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1748 lines
75 KiB
Plaintext
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=============================
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Sculpt Operating System 22.10
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=============================
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Norman Feske
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Introduction
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############
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Sculpt is a component-based desktop operating system that puts the user in
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the position of full control. It is empowered by the Genode OS Framework,
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which provides a comprehensive set of building blocks, out of which custom
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system scenarios can be created. The name Sculpt hints at the underlying
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idea of crafting, molding, and tweaking the system interactively. Starting
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from a fairly minimalistic and generic base system, this tour through the
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Sculpt system will cover the following topics:
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* A boot image that is a live system, rescue system, and bootstrap system all
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in one,
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* Connecting to a wired or wireless network,
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* Installing and deploying software,
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* Ways to tweak and introspect the system, and
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* Managing and accessing storage devices.
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Community
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---------
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The best place to learn more about using and tweaking Sculpt, to follow the
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work of the developers, and to get hold of announcements of new software and
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features is the federated Genodians blog:
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:Genodians.org community blog:
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[https://genodians.org]
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Feedback and contact
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--------------------
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Your feedback is appreciated!
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:Join the Genode mailing list for discussion:
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[https://genode.org/community/mailing-lists]
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:Get in touch with the developers at GitHub:
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[https://github.com/genodelabs/genode]
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:Contact Genode Labs for commercial inquiries:
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[https://www.genode-labs.com]
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A printable PDF version of this document is available at the
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[https://genode.org/documentation/sculpt-22-10.pdf - Genode website].
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Hardware requirements and preparations
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######################################
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Sculpt should be compatible with recent Intel-based PC hardware featuring
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Intel graphics, E1000 networking, Intel wireless, and AHCI/NVMe.
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It is tested best on laptops of the Lenovo X and T series (X220, X250, X260,
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T430, T460, T470, T490). For experimenting with Sculpt, we recommend getting a
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refurbished version of one of these. You may also find the unofficial
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[https://usr.sysret.de/jws/genode/hcl.html - hardware compatibility list]
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helpful for finding Genode-compatible hardware.
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Sculpt has been tested with screen resolutions up to 2560 x 1440. Displays
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with a higher resolution are not expected to work. The sweet spot is a full-HD
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display.
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Please revisit the BIOS settings of your machine in the following respects:
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:VT-d enabled: Even though Sculpt is able to run without an IOMMU, we
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advise to enable this option for the sandboxing of device drivers.
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:VT-x enabled: Hardware-assisted virtualization is needed to run VirtualBox
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on top of Sculpt.
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:Execution prevention enabled: The standard Sculpt package is provided
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for x86-64 and expects your platform to support data execution
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prevention (abbreviated DEP or NX). If this feature is disabled your
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PC will just reboot on startup.
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:Boot from USB enabled: Sculpt is usually booted from a USB stick.
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:UEFI boot enabled: Sculpt boots via UEFI by default. The boot image
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is specially prepared such that it can be started via legacy boot on older
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machines. However, booting it via legacy boot on a modern machine is
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hit or miss.
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:UEFI secure boot disabled: The Sculpt boot image is not cryptographically
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signed.
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:Optimize for performance when battery powered: If the latter is not set,
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the hardware may behave erratically (e.g., non-working trackpoint when on
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battery).
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Getting a first impression
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##########################
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Sculpt is best explored by first booting the prebuilt disk image downloadable
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from [https://genode.org/download/sculpt].
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Right after system boot, Sculpt's system-management user interface
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("Leitzentrale") appears.
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The panel at the top of the screen contains two centered tabs for switching
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between the "Components" view and a "Files" view (Figure [sculpt_20_08_panel]).
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The components view displays a live graph of the software components and their
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relationships. It also provides convenient access to the connected storage
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devices. The "Log" button at the right side of the panel reveals diagnostic
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messages, the "Network" button allows you to configure network connectivity,
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and the "Settings" button on the left gives access to a few user-interface
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tweaks (Figure [sculpt_20_08_panel]).
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[image sculpt_20_08_panel 60%]
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Consider the following steps as a warm-up with Sculpt OS.
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Select the in-memory file system as *default storage location* by clicking
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on the "ram fs" component in the graph and pressing the "Use" button
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(Figure [sculpt_20_08_use_ram_fs]).
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This way, software will be installed solely into memory without accessing any
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real storage device.
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[image sculpt_20_08_use_ram_fs 40%]
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Enable *networking* in the "Network" dialog by selecting the "Wired" or
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"Wifi" option. In the latter case, select an access point and enter the
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corresponding passphrase (if needed). A successful network connection is
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indicated by the IP address displayed at the bottom of the network dialog
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(Figure [sculpt_20_08_network]).
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[image sculpt_20_08_network 40%]
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With a storage location selected and established network connectivity, it is
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time to *install and start* additional components by clicking on the '+'
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button of the components view. Select "Depot ..." from the menu
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(Figure [sculpt_21_10_menu]).
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[image sculpt_21_10_menu 40%]
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The depot contains software packages, which can be obtained by different
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independent software providers. The selection of software providers is
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completely up to the user and can be defined in the "Selection ..." sub menu
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(Figure [sculpt_21_10_select]).
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[image sculpt_21_10_select 32%]
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Select "genodelabs" to download the directory of software officially
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provided by Genode Labs. Note that the other options are not necessarily
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affiliated with Genode Labs. Think of each option as a different individual.
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If you don't trust one particular software provider, you can still install and
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use the provided software without risk as long as you don't explicitly grant
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their components access to sensitive parts of your system. The judgement
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of trust is entirely yours.
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When now going back to the depot menu, a new menu item "genodelabs ..."
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appears. It leads to a catalogue of software browsable via hierarchically
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structured menus. As a starter, let's add a desktop background.
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In the "GUI ..." sub menu, a click on the first item named "sticks blue
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backdrop" reveals the option to install the package
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(Figure [sculpt_20_08_install_backdrop]).
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[image sculpt_20_08_install_backdrop 48%]
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A click on the "Install" button triggers the download of the package and its
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dependencies. Once the download is complete, the menu presents a configuration
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dialog that allows you to define the interplay of the new component with the
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system. In this particular case, you have to decide for a GUI service to be
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used by the backdrop (Figure [sculpt_20_08_backdrop_routes]).
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[image sculpt_20_08_backdrop_routes 40%]
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The first option "system GUI server" would grant direct access to the system's
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low-level GUI server, which is normally not used by applications but by
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higher-level GUI servers like a window manager. The second option would give
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the component the privilege to act as a lock screen. The third option would
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connect the component to the special "desktop background" GUI session, which
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appears as a layer behind all other applications. The fourth option "keyboard
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focus" is preserved for a single component that controls the keyboard focus.
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In our case, "desktop background" is the correct choice.
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Once the configuration is complete, a new button for adding the component to
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the system appears (Figure [sculpt_20_08_add_backdrop]).
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[image sculpt_20_08_add_backdrop 40%]
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After pressing the button, you should notice a slight visual change. *Press*
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*F12* to toggle between the Leitzentrale and the desktop. Now, the backdrop
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should become visible in full glory. In the component graph, the new component
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appears connected to the "GUI". A click on the component reveals further
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information along with the options to remove it from the system or to
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restart it (Figure [sculpt_20_08_backdrop_selected]).
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[image sculpt_20_08_backdrop_selected 40%]
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As a next step, let us add a window system. In the '+' menu, you can find
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a readily packaged window system at _genodelabs_ -> _GUI_ -> _themed wm_.
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After installing the package, you are asked to take five decisions:
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The _GUI (focus)_ should be assigned to "keyboard focus" to put the
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window manager in charge of controlling the keyboard focus, which is part
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of its job after all.
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The _GUI_ should be assigned to "system GUI server" as the basic mechanism
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to be used for graphical output and user input for the windowed applications.
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By assigning _Report (shape)_ to _pointer shape_, we allow the window
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manager to report information about mouse-pointer shapes.
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By assigning _Report (clipboard)_ to _global clipboard_, we grant the
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window manager the right to change the content of the global clipboard.
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Vice versa, by assigning _ROM (clipboard)_, we permit the window manager
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to obtain clipboard content.
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After adding the component, the "themed wm" will appear in the components view.
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To give the window system a quick try, add the small demo you can find at
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_genodelabs_ -> _Demos_ -> _nano3d_ and assign its _GUI_ to our "themed wm".
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You will be greeted with the window as shown in Figure [sculpt_ce_nano3d].
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[image sculpt_ce_nano3d 40%]
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Next, let us add a *small Unix-like subsystem* called _system shell_ hosted in
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a window. This subsystem will be presented in a terminal window. The font
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used by the terminal is obtained from a font server. To create the font
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server, install and add the package _genodelabs_ -> _GUI_ -> _fonts fs_, and
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assign the _system font configuration_ to its _ROM (config)_. "ROM" means
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read-only memory. So we grant the font server read-only access to the system's
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default font configuration (which is generated automatically according to the
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screen resolution).
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For starting the actual system shell, select and install
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_genodelabs_ -> _Tools_ -> _system shell_ from the menu. The configuration
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dialog is a bit more elaborate this time.
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:GUI: defines the GUI server that should host the terminal.
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Select "themed wm".
