diff options
author | Kenta <murakami.kenta002@jp.panasonic.com> | 2024-11-05 22:17:36 +0900 |
---|---|---|
committer | Jan-Simon Moeller <jsmoeller@linuxfoundation.org> | 2024-12-16 11:04:12 +0000 |
commit | f8e5a60025f761e4766e6f4292b7fad7645a2f30 (patch) | |
tree | fbeab20b85e43432651d4471b540f843d90c1db4 /docs/06_Component_Documentation | |
parent | 0fd6c42765ac7954bf6892a8fe0958a22c00b22d (diff) |
Update documentation for Unified HMIHEADsalmon_18.92.0salmon/18.92.018.92.0master
Updated the README to include support for the Distributed Display
Framework (DDFW) and Flutter applications.
Instructions for environment setup and the demo procedure using the
Unified HMI framework are provided.
Bug-AGL: SPEC-5254
Change-Id: I2a0a05d7307ccb9f0c48c90dcbfa1e64d7c6ed72
Signed-off-by: Kenta <murakami.kenta002@jp.panasonic.com>
Reviewed-on: https://gerrit.automotivelinux.org/gerrit/c/AGL/documentation/+/30498
Reviewed-by: Jan-Simon Moeller <jsmoeller@linuxfoundation.org>
Tested-by: Jan-Simon Moeller <jsmoeller@linuxfoundation.org>
Reviewed-by: Marius Vlad <marius.vlad@collabora.com>
Diffstat (limited to 'docs/06_Component_Documentation')
11 files changed, 375 insertions, 73 deletions
diff --git a/docs/06_Component_Documentation/11_Unified_HMI.md b/docs/06_Component_Documentation/11_Unified_HMI.md index f908215..2b054b0 100644 --- a/docs/06_Component_Documentation/11_Unified_HMI.md +++ b/docs/06_Component_Documentation/11_Unified_HMI.md @@ -5,61 +5,104 @@ title: Unified HMI ## Introduction -This document describes the design and usage of the **Unified HMI**, which is a common platform technology for UX innovation in integrated cockpit by flexible information display on multiple displays of various applications. Applications can be rendered to any display via a unified virtual display. +This document describes the design and usage of the **Unified HMI**, which is a `Software-Defined` display virtualization platform based on VirtIO GPU tecnology. Unified HMI allows for flexible development of the entire cockpit and cabin UI/UX, across multiple displays, independent of hardware and OS configuration. Applications can be rendered to any display via a unified virtual display. + +![Unified HMI Concept](images/Unified-HMI/UHMI_Concept.png) + +## Unified HMI frameworks + +Unified HMI consists of two main components: + +1. Remote VirtIO GPU Device(RVGPU):Render apps remotely in different SoCs. +2. Distributed Display Framework(DDFW):Flexible layout control of apps across multiple displays. + +![Unified HMI Architecture](images/Unified-HMI/UHMI_Architecture.png) ### Remote Virtio GPU (RVGPU) -The RVGPU rendering engine, operating on a client-server model, creates 3D rendering commands on a client device and transmits them to a server device via the network, where the server-side device performs GPU-based rendering and displays the results. The meta-rvgpu currently supports x86, Raspberry Pi 4, and Renesas Boards platforms. +RVGPU is a client-server based rendering engine, which allows to render 3D on one device (client) and display it via network on another device (server) + +RVGPU consists of three repositories on Github: + +1. [remote-virtio-gpu](https://github.com/unified-hmi/remote-virtio-gpu): Main framework of RVGPU. +2. [virio-loopback-driver](https://github.com/unified-hmi/virtio-loopback-driver): Capture the drawing commands for VirtIO GPU and transfer them to the RVGPU framework. +3. [rvgpu-wlproxy](https://github.com/unified-hmi/rvgpu-wlproxy): Apply applications that operate on the Wayland Protocol, including Flutter apps, to RVGPU. + +### Distributed Display Framework (DDFW) + +DDFW provides essential services for managing distributed display applications. This framework is designed to work with a variety of hardware and software