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776 lines
36 KiB
Plaintext
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===============================================
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Release notes for the Genode OS Framework 22.05
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===============================================
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Genode Labs
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The Genode release 22.05 stays true to this year's
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[https://genode.org/about/road-map - roadmap].
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According to the plan, we continue our tradition of revising the framework's
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documentation as part of the May release. Since last year, the Genode
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Foundations book is accompanied with the Genode Platforms document that
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covers low-level topics. The second revision has just doubled in size
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(Section [Updated and new documentation]).
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Functionality-wise, the added support for WireGuard-based virtual private
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networks is certainly the flagship feature of the release.
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Section [WireGuard] briefly introduces the new component while leaving
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in-depth information to a
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[https://genodians.org/m-stein/2022-05-26-wireguard-1 - dedicated article].
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Among the other topics of the release, our continued work on device drivers
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stands out. We managed to bring Genode's lineup of PC drivers ported from the
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Linux kernel up to the kernel version 5.14.21 using Genode's unique DDE-Linux
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porting approach.
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As described by Section [New generation of DDE-Linux-based PC drivers], this
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work comprises complex drivers like the wireless LAN stack including Intel's
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Wifi driver and the latest Intel display driver. At the framework's side, the
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modernization of Genode's platform driver for PC hardware is in full swing.
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Even though not yet used by default, the new driver has reached feature parity
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with the original PC-specific platform driver while sharing much of its code
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base with the growing number of ARM platform drivers such as the FPGA-aware
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platform-driver for Xilinx Zynq (Section [Xilinx Zynq]).
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Regarding the PinePhone, Genode 22.05 introduces the basic ability to issue
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and receive phone calls, which entails the proper routing of audio signals and
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controlling the LTE modem. Furthermore, in anticipation of implementing
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advanced energy-management strategies, the release features a custom developed
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firmware for the PinePhone's system-control processor. Both topics are
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outlined in Section [PinePhone] while further details and examples are given
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in dedicated articles.
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The release is wrapped up by usability improvements of the framework's
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light-weight event-tracing mechanism, low-level optimizations, and API
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refinements.
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WireGuard
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#########
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[https://www.wireguard.com/ - WireGuard] is a protocol for encrypted, virtual
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private networks (VPNs) with the goal of bringing ease-of-use and
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state-of-the-art network security together. Furthermore, it is designed to be
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implemented both light-weighted and highly performant at the same time. For
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years now, we were keen to support WireGuard as a native standard solution for
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peer-to-peer network encryption. With Genode 22.05, we could finally
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accomplish that goal.
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After we had considered various implementations as starting point, we chose to
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port the Linux kernel implementation of WireGuard using our modernized
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DDE-Linux tool set. The outcome is a user-land component that acts as client
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to one NIC session and one uplink session. At the uplink session, the
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WireGuard component plays the role of a VPN-internal network device that
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communicates plain-text with the VPN participants. At the NIC session,
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however, the component drives an encrypted UDP tunnel through the public
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network towards other WireGuard instances.
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In Genode, a WireGuard instance receives its parameters through the component
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configuration with the peer configuration being re-configurable:
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! <config private_key="0CtU34qsl97IGiYKSO4tMaF/SJvy04zzeQkhZEbZSk0="
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! listen_port="49001">
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!
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! <peer public_key="GrvyALPZ3PQ2AWM+ovxJqnxSqKpmTyqUui5jH+C8I0E="
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! endpoint_ip="10.1.2.1"
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! endpoint_port="49002"
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! allowed_ip="10.0.9.2/32" />
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!
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! </config>
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A typical integration scenario would use two instances of Genode's NIC router.
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One router serves the public network side of WireGuard and connects to the
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internet via the device driver whereas the other router uses the private
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network side of WireGuard as uplink interface. In this scenario, there is no
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way around the WireGuard tunnel towards the Internet even when looking only at
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components and sessions. Alternatively, we could accomplish the same goal with
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only one router instance in contexts that allow us to trust in the integrity
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of the router's own security domains.
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[image wireguard_integration]
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A typical integration scenario for WireGuard
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For more details on how to integrate and route WireGuard in Genode, you may
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refer to the new run scripts _wg_ping_inwards.run_, _wg_ping_outwards.run_,
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_wg_lighttpd.run_, and _wg_fetchurl.run_, which are located at
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_repos/dde_linux/run/_.
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Please be aware that this is the first official version of the WireGuard
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component. Although we are convinced of the quality of the underlying
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time-tested Linux implementation, we strongly recommend against basing
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security-critical scenarios on Genode's port before it had the time to mature
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through real-world testing as well.