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:File system (config): defines which file system should be mounted at
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_/config/_ inside the instance. There exist a number of options.
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By selecting _writeable system configuration_, we grant control over
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the whole system. It goes without saying that this should not be done
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lightheartedly. However, since we trust the "system shell" package from
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Genode Labs, let's do it.
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:File system (report): defines the file system to be mounted at _/report/_
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inside the instance. By selecting "read-only system reports", we allow
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the instance to look at the state of various parts of the system.
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:File system (target): defines a file system to be mounted at _/rw/_.
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This can be any file system you'd like to work with or explore, for
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example the "ram fs".
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:File system (fonts): defines the place where to obtain the font used by
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the terminal. Select the "fonts fs" component we have started earlier.
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:ROM (vimrc): defines the configuration for the vim text editor used
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within the instance. Select "default vim configuration" to grant
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read-only access to this information.
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:ROM (clipboard): defines the service to obtain clipboard content from.
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Select "themed wm" (not "global clipboard").
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:Report (clipboard): defines the service for reporting new clipboard content.
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Select "themed wm". More information about the integration and use of the
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clipboard can be found in
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[https://genodians.org/nfeske/2019-07-03-copy-paste - a dedicated article].
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:Region maps:
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Select "custom virtual memory objects" to allow the subsystem to manage
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its virtual memory layout by itself.
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With those decisions taken, a fresh system shell can be started, which appears
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in a window (Figure [sculpt_20_08_system_shell]).
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[image sculpt_20_08_system_shell 60%]
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When selecting the "system shell" component in the graph, the
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relationship to the other components of the system is presented. This provides
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a convenient way to reveal the _trusted computing base_ of the selected
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component (Figure [sculpt_20_08_system_shell_selected]).
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For example, since there is no connection from _system shell_ to the
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_nic_router_, we know that this component is isolated from the network. The
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network-related components are outside the trusted computing base of the
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system shell.
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[image sculpt_20_08_system_shell_selected 50%]
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Further exploration
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-------------------
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Of course, there are many more components to explore and to combine.
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For inspiration, please follow the postings at
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[https://genodians.org], for example:
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:Copy and paste mechanism:
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Sculpt provides a built-in mechanism for exchanging data between
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virtual machines, terminals, and Qt applications:
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[https://genodians.org/nfeske/2019-07-03-copy-paste]
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:Use GNU/Linux inside a virtual machine on top of Sculpt:
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There is a ready-to-use package for downloading Debian for the use inside
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a virtual machine along with the ability to use VirtualBox guest
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additions:
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[https://genodians.org/jws/2019-07-08-download_debian-guest-additions-reloaded]
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For configuring and starting the virtual machine, you may find the
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following guides useful:
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[https://genodians.org/jschlatow/2022-10-27-fresh-vm-on-sculpt]
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[https://genodians.org/m-stein/2019-03-07-vm-with-sculpt-ce-preview]
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You may even go a step further by re-using an existing Linux installation
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inside VirtualBox on Sculpt:
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[https://genodians.org/jschlatow/2021-04-23-start-existing-linux-from-sculpt]
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:Disposable Firefox VMs:
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Use a minimalistic Tinycore-Linux system to run Firefox in memory without
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access to any persistent storage:
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[https://genodians.org/alex-ab/2019-03-06-disposal-browser-vm]
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:Advanced window management:
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Let Sculpt remember window positions across reboots, swap out window
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decorations on the fly, and have fun with manipulating the window layout
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directly via a textual interface.
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[https://genodians.org/nfeske/2020-03-27-window-management]
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:Encrypted file store:
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The file-vault package provides Sculpt users with an easy way to set
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up and use an encrypted file store using Genode's custom CBE block
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encrypter.
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[https://genodians.org/m-stein/2021-05-17-introducing-the-file-vault]
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:Network connectivity via LTE:
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The article describes several ways of using Genode's LTE modem driver
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as network uplink.
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[https://genodians.org/jschlatow/2021-07-21-mobile-network]
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Base system
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###########
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Unless customized, the Sculpt base system resides as a self-contained live
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operating system on a USB stick, not installed on disk. This has two
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advantages. First, it makes the update of the base system straight-forward
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and completely risk-free. Simply install the new version on a second USB
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stick. Should the new version cause any trouble, one can fall back to the
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original one by swapping the USB sticks. Second, it alleviates the need to
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install any boot-loader infrastructure on disk. In fact, one can use an
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entire disk as one file system without creating a partition table.
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_Note that Genode is not limited to booting from USB. It also supports_
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_the use of partitions. But for this guide, we keep things as simple as_
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_possible._
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System overview
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===============
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; Drivers | Leitzentrale | Runtime
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; subsystem | subsystem | subsystem
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; ---------------+--------------------+---------------
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; static part of the system
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; ----------------------------------------------------
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; microkernel / core
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[image sculpt_overview]
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System overview
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The Sculpt system consists of four parts living on top of the microkernel
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(Figure [sculpt_overview]).
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Static system
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-------------
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The first - static - part of the system is baked into the boot image. It
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contains components that must be shared by the upper - dynamic - parts and
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defines the relationships between the upper parts via a static policy that
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is fixed by the creator of the boot image (Figure [sculpt_static]).
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; Drivers | Leitzentrale | Runtime
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; --------------------------------------------------------
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; : :
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; Nitpicker Report : : ROM [global policy]
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; GUI server : : : :
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; v v v v
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; Report Config
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; FS FS
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[image sculpt_static]
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Detailed look at the static part of the system
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Besides a low-complexity GUI multiplexer called Nitpicker, the static
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system contains two in-memory file systems. The _config_ file system stores
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configuration data whereas the _report_ file system stores information
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reported by components. These file systems are invisible to regular
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components. Components obtain their configuration data from a (read-only
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memory) ROM service, and report their state to a (write-only) report
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service.
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At boot time, the config file system is pre-populated with information from
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the boot image. It stays in memory. Hence, after rebooting the system, any
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changes are gone.
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Drivers subsystem
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-----------------
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The drivers subsystem provides all the basic services needed to realize an
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interactive system scenario: a framebuffer driver for the graphical
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output, input drivers to obtain user input, and a block service to
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access a storage device. All other drivers like networking or audio drivers
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are not covered by the drivers subsystem. They will enter the picture at a
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later stage and will use the platform service and USB service to access
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device resources.
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; Framebuffer AHCI
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; Driver Driver
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; : \ / :
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; ACPI --- Platform ------- USB Driver : Dynamic :
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; discover driver -- PS/2 : : Manager : Init :
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; : : : : : :
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; : : : : : :
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; : Event : : :
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; : Filter : : :
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; : : : : :
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; : : : : :
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; (platform) (event) (USB) (framebuffer) (block)
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[image sculpt_20_08_drivers 80%]
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Services provided by the drivers subsystem
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As illustrated by Figure [sculpt_20_08_drivers], some drivers like the
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framebuffer driver live in a dynamically managed subsystem that depends on
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runtime discovery of the hardware by the so-called driver-manager component.
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Whenever an Intel graphics device is present, the Intel framebuffer driver
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is spawned. Otherwise, a generic VESA driver or a driver for a
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boot-time-initialized framebuffer is used.
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Several components of the drivers subsystem report their state. For example,
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when the Intel framebuffer is used, it reports the list of connectors present.
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Most importantly, the driver manager reports the available block devices.
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As user input may enter the system in multiple ways - most prominently PS/2
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and USB HID - the drivers subsystem contains a so-called event-filter
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component that merges these event streams and applies transformations like
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key remappings or mouse acceleration.
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Leitzentrale subsystem
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----------------------
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The Leitzentrale gives you - the user - full control over the config file
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system and the report file system. You are free to inspect and
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manipulate the system in any way you wish. The German term Leitzentrale
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refers to a control center that requires a certain degree of sophistication
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from the operator, which would be you. A typo at the wrong place may
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render your system temporarily inaccessible, eventually requiring a reboot.
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But don't be afraid. Since all manual changes performed in the Leitzentrale
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occur in memory only, you are not at risk of permanently bricking your machine.