configurations, making it a versatile choice for developers looking to create scalable and robust display solutions. + +As shown in the figure below, DDFW maps multiple cockpit physical displays, into a single large virtual screen. +By placing applications on the virtual screen, you can control the layout of applications, across multiple displays. + +![DDFW_Concept](images/Unified-HMI/DDFW_Concept.png) + +DDFW consists of three repositories on Github: + +1. [ucl-tools](https://github.com/unified-hmi/ucl-tools): Unified Clustering Tools (UCL), launch applications for multiple platforms and manage execution order and survival. +2. [ula-tools](https://github.com/unified-hmi/ula-tools): Unified Layout Tools (ULA), application layout for virtual displays on virtual screen (mapped from physical displays). +3. [uhmi-ivi-wm](https://github.com/unified-hmi/uhmi-ivi-wm): Apply ivi-layer and ivi-surface layouts to the screen using the layout design output by ula-tools. -### RVGPU Architecture +### Json settings -![RVGPU_Architecture](images/Unified-HMI/RVGPU_Architecture.png) +To run ULA, three Json files are required. + +1. virtual-screen-def.json: Execution environment such as display and node (SoCs/VMs/PCs) informations. Please put this file on all related host. +![Virtual_Screen_Def_Json_Info](images/Unified-HMI/Virtual_Screen_Def_Json.png) + +2. app.json: Application execution information which can also take a sender/receiver relationship. Please put this file on one of the sender/receiver or a host that canbe communicate with them via network. +![APP_Json_Info](images/Unified-HMI/App_Json.png) + +3. initial-vscreen.json: application layout information such as position and size. Please put this file on one of the sender/receiver or a host that canbe communicate with them via network. +![Initial_Vscreen_Json_Info](images/Unified-HMI/Initial_Vscreen_Json.png) + +Json files need to be created correctly for your execution environment. ## How to Build -Follow the [AGL documentation](https://docs.automotivelinux.org/en/master/#01_Getting_Started/02_Building_AGL_Image/01_Build_Process_Overview/) for the build process, and set up the "[Initializing Your Build Environment](https://docs.automotivelinux.org/en/master/#01_Getting_Started/02_Building_AGL_Image/04_Initializing_Your_Build_Environment/)" section as described below to enable the AGL feature 'agl-rvgpu'. For example: +Follow the [AGL documentation](https://docs.automotivelinux.org/en/master/#01_Getting_Started/02_Building_AGL_Image/01_Build_Process_Overview/) for the build process, and set up the "[Initializing Your Build Environment](https://docs.automotivelinux.org/en/master/#01_Getting_Started/02_Building_AGL_Image/04_Initializing_Your_Build_Environment/)" section as described below to enable the AGL feature 'agl-uhmi'. + +For example: ``` $ cd $AGL_TOP/master -$ source ./meta-agl/scripts/aglsetup.sh -m qemux86-64 -b qemux86-64 agl-demo agl-devel agl-rvgpu +$ source ./meta-agl/scripts/aglsetup.sh -m qemux86-64 -b qemux86-64 agl-demo agl-devel agl-uhmi ``` + After adding the feature, execute the command: ``` $ bitbake <image_name> ``` -**Note**: The operation has been confirmed with the **agl-ivi-demo-qt**. If you wish to specify a different `<image_name>` other than agl-ivi-demo-qt, create a file named `<image_name>.bbappend` in the directory -``` -$AGL_TOP/master/meta-agl-devel/meta-uhmi/meta-rvgpu/recipes-platform/images -``` -, and then add the following line to the file: +To add RVGPU and DDFW to the build images, please add the packagegroup that enable RVGPU(packagegroup-rvgpu) and DDFW(packagegroup-ddfw) to the installation target using the following command. ``` -IMAGE_INSTALL:append = " packagegroup-rvgpu" +$ echo 'IMAGE_INSTALL:append = " packagegroup-rvgpu packagegroup-ddfw"' >> conf/local.conf ``` +**Note**: RVGPU and DDFW can each be used independently. If you wish to use them individually, please add only one of the packagegroups to the installation target. -After making this change, you will need to execute the following commands: - +After adding the feature, execute the command: ``` -$ cd $AGL_TOP/master -$ source agl-init-build-env $ bitbake <image_name> -``` +``` +Replace the `<image_name>` with the appropriate values you want. We have confirmed the operation with the **agl-image-weston**. -## How to Setup and Boot +## How to setup and boot -For Environment setup instructions for each platform, refer to the following link in the AGL Documentation. -[Building for x86(Emulation and Hardware)](https://docs.automotivelinux.org/en/master/#01_Getting_Started/02_Building_AGL_Image/07_Building_for_x86_%28Emulation_and_Hardware%29/) -[Building for Raspberry Pi 4](https://docs.automotivelinux.org/en/master/#01_Getting_Started/02_Building_AGL_Image/08_Building_for_Raspberry_Pi_4/) -[Building for Supported Renesas Boards](https://docs.automotivelinux.org/en/master/#01_Getting_Started/02_Building_AGL_Image/09_Building_for_Supported_Renesas_Boards/) +For Environment setup instructions for each platform, refer to the following links in the AGL Documentation: +[Building for x86(Emulation and Hardware)](https://docs.automotivelinux.org/en/master/#01_Getting_Started/02_Building_AGL_Image/06_Building_the_AGL_Image/02_Building_for_x86_%28Emulation_and_Hardware%29/) +[Building for Raspberry Pi 4](https://docs.automotivelinux.org/en/master/#01_Getting_Started/02_Building_AGL_Image/06_Building_the_AGL_Image/03_Building_for_Raspberry_Pi_4/) +[Building for Supported Renesas Boards](https://docs.automotivelinux.org/en/master/#01_Getting_Started/02_Building_AGL_Image/06_Building_the_AGL_Image/04_Building_for_Supported_Renesas_Boards/) -For Raspberry Pi 4 and Supported Renesas Boards, refer to the above URL for boot methods. -For x86 emulation (qemu), network bridge is required to enable communication with other devices when using RVGPU. Here’s an example procedure for your reference. +For Raspberry Pi 4 and Supported Renesas Boards, refer to the above URL for boot methods. +For x86 emulation (qemu), network bridge is required to enable communication with other devices when using RVGPU. + +Here’s an example procedure for your reference. ``` $ sudo ip link add <bridge_name> type bridge $ sudo ip addr add <IP address> dev <bridge_name> $ sudo ip link set dev <interface> master <bridge_name> $ sudo ip link set dev <bridge_name> up ``` -Replace the placeholders with the appropriate values: +Replace the placeholders with the appropriate values: - `<bridge_name>`: You can assign any name, for example: `br0` - `<IP_address>`: Enter an available IP address, for example: `192.168.0.100/24` - `<interface>`: Specify the network interface, for example: `eth0` @@ -68,7 +111,7 @@ To enable the use of the bridge, create or append /etc/qemu directory and /etc/q ``` allow <bridge_name> ``` -Make sure /etc/qemu/ has 755 permissions. +Make sure /etc/qemu/ has 755 permissions. Create the following bash file named **run_qemu_bridge.sh** in any `<WORKDIR>`. ``` #!/bin/bash @@ -88,78 +131,337 @@ qemu-system-x86_64 -enable-kvm -m 2048 \ -netdev bridge,br=$BRIDGE_NAME,id=net0 \ -serial mon:stdio -serial null \ -soundhw hda \ - -append 'root=/dev/vda rw console=ttyS0,115200n8 fstab=no' + -append 'root=/dev/vda swiotlb=65536 rw console=ttyS0,115200n8 fstab=no' ``` Save the file and run the following to start QEMU. ``` -sudo <WORKDIR>/run_qemu_bridge.sh <build_directory>/tmp/deploy/images/qemux86-64/bzImage <build_directory>/tmp/deploy/images/qemux86-64/agl-ivi-demo-qt-qemux86-64.ext4 +sudo <WORKDIR>/run_qemu_bridge.sh <build_directory>/tmp/deploy/images/qemux86-64/bzImage <build_directory>/tmp/deploy/images/qemux86-64/agl-image-weston-qemux86-64.rootfs.ext4 ``` -When QEMU boot, assign an IP address. For example: +When QEMU boot, you can log in to qemu on the terminal where you executed above command, so please assign an IP address there. + +For example: ``` -ifconfig <your environment> 192.168.0.10 netmask 255.255.255.0 +ifconfig <your environment> 192.168.0.100 netmask 255.255.255.0 ``` -## How to run RVGPU remotely -Prepare two images, one as the Sender and the other as the Receiver. -It is necessary for the Sender and Receiver to be within the same network. +## How to use Unified HMI on AGL + +In the following verification procedure, it is assumed that two SoCs or Virtual Machines, are each connected to a Full HD display, with the displays, arranged side by side as shown in the figure. + +In the following sections, introducing the steps to run Unified HMI frameworks on the `agl-image-weston` image. + +![Demo_Env](images/Unified-HMI/Demo_Env.png) + +### Environment settings (for all hosts) -**Receiver side** +To utilize Unified HMI, you need to set up each image with a distinct hostname and static IP address, and ensure that ivi-shell is running using the wayland-ivi-extension. Please note that the following configurations are examples and should be adapted to fit your specific network environment. + +#### Run weston with ivi-shell + +Before setting unique hostnames and configuring static IP addresses, it is essential to start Weston with ivi-shell since DDFW controls the layout of applications using ivi-shell. To initialize ivi-shell, follow these steps: + +First, please create the following content as /etc/xdg/weston/weston_ivi-shell.ini ``` -$ export XDG_RUNTIME_DIR=/run/user/<your_UID> -$ rvgpu-renderer -b <your_Area>@0,0 -p <Port_Number> & +[core] +shell=ivi-shell.so +modules=ivi-controller.so +require-input=false + +[output] +name=HDMI-A-1 +mode=1920x1080@60 + +[output] +name=HDMI-A-2 +mode=1920x1080@60 + +[output] +name=HDMI-A-3 +mode=1920x1080@60 + +[output] +name=DSI-1 +mode=1920x1080@60 + +[output] +name=DSI-2 +mode=1920x1080@60 + +[output] +name=DP-1 +mode=1920x1080@60 + +[output] +name=Virtual-1 +mode=1920x1080 + +[output] +name=Virtual-2 +mode=1920x1080 + +[output] +name=VGA-1 +mode=1920x1080 + +[output] +name=VGA-2 +mode=1920x1080 + +[ivi-shell] +ivi-input-module=ivi-input-controller.so +#ivi-client-name=/usr/bin/simple-weston-client +bkgnd-surface-id=1000000 +bkgnd-color=0xFF000000 ``` -Replace the placeholders with the appropriate values: -- `<your_UID>`: Specify according to your environment, for example:1001 -- `<your_Area>`: Enter an usable area for example: 1080x1488 - With the following command, you can know the usable area. - ``` - $ journalctl | grep -i "usable area" - # Example Output: - Nov 29 11:42:53 qemux86-64 agl-compositor[259]: [11:42:53.166] Usable area: 1080x1488+0,216 - ``` -- `<Port_Number>`: Enter an available port number, for example: 55555 +Next, to start Weston with the configuration created above, please execute the following command. +``` +ln -sf /etc/xdg/weston/weston_ivi-shell.ini /etc/xdg/weston/weston.ini +systemctl restart weston +``` +**Note**: Even after the launch of the ivi-shell is complete, the screen remains black and nothing is displayed until the application is shown. -**Sender side** -Create the following shell script **run_remote_app.sh** in any `<WORKDIR>` for a smooth experience. +#### Configuration to run Unified HMI frameworks on launched weston. + +By setting XDG_RUNTIME_DIR=/run/user/<your_UID> and WAYLAND_DISPLAY=<your_WAYLAND_DISPLAY> in /lib/systemd/system/uhmi-ivi-wm.service, you can display the applications launched by Unified HMI on Weston. + +Please execute `$ls /run/user/` in your environment to check <your_UID>. +Additionally, when Weston is launched, <your_WAYLAND_DISPLAY> will be generated under /run/user/<your_UID>, so please check that as well. + +e.g. In agl-image-weston, <your_UID> is set to 200 and <your_WAYLAND_DISPLAY> is set to wayland-1. Please create **/etc/default/uhmi-ivi-wm** as follows and set correct valiables: ``` -#!