828 lines
26 KiB
Markdown
828 lines
26 KiB
Markdown
<a id="top"></a> <a name="linux"></a> EIVE On-Board Software
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======
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# General information
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Target systems:
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* OBC with Linux OS
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* Xiphos Q7S
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* Based on Zynq-7020 SoC (xc7z020clg484-2)
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* Dual-core ARM Cortex-A9
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* 766 MHz
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* Artix-7 FPGA (85K pogrammable logic cells)
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* Datasheet at https://eive-cloud.irs.uni-stuttgart.de/index.php/apps/files/?dir=/EIVE_IRS/Arbeitsdaten/08_Used%20Components/Q7S&fileid=340648
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* Also a lot of information about the Q7S can be found on
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the [Xiphos Traq Platform](https://trac2.xiphos.ca/eive-q7). Press on index to find all
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relevant pages. The most recent datasheet can be found
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[here](https://trac2.xiphos.ca/manual/wiki/Q7RevB/UserManual).
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* Linux OS built with Yocto 2.5
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* Linux Kernel https://github.com/XiphosSystemsCorp/linux-xlnx.git . EIVE version can be found
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[here](https://github.com/spacefisch/linux-xlnx) . Pre-compiled files can be
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found [here](https://eive-cloud.irs.uni-stuttgart.de/index.php/apps/files/?dir=/EIVE_IRS/Software/q7s-linux-components&fileid=777299).
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* Q7S base project can be found [here](https://egit.irs.uni-stuttgart.de/eive/q7s-base)
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* Minimal base project files can be found [here](https://eive-cloud.irs.uni-stuttgart.de/index.php/apps/files/?dir=/EIVE_IRS/Software/xiphos-q7s-sdk&fileid=510908)
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* Host System
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* Generic software components which are not dependant on hardware can also
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be run on a host system. All host code is contained in the `bsp_hosted` folder
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* Tested for Linux (Ubuntu 20.04) and Windows 10
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* Raspberry Pi
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* EIVE OBC can be built for Raspberry Pi as well (either directly on Raspberry Pi or by installing a cross compiler)
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The steps in the primary README are related to the main OBC target Q7S.
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The CMake build system can be used to generate build systems as well (see helper scripts in `cmake/scripts`:
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- Linux (Raspberry Pi): See special section below.
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- Linux Host: Uses the `bsp_hosted` BSP folder and the CMake Unix Makefiles generator.
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- Windows Host: Uses the `bsp_hosted` BSP folder, the CMake MinGW Makefiles generator and MSYS2.
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# Setting up development environment
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## Installing Vivado the the Xilinx development tools
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It's also possible to perform debugging with a normal Eclipse installation by installing
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the TCF plugin and downloading the cross-compiler as specified in the section below. However,
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if you want to generate the `*.xdi` files necessary to update the firmware, you need to
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installed Vivado with the SDK core tools.
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* Install Vivado 2018.2 and Xilinx SDK from https://www.xilinx.com/support/download/index.html/content/xilinx/en/downloadNav/vivado-design-tools/archive.html.
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Install the Vivado Design Suite - HLx Editions - 2018.2 Full Product Installation instead of
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the updates. It is recommended to use the installer.
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* Install settings. In the Devices selection, it is sufficient to pick SoC → Zynq-7000: <br>
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<img src="https://egit.irs.uni-stuttgart.de/eive/eive-obsw/raw/branch/develop/doc/img/vivado-edition.png" width="50%"> <br>
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<img src="https://egit.irs.uni-stuttgart.de/eive/eive-obsw/raw/branch/mueller/master/doc/img/vivado-hl-design.png" width="50%"> <br>
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<img src="https://egit.irs.uni-stuttgart.de/eive/eive-obsw/raw/branch/mueller/master/doc/img/xilinx-install.PNG" width="50%"> <br>
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* For supported OS refer to https://www.xilinx.com/support/documentation/sw_manuals/xilinx2018_2/ug973-vivado-release-notes-install-license.pdf .