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The Leitzentrale can be toggled at any time by pressing F12 and will be enabled
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right after boot. It presents itself with a minimalistic GUI for accessing
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the storage devices attached to your machine and for configuring your network
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connectivity. Most importantly, however, it allows the user to access the
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_config_ and _report_ file systems. Both file systems are readily accessible
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under the "Files" tab of the panel. The file browser allows you to traverse
|
|
directory hierarchies, inspect individual files, and edit files.
|
|
Alternatively to the "Files" tab, Sculpt 22.10 features a command-line
|
|
interface. To spawn this command-line interface, click on the "ram fs"
|
|
component in the graph and select "Inspect". In the panel, a third tab named
|
|
"Inspect" appears, which hosts the command-line interface
|
|
(Figure [sculpt_20_08_inspect_tab]).
|
|
|
|
[image sculpt_20_08_inspect_tab 60%]
|
|
|
|
The inspect tab hosts a small Unix-like runtime as user interface. Don't let
|
|
the presence of a Unix shell mislead you. Sculpt is not a Unix system. It
|
|
merely uses Unix-like subsystems as convenient tools for managing and editing
|
|
files. Within the inspect tab, you can interact with both the report and
|
|
config file systems using familiar commands such as the bash shell, a subset
|
|
of coreutils, and Vim.
|
|
|
|
_Note that the interactive inspect view is not bullet-proof. Should you get_
|
|
_stuck, you may re-spawn it at any time by toggling the "Inspect" button._
|
|
|
|
Besides the interactive shell, the Leitzentrale employs a simple viewer of the
|
|
most recent diagnostic log messages. You can toggle the log display via the
|
|
panel's log button. Each line of the log is prefixed by the label of the
|
|
originating component. For detailed analysis, the complete log is also
|
|
available at _report/log_ and can be browsed with Vim in the inspect window.
|
|
|
|
|
|
Tweaking and inspecting the system
|
|
==================================
|
|
|
|
The Leitzentrale subsystem empowers you to interactively inspect and tweak
|
|
the running system either by using the file browser hosted in the "Files"
|
|
tab or by using the command-line interface and the Vim text editor provided by
|
|
the "Inspect" tab.
|
|
|
|
|
|
Interactive file browser
|
|
------------------------
|
|
|
|
The "Files" tab of the panel switches the main screen area to a simple file
|
|
browser that lists all file systems available, in particular the _config_
|
|
and _report_ file systems (Figure [sculpt_21_03_files_tab]).
|
|
By toggling one of the file-system buttons, the
|
|
respective directory hierarchy can be browsed. When hovering a file, an "Edit"
|
|
or "View" button appears, which can be used to open the file in a text area
|
|
that appears on the right side of the file browser. The editor supports the
|
|
usual notepad-like motions, operations, and shortcuts (control-c for copy,
|
|
control-v for paste, control-s for save).
|
|
|
|
[image sculpt_21_03_files_tab 80%]
|
|
|
|
_Note that the file browser as the most recent addition to Sculpt does not_
|
|
_yet support file operations like the copying, renaming, or removal of_
|
|
_files. Also the editing of files with long lines or the browsing of_
|
|
_directories with many entries is not appropriately covered yet. As a_
|
|
_fallback when encountering these limitations, the current version of Sculpt_
|
|
_still features the Unix-based inspect tab, which can be activated by_
|
|
_toggling the "Inspect" button inside the USB or storage nodes of the_
|
|
_component graph._
|
|
|
|
|
|
Vim skills recommended for using the inspect tab
|
|
------------------------------------------------
|
|
|
|
With the "Inspect" button toggled for at least one file system, the inspect
|
|
tab leverages (a subset of) GNU coreutils, bash, and Vim as the user interface
|
|
for sculpting the system. If you are not yet familiar with using Vim, you may
|
|
take Sculpt as a welcome chance to get your toes wet. To enjoy the experience,
|
|
you should be comfortable with the following operations:
|
|
|
|
* Opening and navigating within a text file (moving the cursor,
|
|
using '/' to search),
|
|
* Using the insert mode to make modifications,
|
|
* Reverting accidental modifications ('u' undo),
|
|
* Saving a modified file (':w'),
|
|
* Opening a file in a secondary buffer (':e'),
|
|
* Switching between buffers (':bn' for next, ':bp' for previous),
|
|
* Copy and paste ('v' start selection, 'V' start line selection,
|
|
'y' remember selection, 'p' paste remembered selection),
|
|
* Exiting Vim (':x' save and exit, ':q!' discard changes).
|
|
|
|
|
|
Adjusting the user-input handling
|
|
---------------------------------
|
|
|
|
By default, Sculpt uses the US-English keyboard layout but it offers a few
|
|
alternative keyboard layouts like French and German in the settings menu at
|
|
the upper left corner. A change of this setting is reflected in the
|
|
_config/managed/event_filter_ file, which is the configuration for the
|
|
event-filter component mentioned in Section [System overview]. For tweaking
|
|
the input processing beyond the keyboard-layout setting, copy this file to
|
|
_config/event_filter_.
|
|
|
|
! inspect:/> cp /config/managed/event_filter /config/event_filter
|
|
|
|
With the _config/event_filter_ file in place, you may notice that the
|
|
keyboard-layout menu has vanished. This is because now you have taken over
|
|
manual control. (BTW, you can get the menu back at any time by removing the
|
|
file).
|
|
|
|
As a Vim user, you most likely want to remap the useless capslock key to
|
|
escape, don't you? You can accomplish this by editing your
|
|
_/config/event_filter_ file.
|
|
|
|
! inspect:/> vim /config/event_filter
|
|
|
|
To remap the capslock key to escape, change the following line
|
|
! <key name="KEY_CAPSLOCK" to="KEY_CAPSLOCK"/>
|
|
to
|
|
! <key name="KEY_CAPSLOCK" to="KEY_ESC"/>
|
|
|
|
After saving the file, a Vim user's life suddenly becomes much more pleasant.
|
|
|
|
[image event_filter 80%]
|
|
Filter chain for user-input events
|
|
|
|
Take the time to review the remaining parts of the event-filter
|
|
configuration. The nested configuration nodes define a hierarchy of
|
|
filters that are applied in the order from the inside to outside
|
|
(Figure [event_filter]). There are filters for merging events ('<merge>'),
|
|
remapping buttons and keys ('<remap>'), supplementing symbolic character
|
|
information ('<chargen>'), pointer acceleration ('<accelerate>'), and
|
|
emulating a scroll wheel by moving the pointer while pressing the middle
|
|
mouse button ('<button-scroll>').
|
|
|
|
|
|
Display settings
|
|
----------------
|
|
|
|
If you are running the Intel graphics driver, you can inspect the connected
|
|
displays and their supported resolutions by taking a look at the report at
|
|
_/report/drivers/dynamic/intel_fb_drv/connectors_. This report is updated
|
|
whenever a display is connected or disconnected. You can use this
|
|
information to enable or disable a display in the driver's configuration,
|
|
which you can find at _/config/fb_drv_.
|
|
|
|
For a quick test, change the attribute 'height="768"' to 'force_height="768"'
|
|
(you may modify 'width' analogously). When saving the file, the screen
|
|
real-estate will forcibly be limited to the specified size. This is helpful
|
|
during presentations where the projector has a lower resolution than the
|
|
laptop's internal display. By specifying the beamer's resolution, both the
|
|
laptop and the beamer show the same content.
|
|
|
|
|
|
Exploring the drivers and Leitzentrale subsystems
|
|
-------------------------------------------------
|
|
|
|
You can review the construction plan of the drivers subsystem by opening the
|
|
file _drivers_ at the config file system. In particular, it is interesting to
|
|
follow the '<route>' rules to see how the various components are connected.
|
|
But there is more. The configuration is live. It enables you to reconfigure
|
|
individual components on-the-fly. For example, search for the '<start>' node
|
|
of the PS/2 driver and add the attribute 'verbose_keyboard="yes"' to the
|
|
embedded '<config>' node. By saving the file, the changed configuration
|
|
becomes effective. Any key pressed or released on the PS/2 keyboard will
|
|
result in a log message on the right. You may revert this change (vim: 'u')
|
|
and save the original version of the file.
|
|
|
|
_Note that not all components are dynamically reconfigurable but many_
|
|
_modern ones - in particular the init component and most long-running_
|
|
_server components - are._
|
|
|
|
_It is possible to forcibly restart a component by adding a 'version'_
|
|
_attribute to the '<start>' node. Whenever the 'version' value is changed,_
|
|
_the component is re-spawned._
|
|
|
|
_The component-specific configuration options are documented in the README_
|
|
_files accompanying the respective components in the source tree._
|
|
|
|
Analogously to the drivers subsystem, you can find the construction plan
|
|
for the Leitzentrale subsystem at the file _leitzentrale_. Try out
|
|
the following tweaks:
|
|
|
|
* Change the transparency of the Leitzentrale by modifying the 'alpha'
|
|
attribute of the 'fader' component.
|
|
|
|
* Change the font size of the 'log_terminal' component from "10"
|
|
to "18".
|
|
|
|
You may also enjoy tinkering with the configuration of the Nitpicker GUI
|
|
server, which is located at the file _nitpicker_. For example, you
|
|
may change the background color or the labeling color of the "default"
|
|
domain.
|
|
|
|
|
|
System resources
|
|
================
|
|
|
|
Whenever adding a new component via the '+' menu, one has to define how to
|
|
connect the component with the rest of the system. It is important to know
|
|
what the presented options mean to take educated decisions.
|
|
|
|
[image sculpt_20_08_system_shell_routing 40%]
|
|
|
|
Each choice represents a connection to a system resource of a particular type.
|
|
Initially, the presented options are resources that are built-in into Sculpt's
|
|
base system. Once new components enter the picture, their services also appear
|
|
as options.