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For the whole story behind the new WireGuard support in Genode, have a look at
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the following dedicated article at [https://genodians.org]:
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:Bringing WireGuard to Genode:
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[https://genodians.org/m-stein/2022-05-26-wireguard-1]
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New generation of DDE-Linux-based PC drivers
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############################################
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With the
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[https://genode.org/documentation/release-notes/22.02#New_Linux-device-driver_environment_for_PC_drivers - previous release],
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we started to apply the
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[https://genode.org/documentation/release-notes/21.08#Linux-device-driver_environment_re-imagined - new DDE Linux approach]
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to Linux-based PC drivers.
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The first driver to be converted was the USB host-controller driver. In the
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current release, we finished up this line of work. By now, all remaining
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Linux-based PC drivers have been converted and updated. Those drivers now
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share the same kernel version 5.14.21. The ports and configuration reside in
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the _pc_ repository.
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Based on the groundwork laid by the USB host-controller driver, we started
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working on the Intel display and Intel wireless drivers. With the stumbling
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blocks already out of the way, namely the x86 support in DDE Linux, we could
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focus entirely on the intricacies of each driver.
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In case of the Intel display driver, we could eliminate all our patches to the
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kernel that we previously needed to manage the display connectors. Due to the
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update, we gained support for newer Intel Gen11 and Gen12 graphics generations
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as found in recent Intel CPUs. The old driver has been removed and the new
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driver is now called _pc_intel_fb_drv_. Its configuration, however, remained
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compatible and is documented in detail in the README of the driver.
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The Intel wireless driver also profited from the version update as it now
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supports 802.11ax capable devices. In particular, the driver was tested with
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Intel Wi-Fi6 AX201 cards. The driver's unique physique - where the component
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not only incorporates the driver but also the supporting user-land supplicant -
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required changes to the way the Linux emulation environment is initialized.
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We utilize a new VFS 'wifi' plugin that is executed during the component
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start-up to prepare the emulation environment.
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The following snippet shows how to configure the driver:
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!<start name="pc_wifi_drv" caps="250">
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! <resource name="RAM" quantum="32M"/>
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! <provides><service name="Nic"/></provides>
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! <config>
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! <libc stdout="/dev/null" stderr="/dev/null" rtc="/dev/rtc"/>
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! <vfs>
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! <dir name="dev">
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! <log/> <null/> <rtc/> <wifi/>
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! <jitterentropy name="random"/>
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! <jitterentropy name="urandom"/>
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! </dir>
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! </vfs>
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! </config>
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! <route>
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! <service name="Rtc"> <any-child /> </service>
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! <any-service> <parent/> <any-child /> </any-service>
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! </route>
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!</start
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Apart from the added VFS plugin, the configuration remained unchanged.
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So using the new driver is opaque to the user. The old driver was removed
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and the new driver is now called _pc_wifi_drv_. Instead of preparing the
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'dde_linux' port, the 'libnl' and 'wpa_supplicant' ports are now required for
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building the driver.
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! tool/ports/prepare libnl wpa_supplicant
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Additionally to both driver updates, we wrapped up working on the USB
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host-controller driver component by enabling the UHCI host-controller driver.
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Support for such controllers was omitted in the previous release and
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supporting the driver required us to add I/O port support to the 'lx_kit' for
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x86. With this remaining feature gap closed, the _legacy_pc_usb_host_drv_
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driver component has been removed in favour of the new one. Furthermore, the
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Genode C-API for USB glue code, which was initially copied from the i.MX8 USB
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host-controller driver, was consolidated and moved into the _dde_linux_
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repository where it now is referenced by all recent USB host-controller
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drivers.
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With all updated drivers in place, it was time to make inventory and
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de-duplicate the drivers since each driver accumulated redundant bits and
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pieces of code. This consolidation effort simplified things greatly. We moved
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most of the code shared by all drivers into a separate 'pc_lx_emul' library,
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which is the back bone of those ported drivers. Since not all of them require
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the same sophistication when it comes to the kernel API emulation, we followed
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the same modular pattern already established in the _dde_linux_ repository,
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which allows for mixing and matching of the available dummy implementations
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individually per driver.