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Installation was tested on Windows and Ubuntu 21.04.
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* Add path of linux cross-compiler to permanent environment variables (`.bashrc` file in Linux):
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`<XilinxInstallation>\SDK\2018.2\gnu\aarch32\nt\gcc-arm-linux-gnueabi\bin`
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or set up path each time before debugging.
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### Installing on Linux - Device List Issue
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When installing on Ubuntu, the installer might get stuck at the `Generating installed device list`
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step. When this happens, you can kill the installation process (might be necessara to kill a process
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twice) and generate this list manually with the following commands, according to
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[this forum entry](https://forums.xilinx.com/t5/Installation-and-Licensing/Vivado-2018-3-Final-Processing-hangs-at-Generating-installed/m-p/972114#M25861).
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1. Install the following library
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```sh
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sudo apt install libncurses5
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```
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2. ```sh
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sudo <installRoot>/Vivado/2018.2/bin/vivado -nolog -nojournal -mode batch -source
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<installRoot>/.xinstall/Vivado_2018.2/scripts/xlpartinfo.tcl -tclargs
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<installRoot>/Vivado/2018.2/data/parts/installed_devices.txt
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```
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For Linux, you can also download a more recent version of the
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[Linaro 8.3.0 cross-compiler](https://developer.arm.com/tools-and-software/open-source-software/developer-tools/gnu-toolchain/gnu-a/downloads)
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from [here](https://developer.arm.com/-/media/Files/downloads/gnu-a/8.3-2019.03/binrel/gcc-arm-8.3-2019.03-x86_64-arm-linux-gnueabihf.tar.xz?revision=e09a1c45-0ed3-4a8e-b06b-db3978fd8d56&la=en&hash=93ED4444B8B3A812B893373B490B90BBB28FD2E3)
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## Installing toolchain without Vivado
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You can download the toolchains for Windows and Linux
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[from the EIVE cloud](https://eive-cloud.irs.uni-stuttgart.de/index.php/apps/files?dir=/EIVE_IRS/Software/tools&fileid=831898).
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If `wget` is available (e.g. MinGW64), you can use the following command to download the
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toolchain for Windows
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```sh
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wget https://eive-cloud.irs.uni-stuttgart.de/index.php/s/rfoaistRd67yBbH/download/gcc-arm-linux-gnueabi-win.zip
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```
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or the following command for Linux (could be useful for CI/CD)
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```sh
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wget https://eive-cloud.irs.uni-stuttgart.de/index.php/s/2Fp2ag6NGnbtAsK/download/gcc-arm-linux-gnueabi.tar.gz
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```
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## Installing CMake and MSYS2 on Windows
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1. Install [MSYS2](https://www.msys2.org/) and [CMake](https://cmake.org/download/) first.
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2. Open the MinGW64 console. It is recommended to set up aliases in `.bashrc` to navigate to the
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software repository quickly
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3. Run the following commands in MinGW64
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```sh
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pacman -Syu
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```
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It is recommended to install the full base development toolchain
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```sh
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pacman -S base-devel
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```
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It is also possible to only install required packages
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```sh
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pacman -S mingw-w64-x86_64-cmake mingw-w64-x86_64-make mingw-w64-x86_64-gcc mingw-w64-x86_64-gdb python3
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```
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## Installing CMake on Linux
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1. Run the following command
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```sh
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sudo apt-get install cmake
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````
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## Getting the Q7S system root
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It is necessary to copy the Q7S system root to your local development machine for libraries
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like `libgpio`. You can find the system root for the Q7S, the Raspberry Pi and the
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Beagle Bone Black for download here
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[here](https://eive-cloud.irs.uni-stuttgart.de/index.php/apps/files/?dir=/EIVE_IRS/Software/rootfs&fileid=831849).
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Download it and unzip it somewhere in the Xilinx installation folder.