|
|
|
|
|
|
Resource type | Interface | Built-in options
|
|
----------------------------------------------------------------------------
|
|
----------------------------------------------------------------------------
|
|
Audio input | 'Audio_in' |
|
|
----------------------------------------------------------------------------
|
|
Audio output | 'Audio_out' |
|
|
----------------------------------------------------------------------------
|
|
Block device | 'Block' | direct block-device access
|
|
----------------------------------------------------------------------------
|
|
Capture | 'Capture' | system GUI
|
|
----------------------------------------------------------------------------
|
|
| | management GUI
|
|
----------------------------------------------------------------------------
|
|
Device access | 'Platform' | wifi hardware
|
|
----------------------------------------------------------------------------
|
|
| | network hardware
|
|
----------------------------------------------------------------------------
|
|
| | audio hardware
|
|
----------------------------------------------------------------------------
|
|
| | ACPI
|
|
----------------------------------------------------------------------------
|
|
Direct memory-mapped I/O | 'IO_MEM' | raw hardware access
|
|
----------------------------------------------------------------------------
|
|
Direct port I/O | 'IO_PORT' | raw hardware access
|
|
----------------------------------------------------------------------------
|
|
Direct device interrupts | 'IRQ' | raw hardware access
|
|
----------------------------------------------------------------------------
|
|
Event | 'Event' | system input events
|
|
----------------------------------------------------------------------------
|
|
| | management GUI events
|
|
----------------------------------------------------------------------------
|
|
File system | 'File_system' | writeable system configuration
|
|
----------------------------------------------------------------------------
|
|
| | read-only system reports
|
|
----------------------------------------------------------------------------
|
|
| | used file system
|
|
----------------------------------------------------------------------------
|
|
GPU | 'Gpu' | hardware-accelerated graphics
|
|
----------------------------------------------------------------------------
|
|
GUI | 'Gui' | keyboard focus
|
|
----------------------------------------------------------------------------
|
|
| | desktop lock screen
|
|
----------------------------------------------------------------------------
|
|
| | desktop background
|
|
----------------------------------------------------------------------------
|
|
| | system GUI server
|
|
----------------------------------------------------------------------------
|
|
Hardware virtualization | 'VM' | virtualization hardware
|
|
----------------------------------------------------------------------------
|
|
Network | 'Nic' |
|
|
----------------------------------------------------------------------------
|
|
Network uplink | 'Uplink' |
|
|
----------------------------------------------------------------------------
|
|
Protection domain | 'PD' | system PD service
|
|
----------------------------------------------------------------------------
|
|
Real-time clock | 'Rtc' |
|
|
----------------------------------------------------------------------------
|
|
Region maps | 'RM' | custom virtual memory objects
|
|
----------------------------------------------------------------------------
|
|
Report | 'Report' | system reports
|
|
----------------------------------------------------------------------------
|
|
| | pointer shape
|
|
----------------------------------------------------------------------------
|
|
| | global clipboard
|
|
----------------------------------------------------------------------------
|
|
ROM | 'ROM' | global capslock state
|
|
----------------------------------------------------------------------------
|
|
| | default vim configuration
|
|
----------------------------------------------------------------------------
|
|
| | system font configuration
|
|
----------------------------------------------------------------------------
|
|
| | platform information
|
|
----------------------------------------------------------------------------
|
|
| | system status
|
|
----------------------------------------------------------------------------
|
|
| | global clipboard
|
|
----------------------------------------------------------------------------
|
|
Terminal | 'Terminal' |
|
|
----------------------------------------------------------------------------
|
|
Tracing | 'TRACE' | system-global tracing
|
|
----------------------------------------------------------------------------
|
|
USB | 'Usb' | direct USB-device access
|
|
|
|
|
|
|
|
[table resources]
|
|
Overview of system resources
|
|
|
|
Table [resources] gives an overview of the different built-in
|
|
resources and their types. The names given in the interface column correspond
|
|
to the Genode session types as found in the routing rules of the deploy
|
|
configuration or launcher definitions (Section [Runtime management]).
|
|
Let's look into each type in more detail.
|
|
|
|
|
|
GUI
|
|
~~~
|
|
|
|
The GUI service interface is provided by the low-level system GUI server
|
|
(named Nitpicker) as well as the higher-level window manager. It entails both
|
|
the ability to perform graphical output and the reception of user input. Note
|
|
that the low-level GUI server keeps its client applications isolated by
|
|
default. One application cannot see the output of other applications nor can
|
|
it sniff user input globally. One can connect multiple applications -
|
|
trusted and untrusted alike - to the low-level GUI server without fear.
|
|
|
|
However, in typical scenarios, applications don't use the bare-bone system GUI
|
|
server directly but rather employ a window manager that sits in-between the
|
|
system GUI server and the applications, and equips the system with the
|
|
notion of windows.
|
|
|
|
The base system provides three different GUI options.
|
|
|
|
:keyboard focus: grants control over the keyboard focus. It should be
|
|
assigned to only one component, typically a window manager. However,
|
|
in principle, another component like the _system shell_ can be connected
|
|
to it and thereby becomes able to receive keyboard input.
|
|
|
|
:desktop lock screen: assigns the component the role of a lock screen. Once
|
|
the component is present at the GUI, it seizes the keyboard focus and is
|
|
able to cover the entire screen.
|
|
|
|
_Note that - with the current version of Sculpt - global keys as defined in_
|
|
_the nitpicker configuration are not affected by the lock screen, i.e.,_
|
|
_as is the case with the screen key assigned to the window manager._
|
|
|
|
:desktop background: allows a component to present its graphical output
|
|
in a dedicated layer behind all other applications. The desktop background
|
|
cannot receive keyboard focus. But it can respond to pointer events
|
|
(mouse clicks and motion).
|
|
|
|
:system GUI server: allows a component to perform graphical output and
|
|
handle pointer events, but no keyboard input. It is designated as a
|
|
base mechanism for the window manager, or for implementing GUI features
|
|
like global overlays or status displays.
|
|
|
|
By the way, the configuration of the low-level GUI server can be found at
|
|
_/config/nitpicker_ and can be modified on the fly.
|
|
|
|
|
|
ROM
|
|
~~~
|
|
|
|
ROM stands for read-only memory. A ROM service reveals information to
|
|
its clients but a client cannot change the information. Note that the
|
|
provided information does not need to be static. It can potentially
|
|
change over time. Whenever that happens, the ROM service informs its
|
|
clients about the availability of a new version. The base system provides
|
|
the following built-in ROM resources:
|
|
|
|
:global capslock state: the system-global state of the capslock key.
|
|
It can be handed out to components like virtual machines to keep the
|
|
capslock state of guest operation systems consistent with the host.
|
|
|
|
:default vim configuration: the configuration of the Vim text
|
|
editor as used in the Leitzentrale's inspect window and managed at
|
|
_/config/vimrc_. It allows you to customize one vim configuration at a
|
|
central place and use this configuration consistently across Sculpt's
|
|
inspect window and manually deployed components.
|
|
|
|
:system font configuration: is the default font configuration managed
|
|
by Sculpt according to the current screen resolution. It is of course
|
|
customizable by the user. By using this configuration, components can
|
|
foster a consistent user experience regarding the display of text.
|
|
|
|
:platform information: provides details about the underlying kernel and
|
|
hardware. Some drivers and virtual machine monitors need this information to
|
|
take platform intrinsics like the concrete flavor of virtualization hardware
|
|
into account. Normal applications should never need this information.
|
|
|
|
:system status: reflects the system-global power state. It is used by the
|
|
optional ACPICA driver to respond to requests for a system reset or
|
|
power-down.
|
|
|
|
:global clipboard: provides the current content of the global clipboard.
|
|
The content can be accessed by a component only when the user interacts
|
|
with the component. This prevents overly nosey components from snooping the
|
|
clipboard content.
|
|
|
|
|
|
Report
|
|
~~~~~~
|
|
|
|
Report services play the counterpart of ROM services. They allow clients
|
|
to report information in a fire-and-forget fashion, but not to retrieve
|
|
information. As explained in Section [System overview], the base system
|
|
includes a report service that aggregates incoming reports into the in-memory
|
|
report file system. The incoming reports are organized according to their
|
|
origin (their session labels). By granting a component access to the _system_
|
|
_reports_, the component can contribute to this knowledge base. However,
|
|
keep in mind that Sculpt's built-in report file system is limited in size.
|
|
A misbehaving component may put the system in jeopardy by producing overly
|
|
sized reports.
|
|
|
|
:pointer shape: Reports labeled with 'shape' play a special role.
|
|
They are routed to the mouse pointer and thereby enable graphical
|
|
applications to suggest context-specific pointer shapes. The
|
|
application-provided shape is shown whenever the corresponding application
|
|
is hovered.
|
|
|
|
:global clipboard: enables components to write new content to the
|
|
system-global clipboard. This operation, however, is restricted to the
|
|
single component that the user currently interacts with. This prevents
|
|
rogue components from spamming the global clipboard.
|
|
|
|
|
|
File system
|
|
~~~~~~~~~~~
|
|
|
|
A file-system service offers the storage and retrieval of data organized in
|
|
a hierarchical directory structure. Access to a file system can be restricted
|
|
to be read only. The distinction between read-only and read-writeable does
|
|
not exist per file but for the entire file-system resource.
|
|
|
|
Of course, many use cases call for finer-grained access control. This is
|
|
where intermediate _chroot_ file-system components come into play. Such
|
|
a component reduces the view on an existing file system to a specific
|
|
sub directory, which then appears as a new file system to the application.
|
|
For examples, please review the launchers at _/config/launcher/_ such as the
|
|
_shared_fs_.
|
|
|
|
The Sculpt base system has two built-in file systems.