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Updated and new documentation
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#############################
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Genode Platforms
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----------------
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The second revision of the "Genode Platforms" document condenses two years of
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practical work with enabling Genode on a new hardware platform, taking the
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PinePhone as concrete example. Compared to the first version published one
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year ago, the content has doubled. Among the new topics are
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: <div class="visualClear"><!-- --></div>
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: <p>
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: <div style="clear: both; float: left; margin-right:20px;">
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: <a class="internal-link" href="https://genode.org">
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: <img class="image-inline" src="https://genode.org/documentation/genode-platforms-title.png">
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: </a>
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: </div>
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: </p>
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* Working with bare-bones Linux kernels,
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* Network driver based on DDE-Linux,
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* Display and touchscreen,
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* Clocks, resets, and power controls, and
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* Modem control and telephony.
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:Second revision of the Genode Platforms document:
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[https://genode.org/documentation/genode-platforms-22-05.pdf]
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Genode Foundations
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------------------
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The "Genode Foundations" book received its annual update. It is available at
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the [https://genode.org] website as a PDF document and an online version.
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The most noteworthy additions and changes are:
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: <div class="visualClear"><!-- --></div>
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: <p>
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: <div style="clear: both; float: left; margin-right:20px;">
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: <a class="internal-link" href="https://genode.org">
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: <img class="image-inline" src="https://genode.org/documentation/genode-foundations-title.png">
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: </a>
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: </div>
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: </p>
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* Revised under-the-hood section about the base-hw kernel,
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* Adaptation to changed repository structure (pc repository, SoC-specific
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repositories),
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* Updated API documentation, and
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* Adjusted package-management description.
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: <div class="visualClear"><!-- --></div>
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To examine the changes in detail, please refer to the book's
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[https://github.com/nfeske/genode-manual/commits/master - revision history].
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Base framework and OS-level infrastructure
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##########################################
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Revised tracing facilities
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==========================
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Even though a light-weight event tracing mechanism has been with Genode since
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[https://genode.org/documentation/release-notes/13.08#Light-weight_event_tracing - version 13.08],
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in practice, this powerful tool remains sparingly used because it is arguable
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less convenient than plain old debug instrumentation.
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The trace-logger component introduced later in
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[https://genode.org/documentation/release-notes/18.02#New_trace-logging_component - version 18.02]
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tried to lower the barrier, but tracing remains being an underused feature.
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The current release brings a number of usability improvements that will
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hopefully make the tool more attractive for routine use.
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Concise human-oriented output format
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------------------------------------
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First, we changed the output format of the trace logger to become better
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suitable for human consumption, reducing syntactic noise and filtering out
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repetitive information. For example, when instrumenting the VFS server in
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Sculpt using the new GENODE_TRACE_TSC utility (see below), the trace logger
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now generates tabular output as follows.
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! Report 4
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!
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! PD "init -> runtime -> arch_vbox6 -> vbox -> " ----------------
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! Thread "vCPU" at (0,0) total:12909024 recent:989229
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! Thread "vCPU" at (1,0) total:5643234 recent:786437
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!
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! PD "init -> runtime -> ahci-0.fs" -----------------------------
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! Thread "ahci-0.fs" at (0,0) total:910497 recent:6335
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! Thread "ep" at (0,0) total:0 recent:0
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! 71919692932: TSC process_packets: 8005M (4998 calls, last 4932K)
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! 71921558516: TSC process_packets: 8006M (4999 calls, last 1596K)
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! 71922760220: TSC process_packets: 8007M (5000 calls, last 1006K)
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! 71929853586: TSC process_packets: 8009M (5001 calls, last 1840K)
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! 71931315246: TSC process_packets: 8011M (5002 calls, last 1253K)
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! 72127999920: TSC process_packets: 8016M (5003 calls, last 5606K)
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! 72129568198: TSC process_packets: 8018M (5004 calls, last 1345K)
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! 77161908178: TSC process_packets: 8029M (5005 calls, last 11349K)
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! 77643225736: TSC process_packets: 8029M (5006 calls, last 217K)
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! 89422100594: TSC process_packets: 8035M (5007 calls, last 5656K)
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! 89422123632: TSC process_packets: 8035M (5008 calls, last 1342)
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! Thread "signal handler" at (0,0) total:36329 recent:3001
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! Thread "signal_proxy" at (0,0) total:51838 recent:13099
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! Thread "pdaemon" at (0,0) total:97184 recent:332
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! Thread "vdrain" at (0,0) total:1266 recent:286
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! Thread "vrele" at (0,0) total:1904 recent:516
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!
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! PD "init -> runtime -> nic_drv" -------------------------------
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! Thread "nic_drv" at (0,0) total:34044 recent:897
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! Thread "signal handler" at (0,0) total:369 recent:142
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!
