Driver

For more informations on the connection read the wiki at SolidRun.

Preparing SD Card
If the first test worked okay you can partition and format the card. As in the goal described in a two partition scheme will be used.
 * will be ext2 with 100MB (boot)
 * will be btrfs with the rest of the capacity (root)

can be different in your computer probably

The minimal configuration of the root has to be done already on the other computer
 * 1) extract stage3
 * 2) edit
 * 3) set root password
 * 4) enable serial console

Extract stage 3
Get the latest stage 3 and extract it to the root partition.

Edit /etc/fstab
Edit on the root partition on the sdcard :

Edit root password
To be able to login later we need to set a root password, we create passwor hash and edit it to the.

Replace the star or current hash of the root user with the output from the command above.

Enable serial console
To also have a serial console after we booted the current system we need to modify.

Change the s0 line to the following:

This should be enough that a kernel can boot the system and that we can work with it afterwards.

Kernel
At the moment the are multiple sources for kernels available all with their specific advantages and drawbacks.

If you are using the u-boot from this wiki you can boot directly the zImage. It isn't necessary to convert it to a uImage.

Official (patched by SolidRun)
This is the current stable version: https://github.com/SolidRun/linux-imx6-3.14 Most documentation will assume that you are running this kernel.

Vanilla (or Gentoo sources)
Vanilla kernel 3.19+ (and the gentoo-sources version) runs on the hardware complete with graphics and networking simply run

enable all the atheros devices in Device Drivers > Network device support > Ethernet driver support then...

Kernel will be in arch/arm/boot/zImage and the the device tree will be in arch/arm/boot/dts/imx6dl-cubox-i.dtb (or imx6q-cubox-i.dtb, imx6dl-hummingboard.dtb etc...)

Latest patched version

 * These patches apply to the latest kernel. As of this writing you can apply them to sys-kernel/git-sources-4.1-rc1. Gentoo can do this automatically for you. Unzip the latest patch to /etc/portage/patches/sys-kernel/git-sources and create /etc/portage/bashrc as is documented here: https://wiki.gentoo.org/wiki//etc/portage/patches.

Create the zImage and the dtb file

You can find other/more patches here: some

Wifi
The drivers for wifi need a firmware. In case you are have set them to built-in you have to include the blobs already in the kernel

The following settings are necessay for the driver:

I have the blobs from the geexbox package firmware-wifi-brcm80211_20140206-d7f8a7c81a3-1_armv7.opk
 * brcmfmac4329-sdio.bin
 * brcmfmac4329-sdio.txt

The files have to be dropped in if the driver is compiled as module or directly into the kernel source folder under  if they will be compiled built-in.

Headers
To compile certain applications like xbmc that have modified/additional codecs you need to expose the patched kernel headers. Fortunately there is a script for that:

If you install them into /usr/local/include then you don't overwrite the ones provided by the gentoo package.

Default
If you use the u-boot from this wiki you can use the default settings and no direct modification of the u-boot configuration might be necessary. If the first partition of the SD-card is formatted with ext2 or fat it will read the the file uEnv.txt with the configuration from it.

These two lines should be enough to boot the kernel. The u-boot from this wiki can boot a zImage directly (no conversion to uImage necessary). The zImage and the *.dtb file have to reside in the root folder of this partition next to the uEnv.txt. The second line contains the kernelflags (for example the root).

Interactive
Connect to your Cubox-i with a serial console (or with a keyboard and a display) and interrupt the u-boot bootloader with and type the following commands.

setenv ipaddr 192.168.0. setenv serverip 192.168.0. setenv bootargs root=/dev/mmcblk0p2 rootfstype=btrfs ro rootwait console=ttymxc0,115200 tftpboot 0x10800000 uimage bootm 0x10800000

This should boot you in your Cubox-i installation and you should be able to login as root with your password. From here you can continue with a default Gentoo installation. To make this boot configuration permanent follow the next step "Default".

Hardcoded
In the following we will make the settings permanent. The uImage file is copied to the boot partition. The first line contains the settings for loading the kernel into memory. The second holds the arguments for the kernel. The third one is the code to execute the kernel.

The bootcmd is called by default and executes theses three steps in order. The last line makes these variables permanent in the u-boot settings. setenv mybootload ext2load mmc 0:1 0x10800000 /uimage setenv mybootset setenv bootargs root=/dev/mmcblk0p2 rootfstype=btrfs ro rootwait console=ttymxc0,115200 setenv mybootstart bootm 0x10800000 setenv bootcmd run mybootset mybootload mybootstart saveenv

uEnv
u-Boot can also read configuration values from a file. This way the boot process can be modified without going into the u-Boot console and the settings are permanent as well. The following script is modified from the original mini-image used for the installation.

setenv gsetmmc 'root="root=/dev/mmcblk${rootunit}p$rootpart rootfstype=$rootfs ro rootwait"' setenv gconsole console=ttymxc0,115200 consoleblank=0 setenv gbootextra init=/init setenv grootflags "" setenv gvideo mxcfb0:dev=hdmi,1920x1080M@60,if=RGB24 dmfc=3 setenv gbootpreset 'bootdev=mmc; bootunit=0; bootpart=1; bootfs=ext2; envfile=uEnv.txt; bootroot=; bootfile=uImage' setenv grootpreset 'rootunit=0; rootpart=2; rootfs=btrfs' setenv gsetenvscript setenv gbootenv "\'run gset\${bootdev}; setenv bootargs \$root \$gvideo \$gconsole \$gbootextra \$grootflags $end\'" setenv gloaduenv 'if ${bootfs}load $bootdev $bootunit:$bootpart $loadaddr $envfile; then env import -t $loadaddr $filesize; fi' setenv grootpresetup 'bootrun=bootm; loadfile=$bootfile; rootdev=$bootdev; rootunit=$bootunit; rootpart=$rootpart; rootfs=$rootfs' setenv gbootload '${bootfs}load $bootdev $bootunit:$bootpart $loadaddr $bootroot/$loadfile' setenv gbootstart '$bootrun' setenv bootcmd run gbootpreset grootpreset gsetenvscript gloaduenv grootpresetup gbootenv gbootload gbootstart

In the minimal [uEnv.txt] is enough to boot a stock ext4 system on the SD card. To boot from usb you must use rootwait or rootdelay.

Continue Gentoo install
Steps that should be done right after the installation
 * 1) setup network
 * 2) set date
 * 3) emerge-webrsync
 * 4) emerge ntpd
 * 5) /etc/init.d/sshd

Gentoo arm install Handbook

Graphics driver (closed source)
You can find a portage repository with packages for the closed source drivers on github: https://github.com/stefan-langenmaier/gentoo-cubox-i-repository

XBMC
If you want to install XBMC make sure that:


 * consoleblank=0 is enabled in the bootargs otherwise you will get a "No signal/no video" after 10 minutes
 * for the moment you should use XBMC and libCEC from the custom repos
 * you have make headers_install executed

Open Questions

 * open-source hardware-accelerated video driver
 * reverse engineereddrivers
 * kms driver is disabled in patched kernel