|
|
|
|
:writeable system configuration: corresponds to the config file system
|
|
described in Section [System overview]. The ability to access this file
|
|
system equals to total control over the system. Hence, never assign
|
|
this file system to components that you don't fully trust.
|
|
|
|
:read-only system reports: allows the client to inspect the global state of
|
|
the system. The reports found in this file system are organized in a
|
|
directory structure that corresponds to the system structure. For example,
|
|
all reports generated by the runtime sub system reside within the _runtime/_
|
|
directory. Note that this global state may contain sensible information.
|
|
For this reason, the system reports should not be handed out to components
|
|
that are suspected of information leakage.
|
|
|
|
The two built-in file systems reside in memory. In order to access persistent
|
|
storage, additional file-system services can be started as regular components
|
|
within the runtime subsystem. Those components, in turn, need to be connected
|
|
to the corresponding block devices.
|
|
|
|
:used file system: is the file system selected for the use of Sculpt.
|
|
In principle, the specific file system such as "usb-1-10.3.fs" can be
|
|
selected directly. But when moving configurations from one device to
|
|
another, the generic "used file system" option avoids tying the component to
|
|
a particular physical file-system name. The resulting configuration works
|
|
regardless of where it is deployed.
|
|
|
|
|
|
Block device
|
|
~~~~~~~~~~~~
|
|
|
|
A block-device resource allows for the block-level storage and retrieval
|
|
of data whereas a block-device can be read-only or read-writeable. The base
|
|
system's built-in block service hands out the devices listed at
|
|
_/report/drivers/block_devices_ according to the label of the client's session.
|
|
The label must correspond to the name of the block device. Typically, the
|
|
built-in block service is used via manually created launchers by using a route
|
|
like this:
|
|
|
|
! <route>
|
|
! <service name="Block"> <parent label="ahci-1"/> </service>
|
|
! </route>
|
|
|
|
|
|
Device access
|
|
~~~~~~~~~~~~~
|
|
|
|
With Sculpt, device drivers can be installed and used like any regular
|
|
component. In contrast to plain applications, however, device drivers need
|
|
to access the corresponding device hardware. This access is guarded by the
|
|
so-called platform driver hosted in the _drivers_ subsystem. The platform
|
|
driver has two purposes.
|
|
First, it uses the IOMMU to isolate devices from each other and to restrict
|
|
the reach of each device to the memory explicitly assigned to the device
|
|
(DMA buffers).
|
|
Second, it arbitrates the access of device-driver components to devices.
|
|
|
|
Regarding the latter, the platform driver differentiates four categories
|
|
of drivers, namely wifi, network, audio, and ACPI. When assigning one
|
|
of those resources to a driver component, the driver will see a virtual
|
|
PCI bus with only the devices that fall in the chosen category.
|
|
|
|
Note that USB, AHCI, NVMe, and PS/2 are handled differently as those
|
|
devices are driven by Sculpt's _drivers_ subsystem.
|
|
|
|
|
|
USB
|
|
~~~
|
|
|
|
By connecting a component to USB, the component becomes able to access
|
|
individual USB devices. The device is selected by the component by specifying
|
|
a session label that corresponds to a name of a device listed at
|
|
_/report/drivers/usb_devices_. The most prominent use case for the USB
|
|
resource is the direct assignment of USB devices to virtual machines
|
|
as described in Section
|
|
[Updating the USB boot device from within VirtualBox].
|
|
|
|
|
|
Real-time clock
|
|
~~~~~~~~~~~~~~~
|
|
|
|
The real-time clock enables a component to know what time it is. The service is
|
|
optionally provided by a package called system clock.
|
|
|
|
|
|
GPU
|
|
~~~
|
|
|
|
Access to the GPU (graphics processing unit) service allows a component to
|
|
utilize hardware-accelerated graphics on machines that feature a GPU supported
|
|
by Sculpt. Supported are Intel GPUs of generation 8 (Broadwell) or newer.
|
|
|
|
_Note that GPU support is a very recent feature and has thereby not_
|
|
_received intensive testing yet. Please regard it as experimental and_
|
|
_use it with caution._
|
|
|
|
|
|
Region maps
|
|
~~~~~~~~~~~
|
|
|
|
The region-map service of the base system gives components a flexible way to
|
|
manage their virtual address spaces manually. This mechanism is used by a few
|
|
advanced components only, most specifically virtual machine monitors. Access
|
|
to the region-map service is not security critical. But as it is rarely
|
|
needed, it is not granted by default to limit the potential (attack) surface
|
|
of the base system as far as possible by default.
|
|
|
|
|
|
Direct memory-mapped I/O, port I/O, and device interrupts
|
|
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
These low-level services are provided by Genode's core component. They
|
|
should never be needed by any regular component. Even device drivers
|
|
don't use those services directly but rather rely on the higher-level
|
|
device-access service described in Section [Device access].
|
|
|
|
However, a few special use cases demand for such low-level access. In
|
|
particular the use of ACPI functionality.
|
|
|
|
As a rule of thumb, never grant access of those resources to any component
|
|
except you know exactly what you are doing and you completely trust the
|
|
provider of the component.
|
|
|
|
|
|
Tracing
|
|
~~~~~~~
|
|
|
|
The low-level tracing interface allows a component to observe and to
|
|
manipulate all activities in the system. It should only be granted to
|
|
components that are fully trusted.
|
|
|
|
|
|
Hardware virtualization
|
|
~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
The hardware-virtualization service allows virtual machine monitors to
|
|
leverage virtualization technology (Intel VT).
|
|
|
|
|
|
Protection domain
|
|
~~~~~~~~~~~~~~~~~
|
|
|
|
By default, each component implicitly relies on the protection-domain (PD)
|
|
mechanism provided by the operating-system kernel. However, Sculpt OS allows
|
|
for the optional interception of a component's interplay with this low-level
|
|
mechanism through another component. This is useful for dynamic CPU-load
|
|
balancing, debugging, or statistical profiling.
|
|
|
|
The option to select a protection-domain service is only displayed in the
|
|
presence of at least one component that provides a PD service. Note that
|
|
a PD service is able to exercise full control over each component that uses
|
|
the service.
|
|
|
|
|
|
Network and uplink
|
|
~~~~~~~~~~~~~~~~~~
|
|
|
|
Network services provide an interface for sending and receiving network
|
|
packets. Sculpt's Leitzentrale conveniently manages drivers for wireless (wifi
|
|
drv) and wired (nic drv) networking as well as the user-level network routing
|
|
component (nic router). So you usually see the NIC router as an option. The
|
|
NIC router multiplexes the network access among multiple network applications.
|
|
By default, it acts as a virtual NAT router, handing out a distinct IP address
|
|
to each client.
|
|
|
|
An uplink server is a connection point of a network driver, which supplies
|
|
the driver with network packets to send, and accepts incoming packets received
|
|
by the driver. In most situations, the NIC router provides this service.
|
|
|
|
|
|
Terminal, audio input, and audio output
|
|
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
Terminal services allow for the input and output of streams of text. Examples
|
|
are a graphical terminal, or a UART driver. The base system has no built-in
|
|
terminal service.
|
|
|
|
As the names suggest, audio input and output enable components to record
|
|
and play audio. The base system does not provide such services. Instead,
|
|
audio infrastructure like drivers and a mixer can be installed as regular
|
|
components.
|
|
|
|
|
|
Capture and event
|
|
~~~~~~~~~~~~~~~~~
|
|
|
|
The capture and event interfaces serve as counter parts of the GUI interface.
|
|
Whereas the GUI interface allows a client to put pixels on screen and receive
|
|
input events, the capture and event interfaces allow a client to capture the
|
|
screen and inject user-input events into the system. Normally, these
|
|
interfaces are used by graphics and input-device drivers. However, they
|
|
are also useful for remote-desktop scenarios, virtual keyboards, or for
|
|
taking screen shots.
|
|
|
|
Note that those interfaces are _security critical_. When handing out a
|
|
capture interface to a component, the component becomes able to observe the
|
|
screen content of all applications present at the GUI server. Vice versa, by
|
|
handing out an event interface to a component, the component becomes able to
|
|
inject user-input events to the GUI server, acting on behalf of the user. The
|
|
built-in choices allow a component to be connected to either the system-global
|
|
GUI server, or specifically to the management GUI.
|
|
|
|
|
|
CPU-resource assignment
|
|
~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
[image sculpt_21_03_affinity 40%]
|
|
|
|
You may already have noticed the additional item "Resource assignment ..."
|
|
in the component-configuration dialog (Figure [sculpt_21_03_affinity]).
|
|
It leads to a sub menu for restricting the CPU usage of the new component. The
|
|
configuration dialog shows a matrix of CPU cores where the x-axis denotes the
|
|
physical cores and the y-axis the hyperthreads. By default, all available CPU
|
|
cores are selected. You can toggle the nodes by clicking on them. The dialog
|
|
ensures that the selection is always a rectangular area. So one click may
|
|
affect nodes other than only the clicked one.