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! ...
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Subjects that belong to the same protection domain are grouped together.
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The formerly optional affinity and activity options have been removed.
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These pieces of information are now unconditionally displayed. The trace
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entries belonging to a thread appear as slightly indented. Trace subjects with
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no activity do not produce any output. This way, the new version can be easily
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used to capture CPU usage of all threads over time, as a possible alternative
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to the top tool, which gives only momentarily sampled information.
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Straight-forward trace logging with Sculpt OS
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---------------------------------------------
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Second, we added the trace-logger utility to the default set of packages along
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with an optional launcher. With this change, only two steps are needed to use
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the tracing mechanism with the
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[https://genode.org/documentation/release-notes/22.02#Framework_for_special-purpose_Sculpt-based_operating_systems - modularized Sculpt]:
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# Add 'trace_logger' to the 'launcher:' list of the .sculpt file
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# Either manually select the 'trace_logger' from the '+' menu,
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or add the following entry to the deploy configuration:
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! <start name="trace_logger"/>
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By default, the trace logger is configured to trace all threads executed in
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the runtime subsystem and to print a report every 10 seconds. This default
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policy can be refined in the launcher's '<config>' node. Note that the trace
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logger does not respond to configuration changes during runtime. Changes come
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into effect not before restarting the component.
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Capturing performance measurements as trace events
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--------------------------------------------------
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Finally, to leverage the high efficiency of the tracing mechanism for
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performance analysis, we complement the convenient
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[https://genodians.org/nfeske/2021-04-07-performance - GENODE_LOG_TSC]
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measurement device provided by _base/log.h_ with new versions that target the
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trace buffer. The new macros GENODE_TRACE_TSC and GENODE_TRACE_TSC_NAMED
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thereby simplify the capturing of highly accurate time-stamp-counter-based
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measurements for performance-critical code paths that prohibit the use of
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regular log messages.
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Memcpy and memset optimization
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==============================
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With the improving support for the Zynq-7000 SoC, it was time to collect a few
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basic performance metrics. For the purpose of evaluating memory throughput,
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there exists a test suite in _libports/run/memcpy.run_. It takes a couple of
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measurements for different memcpy and memset implementations. There also
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exists a Makefile in _libports/src/test/memcpy/linux_ to build a similar test
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suite for Linux that serves as a baseline. By comparing the results, we get an
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indicator of whether our board support is setting up the hardware correctly.
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Looking at the numbers for the Zynq-7000 SoC, however, we were puzzled about
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why we achieved significantly less memcpy throughput on Genode than on Linux.
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This eventually sparked an in-depth investigation of memcpy implementations
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and of the Cortex-A9's memory subsystem.
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As it turned out, the major difference was caused by our Linux tests hitting
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the kernel's copy-on-write optimization and, therefore, accidentally mimicking
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a memset scenario rather than a memcpy scenario. Nevertheless, in the
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debugging process, we were able to identify a few low-hanging fruits for
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general optimization of Genode's memset and memcpy implementations: Replacing
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the bytewise memset implementation with a wordwise memset yielded a speedup of
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~6 on Cortex-A9 (base-hw) and x86 (base-linux). Similarly, we achieved a
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memcpy speedup of ~3 on x86. On arm_v7, we also experimented with the
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preloading instruction (pld) and L2 prefetching. On Zynq-7000 (Cortex-A9), we
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gained a speedup of ~2-3 by tuning these parameters.
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Extended black-hole component
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=============================
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The black-hole component introduced in
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[https://genode.org/documentation/release-notes/22.02#Black-hole_server_component - version 22.02]
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provides pseudo services for commonly used session interfaces and is thereby
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able to satisfy the resource requirements of a component without handing out
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real resources. This is especially useful for deploying highly flexible
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subsystems like VirtualBox, which supports many host-guest integration
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features, most of which are desired only in a few scenarios. For example, to
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shield a virtual machine from the network, the NIC session requested by the
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VirtualBox instance can simply be assigned to the black-hole server while
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keeping the network configuration of the virtual machine untouched.
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The current release extends the black-hole component to cover ROM, GPU, and
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USB services in addition to the already supported NIC, uplink, audio, capture,
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and event services. The ROM service hands out a static '<empty/>' XML node.
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The USB and GPU services accept the creation of new sessions but respond in a
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denying way to any invocation of the session interfaces. The black-hole server
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is located at _os/src/server/black_hole/_.