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You can use the following command if `wget` can be used or for CI/CD:
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```
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wget https://eive-cloud.irs.uni-stuttgart.de/index.php/s/agnJGYeRf6fw2ci/download/cortexa9hf-neon-xiphos-linux-gnueabi.tar.gz
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```
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Then, create a new environmental variables `Q7S_SYSROOT` and set it to the local system root path.
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# Building the software with CMake
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When using Windows, run theses steps in MSYS2.
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1. Clone the repository with
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```sh
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git clone https://egit.irs.uni-stuttgart.de/eive/eive_obsw.git
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```
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2. Update all the submodules
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```sh
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git submodule init
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git submodule sync
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git submodule update
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```
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3. Ensure that the cross-compiler is working with `arm-linux-gnueabihf-gcc --version`.
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It is recommended to run the shell script `win_path_helper_xilinx_tools.sh` in `cmake/scripts/Q7S`
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or to set up the [PATH and the CROSS_COMPILE variable permanently](https://unix.stackexchange.com/questions/26047/how-to-correctly-add-a-path-to-path)
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in the `.profile` file.
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4. Run the CMake configuration to create the build system in a `build-Debug-Q7S` folder.
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Add `-G "MinGW Makefiles` in MinGW64 on Windows.
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```sh
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mkdir build-Debug-Q7S && cd build-Debug-Q7S
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cmake -DTGT_BSP="arm/q7s" -DCMAKE_BUILD_TYPE=Debug -DOS_FSFW=linux ..
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cmake --build . -j
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```
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You can also use provided shell scripts to perform these commands
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```sh
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cd cmake/scripts/Q7S
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./make_debug_cfg.sh
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cd ../../..
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```
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This will invoke a Python script which in turn invokes CMake with the correct
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arguments to configure CMake for Q7S cross-compilation.
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You can build the hosted variant of the OBSW by replacing `-DOS_FSFW=linux` with
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`-DOS_FSFW=host`. There are also different values for `-DTGT_BSP` to build for the Raspberry Pi
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or the Beagle Bone Black: `arm/raspberrypi` and `arm/beagleboneblack`.
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5. Build the software with
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```sh
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cd Debug
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cmake --build . -j
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```
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## Setting up default Eclipse for Q7S projects - TCF agent
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The [TCF agent](https://wiki.eclipse.org/TCF) can be used to perform remote debugging on the Q7S.
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1. Install the TCF agent plugin in Eclipse from the [releases](https://www.eclipse.org/tcf/downloads.php). Go to Help → Install New Software and use the download page, for example https://download.eclipse.org/tools/tcf/releases/1.6/1.6.2/ to search for the plugin and install it.
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2. Go to Window → Perspective → Open Perspective and open the **Target Explorer Perspective**.
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Here, the Q7S should show up if the local port forwarding was set up as explained previously. Please note that you have to connect to `localhost` and port `1534` with port forwaring set up.
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3. A launch configuration was provided, but it might be necessary to adapt it for your own needs. Alternatively:
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- Create a new **TCF Remote Application** by pressing the cogs button at the top or going to Run → Debug Configurations → Remote Application and creating a new one there.
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- Set up the correct image in the main tab (it might be necessary to send the image to the Q7S manually once) and file transfer properties
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- It is also recommended to link the correct Eclipse project.
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After that, comfortable remote debugging should be possible with the Debug button.
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A build configuration and a shell helper script has been provided to set up the path variables and
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build the Q7S binary on Windows, but a launch configuration needs to be newly created because the
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IP address and path settings differ from machine to machine.
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## Building in Xilinx SDK 2018.2
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1. Open Xilinx SDK 2018.2
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2. Import project
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* File → Import → C/C++ → Existing Code as Makefile Project
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3. Set build command. Replace \<target\> with either debug or release.
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* When on Linux right click project → Properties → C/C++ Build → Set build command to `make <target> -j`
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* -j causes the compiler to use all available cores
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* The target is used to either compile the debug or the optimized release build.
