Yocto Scarthgap OpenSTLinux for VisionSOM-STM32MP1: Difference between revisions
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Created page with "{{PageHeader|Yocto Scarthgap OpenSTLinux for VisionSOM-STM32MP1}} __toc__ == Introduction == This tutorial explains how to build a Yocto-based OpenSTLinux system for VisionSOM-STM32MP1 modules with VisionCB-STM32MP1-STD carrier board and meta-somlabs support layer. * meta-somlabs (scarthgap): https://github.com/SoMLabs/openst-meta-somlabs/tree/scarthgap == meta-somlabs == Meta-somlabs layer should be used in order to build the st-image-weston image. == Building th..." |
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Meta-somlabs layer should be used in order to build the st-image-weston image. | Meta-somlabs layer should be used in order to build the st-image-weston image. | ||
'''NOTE''' The device-tree files in the scarthgap release were not generated by STM32CubeMX tool. | |||
== Building the system image == | == Building the system image == |
Latest revision as of 08:13, 19 December 2024
Yocto Scarthgap OpenSTLinux for VisionSOM-STM32MP1
Introduction
This tutorial explains how to build a Yocto-based OpenSTLinux system for VisionSOM-STM32MP1 modules with VisionCB-STM32MP1-STD carrier board and meta-somlabs support layer.
- meta-somlabs (scarthgap): https://github.com/SoMLabs/openst-meta-somlabs/tree/scarthgap
meta-somlabs
Meta-somlabs layer should be used in order to build the st-image-weston image.
NOTE The device-tree files in the scarthgap release were not generated by STM32CubeMX tool.
Building the system image
In order to build the system image a Distribution Package provided by STMicroelectronics is required. The whole building process is described on the ST wiki pages:
https://wiki.st.com/stm32mpu/wiki/STM32MP1_Distribution_Package
Yocto is using absolute directory path to give names to intermediate files. If the path is too long, Yocto build fails because file names exceed the maximum size supported by the file system. In that case, installation directory path should be renamed to reduce the overall absolute path name.
The summary of required steps is shown below:
mkdir st-yocto cd st-yocto repo init -u https://github.com/STMicroelectronics/oe-manifest -b refs/tags/openstlinux-6.6-yocto-scarthgap-mpu-v24.12.05 repo sync cd layers/meta-st git clone -b scarthgap https://github.com/SoMLabs/openst-meta-somlabs.git meta-somlabs cd ../../ DISTRO=openstlinux-weston MACHINE=<MACHINE_NAME> source layers/meta-st/scripts/envsetup.sh bitbake st-image-weston
The following VisionSOM machines are available:
- mp157a-dsi-rvt-emmc-mx VisionSOM-STM32MP1 eMMC module with VisionCB-STM32MP1-STD board and rvt70hsmnwc00 DSI display
- mp157a-hdmi-lt-emmc-mx VisionSOM-STM32MP1 eMMC module with VisionCB-STM32MP1-STD board and lt8912b HDMI bridge
The compiled image files are located in the directory:
st-yocto/build-openstlinuxweston-<MACHINE_NAME>/tmp-glibc/deploy/images/<MACHINE_NAME>
Installing eMMC image
To install the built system on eMMC memory the STM32CubeProgrammer has to be used. It is available to download from the STMicroelectronics website: https://www.st.com/en/development-tools/stm32cubeprog.html
In order to program the module on VisionCB-STM32MP1-STD board, the BOOT jumpers need to be set to 000 to enable DFU boot. STM32CubeProgrammer should be connected by the USB cable connected to the USB-OTG socket. After programming the BOOT jumpers need to be set to 010 in order to run the installed system.
The details about using the STM32CubeProgrammer may be found on the ST wiki pages:
https://wiki.st.com/stm32mpu/wiki/STM32CubeProgrammer https://wiki.st.com/stm32mpu/wiki/STM32CubeProgrammer_flashlayout