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Refined low-level block I/O interfaces
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======================================
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In the original version of the 'Block::Connection::Job' API introduced in
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[https://genode.org/documentation/release-notes/19.05#Modernized_block-storage_interfaces - version 19.05],
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split read/write operations were rather difficult to accommodate and remained
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largely unsupported by clients of the block-session interface. In practice,
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this limitation was side-stepped by dimensioning the default I/O buffer sizes
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large enough to avoid splitting. The current release addresses this limitation
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by changing the meaning of the 'offset' parameter of the
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'produce_write_content' and 'consume_read_result' hook functions. The value
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used to reflect the absolute byte position. In the new version, it is relative
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to the job's operation.
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_This API change requires the adaptation of existing block-session clients._
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We adapted all block-session clients accordingly, including part_block,
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vfs/rump, vfs/fatfs, and Genode's ARM virtual machine monitor. Those
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components thereby became able to work with arbitrary block I/O buffer sizes.
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Improved touch-event support
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============================
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Until recently, Genode's GUI stack largely relied on the notion of an absolute
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pointer position. For targeting touch-screen devices, our initial approach
|
|
was the translation of touch events to absolute motion events using the
|
|
event-filter component
|
|
([https://genode.org/documentation/release-notes/21.11#Event_filter_for_converting_touch_to_pointer_input - version 21.11]).
|
|
|
|
However, the event types are subtly different, which creates uncertainties.
|
|
Whereas a pointer has always a defined (most recent) position that can be used
|
|
to infer a hovered UI element in any situation, touch input yields a valid
|
|
position only while touching. Because both event types are different after all,
|
|
the conversion of touch input to pointer motion can only be an intermediate
|
|
solution. The current release enhances several components of Genode's GUI
|
|
stack with the ability to handle touch events directly.
|
|
|
|
In particular, the nitpicker GUI server has become able to take touch events
|
|
into consideration for steering the keyboard focus and the routing of
|
|
input-event sequences. The window-manager component (wm) has been enhanced to
|
|
transform touch events similarly to motion events by using one virtual
|
|
coordinate system per window. Finally, the menu-view component, which
|
|
implements the rudimentary widget set as used by Sculpt OS' administrative
|
|
user interface, evaluates touch events for generating hover reports now.
|
|
Combined, these changes make the existing GUI stack fit for our anticipated
|
|
touch-screen based usage scenarios such as the user interface for Genode on
|
|
the PinePhone.
|
|
|
|
|
|
Platform driver
|
|
===============
|
|
|
|
The architecture-independent platform driver that unified the platform API since
|
|
[https://genode.org/documentation/release-notes/22.02#Platform_driver - release 22.02],
|
|
still missed some features to replace the deprecated x86-specific variant.
|
|
Most importantly, it was not aware of PCI devices and their special treatment.
|
|
|
|
PCI decode component
|
|
--------------------
|
|
|
|
The platform driver is a central resource multiplexer in the system, and
|
|
literally all device drivers depend on it. Therefore, it is crucial to keep it
|
|
as simple as possible to minimize its code complexity. To facilitate
|
|
PCI-device resource handling of the platform driver, we introduce a new
|
|
component called _pci_decode_. It examines information delivered by the ACPI
|
|
driver about the location of the PCI configuration spaces of PCI host bridges,
|
|
as well as additional interrupt re-routing information, and finally probes for
|
|
all available PCI devices, and their functions. Dependent on additional
|
|
kernel-related facilities, e.g., whether the micro-kernel supports
|
|
message-signaled interrupts, it finally publishes a report about all PCI
|
|
devices and their related resources.
|
|
|
|
An example report looks like the following:
|
|
|
|
! <devices>
|
|
! <device name="00:02.0" type="pci">
|
|
! <pci-config address="0xf8010000" bus="0x0" device="0x2" function="0x0"
|
|
! vendor_id="0x8086" device_id="0x1616" class="0x30000"
|
|
! bridge="no"/>
|
|
! <io_mem address="0xf0000000" size="0x1000000"/>
|
|
! <io_mem address="0xe0000000" size="0x10000000"/>
|
|
! <io_port_range address="0x3000" size="0xffff0040"/>
|
|
! <irq type="msi" number="11"/>
|
|
! </device>
|
|
!
|
|
! ...
|
|
! </devices>
|
|
|
|
The device and resource description in this report is compatible with the
|
|
device configuration patterns already used by the platform driver before.
|
|
|
|
Devices ROM
|
|
-----------
|
|
|
|
To better cope with device information gathered at runtime, like the one
|
|
provided by the PCI decoder, the platform driver no longer retrieves the device
|
|
information from its configuration. Instead, it requests a devices ROM
|
|
explicitly. The policy information about which devices are assigned to which
|
|
client remains an integral part of the platform driver's configuration.