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* On windows create a make target additionally (Windows → Show View → Make Target)
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* Right click eive_obsw → New
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* Target name: all
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* Uncheck "Same as the target name"
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* Uncheck "Use builder settings"
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* As build command type: `cmake --build .`
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* In the Behaviour tab, you can enable build acceleration
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4. Run build command by double clicking the created target or by right clicking
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the project folder and selecting Build Project.
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## TCF-Agent
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1. On reboot, some steps have to be taken on the Q7S. Set static IP address and netmask
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```sh
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ifconfig eth0 192.168.133.10
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ifconfig eth0 netmask 255.255.255.0
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```
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2. `tcfagent` application should run automatically but this can be checked with
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```sh
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systemctl status tcfagent
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```
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3. If the agent is not running, check whether `agent` is located inside `usr/bin`.
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You can run it manually there. To perform auto-start on boot, have a look at the start-up
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application section.
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# Debugging the software via Flatsat PC
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Open SSH connection to flatsat PC:
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```sh
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ssh eive@flatsat.eive.absatvirt.lw
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```
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or
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```sh
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ssh eive@2001:7c0:2018:1099:babe:0:e1fe:f1a5
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```
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or
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```sh
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ssh eive@192.168.199.227
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```
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If the static IP address of the Q7S has already been set,
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you can access it with ssh
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```sh
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ssh root@192.168.133.10
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```
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If this has not been done yet, you can access the serial
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console of the Q7S like this to set it
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```sh
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picocom -b 115200 /dev/ttyUSB0
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```
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If the serial port is blocked for some reason, you can kill
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the process using it with `q7s_kill`.
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You can use `AltGr` + `X` to exit the picocom session.
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To debug an application, first make sure a static IP address is assigned to the Q7S. Run ifconfig
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on the Q7S serial console.
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```sh
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ifconfig
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```
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Set IP address and netmask with
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```sh
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ifconfig eth0 192.168.133.10
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ifconfig eth0 netmask 255.255.255.0
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```
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To launch application from Xilinx SDK setup port fowarding on the development machine
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(not on the flatsat!)
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```sh
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ssh -L 1534:192.168.133.10:1534 eive@2001:7c0:2018:1099:babe:0:e1fe:f1a5 -t bash
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```
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This forwards any requests to localhost:1534 to the port 1534 of the Q7S with the IP address
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192.168.133.10.
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This needs to be done every time, so it is recommended to create an alias to do this quickly.
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Note: When now setting up a debug session in the Xilinx SDK or Eclipse, the host must be set
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to localhost instead of the IP address of the Q7S.
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# Transfering files via SCP
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To transfer files from the local machine to the Q7S, use port forwarding
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```sh
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ssh -L 1535:192.168.133.10:22 eive@2001:7c0:2018:1099:babe:0:e1fe:f1a5
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```
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An `example` file can be copied like this
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```sh
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scp -P 1535 example root@localhost:/tmp
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```
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Copying a file from Q7S to flatsat PC
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````
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scp -P 22 root@192.168.133.10:/tmp/kernel-config /tmp
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````
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From a windows machine files can be copied with putty tools (note: use IPv4 address)
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````
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pscp -scp -P 22 eive@192.168.199.227:</directory-to-example-file/>/example-file </windows-machine-path/>
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````
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# Launching an application at start-up
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Load the root partiton from the flash memory (there are to nor-flash memories and each flash holds
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two xdi images). Note: It is not possible to modify the currently loaded root partition, e.g.
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creating directories. To do this, the parition needs to be mounted.
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1. Disable write protection of the desired root partition
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```sh
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writeprotect 0 0 0 # unlocks nominal image on nor-flash 0
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```
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2. Mount the root partition
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```sh
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xsc_mount_copy 0 0 # Mounts the nominal image from nor-flash 0
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```
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The mounted partition will be located inside the `/tmp` folder
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3. Copy the executable to `/usr/bin`
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4. Make sure the permissions to execute the application are set
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```sh
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chmod +x application
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```
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5. Create systemd service in /lib/systemd/system. The following shows an example service.
