Qualcomm Robotics RB5/RB6 - Build image

Qualcomm Robotics RB5 RidgeRun documentation is currently under development. Come back soon to read the completed information on RidgeRun's support for this platform. Please Contact RidgeRun OR email to support@ridgerun.com, if you have any questions.

Qualcomm Robotics RB5/RB6
Introduction
SoM Overview Carrier Boards Qualcomm Robotics RB5 developer kit Qualcomm Robotics RB6 platform
Software Development Support
Boot Devices Thundercomm SDK Downloading SDK Installing SDK Generating Image and flashing Linaro Getting Started Flashing Bootloader Flashing Boot Image and Rootfs Special / Debug Modes Setting up board in EDL Mode Setting up board in Fastboot Mode
Development in the Board
Getting into the Board Using ADB Using Serial Console Using SSH Device Setup WiFi setup HDMI setup Update Ubuntu Packages
Build from source
Base Image Customize Image
Capture Subsystem
Hardware Capture Components Software Capture Components Building your own camera sensor driver
Image Processing and Acceleration Software
GPU Profiling Fast CV Installing Hexagon SDK Installing Fast CV Building your own Fast CV application
GStreamer Pipelines
Capture and Display Video Encoding Video Decoding
AI Acceleration
Neural Processing SDK Downloading Requirements Setup SDK Environment Install qtimlesnpe Example Project TensorFlow Example pipeline
Contact Us

In this section, we will cover how to build your own image using the Yocto Project. The Yocto Project is an open source project that has the tools and processes that enable the creation of Linux-based systems for embedded systems^[1]. Yocto runs in our host computer and we define the target machine for which we are going to develop, that in our case is the Qualcomm Robotics RB5. We have two parts, the first one will show how to setup the Yocto environment in your host computer so we are ready to start developing. In the second part, we will show the steps to use Yocto and build a base Image that will be ready to flash into your QRB5. The host computer must have:

• Operating system (OS): Ubuntu 18.04 or later.
• Disk-space: 50GB
• RAM: 16GB

Setting up host machine

The following steps show how to setup your host computer with the Yocto Project^[2][3]. This will allow us to have all the right tools needes to then create an Image.

1. First we need to install the dependencies of the Yocto Project in our host computer. For this, open a terminal and run the following command:

sudo apt-get install git python zstd gawk wget git-core diffstat unzip texinfo \
    gcc-multilib build-essential chrpath socat cpio python python3 python3-pip \
    python3-pexpect xz-utils debianutils iputils-ping

2. Now we need to create a directory to download the build metadata, run the next command:

mkdir -p ${HOME}/bin

3. Add the created directory to PATH environment variable with the following command:

export PATH=${HOME}/bin:${PATH}

4. Download the files and save them in the previously created directory runnning the command below:

curl https://storage.googleapis.com/git-repo-downloads/repo > ${HOME}/bin/repo

5. Assign the downloaded file the needed permission for execution with the next command:

chmod a+x ${HOME}/bin/repo

6. Now we are going to create a new working directory where all of the files needed to develop in Yocto are going to br stored. The next command creates the directory and then moves inside it:

mkdir oe-rpb && cd oe-rpb

7. The Yocto Project has many version releases ^[4], and each of them has a name assigned. For this reason, we are going to create an environment variable for the version of Yocto we want to use. Here we are working with dunfell, but the kirkstone release has also been tested.

export BRANCH="dunfell"

8. Now we are going to initialize the repository with a GitHub repository to setup the build environment. It will initialize with its latest version and it check out the specified Yocto branch.

repo init -u https://github.com/96boards/oe-rpb-manifest.git -b qcom/${BRANCH}

The output of the above command should state that the repo is initialized:

repo has been initialized in /home/user/oe-rpb

Your directory should now contain a .repo directory where files such as the manifest will be kept.

user@desktop:~/oe-rpb$ ls -al
total 12
drwxrwxr-x  3 user user 4096 ene 31 20:31 .
drwxr-xr-x 38 user user 4096 ene 31 20:30 ..
drwxrwxr-x  5 user user 4096 ene 31 20:31 .repo

9. The following command will pull down the metadata resources. It updates the working tree to the latest revision, synchronizing the local project directories with the remote ones.

Note

This command can take up to 5 min depending on your internet connectivity.

repo sync

The above command will output the following:

remote: Enumerating objects: 910, done.
remote: Counting objects: 100% (371/371), done.
remote: Compressing objects: 100% (130/130), done.
remote: Total 910 (delta 240), reused 335 (delta 223), pack-reused 539
Receiving objects: 100% (910/910), 181.67 KiB | 712.00 KiB/s, done.
Resolving deltas: 100% (491/491), completed with 44 local objects.
Fetching: 100% (17/17), done in 1m8.781s
Checking out: 100% (17/17), done in 0.638s
repo sync has finished successfully.