/bin/bash +XDG_RUNTIME_DIR=/run/user/200 +WAYLAND_DISPLAY=wayland-1 +``` + +#### Set Unique Hostnames -export XDG_RUNTIME_DIR=/tmp -export LD_LIBRARY_PATH=/usr/lib/mesa-virtio +Edit the `/etc/hostname` file on each image to set a unique hostname. Here are the suggested hostnames for the first two images: -# ------------- -# launch app -# ------------- -$@ +- **For the first image:** +``` +echo "agl-host0" | tee /etc/hostname +``` +- **For the second image:** +``` +echo "agl-host1" | tee /etc/hostname ``` -Save the file and run the following to start weston. +#### Assign Static IP Addresses +Configure a static IP address for each image by editing the `/etc/systemd/network/wired.network` file. If this file does not exist, please create a new one. Use the following template and replace `<IP_address>` and `<Netmask>` with your network's specific settings: + +```ini +[Match] +KernelCommandLine=!root=/dev/nfs +Name=eth* en* + +[Network] +Address=<IP_address>/<Netmask> ``` -$ rvgpu-proxy -s 1080x1488@0,0 -n <IP_address_of_Receiver>:<Port_Number> & -$ <WORKDIR>/run_remote_app.sh weston --backend drm-backend.so -Swayland-0 --seat=seat_virtual -i 0 & -``` -Replace the placeholders with the appropriate values: -- `<Port_Number>`: Port set in the renderer. +Here is how you might configure the static IP addresses for the first two images: -After completing these steps, the Weston screen from the Sender will be transferred and displayed on the Receiver using rvgpu-proxy and rvgpu-renderer. You can verify that everything is functioning properly by launching wayland applications on the Sender side, such as: +- **For the first image:** ``` -$ weston-simple-egl -f -``` +[Match] +KernelCommandLine=!root=/dev/nfs +Name=eth* en* -You can also verify the touch or keyboard operation support of the RVGPU by using app such as +[Network] +Address=192.168.0.100/24 ``` -$ weston-smoke -$ weston-editor +- **For the second image:** ``` -**Note**: There are known issues with mouse, such as the cursor becoming invisible and occasional flickering of a green screen. +[Match] +KernelCommandLine=!root=/dev/nfs +Name=eth* en* + +[Network] +Address=192.168.0.101/24 +``` + +Once the hostname and IP addresses settings are complete, please reboot to reflect these settings. + +### Demo Image + +In this documentation, we will use the demo environment prepared as shown in the following diagram. In this diagram, there are two hosts, agl-host0 and agl-host1, each have a display output with a resolusion of 1920x1080(FullHD), arranged in order from left to right as agl-host0 and then agl-host1. + +![Demo_Setting](images/Unified-HMI/Demo_Settings.png) + +Here, agl-host0 will act as the sender, and the application will be executed on agl-host0. Both agl-host0 (itself) and agl-host1 will render it remotely as receivers, enabling the display of the application across two displays. + +In the following sections, specify where to carry out the steps for agl-host0 or agl-host1 for clarity. However, in practice, the UCL and ULA commands can be executed on one of any sender/receiver or any other host. + +### Customizing Virtual Screen Definitions (both agl-host0/agl-host1) + +Adjust the `/etc/uhmi-framework/virtual-screen-def.json` file to match your environment. In this demo, please create that Json file as shown in below: + +``` +{ + "virtual_screen_2d": { + "size": {"virtual_w": 3840, "virtual_h": 1080}, + "virtual_displays": [ + {"vdisplay_id": 