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```sh
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cat > example.service
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[Unit]
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Description=Example Service
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StartLimitIntervalSec=0
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[Service]
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Type=simple
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Restart=always
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RestartSec=1
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User=root
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ExecStart=/usr/bin/application
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[Install]
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WantedBy=multi-user.target
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```
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6. Enable the service. This is normally done with systemctl enable. However, this is not possible
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when the service is created for a mounted root partition. Therefore create a symlink as follows.
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```sh
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ln -s '/tmp/the-mounted-xdi-image/lib/systemd/system/example.service' '/tmp/the-mounted-xdi-image/etc/systemd/system/multi-user.target.wants/example.service'
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```
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7. The modified root partition is written back when the partion is locked again.
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```sh
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writeprotect 0 0 1
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```
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8. Now verify the application start by booting from the modified image
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```sh
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xsc_boot_copy 0 0
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````
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9. After booting verify if the service is running
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```sh
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systemctl status example
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```
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More detailed information about the used q7s commands can be found in the Q7S user manual.
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## Setting up UNIX environment for real-time functionalities
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Please note that on most UNIX environments (e.g. Ubuntu), the real time functionalities
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used by the UNIX pthread module are restricted, which will lead to permission errors when creating
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these tasks and configuring real-time properites like scheduling priorities.
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To solve this issues, try following steps:
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1. Edit the /etc/security/limits.conf
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file and add following lines at the end:
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```sh
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<username> hard rtprio 99
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<username> soft rtprio 99
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```
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The soft limit can also be set in the console with `ulimit -Sr` if the hard
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limit has been increased, but it is recommended to add it to the file as well for convenience.
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If adding the second line is not desired for security reasons,
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the soft limit needs to be set for each session. If using an IDE like eclipse
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in that case, the IDE needs to be started from the console after setting
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the soft limit higher there. After adding the two lines to the file,
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the computer needs to be restarted.
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It is also recommended to perform the following change so that the unlockRealtime
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script does not need to be run anymore each time. The following steps
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raise the maximum allowed message queue length to a higher number permanently, which is