Setup environment and building

Now that our host computer has everything needed to develop in Yocto, the following steps show how to setup the build environment. The build environment will help us specify the target machine, the distribution and the type of Image we are going to build, then it will build it for us.

1. Create an environment variable for the distro you want to use. There are two possible options: rpb and rpb-wayland. Both of them include the core packages as well aas typical development packages, but the rpb distro is a headless one, meaning it does not have a desktop environment to use with a monitor. On the other hand, the rpb-wayland distro includes one desktop environment with Wayland and Weston servers ^[5]. For this guide, we chose the rpb-wayland distro, but the rpb one has also been tested.

export DISTRO_RB5="rpb-wayland"

2. The following command setups the build environment. In here we first are specifying the target machine; Qualcomm Robotics RB5 in our case, the distribution we chose in the previous step and sources the environment.

Note

The build-wayland is the name of the directory that will be created.

MACHINE=qrb5165-rb5 DISTRO=${DISTRO_RB5} source setup-environment build-wayland

The above command will output the following:

Welcome to OpenEmbedded Reference Platform Build (OE RPB)

For more information about OpenEmbedded see their website:
    http://www.openembedded.org/

Your build environment has been configured with:

    MACHINE = qrb5165-rb5
    SDKMACHINE = x86_64
    DISTRO = rpb-wayland

You can now run 'bitbake <target>'

Some of common targets are:
    rpb-console-image
    rpb-desktop-image
    rpb-weston-image
    core-image-base
    core-image-minimal

3. Now that our build environment is setup and ready, we can now build our Image. In the last output, Yocto tells us possible Images to build (common targets). For this guide, we chose the rpb-weston-image-test. The -test variant means it includes additional packages typically useful for testing and validation. (If you chose the rpb distro, the rpb-console-image-test Image was tested)

Note

The process takes about 3.5h in Intel® Core™ i7-1065G7 CPU @ 1.30GHz × 8.

bitbake rpb-weston-image-test

4. If the building process went fine, the built files will be located in the tmp-rpb_wayland-glibc/deploy/images/qrb5165-rb5 folder.

user@desktop:~/oe-rpb/build-wayland/tmp-rpb_wayland-glibc/deploy/images/qrb5165-rb5$ ls
boot-qrb5165-rb5--5.15-r0-qrb5165-rb5-20230130164642.img     modules--5.15-r0-qrb5165-rb5-20230130164642.tgz                    rpb-weston-image-test-qrb5165-rb5-20230130164642.testdata.json
boot-qrb5165-rb5.img                                         modules-qrb5165-rb5.tgz                                            rpb-weston-image-test-qrb5165-rb5.ext4.gz
boot-qrb5165-rb5-qrb5165-rb5.img                             qrb5165-rb5--5.15-r0-qrb5165-rb5-20230130164642.dtb                rpb-weston-image-test-qrb5165-rb5.manifest
boot-sm8250-rb5-dvt--5.15-r0-qrb5165-rb5-20230130164642.img  qrb5165-rb5.dtb                                                    rpb-weston-image-test-qrb5165-rb5.tar.xz
boot-sm8250-rb5-dvt-qrb5165-rb5.img                          qrb5165-rb5-qrb5165-rb5.dtb                                        rpb-weston-image-test-qrb5165-rb5.testdata.json
Image.gz                                                     rpb-weston-image-test-qrb5165-rb5-20230130164642.rootfs.ext4.gz   sm8250-rb5-dvt--5.15-r0-qrb5165-rb5-20230130164642.dtb
Image.gz--5.15-r0-qrb5165-rb5-20230130164642.bin             rpb-weston-image-test-qrb5165-rb5-20230130164642.rootfs.manifest  sm8250-rb5-dvt.dtb
Image.gz-qrb5165-rb5.bin                                     rpb-weston-image-test-qrb5165-rb5-20230130164642.rootfs.tar.xz    sm8250-rb5-dvt-qrb5165-rb5.dtb

To flash the board, you will need the boot image and rootfs. The following shows the name of the files.

Note

The long number in the rootfs file will be different because it is the date when it was created.

Boot Image: boot-qrb5165-rb5.img
Rootfs Image: rpb-weston-image-test-qrb5165-rb5-20230130164642.rootfs.ext4.gz

5. Now that everything is ready, we are ready to flash our board. First, we need a bootloader, this bootloader is not built by Yocto, instead, we need to download one from Linaro. You can download it from this link, it will automatically download a bootloader for Linux. Then, you can check our Flashing Bootloader section on how to flash it to the board. After it is done, please come back to this section.

6. With the bootloader flashed to the board, we can now flash the boot image and rootfs built by Yocto. Please check our Flashing Boot Image and Rootfs section on how to do this. You will need the boot image boot-qrb5165-rb5.img and rootfs rpb-weston-image-test-qrb5165-rb5-20230130164642.rootfs.ext4.gz for it.

7. Congratulations! You built an image in Yocto and flashed it to your board, now it is ready to use.

References