|
|
The devices ROM is requested via the label "devices" by default. If one needs
|
|
to name the ROM differently, one can state the label in the configuration:
|
|
|
|
! <config devices_rom="config"/>
|
|
|
|
Using the example above, the former behavior can be emulated. It prompts the
|
|
platform driver to obtain both its policy configuration and device information
|
|
from the same "config" ROM.
|
|
|
|
Static device information for a specific SoC respectively board does now
|
|
reside in the SoC-specific repositories within the _board/_ directory.
|
|
For instance, the device information for the MNT Reform 2 resides in the
|
|
genode-imx repository under _board/mnt_reform2/devices_. All scenarios and
|
|
test-scripts can refer to this central file.
|
|
|
|
Report facility
|
|
---------------
|
|
|
|
The platform driver can report its current view on devices as well as its
|
|
configuration. An external management component might monitor this information
|
|
to dynamically apply policies. With the following configuration switches, one
|
|
can enable the reports "config" and "devices":
|
|
|
|
! <config>
|
|
! <report devices="yes" config="yes"/>
|
|
! ...
|
|
! </config>
|
|
|
|
Interrupt configuration
|
|
-----------------------
|
|
|
|
The need for additional information to set up interrupts appropriately led to
|
|
changes in the interrupt resource description consumed by the platform driver.
|
|
It can now parse additional attributes, like mode, type, and polarity. It
|
|
distinguishes "msi" and "legacy" as type, "high" and "low" as polarity,
|
|
"level" and "edge" as mode. Dependent on the stated information in the devices
|
|
ROM, the platform driver will open the IRQ session for the client accordingly.
|
|
|
|
I/O ports
|
|
---------
|
|
|
|
A new resource type in the device description interpreted by the platform
|
|
driver is the I/O port range. It looks like the following:
|
|
|
|
! <devices>
|
|
! <device name="00:1f.2" type="pci">
|
|
! ...
|
|
! <io_port_range address="0x3080" size="0x8"/>
|
|
! ...
|
|
! </device>
|
|
! ...
|
|
! </devices>
|
|
|
|
The generic platform API's device interface got extended to deliver an IO_PORTS
|
|
session capability for a given index. The index is dependent on which I/O port
|
|
ranges are stated for a given device.
|
|
|
|
The helper utility 'Platform::Device::Io_port_range' simplifies the usage of
|
|
I/O ports by device driver clients. It can be found in
|
|
_repos/os/include/platform_session/device.h_.
|
|
|
|
DMA protection
|
|
--------------
|
|
|
|
The generic platform driver now uses device PDs and attaches all DMA buffers
|
|
requested by a client to it. Moreover, it assigns PCI devices to the device PD
|
|
too. On the NOVA kernel, this information is used to
|
|
configure the IOMMU correspondingly.
|
|
|
|
PCI device clients
|
|
------------------
|
|
|
|
The platform API and its utilities no longer differentiate between PCI and
|
|
non-PCI devices. However, under the hood, the platform driver performs
|
|
additional initialization steps once a PCI device gets acquired. Dependent on
|
|
the resources assigned to the device, the platform driver enables I/O and
|
|
memory access in the PCI configuration space of the device. Moreover, it
|
|
enables bus-master access for DMA transfers.
|
|
|
|
To assign PCI devices to a client, the policy rules in the platform driver can
|
|
refer to it either by a device/vendor ID tuple, or by stating a PCI class.
|
|
The PCI class names are the same supported by the previous x86-specific
|
|
platform driver. Of course, one can still refer to any device via its unique
|
|
name. Here is an example for a policy set:
|
|
|
|
! <config>
|
|
! <policy label="usb_drv -> ">
|
|
! <pci class="USB"/>
|
|
! </policy>
|
|
! <policy label="nvme_drv -> ">
|
|
! <pci vendor_id="0x1987" device_id="0x5007"/>
|
|
! </policy>
|
|
! <policy label="ps2_drv -> ">
|
|
! <device name="ps2"/>
|
|
! </policy>
|
|
! </config>
|
|
|
|
Wait for platform device availability
|
|
-------------------------------------
|
|
|
|
Now that device information can be gathered dynamically at runtime it might
|
|
happen that a client opens a session to the platform driver before the device
|
|
becomes available. As long as a valid policy is defined for the client, the
|
|
platform driver will establish the connection, but deliver an empty devices
|
|
ROM to the client.