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required for some framework components. The recommended values for the new message
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length is 130.
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2. Edit the /etc/sysctl.conf file
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```sh
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sudo nano /etc/sysctl.conf
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```
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|
|
Append at end:
|
|
```sh
|
|
fs/mqueue/msg_max = <newMsgMaxLen>
|
|
```
|
|
|
|
Apply changes with:
|
|
```sh
|
|
sudo sysctl -p
|
|
```
|
|
|
|
A possible solution which only persists for the current session is
|
|
```sh
|
|
echo <newMsgMax> | sudo tee /proc/sys/fs/mqueue/msg_max
|
|
```
|
|
|
|
# PCDU
|
|
|
|
Connect to serial console of P60 Dock
|
|
````
|
|
picocom -b 500000 /dev/ttyUSBx
|
|
````
|
|
General information
|
|
````
|
|
cmp ident
|
|
````
|
|
List parameter table:
|
|
x values: 1,2 or 4
|
|
````
|
|
param list x
|
|
````
|
|
Table 4 lists HK parameters
|
|
Changing parameters
|
|
First switch to table where parameter shall be changed (here table id is 1)
|
|
````
|
|
p60-dock # param mem 1
|
|
p60-dock # param set out_en[0] 1
|
|
p60-dock # param get out_en[0]
|
|
GET out_en[0] = 1
|
|
````
|
|
|
|
# Debugging the software (when workstation is directly conncected to Q7S)
|
|
|
|
1. Assign static IP address to Q7S
|
|
* Open serial console of Q7S (Accessible via the micro-USB of the PIM, see also Q7S user
|
|
manual chapter 10.3)
|
|
* Baudrate 115200
|
|
* Login to Q7S:
|
|
* user: root
|
|
* pw: root
|
|
|
|
2. Connect Q7S to workstation via ethernet
|
|
3. Make sure the netmask of the ehternet interface of the workstation matches the netmask of the Q7S
|
|
* When IP address is set to 192.168.133.10 and the netmask is 255.255.255.0, an example IP address for the workstation
|
|
is 192.168.133.2
|
|
|
|
4. Run tcf-agent on Q7S
|
|
|
|
* Tcf-agent is not yet integrated in the rootfs of the Q7S. Therefore build tcf-agent manually
|
|
|
|
```sh
|
|
git clone git://git.eclipse.org/gitroot/tcf/org.eclipse.tcf.agent.git
|
|
cd org.eclipse.tcf.agent/agent
|
|
make CC=arm-linux-gnueabihf-gcc LD=arm-linux-gnueabihf-ld MACHINE=arm NO_SSL=1 NO_UUID=1
|
|
```
|
|
|
|
* Transfer executable agent from org.eclipse.tcf.agent/agent/obj/GNU/Linux/arm/Debug to /tmp of Q7S
|
|
|
|
```sh
|
|
cd obj/GNU/Linux/arm/Debug
|
|
scp agent root@192.168.133.10:/tmp
|
|
```
|
|
|
|
* On Q7S
|
|
```sh
|
|
cd /tmp
|
|
chmod +x agent
|
|
```
|
|
|
|
* Run agent
|
|
```sh
|
|
./agent
|
|
```
|
|
|
|
5. In Xilinx SDK 2018.2 right click on project → Debug As → Debug Configurations
|
|
6. Right click Xilinx C/C++ applicaton (System Debugger) → New →
|
|
7. Set Debug Type to Linux Application Debug and Connectin to Linux Agent
|
|
8. Click New
|
|
9. Give connection a name
|
|
10. Set Host to static IP address of Q7S. e.g. 192.168.133.10
|
|
11. Test connection (This ensures the TCF Agent is running on the Q7S)
|
|
12. Select Application tab
|
|
* Project Name: eive_obsw
|
|
* Local File Path: Path to eiveobsw-linux.elf (in `_bin\linux\devel`)
|
|
* Remote File Path: `/tmp/eive_obsw.elf`
|
|
|
|
# Running cppcheck on the Software
|
|
|
|
Static code analysis can be useful to find bugs.
|
|
`cppcheck` can be used for this purpose. On Windows you can use MinGW64 to do this.
|
|
|
|
```sh
|
|
pacman -S mingw-w64-x86_64-cppcheck
|
|
```
|
|
|
|
On Ubuntu, install with
|
|
|
|
```sh
|
|
sudo apt-get install cppcheck
|
|
```
|
|
|
|
You can use the Eclipse integration or you can perform the scanning manually from the command line.
|
|
CMake will be used for this.
|
|
|
|
Run the CMake build generation commands specified above but supply
|
|
`-DCMAKE_EXPORT_COMPILE_COMMANDS=ON` to the build generation. Invoking the build command will
|
|
generate a `compile_commands.json` file which can be used by cppcheck.
|
|
|
|
```sh
|
|
cppcheck --project=compile_commands.json --xml 2> report.xml
|
|
```
|
|
|
|
Finally, you can convert the generated `.xml` file to HTML with the following command
|
|
|
|
```sh
|
|
cppcheck-htmlreport --file=report.xml --report-dir=cppcheck --source-dir=..
|
|
```
|
|
|
|
# Special notes on Eclipse
|
|
|
|
When using Eclipse, there are two special build variables in the project properties
|
|
→ C/C++ Build → Build Variables called `Q7S_SYSROOT` or `RPI_SYSROOT`. You can set
|
|
the sysroot path in those variables to get any additional includes like `gpiod.h` in the
|
|
Eclipse indexer.
|
|
|
|
# Q7S Utilities and Troubleshooting
|
|
|
|
## Core commands
|
|
|
|
Display currently running image:
|
|
|
|
```sh
|
|
xsc_boot_copy
|
|
```
|
|
|
|
Rebooting currently running image:
|
|
|
|
```sh
|
|
xsc_boot_copy -r
|
|
```
|
|
|
|
## pa3tool Host Tool
|
|
|
|
The `pa3tool` is a host tool to interface with the ProASIC3 on the Q7S board. It was
|
|
installed on the clean room PC but it can also be found
|
|
[on the Traq platform](https://trac2.xiphos.ca/manual/attachment/wiki/WikiStart/libpa3-1.3.4.tar.gz).