|
|
|
|
Below the CPU-affinity matrix, the dialog allows for the selection of the
|
|
component's scheduling priority. Note that here the notion of priority refers
|
|
to hard static priorities as opposed to nice levels. That is, a high-priority
|
|
activity prevents all lower-level priorities from executing. Consequently, the
|
|
assignment of a high priority comes at the risk of starving lower-priority
|
|
components. The dialog presents four options:
|
|
|
|
:Driver:
|
|
|
|
The highest priority should be preserved to latency-critical device drivers
|
|
such as audio drivers. This option is also a sensible choice for trusted
|
|
components that must stay somewhat responsive under any condition. For
|
|
example, the components of the leitzentrale GUI operate on this priority to
|
|
preserve the user's control over the system even in the event of a rampaging
|
|
high-priority device driver.
|
|
|
|
:Multimedia:
|
|
|
|
The second-highest priority is recommended for latency-sensitive
|
|
applications such as audio and video players as well as their dependencies.
|
|
For example, it is the appropriate priority for window-management
|
|
components.
|
|
|
|
:Default:
|
|
|
|
The default priority is suitable for all regular applications as well as
|
|
storage and networking components.
|
|
|
|
:Background:
|
|
|
|
The lowest priority is designated for non-interactive best-effort workloads
|
|
such as long-running computations. By assigning the background priority to
|
|
such components, they won't impede the user's perception of the
|
|
responsiveness of the system.
|
|
|
|
|
|
Service-level sandboxing
|
|
========================
|
|
|
|
In order to deploy any component, all resources requested by the component must
|
|
be assigned to appropriate services. For example, when adding a web browser,
|
|
the browser's request for audio-in/out session must be satisfied, which is
|
|
natural when consuming multimedia content. However, in other situations, we
|
|
may deliberately want to isolate the web browser from the audio hardware,
|
|
forcibly preventing the browser from producing any noise or tapping the
|
|
microphone.
|
|
|
|
This is where the so-called "black hole" component enters the picture,
|
|
which can readily be deployed from the package _genodelabs_ -> _Tools_ ->
|
|
_black hole_. The black-hole component provides pseudo services for most
|
|
resources mentioned in the previous section, including audio, networking,
|
|
video capture, USB, and ROM. Hence, the resource requirements of an untrusted
|
|
component can be satisfied without exposing a real resource. This is
|
|
especially useful for deploying highly flexible components like VirtualBox,
|
|
which supports many host-guest integration features, most of which are
|
|
desired only in a few scenarios. For example, to shield a virtual machine from
|
|
the network, the "Network" resource of the VirtualBox instance can simply
|
|
be assigned to the "black hole".
|
|
|
|
|
|
Runtime management
|
|
==================
|
|
|
|
[image sculpt_runtime_highlighted]
|
|
|
|
In contrast to the drivers subsystem and the Leitzentrale, which have a
|
|
predefined purpose, the runtime subsystem is shaped by the user. The
|
|
components present in the runtime subsystem are displayed by the components view.
|
|
Some of them are managed by the Leitzentrale. For example, while inspecting a
|
|
file system, the corresponding "inspect" component appear automatically. Other
|
|
components correspond to subsystems deployed from installed packages, in
|
|
particular the ones created via the "+" menu.
|
|
|
|
The current configuration of the runtime subsystem is available at the
|
|
_config_ file system at _managed/runtime_. It is not recommended to modify
|
|
this file manually. However, in some situations, it is useful to take manual
|
|
control over the runtime configuration. This is possible by copying the file
|
|
to the root of the config file system.
|
|
Note that this will inhibit the management functionality of the Leitzentrale.
|
|
You can yield back the control to the Leitzentrale by removing the _runtime_
|
|
file from the root of the config file system.
|
|
|
|
As a prerequisite for deploying user-selected components, a default storage
|
|
location must be defined by selecting the "Use" button of a file system
|
|
in the menu. For the start, it is best to select the "ram" file system as
|
|
storage location. Once you are comfortable with Sculpt, you may make the
|
|
installation and customizations permanent by using a real storage device
|
|
instead.
|
|
|
|
The selection of a "used" file system has two immediate effects. First, any
|
|
files present at _config/<VERSION>/_ at the selected file system are copied to
|
|
the config file system. As the RAM file system is empty, no files are copied.
|
|
Second, the so-called _depot/_ is initialized at the selected file system. The
|
|
depot is the designated place for the installation of software packages. By
|
|
default, the depot is initialized such that the Sculpt system accepts software
|
|
from Genode Labs as well as from a few members of the Genode community. You
|
|
may inspect the content of _/ram/depot_ using the inspect window.
|
|
|
|
With a file system and an Internet connection selected, additional software
|
|
can be installed and run. The most convenient way is the interactive use of
|
|
the '+' menu to browse the catalogues of packages provided by software
|
|
providers and to configure new component instances.
|
|
|
|
Additionally, the deployment can be controlled by the _deploy_ file of the
|
|
_config_ file system and the so-called launchers located at the _launcher/_
|
|
sub directory.
|
|
The _deploy_ file contains a '<start>' node for each running component.
|
|
Such a <start> node specifies the package, the assigned resources,
|
|
and the rules of how the component is connected with other components.
|
|
|
|
Alternatively, a <start> node may refer to a launcher that encapsulates
|
|
this policy as a separate file at the _launcher/_ directory.
|
|
By default, the launcher corresponds to the 'name' attribute of the start node.
|
|
It is possible to explicitly refer to a differently named launcher by
|
|
specifying a 'launcher' attribute. This way, one launcher can be instantiated
|
|
multiple times.
|
|
The files within the _launcher/_ directory are monitored by Sculpt and
|
|
therefore can be edited on the fly. This is especially useful for editing
|
|
'<config>' nodes of already running components.
|
|
A '<config>' node within a launcher - when present - overrides the one
|
|
provided by the package. In turn, a '<config>' node within a node of the
|
|
deploy config overrides any other '<config>' node. Both the launcher and a
|
|
'<start>' node may contain a '<route>' node. The routing rules defined in the
|
|
'<start>' node have precedence over the ones defined by the launcher. This
|
|
way, the routing of a launcher can be parameterized at the deploy
|
|
configuration.
|
|
|
|
Each time the _deploy_ file or a launcher file is written, the change
|
|
takes immediate effect. In particular, the Sculpt manager will automatically
|
|
kick off the download of the referenced packages and its dependencies and
|
|
thereby populates the depot. Once the download has completed, the packages are
|
|
started.
|
|
|
|
|
|
Interplay of the deploy configuration and interactive changes
|
|
-------------------------------------------------------------
|
|
|
|
The content of the _deploy_ file is taken as the starting point for the
|
|
interactive use via the '+' menu. All interactive changes to the deployment
|
|
are reflected in the _managed/deploy_ file.
|
|
Note that any modification of _deploy_ resets _managed/deploy_ to the state
|
|
defined in the _deploy_ file.
|
|
|
|
Launchers appear at the top level of the '+' menu. So they are a convenient
|
|
mechanism to quickly add often-used components with specific policies to the
|
|
system.
|
|
|
|
|
|
Storage device access and preparation
|
|
=====================================
|
|
|
|
Whereas the RAM file system is practical for quick tests, it goes without
|
|
saying that we want to persistently store data, programs, and configuration
|
|
information on a storage device. Sculpt supports SATA disks, NVMe devices,
|
|
and USB-storage devices. The storage and USB nodes of the components view list
|
|
all devices detected by the drivers subsystem. A click on a device reveals
|
|
possible operations or - if a partition table is present - more details about
|
|
the device structure.
|
|
|
|
Depending on the operation selected by the user, the Sculpt manager will
|
|
automatically spawn helper components in the runtime to perform the selected
|
|
operation.
|
|
For example, by selecting the "Format device" operation, the Sculpt manager
|
|
will create a tiny Unix-like subsystem with the selected block device mounted at
|
|
'/dev/block' and e2fsprogs mounted at '/'. This Unix-like subsystem runs
|
|
'mkfs.ext2' as init process. Likewise, an existing EXT2 file system
|
|
can be checked by activating the "Check" button, which triggers the execution
|
|
of 'fsck.ext2' for the selected file system.
|
|
|
|
A particularly interesting option is presented at the last partition of the
|
|
Sculpt USB stick. Initially - right after copying Sculpt's tiny disk image to
|
|
the USB stick - the partition is only a few MiB in size. However, using the
|
|
"Expand" operation, the partition can be extended to the full size of the USB
|
|
stick, which makes enough room to use the USB stick as Sculpt file system.
|
|
This clears the way for sculpting a custom live system stored entirely on
|
|
the USB stick.
|
|
|
|
All file systems supported by Sculpt present an "Inspect" button. By toggling
|
|
this button, the selected file system becomes accessible in the "Inspect"
|
|
tab. Note that more than one file system can be inspected at a time.
|
|
Each file system will appear as a directory at the root of the inspect
|
|
directory tree, named after the corresponding device and partition number.
|
|
This way, the inspect window becomes a convenient tool for copying files
|
|
between file systems. Under the hood, the Sculpt manager spawns a file-system
|
|
component for each inspected file system, which translates the notion of files
|
|
and directories to block-device accesses.
|
|
|
|
|
|
Making customizations permanent
|
|
===============================
|
|
|
|
It is possible to make any customization of the _config_ file system
|
|
permanent by copying the modified files to a directory named
|
|
_config/<VERSION>_ on a persistent file system where _<VERSION>_ corresponds
|
|
to the Sculpt version number as found in the _/VERSION_ file.