|
|
|
|
To simplify the usage by device drivers, the utilities to acquire a device
|
|
from the platform driver in 'Platform::Device' and 'Platform::Connection' will
|
|
wait for the availability of the device. This is done by implicitly
|
|
registering a signal handler for devices ROM updates at the platform driver
|
|
when the acquisition failed, and waiting for ROM updates until the device is
|
|
available.
|
|
|
|
Any signal handler that was registered before gets lost in this case.
|
|
The developer of a device driver shall register a devices ROM signal handler
|
|
once its devices were acquired, or shall only acquire devices known to be
|
|
available, after inspecting the devices ROM independently.
|
|
|
|
|
|
Platforms
|
|
#########
|
|
|
|
PinePhone
|
|
=========
|
|
|
|
Telephony
|
|
~~~~~~~~~
|
|
|
|
The current release introduces the principle ability to issue and receive
|
|
voice calls with the PinePhone. This work involved two topics. First, we had
|
|
to tackle the integration, configuration, and operation of the LTE modem. The
|
|
second piece of the puzzle was the configuration of the audio paths between
|
|
the mic, the speaker, and the modem. Since the complexity of those topics
|
|
would exceed the scope of the release documentation, the technical details are
|
|
covered in a dedicated article.
|
|
|
|
:Pine fun - Telephony _(Roger, Roger?)_:
|
|
|
|
[https://genodians.org/ssumpf/2022-05-09-telephony]
|
|
|
|
[image pinephone_telephony]
|
|
|
|
The image above illustrates a simple system exemplified by the
|
|
[https://github.com/genodelabs/genode-allwinner/blob/master/run/modem_pinephone.run - modem_pinephone.run]
|
|
script. It allows a terminal emulator on a host machine connected to the
|
|
serial connector of the PinePhone to interact with the command interface of
|
|
the modem, e.g., allowing the user to unlock the SIM card via the 'AT+CPIN'
|
|
command, or to issue a call using the 'ATD' command.
|
|
|
|
|
|
Custom system-control processor (SCP) firmware
|
|
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
Battery lifetime is one of the most pressing concerns for mobile phones. While
|
|
exploring the PinePhone hardware, we discovered early on that the key for
|
|
sophisticated energy management lies in the so-called system control processor
|
|
(SCP), which is a low-power companion microcontroller that complements the
|
|
high-performance application processor. The SCP can remain active even if the
|
|
device is visibly switched off.
|
|
Surprisingly, even though its designated purpose is rather narrow, the SCP is
|
|
a freely programmable general-purpose CPU (called AR100) with ultimate access
|
|
to every corner of the SoC. It can control all peripherals including the
|
|
modem, and access the entirety of physical memory.
|
|
|
|
In contrast to most consumer devices, which operate their SCPs with
|
|
proprietary firmware, the PinePhone gives users the freedom to use an
|
|
open-source firmware called [https://github.com/crust-firmware/crust - Crust].
|
|
Moreover, the Crust developers thoroughly documented their findings of the
|
|
[https://linux-sunxi.org/AR100 - AR100 limitations] and its
|
|
[https://linux-sunxi.org/AR100/HardwareSharing - interplay with the ARM CPU].
|
|
|
|
Given that the Crust firmware was specifically developed to augment a
|
|
Linux-based OS with suspend-resume functionality, its fixed-function feature
|
|
set is rather constrained. For running Genode on the PinePhone, we'd like to
|
|
move more freely, e.g., letting the SCP interact with the modem while the
|
|
application processor is powered off. To break free from the limitations of a
|
|
fixed-function feature set of an SCP firmware implemented in C, we explored
|
|
the opportunity to deploy a minimal-complexity Forth interpreter as the basis
|
|
for a custom SCP firmware. The story behind this line of development is
|
|
covered by the following dedicated article:
|
|
|
|
:Darling, I FORTHified my PinePhone!:
|
|
|
|
[https://genodians.org/nfeske/2022-03-29-pinephone-forth]
|
|
|
|
|
|
Inter-communication between SCP and ARM
|
|
---------------------------------------
|
|
|
|
To enable a tight interplay of Genode with the SCP, we introduce a new
|
|
[https://github.com/genodelabs/genode-allwinner/tree/master/include/scp_session - interface] and
|
|
[https://github.com/genodelabs/genode-allwinner/tree/master/src/drivers/scp/a64 - driver]
|
|
for supplying and invoking custom functionality to the SCP at runtime.