0, "disp_name": "AGL_SCREEN0", "virtual_x": 0, "virtual_y": 0, "virtual_w": 1920, "virtual_h": 1080}, + {"vdisplay_id": 1, "disp_name": "AGL_SCREEN1", "virtual_x": 1920, "virtual_y": 0, "virtual_w": 1920, "virtual_h": 1080} + ] + }, + "virtual_screen_3d": {}, + "real_displays": [ + {"node_id": 0, "vdisplay_id": 0, "pixel_w": 1920, "pixel_h": 1080, "rdisplay_id": 0}, + {"node_id": 1, "vdisplay_id": 1, "pixel_w": 1920, "pixel_h": 1080, "rdisplay_id": 0} + ], + "node": [ + {"node_id": 0, "hostname": "agl-host0", "ip": "192.168.0.100"}, + {"node_id": 1, "hostname": "agl-host1", "ip": "192.168.0.101"} + ], + "distributed_window_system": { + "window_manager": {}, + "framework_node": [ + {"node_id": 0, "ula": {"debug": false, "debug_port": 8080, "port": 10100}, "ucl": {"port": 7654}}, + {"node_id": 1, "ula": {"debug": false, "debug_port": 8080, "port": 10100}, "ucl": {"port": 7654}} + ] + } +} +``` + +Please put the same virtual-screen-def.json on both agl-host0/agl-host1. + +Be sure to update the virtual_w, virtual_h, virtual_x, virtual_y, pixel_w, pixel_h, hostname, and ip fields to accurately reflect your specific network configuration. + +### Restarting Services (both agl-host0/agl-host1) +Once you have prepared the virtual-screen-def.json file and configured the system, you need to restart the system or the following system services for the changes to take effect in all hosts: +``` +systemctl restart uhmi-ivi-wm +systemctl restart ula-node +systemctl restart ucl-launcher +``` + +After restarting these services, your system should be ready to use the DDFW commands with the new configuration. + +### Remote rendering of apps with RVGPU using UCL + +UCL provides a distributed launch feature for applications using RVGPU. By preparing a app.json configuration, you can enable the launch of applications across multiple devices in a distributed environment. + +#### Setting Up for Application Launch using UCL (agl-host0) + +To facilitate the distributed launch of an application with UCL, you need to create a app.json file on agl-host0 that specifies the details of the application and how it should be executed on the sender and receiver nodes. + +Example of `app.json`: +``` +{ + "format_v1": { + "command_type" : "remote_virtio_gpu", + "appli_name" : "weston-simple-egl", + "sender" : { + "launcher" : "agl-host0", + "command" : "/usr/bin/ucl-virtio-gpu-wl-send", + "frontend_params" : { + "scanout_x" : 0, + "scanout_y" : 0, + "scanout_w" : 1920, + "scanout_h" : 1080, + "server_port" : 33445 + }, + "appli" : "/usr/bin/weston-simple-egl -s 1920x1080", + "env" : "LD_LIBRARY_PATH=/usr/lib/mesa-virtio" + }, + "receivers" : [ + { + "launcher" : "agl-host0", + "command" : "/usr/bin/ucl-virtio-gpu-wl-recv", + "backend_params" : { + "ivi_surface_id" : 101000, + "scanout_x" : 0, + "scanout_y" : 0, + "scanout_w" : 1920, + "scanout_h" : 1080, + "listen_port" : 33445, + "initial_screen_color" : "0x33333333" + }, + "env" : "XDG_RUNTIME_DIR=/run/user/200 WAYLAND_DISPLAY=wayland-1" + }, + { + "launcher" : "agl-host1", + "command" : "/usr/bin/ucl-virtio-gpu-wl-recv", + "backend_params" : { + "ivi_surface_id" : 101000, + "scanout_x" : 0, + "scanout_y" : 0, + "scanout_w" : 1920, + "scanout_h" : 1080, + "listen_port" : 33445, + "initial_screen_color" : "0x33333333" + }, + "env" : "XDG_RUNTIME_DIR=/run/user/200 WAYLAND_DISPLAY=wayland-1" + } + ] + } +} +``` + +In this example, the application weston-simple-egl is configured to launch on the sender node `agl-host0` and display its output on the receiver nodes `agl-host0` and `agl-host1`. The `scanout_x`, `scanout_y`, `scanout_w`, `scanout_h` parameters define the size of the window, while `server_port` and `listen_port` ensure the communication between sender and receivers. + +#### Launching the Application (agl-host0) + +Once the app.json file is ready, you can execute the application across the distributed system by piping the JSON content to the `ucl-distrib-com` command along with the path to the `virtual-screen-def.json` file: + +``` +cat app.json | ucl-distrib-com /etc/uhmi-framework/virtual-screen-def.json +``` + +This command will read the configuration and initiate the application launch process, distributing the workload as defined in the JSON files. + +Please ensure that the app.json file you create is correctly formatted and contains the appropriate parameters for your specific use case. + +### Layout application by ULA + +ULA allows for the definition of physical displays on a virtual screen and provides the ability to apply layout settings such as position and size to applications launched using the UCL Framework. + +#### Creating a Layout Configuration File (agl-host0) + +To define the layout for your applications, you need to create a `initial_vscreen.json` file, with the necessary configuration details on agl-host0. This file will contain the layout settings that specify how applications should be positioned and sized within the virtual screen. Here is an example of what the contents of `initial_vscreen.json` file might look like: + +``` +{ + "command": "initial_vscreen", + "vlayer": [ + { + "VID": 1010000, + "coord": "global", + "virtual_w": 1920, "virtual_h": 1080, + "vsrc_x": 0, "vsrc_y": 0, "vsrc_w": 1920, "vsrc_h": 1080, + "vdst_x": 960, "vdst_y": 0, "vdst_w": 1920, "vdst_h": 1080, + "vsurface": [ + { + "VID": 101000, + "pixel_w": 1920, "pixel_h": 1080, + "psrc_x": 0, "psrc_y": 0, "psrc_w": 1920, "psrc_h": 1080, + "vdst_x": 0, "vdst_y": 0, "vdst_w": 1920, "vdst_h": 1080 + } + ] + } + ] +} +``` + +In this example, the application is renderd across the right half of the agl-host0 and the left half of agl-host1 display. + +- **vlayer** defines a virtual layer that represents a group of surfaces within the virtual screen. Each layer has a unique Virtual ID (VID) and can contain multiple surfaces. The layer's source (`vsrc_x`, `vsrc_y`, `vsrc_w`, `vsrc_h`) and destination (`vdst_x`, `vdst_y`, `vdst_w`, `vdst_h`) coordinates determine where and how large the layer appears on the virtual screen. + +- **vsurface** defines individual surfaces within the virtual layer. Each surface also has a VID, and its pixel dimensions (`pixel_w`, `pixel_h`) represent the actual size of the content. The source (`psrc_x`, `psrc_y`, `psrc_w`, `psrc_h`) and destination (`vdst_x`, `vdst_y`, `vdst_w`, `vdst_h`) coordinates determine the portion of the content to display and its location within the layer. + +#### Applying the Layout Configuration (agl-host0) + +Once you have created the `initial_vscreen.json` file with your layout configuration, you can apply it to your system using the following command: + +``` +cat initial_vscreen.json | ula-distrib-com +``` + +Executing this command will process the configuration from the JSON file and apply the layout settings to the virtual screen. As a result, the applications will appear in the specified positions and sizes according to the layout defined in the Json file. -**Appendix** -- By building the RVGPU on Ubuntu, it is possible to enable bidirectional remote rendering between the agl-ivi-demo-qt and Ubuntu. -For the build procedure on Ubuntu, see the following URL: https://github.com/unified-hmi/remote-virtio-gpu -The figure below shows an example where Ubuntu is used as the Sender and AGL as the Receiver, running RVGPU. +Ensure that `initial_vscreen.json` file you create accurately reflects the desired layout for your applications and display setup. -![Using_RVGPU_from_Ubuntu_to_AGL](images/Unified-HMI/Using_RVGPU_from_Ubuntu_to_AGL.png)
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