|
|
Each time this file system is selected for "Use", those files will be
|
|
automatically copied to the in-memory config file system.
|
|
|
|
The most important customization is the system composition, usually created
|
|
via the '+' menu. To make it permanent, copy the current state of
|
|
_/config/managed/deploy_ to _/<DISK>/config/<VERSION>/deploy_ where _<DISK>_
|
|
corresponds to your Sculpt partition. This deploy configuration will take
|
|
effect whenever the Sculpt partition is selected for "Use".
|
|
|
|
To streamline the boot procedure into a customized Sculpt system even more,
|
|
it is possible to mark one file system as default. At boot time - when the
|
|
Sculpt manager discovers the attached storage devices - it automatically
|
|
selects a file system for use according to the following order of preference:
|
|
|
|
# Partition named "GENODE*" on a USB device in a GPT (GUID Partition Table),
|
|
# Partition named "GENODE*" on a SATA or NVMe storage device in a GPT,
|
|
# An entire SATA or NVMe device used as a single EXT2 file system (as devised
|
|
by Sculpt EA).
|
|
|
|
The storage dialog hosts a convenient "Default" button that allows one
|
|
to toggle a partition label between "GENODE" and "GENODE*". For example,
|
|
the last partition of the Sculpt USB stick can be marked as default or
|
|
non-default using this button.
|
|
|
|
|
|
Advanced usage
|
|
##############
|
|
|
|
Manual configuration
|
|
====================
|
|
|
|
Thanks to the Sculpt-manager component of the Leitzentrale, many typical
|
|
work flows and configuration tweaks are largely automated. For example,
|
|
|
|
* The management of storage devices,
|
|
* The creation of file-system components for used or inspected file systems,
|
|
* The selection and configuration of network access,
|
|
* Font size selection depending on the screen resolution,
|
|
* Keyboard-layout selection, or
|
|
* Triggering the download of missing depot content on demand.
|
|
|
|
This convenience comes at the price of built-in policy, which may stand in
|
|
the way of sophisticated scenarios. For this reason, almost all policies
|
|
of the Sculpt manager can be overridden by manually managed configuration
|
|
files.
|
|
|
|
The Sculpt manager interacts with the rest of the system solely by
|
|
monitoring reports aggregated in the report file system, and writing
|
|
configuration files into the config file system. All files generated
|
|
by the Sculpt manager are located at the _managed/_ sub directory of the
|
|
config file system. By manually creating a same-named file at the root of the
|
|
config file system, one can supply a custom managed configuration to the
|
|
Sculpt manager. A useful practice is taking a snapshot of the generated
|
|
configuration as a starting point for the custom version. For example, by
|
|
copying the NIC router configuration while it is connected to a network:
|
|
|
|
! cp /config/managed/nic_router /config
|
|
|
|
Now, the copy at _/config/nic_router_ can be edited. Note that changes
|
|
usually take immediate effect.
|
|
|
|
Examples of manual customization are:
|
|
* Adding custom NIC router policies such as port-forwarding rules,
|
|
* Installing depot content manually by managing _/config/installation_
|
|
by hand. This includes the ability to download the source code for
|
|
any package.
|
|
* Disarming the automated update mechanism by using a _/config/installation_
|
|
file with no '<archive>' entries.
|
|
* Fixing the current state of the runtime subsystem by copying
|
|
_/config/managed/runtime_ to _/config/runtime_. This allows one to
|
|
manually tweak and inspect the runtime in any way, e.g., to enable
|
|
additional reporting when troubleshooting.
|
|
* Manually defining the default font sizes by creating a custom _config/fonts_
|
|
configuration.
|
|
* Managing Wifi credentials manually by supplying a custom _config/wifi_ file.
|
|
|
|
To revert any manual customization, delete the corresponding file. In this
|
|
case, the Sculpt manager will take over again. Note that all manual
|
|
customizations can be made permanent by following the steps explained in
|
|
Section [Making customizations permanent].
|
|
|
|
|
|
Building the boot image
|
|
=======================
|
|
|
|
The following steps assume that you have the Genode tool chain installed on a
|
|
GNU/Linux system. For reference, Ubuntu LTS is known to work well. If you
|
|
don't know your way around Genode's source tree yet, please consider the
|
|
"Getting started" section of the Genode Foundations book that is available as
|
|
a free download at [https://genode.org].
|
|
|
|
# Clone Genode's Git repository:
|
|
|
|
! git clone https://github.com/genodelabs/genode.git
|
|
! cd genode
|
|
! git checkout -b sculpt-22.10 sculpt-22.10
|
|
|
|
# Download the support for the NOVA microkernel
|
|
|
|
! ./tool/depot/download genodelabs/bin/x86_64/base-nova/2022-10-11
|
|
|
|
The content is downloaded to the _public/_ directory and extracted to
|
|
the _depot/_ directory.
|
|
|
|
# Download all ingredients for the Sculpt boot image
|
|
|
|
! ./tool/depot/download \
|
|
! genodelabs/pkg/x86_64/sculpt/2022-10-13 \
|
|
! genodelabs/pkg/x86_64/drivers_managed-pc/2022-10-11 \
|
|
! genodelabs/pkg/x86_64/wifi/2022-10-13 \
|
|
! genodelabs/bin/x86_64/ipxe_nic_drv/2022-10-11
|
|
|
|
# Create a build directory
|
|
|
|
! ./tool/create_builddir x86_64
|
|
|
|
# Configure the build directory by editing _build/x86_64/etc/build.conf_.
|
|
Most importantly, enable the 'gems' source-code repository where the Sculpt
|
|
scenario resides. In addition, the 'libports', 'ports', 'pc', 'dde_linux',
|
|
'dde_rump', and 'dde_ipxe' repositories are needed as well.
|
|
Second, change the default configuration of the 'QEMU_RUN_OPT' variable to
|
|
'image/disk' instead of 'image/iso'. This way, the build process will
|
|
produce a valid disk image with a GPT partition table instead of a legacy
|
|
ISO image.
|
|
|
|
# Prepare GRUB 2, which is needed for booting from the disk image
|
|
|
|
! ./tool/ports/prepare_port grub2
|
|
|
|
# Create the Sculpt boot image (defined by the run script at
|
|
_repos/gems/run/sculpt.run_)
|
|
|
|
! make -C build/x86_64 run/sculpt KERNEL=nova BOARD=pc
|
|
|
|
The boot image is created at _build/x86_64/var/run/sculpt.img_.
|
|
|
|
# Write the boot image to a USB stick:
|
|
|
|
! sudo dd if=build/x86_64/var/run/sculpt.img of=/dev/sdx bs=1M conv=fsync
|
|
|
|
Here, '/dev/sdx' refers to the device node of your USB stick. To determine
|
|
it, you may inspect the output of 'dmesg' after plugging it in.
|
|
|
|
|
|
Reproducing the system from source
|
|
==================================
|
|
|
|
Section [Building the boot image] presents the creation of the boot image
|
|
from pre-built packages. You may prefer to build those packages from source,
|
|
in particular for customizing the system.
|
|
|
|
Before building the packages, various ports of 3rd-party software need to
|
|
be prepared. The following command prepares all of them at once:
|
|
|
|
! <GENODE-DIR>/tool/ports/prepare_port \
|
|
! acpica ada-runtime bash cbe coreutils curl \
|
|
! dde_bsd dde_ipxe dde_linux dde_rump e2fsprogs-lib \
|
|
! expat freetype gnupg grub2 jitterentropy jpeg \
|
|
! libarchive libc libdrm libgcrypt libiconv libnl libpng \
|
|
! libsparkcrypto libssh libusb libyuv libuvc linux \
|
|
! linux-firmware mesa ncurses nova openssl qemu-usb \
|
|
! qoost qt5 stb stdcxx ttf-bitstream-vera vim \
|
|
! virtualbox6 wpa_supplicant x86emu xz zlib
|
|
|
|
To be able to compile components that are dependent on the Qt5-library, the
|
|
corresponding toolchain needs to be installed in addition to the base Genode
|
|
toolchain. You can build and install it by using the following commands:
|
|
|
|
! <GENODE-DIR>/tool/tool_chain_qt5 build
|
|
! <GENODE-DIR>/tool/tool_chain_qt5 install
|
|
|
|
The ingredients of the boot image are defined by the _sculpt/default-pc.sculpt_
|
|
file located in the _repos/gems/_ repository. The default set of software
|
|
installable at runtime is subsumed by the 'pkg/sculpt_distribution' and
|
|
'pkg/sculpt_distribution-pc' packages. You can find the depot recipes for these
|
|
packages at _repos/gems/recipes/pkg/_. You may want to create your version of
|
|
these packages by changing the package provider from 'genodelabs' to '<YOU>' by
|
|
adding the line
|
|
|
|
! RUN_OPT += --depot-user <YOU>
|
|
|
|
to your _<build-dir>/etc/build.conf_.
|
|
|
|
To build the boot image including all required depot packages, it's best to
|
|
instruct the build system to manage the versioning and updating of the depot
|
|
content automatically by enabling the following line in your _build.conf_
|
|
file.