|
|
The new "Scp" service allows clients to supply snippets of Forth code for
|
|
execution at the SCP and retrieve the result. Both the program and the result
|
|
are constrained to 1000 bytes. Hence, the loading of larger programs may need
|
|
multiple subsequent 'Scp::Connection::execute' calls.
|
|
|
|
As illustrated by the example
|
|
[https://github.com/genodelabs/genode-allwinner/blob/master/run/a64_scp_drv.run - a64_scp_drv.run]
|
|
script, the mechanism supports multiple clients. Since the SCP's state is
|
|
global, however, all clients are expected to behave cooperatively. Given the
|
|
SCP's ultimate power, SCP clients must be fully trusted anyway.
|
|
|
|
As a nice tidbit for development, the PinePhone-specific SCP firmware features
|
|
a break-in debug shell for interactive use over UART that can be activated by
|
|
briefly connecting the INT and GND
|
|
[https://wiki.pine64.org/index.php/PinePhone#Pogo_pins - pogo pins].
|
|
Note that this interactive debugging facility works independently from the
|
|
application processor. Hence, it can be invoked at any time, e.g., to inspect
|
|
any hardware register while running a regular Linux distribution on the phone.
|
|
|
|
|
|
NXP i.MX8
|
|
=========
|
|
|
|
Analogously to the PCI decoder introduced in Section [Platform driver], a
|
|
component to retrieve PCI information on the i.MX 8MQ is part of this release.
|
|
It reports all PCI devices found behind the PCI Express host controller(s)
|
|
detected. In contrast to the PCI decoder, it has to initialize the PCI Express
|
|
host controller first, and needs device resources from the platform driver to
|
|
do so before. The component resides in the
|
|
[https://github.com/genodelabs/genode-imx - genode-imx]
|
|
repository and is called _imx8mq_pci_host_drv_.
|
|
|
|
|
|
Xilinx Zynq
|
|
===========
|
|
|
|
For the Zynq-7000 SoCs, we focused on two main topics in this release. First,
|
|
we leveraged the aforementioned improvements on the generic platform driver to
|
|
handle the (dis)appearance of devices in consequence of FPGA reconfiguration.
|
|
Second, we applied our new DDE Linux approach in order to port the SD-card
|
|
driver.
|
|
|
|
The platform driver for the Xilinx Zynq is now available in the
|
|
[https://github.com/genodelabs/genode-zynq - genode-zynq] repository as
|
|
_src/zynq_platform_drv_. The default devices ROMs are provided by the
|
|
_raw/<board>-devices_ archives. In addition to the generic driver, it features
|
|
the readout of clock frequencies. You can use _zynq_clocks.run_ to dump the
|
|
frequencies of all clocks.
|
|
|
|
Since the Xilinx Zynq comprises an FPGA that can be reconfigured at run time,
|
|
we also need to handle the appearance and disappearance of devices. For this
|
|
purpose, we added a driver manager that consumes the platform driver's devices
|
|
report and launches respectively kills device drivers accordingly. This
|
|
scenario is accompanied by the _pkg/drivers_fpga-zynq_ archive that assembles
|
|
the _devices_ ROM for the platform driver depending on the FPGA's
|
|
reconfiguration state. The figure below illustrates this scenario: The
|
|
subsystem provided by the _pkg/drivers_fpga-zynq_ archive is a replacement for
|
|
the platform driver. It consumes the _fpga.bit_ ROM that contains the FPGA's
|
|
bitstream. Once the bitstream has been loaded, the _fpga_devices_ ROM is
|
|
merged with the _devices_ ROM provided by the _raw/<board>-devices_ archive.
|
|
The _policy_ ROM contains the config of the internal zynq_platform_driver
|
|
(policies and reporting config). By enabling device reporting, the
|
|
zynq_driver_manager is able to react upon device changes and updates the
|
|
_init.config_ for a drivers subsystem accordingly. An example is available in
|
|
_run/zynq_driver_manager.run_.
|
|
|
|
[image zynq_driver_manager]
|
|
|
|
As a prerequisite for porting the first driver for the Zynq following our new
|
|
DDE Linux approach, we added a zynq_linux target that builds a stripped-down
|
|
Linux kernel for the Xilinx Zynq. Although Xilinx provides its own vendor
|
|
kernel, most drivers have been mainlined. To eliminate version mismatch
|
|
issues, we therefore use our mainline Linux port from _repos/dde_linux_
|
|
instead. With this foundation, we were able to port the SD card driver, which
|
|
is now available as _src/zynq_sd_card_drv_.
|