# Running AGL on Intel MinnowBoard (and most Intel 64 bits HW) ## Scope This documentation is aiming at people who want to run Automotive Grade Linux (AGL) on Intel Hardware (HW). While the reference HW used by AGL project is the Open Source MinnowBoard, this documentation [MinnowBoard wiki](https://minnowboard.org/) can be used to enable most of 64-bit Intel Architecture (IA) platforms using UEFI as boot loader. In addition to the MinnowBoard, support for the [Joule Developer Kit](https://software.intel.com/en-us/iot/hardware/joule/dev-kit) has been added. You need to run the 64-bit version of the UEFI bootloader. MinnowBoard Max and Turbot as well as Joule are both 64-bit capable. **Note**: This page is more focused on those who want to create bespoke AGL images and BSPs. If you are interested in creating ***applications*** to run on AGL, please visit the [Developing Apps for AGL](https://wiki.automotivelinux.org/agl-distro/developer_resources_intel_apps) documentation. UEFI has evolved a lot recently and you likely want to check that your HW firmware is up-to-date, this is mandatory for both the MinnowBoard and the Joule. [`https://firmware.intel.com/projects/minnowboard-max`](https://firmware.intel.com/projects/minnowboard-max) [`https://software.intel.com/en-us/flashing-the-bios-on-joule`](https://software.intel.com/en-us/flashing-the-bios-on-joule) ## Where to find an AGL bootable image ### Building an AGL image from scratch using Yocto **Note**: an alternative method for building an image is to use the AGL SDK delivered in a Docker container. There is currently no SDK dedicated to IA but the SDK provided for the Porter Board can build an IA image without changes (just `aglsetup.sh` needs to call for Intel). See chapter 2 of [Porter QuickStart](http://iot.bzh/download/public/2016/sdk/AGL-Kickstart-on-Renesas-Porter-board.pdf "wikilink"). #### Download AGL source code Downloading the AGL sources from the various Git repositories is automated with the `repo` tool. Basic steps to download the AGL source code is described below and for more advanced topics involving the `repo` tool, please refer to the [`repo` documentation](https://source.android.com/source/using-repo.html "wikilink"). To install the `repo` tool: ```bash mkdir -p ~/bin; export PATH=~/bin:$PATH; curl https://storage.googleapis.com/git-repo-downloads/repo > ~/bin/repo; chmod a+x ~/bin/repo; ``` #### Configuring for the current *(older)* stable (Charming Chinook 3.0.x) ```bash cd AGL-3.0.x; repo init -b chinook -m default.xml -u https://gerrit.automotivelinux.org/gerrit/AGL/AGL-repo ``` #### Configuring for master (DD) ```bash cd AGL-master; repo init -u https://gerrit.automotivelinux.org/gerrit/AGL/AGL-repo; ``` Once that you repo is initialised either with the stable or WIP, you need to sync the repo to fetch the various git trees. #### Downloading the configured AGL source code ```bash repo sync; ``` #### Building the AGL distro You are now ready to initialise your Yocto build. When running the command: ```bash source meta-agl/scripts/aglsetup.sh -h ``` You will notice the Intel entries ```bash intel-corei7-64 joule ``` Simply select that entry to replace porter in the -m option. **Note:** agl-netboot option is required to create the right initramfs even if you do not boot from a network ```bash source meta-agl/scripts/aglsetup.sh \ -m intel-corei7-64 \ -b build \ agl-devel agl-demo agl-appfw-smack agl-netboot ``` **Note:** use the option "-m joule" when building for a Joule developer Kit target. Start the build **This can take several hours depending of your CPU and internet connection and will required several GB on /tmp as well as on your build directory** ```bash bitbake agl-demo-platform ``` **Your newly baked disk image (.hddimg) will be located at**: `tmp/deploy/images/intel-corei7-64/` ##### Alternative: Download a *ready made* image from AGL web site The Continuous Integration (CI) process from AGL creates and publish daily and stable builds. Pointers to both can be found in [AGL supported HW](https://wiki.automotivelinux.org/agl-distro) (see Reference BSP/Intel). Once you have validated your process you can start to play/work with the snapshot pointer. Note that snapshot build may not work. Follow the directory: `intel-corei7-64/deploy/images/intel-corei7-64/` and download the file: `agl-demo-platform-intel-corei7-64.hddimg` ## Create a bootable media Depending your target HW you will use an USB stick, an SD card or a HDD/SDD. The creation process remains the same independently of the selected support. It does require to have access to a Linux machine with `sudo` or root password. ### Insert you removable media in the corresponding interface ### Check the device name where the media can be accessed with the command ```bash lsblk # Note that you want the name of the raw device not of a partition on the media #(eg. /dev/sdc or /dev/mmcblk0) ``` ### Download the script `mkefi-agl.sh` This script is present in the directory meta-agl/scripts from blowfish 2.0.4, alternatively you can download it from the following Git repo: [https://github.com/dominig/mkefi-agl.sh](https://github.com/dominig/mkefi-agl.sh) ### check the available options ```bash sh mkefi-agl.sh -v; ``` ### create your media with the command adjusted to your configuration ```bash sudo sh mkefi-agl.sh MyAglImage.hdd /dev/sdX #/dev/sdX is common for USB stick, /dev/mmcblk0 for laptop integrated SD card reader ``` ## Boot the image on the target device 1. Insert the created media with the AGL image in the target device 1. Power on the device 1. Select Change one off boot option (generally F12 key during power up) 1. Select your removable device 1. Let AGL boot **Note:**: depending on the speed of the removable media, the first boot may not complete, in that case simply reboot the device. This is quite common with USB2 sticks. By default the serial console is configured and activated at the rate of 115200 bps. ## How to create your 1st AGL application [Developing Apps for AGL](https://wiki.automotivelinux.org/agl-distro/developer_resources_intel_apps)