|
|
|
|
For more information, see Q7S datasheet.
|
|
|
|
## Creating files with cat and echo
|
|
|
|
The only folder which can be written in the root filesystem is the `tmp` folder.
|
|
|
|
You can create a simple file with initial content with `echo`
|
|
|
|
```sh
|
|
echo "Hallo Welt" > /tmp/test.txt
|
|
cat /tmp/test.txt
|
|
```
|
|
|
|
For more useful combinations, see this [link](https://www.freecodecamp.org/news/the-cat-command-in-linux-how-to-create-a-text-file-with-cat-or-touch/).
|
|
|
|
## Using the scratch buffer of the ProASIC3
|
|
|
|
The ProASIC3 has a 1024 byte scratch buffer. The values in this scratch buffer will survive
|
|
a reboot, so this buffer can be used as an alternative to the SD cards to exchange information
|
|
between images or to store mission critical information.
|
|
|
|
You can use `xsc_scratch --help` for more information.
|
|
|
|
Write to scratch buffer:
|
|
|
|
```sh
|
|
xsc_scratch write TEST "1"
|
|
```
|
|
|
|
Read from scratch buffer:
|
|
|
|
```sh
|
|
xsc_scratch read TEST
|
|
```
|
|
|
|
Read all keys:
|
|
|
|
```sh
|
|
xsc_scratch read
|
|
|
|
```
|
|
|
|
Get fill count:
|
|
|
|
```sh
|
|
xsc_scratch read | wc -c
|
|
```
|
|
|
|
|
|
## Using `system` when debugging
|
|
|
|
Please note that when using a `system` call in C++/C code and debugging, a new thread will be
|
|
spawned which will appear on the left in Eclipse or Xilinx SDK as a `sh` program.
|
|
The debugger might attach to this child process automatically, depending on debugger configuration,
|
|
and the process needs to be selected and continued/started manually. You can enable or disable
|
|
this behaviour by selecting or deselecting the `Attach Process Children` option in the Remote
|
|
Application Configuration for the TCF plugin like shown in the following picture
|
|
|
|
<img src="https://egit.irs.uni-stuttgart.de/eive/eive-obsw/raw/branch/develop/doc/img/ProcessSettings.png" width="50%"> <br>
|
|
|
|
## Libgpiod
|
|
|
|
Detect all gpio device files:
|
|
````
|
|
gpiodetect
|
|
````
|
|
Get info about a specific gpio group:
|
|
````
|
|
gpioinfo <name of gpio group>
|
|
````
|
|
The following sets the gpio 18 from gpio group gpiochip7 to high level.
|
|
````
|
|
gpioset gpiochip7 18=1
|
|
````
|
|
Setting the gpio to low.
|
|
````
|
|
gpioset gpiochip7 18=0
|
|
````
|
|
Show options for setting gpios.
|
|
````
|
|
gpioset -h
|
|
````
|
|
To get the state of a gpio:
|
|
````
|
|
gpioget <gpiogroup> <offset>
|
|
````
|
|
Example to get state:
|
|
gpioget gpiochip7 14
|
|
|
|
Both the MIOs and EMIOs can be accessed via the zynq_gpio instance which
|
|
comprises 118 pins (54 MIOs and 64 EMIOs).