|
|
|
|
! RUN_OPT += --depot-auto-update
|
|
|
|
With these precautions taken, the execution of the _sculpt.run_ script - as
|
|
described in Section [Building the boot image] - implicitly builds all required
|
|
binary packages from source.
|
|
|
|
The 'sculpt_distribution' and 'sculpt_distribution-pc' packages can be
|
|
created independently from the _sculpt.run_ script by using the 'depot/create'
|
|
tool manually.
|
|
|
|
! <GENODE-DIR>/tool/depot/create \
|
|
! UPDATE_VERSIONS=1 FORCE=1 REBUILD= \
|
|
! <YOU>/pkg/x86_64/sculpt_distribution \
|
|
! <YOU>/pkg/x86_64/sculpt_distribution-pc
|
|
|
|
The 'FORCE=1' argument ensures that source archives are re-created and
|
|
checked for the consistency with their versions. Whenever the source code of any
|
|
of the archives changes, the 'UPDATE_VERSIONS=1' argument automatically
|
|
updates its version. Please don't forget to commit the updated 'hash'
|
|
files. The empty 'REBUILD=' argument limits the creation of binary packages
|
|
to those that do not yet exist in binary form. If not specified, the
|
|
command would recompile all packages each time. You may further add '-j<N>'
|
|
to parallelize the build process where '<N>' is the level of parallelism.
|
|
|
|
To make the created packages available for download from within the running
|
|
Sculpt system, you must publish them. This involves the archiving, signing, and
|
|
uploading of the content. The former two steps are covered by the
|
|
_tool/depot/publish_current_ tool. For more information about working with the
|
|
depot tool, refer to the package-management
|
|
[https://genode.org/documentation/developer-resources/package_management - documentation].
|
|
|
|
The launchers integrated in the boot image are defined in
|
|
_gems/sculpt/default-pc.sculpt_ and the accompanied files at
|
|
_gems/sculpt/launcher/_. Each launcher contains a node with a mandatory 'pkg'
|
|
attribute. If the attribute value contains one or more '/' characters, it is
|
|
assumed to be a complete pkg path of the form '<USER>/pkg/<NAME>/<VERSION>'.
|
|
Otherwise it is assumed to be just the pkg name and is replaced by the current
|
|
version of the current depot user's pkg at system-integration time.
|
|
|
|
|
|
Updating the USB boot device from within VirtualBox
|
|
===================================================
|
|
|
|
The _/config/deploy_ example is prepared to assign USB storage
|
|
devices directly to a running virtual machine. You may inspect the report
|
|
_/report/drivers/usb_devices_ to get a list of attached USB devices.
|
|
Use Vim to copy the '<device>' node of the selected device into the
|
|
'<inline>' section within the _/config/launcher/usb_devices_rom_ file.
|
|
|
|
The updated 'usb_devices' ROM prompts VirtualBox to open a USB session at
|
|
the drivers subsystem. Hence, when saving the modified
|
|
_/config/launcher/usb_devices_rom_ file, the guest OS should detect a new USB
|
|
device (check the output of 'dmesg'). You may now write a new version of the
|
|
Sculpt ISO image to the device by following the steps described in Section
|
|
[Building the boot image].
|
|
|
|
Alternatively, to update a USB storage device that already has Sculpt OS
|
|
installed to a new version built manually via the steps described in
|
|
Section [Building the boot image], you may prefer to replace the files at the
|
|
_boot/_ directory of the "GENODE" partition of the USB device by the content of
|
|
the freshly built _var/run/sculpt/boot/_ directory as found in the build
|
|
directory after executing the 'make run/sculpt' step.
|
|
Make sure to copy the files 'hypervisor' (microkernel) and 'image.elf.gz'
|
|
(system image of the Sculpt base system).
|
|
By backing up your previous _boot/_ directory, you can conveniently roll back
|
|
the Sculpt system to the previous version by restoring the original _boot/_
|
|
content.
|
|
|
|
|
|
Credits
|
|
#######
|
|
|
|
Sculpt is an example system scenario of the Genode project, which is an
|
|
operating-system technology designed and developed from scratch.
|
|
|
|
:Genode OS Framework:
|
|
[https://genode.org]
|
|
|
|
That said, Genode is not developed in a vacuum. It greatly benefits from the
|
|
free-software/open-source community. The following projects play a particularly
|
|
important role for Sculpt OS.
|
|
|
|
:NOVA microhypervisor:
|
|
|
|
Sculpt's kernel is a derivate of NOVA, maintained by Genode Labs.
|
|
NOVA was originally created by Udo Steinberg [https://hypervisor.org].
|
|
|
|
:Linux kernel:
|
|
[https://kernel.org]
|
|
|
|
Sculpt reuses several Linux subsystems as individual components, in
|
|
particular the USB stack, the Intel wireless stack, the Intel graphics
|
|
driver, and the TCP/IP stack.
|
|
|
|
:NetBSD's rump kernel:
|
|
[https://wiki.netbsd.org/rumpkernel/]
|
|
|
|
The file-system support is based on NetBSD kernel code, which became
|
|
reusable on Genode thanks to the rump kernel project.
|
|
|
|
:FreeBSD:
|
|
[https://www.freebsd.org/]
|
|
|
|
The C runtime that is used by most 3rd-part software is based on FreeBSD's
|
|
libc.
|
|
|
|
|
|
Device drivers
|
|
--------------
|
|
|
|
:WPA supplicant:
|
|
[https://w1.fi/wpa_supplicant/]
|
|
_(used by the wireless driver)_
|
|
|
|
:iPXE:
|
|
[https://ipxe.org]
|
|
_(basis of the wired network driver)_
|
|
|
|
:xf86emu:
|
|
[https://xorg.freedesktop.org/]
|
|
_(used by the VESA driver)_
|
|
|
|
:OpenBSD:
|
|
[https://www.openbsd.org]
|
|
_(basis for the audio driver)_
|
|
|
|
:libusb:
|
|
[https://libusb.info]
|
|
_(used by the webcam driver)_
|
|
|
|
:libuvc:
|
|
[https://ken.tossell.net/libuvc/doc/]
|
|
_(used by the webcam driver)_
|
|
|
|
|
|
Programs and libraries used within the Unix-like subsystems
|
|
-----------------------------------------------------------
|
|
|
|
:Vim:
|
|
[https://www.vim.org]
|
|
|
|
:ncurses:
|
|
[https://www.gnu.org/software/ncurses/ncurses.html]
|
|
|
|
:GNU coreutils:
|
|
[https://www.gnu.org/software/coreutils/coreutils.html]
|
|
|
|
:GNU bash:
|
|
[https://www.gnu.org/software/bash/]
|
|
|
|
:E2fsprogs:
|
|
[http://e2fsprogs.sourceforge.net/]
|
|
|
|
|
|
Libraries used for the package-management infrastructure
|
|
--------------------------------------------------------
|
|
|
|
:curl:
|
|
[https://curl.haxx.se]
|
|
_(basis of the fetchurl tool)_
|
|
|
|
:libssh:
|
|
[https://www.libssh.org]
|
|
|
|
:OpenSSL:
|
|
[https://www.openssl.org]
|
|
|
|
:XZ Utils:
|
|
[https://tukaani.org/xz/]
|
|
_(support for tar.xz archives)_
|
|
|
|
:libarchive:
|
|
[https://www.libarchive.org]
|
|
_(basis of the extract tool)_
|
|
|
|
:zlib:
|
|
[https://www.zlib.net]
|
|
|
|
:GnuPG:
|
|
[https://www.gnupg.org]
|
|
_(basis of the verify tool)_
|
|
|
|
:Jitterentropy RNG:
|
|
[https://chronox.de/jent.html]
|
|
|
|
|
|
Applications
|
|
------------
|
|
|
|
:VirtualBox:
|
|
[https://www.virtualbox.org]
|
|
_(used for hosting virtual machines)_
|
|
|
|
|
|
Libraries used for the graphical user interface
|
|
-----------------------------------------------
|
|
|
|
:libpng:
|
|
[http://www.libpng.org/pub/png/libpng.html]
|
|
_(used for decoding PNG images)_
|
|
|
|
:stb:
|
|
[https://github.com/nothings/stb]
|
|
_(used for rasterizing TrueType fonts)_
|
|
|
|
:Mesa 3D:
|
|
[https://mesa3d.org]
|
|
_(used for hardware-accelerated 3D graphics)_
|
|
|
|
|
|
Crucial tools used during development
|
|
-------------------------------------
|
|
|
|
:GNU/Linux: (various distributions)
|
|
|
|
:Git:
|
|
[https://git-scm.com]
|
|
|
|
:GNU compiler collection:
|
|
[https://gcc.gnu.org]
|
|
|
|
:GNU binutils:
|
|
[https://www.gnu.org/software/binutils/]
|
|
|
|
:GNU make:
|
|
[https://www.gnu.org/software/make/]
|
|
|
|
:Tcl:
|
|
[https://www.tcl.tk]
|
|
|
|
:Expect:
|
|
[https://core.tcl-lang.org/expect/index]
|
|
|
|
:Qemu:
|
|
[https://www.qemu.org]
|
|
|
|
:GitHub issues:
|
|
[https://github.com]
|
|
|