|
|
|
|
## Xilinx UARTLIE
|
|
|
|
Get info about ttyUL* devices
|
|
````
|
|
cat /proc/tty/driver
|
|
````
|
|
|
|
## I2C
|
|
|
|
Getting information about I2C device
|
|
````
|
|
ls /sys/class/i2c-dev/i2c-0/device/device/driver
|
|
````
|
|
This shows the memory mapping of /dev/i2c-0
|
|
|
|
## CAN
|
|
|
|
```sh
|
|
ip link set can0 down
|
|
ip link set can0 type can loopback off
|
|
ip link set can0 up type can bitrate 1000000
|
|
```
|
|
|
|
Following command sends 8 bytes to device with id 99 (for petalinux)
|
|
````
|
|
cansend can0 -i99 99 88 77 11 33 11 22 99
|
|
````
|
|
For Q7S use this:
|
|
````
|
|
cansend can0 5A1#11.22.33.44.55.66.77.88
|
|
````
|
|
Turn loopback mode on:
|
|
````
|
|
ip link set can0 type can bitrate 1000000 loopback on
|
|
````
|
|
Reading data from CAN:
|
|
````
|
|
candump can0
|
|
````
|
|
|
|
## Preparation of a fresh rootfs and SD card
|
|
|
|
This section summarizes important changes between a fresh rootfs and the current
|
|
EIVE implementation
|
|
|
|
### rootfs
|
|
|
|
- Mount point `/mnt/sd0` created for SD card 0. Created with `mkdir`
|
|
- Mount point `/mnt/sd1` created for SD card 1. Created with `mkdir`
|
|
- Folder `scripts` in `/home/root` folder.
|
|
- `scripts` folder currently contains `update_main_components.sh` script
|
|
|
|
### SD Cards
|
|
|
|
- Folder `bin` for binaries, for example the OBSW
|
|
- Folder `misc` for miscellaneous files. Contains `ls` for directory listings
|
|
- Folder `tc` for telecommands
|
|
- Folder `tm` for telemetry
|
|
- Folder `xdi` for XDI components (e.g. for firmware or device tree updates)
|
|
|
|
# Running the EIVE OBSW on a Raspberry Pi
|
|
|
|
Special section for running the EIVE OBSW on the Raspberry Pi.
|
|
The Raspberry Pi build uses the `bsp_rpi` BSP folder, and a very similar cross-compiler.
|
|
|
|
For running the software on a Raspberry Pi, it is recommended to follow the steps specified in
|
|
[the fsfw example](https://egit.irs.uni-stuttgart.de/fsfw/fsfw_example/src/branch/mueller/master/doc/README-rpi.md#top)
|
|
and using the TCF agent to have a similar set-up process also required for the Q7S.
|
|
You should run the following command first on your Raspberry Pi
|
|
|
|
```sh
|
|
sudo apt-get install gpiod libgpiod-dev
|
|
```
|
|
|
|
to install the required GPIO libraries before cloning the system root folder.
|
|
|
|
# Flight Software Framework (FSFW)
|
|
|
|
An EIVE fork of the FSFW is submodules into this repository.
|
|
To add the master upstream branch and merge changes and updates from it
|
|
into the fork, run the following command in the fsfw folder first:
|
|
|
|
```sh
|
|
git remote add upstream https://egit.irs.uni-stuttgart.de/fsfw/fsfw.git
|
|
git remote update --prune
|
|
```
|
|
|
|
After that, an update can be merged by running
|
|
|
|
<<<<<<< HEAD
|
|
## Useful Q7S Linux Commands
|
|
Rebooting currently running image:
|
|
````
|
|
xsc_boot_copy -r
|
|
````
|
|
|
|
## Setting time on Q7S
|
|
Setting date and time (only timezone UTC available)
|
|
````
|
|
timedatectl set-time 'YYYY-MM-DD HH:MM:SS'
|
|
````
|
|
Setting UNIX time
|
|
````
|
|
date +%s -s @1626337522
|
|
````
|
|
This only sets the system time and does not updating the time of the real time clock. To harmonize
|
|
the system time with the real time clock run
|
|
````
|
|
hwclock -w
|
|
````
|
|
Reading the real time clock
|
|
````
|
|
hwclock --show
|
|
````
|
|
=======
|
|
```sh
|
|
git merge upstream/master
|
|
```
|
|
|
|
Alternatively, changes from other upstreams (forks) and branches can be merged like that in the same way.
|
|
>>>>>>> develop
|