genode/doc/release_notes/21-02.txt

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2021-02-22 15:49:09 +00:00
===============================================
Release notes for the Genode OS Framework 21.02
===============================================
Genode Labs
Genode 21.02 stays close to the plan laid out on our
[https://genode.org/about/road-map - road map], featuring a healthy dose
of optimizations, extends the framework's ARM SoC options, and introduces
three longed-for new features.
First, we extended our concept of pluggable device drivers to all network
drivers, including Ethernet and Wifi.
As reported in Section [Pluggable network device drivers], such drivers can
now gracefully be started, restarted, removed, and updated at runtime without
disrupting network-application stacks.
Second, the release features the infrastructure needed for mobile-data
communication over LTE, which is a prerequisite for our ambition to use Genode
on the Pinephone. Section [LTE modem stack] gives insights into the involved
components and the architecture.
Third, we are happy to feature the initial version of VirtualBox 6 for
Genode. Section [VirtualBox 6.1.14] gives an overview of the already
supported feature set and the outlook to reach feature-parity to our version
of VirtualBox 5 soon.
Speaking of VirtualBox in general (both versions), we were able
to significantly improve the USB-device pass-through abilities, specifically
covering audio headsets.
Further noteworthy improvements of the current release range from added
VirtIO-block device support for virtual machines on ARM
(Section [VirtIO block devices for virtual machines on ARM]),
revived developments on RISC-V (Section [RISC-V]),
over VFS support for named pipes (Section [VFS support for named pipes]),
to streamlined tooling (Section [Build system and tools]).
Pluggable network device drivers
################################
The results of our approach to
[https://genode.org/documentation/release-notes/20.08#The_GUI_stack__restacked - pluggable framebuffer and input drivers]
encouraged us to take on the third major driver category, namely networking
drivers, which subsumes not only Ethernet drivers but also wireless networking
drivers and mobile baseband drivers. The latter two are of course particularly
interesting for mobile communication devices.
Similarly to the story linked above for the framebuffer and input drivers,
Genode's network drivers used to play the roles of NIC servers, providing a
network-interface service to network applications. As a consequence, the
lifetime of a network application was always bound to the lifetime of the
underlying NIC driver. This is unfortunate because those drivers can be
obscenely complex, putting the liveliness of the dependent application stack
at risk.
[image layered_nic_multi_app_risk]
However, in most scenarios, networking applications do not operate directly on
a network interface because this would prevent the use of the network interface
by more than one application at a time. Instead, there is usually a NIC
multiplexing component in-between the driver and one or multiple applications.
In most contemporary scenarios this is the NIC router that acts as NIC client
towards the driver and as NIC server towards the applications.
Thus, we contemplated the idea of letting the NIC driver operate as NIC client
of the NIC router instead. This would decouple the application from the
driver's lifetime while the driver's special role would be modeled solely by a
routing policy. However, even though the data channel of the NIC interface is
bi-directional, we realized that the reversal of the role of the driver does
not only entail the communication of network payload but also propagation of
the link state and the MAC address. This prompted us to introduce a new Genode
session type called "Uplink" that precisely models the NIC-driver-as-client
scenario.
[image nic_router_services]
In a nutshell, an Uplink session is almost the same as a NIC session with only
three minor differences. First, the MAC address is given by the client (the
driver) as an argument at session-creation time. Second, the roles of the TX
and RX packet streams are interchanged compared to a NIC session. I.e., the
_client_ transmits via TX and receives through RX while at the server side it's
vice-versa. And third - as a mere interface optimization - the link state of an
uplink session is always "up". The session is requested by the client (the
driver) only in the event of a "link-up" edge. Analogously, whenever the link
goes "down", the client closes the session again.
With this new session interface in place, the NIC router becomes the only
long-running component in the scenario. It provides both a NIC and an uplink
session interface. The NIC session interface is used by network applications.
The uplink session interface is used by drivers. Inside the router, uplink
sessions are treated the same as NIC sessions. Therefore, we decided that the
well known '<policy>' tags in the configuration are now simply applied to both
session types. This means, that each '<uplink>' tag that connected a driver in a
router configuration can now be replaced by a '<policy>' tag with a label
attribute that matches the driver's session request.
[image nic_uplink_multi_app]
We divided the process for this architectural change into the following
autonomous steps:
# Introduce the uplink session and uplink-session support in the NIC router.
# Let NIC drivers support both modes, "NIC session server" and "Uplink session
client" depending on a new _transitional_ <config>-tag attribute 'mode'.
This attribute is optional and has two possible values, 'uplink_client'
and 'nic_server', of which it defaults to the latter.
# Adapt all network scenarios in the basic Genode repositories to use NIC
drivers only with '<config mode="uplink_client">'.
# Remove support for the "NIC session server" mode from all NIC drivers and
with it also the transitional 'mode' attribute.
All steps except the last one are completed by now. The transitional 'mode'
attribute and the "NIC session server" mode will remain available in all NIC
drivers until the next Genode release in order to give others the opportunity
to gracefully adapt their NIC drivers and network scenarios to the change.
Further information
-------------------
The overarching topic of pluggable device drivers was covered by our recent
presentation at [https://fosdem.org/2021/ - FOSDEM 2021]. You can find the
video recording and the presentation slides at the following link.
:Pluggable device drivers for Genode:
_presented at FOSDEM 2021_
[https://fosdem.org/2021/schedule/event/microkernel_pluggable_device_drivers_for_genode/]
LTE modem stack
###############
With the current release, Genode adds LTE broadband modem support for packet data
connections. This way, it becomes possible to browse the internet using the SIM
card of your broadband service provider. For a description of the protocols and
the general terminology when talking about LTE modems, our
[https://genodians.org/ssumpf/2020-12-04-mbim - LTE modem support for Genode]
Genodians article is a good starting point.
From the device side, LTE modems register themselves as USB devices at the USB
host controller. The speciality is that a modem offers two interfaces. First, a USB
network interface (like NCM or ECM) and second, a
[https://www.usb.org/document-library/class-definitions-communication-devices-12 - Wireless Mobile Communication Device],
which is a challenge/response control channel to the modem and used to configure
the device. For the actual communication through the control channel, there exist two
binary protocols: Namely, Mobile Broadband Interface Model (MBIM) and Qualcomm
Mobile Station Interface (QMI). Whereas the former is a USB standard, QMI is a
proprietary protocol by Qualcomm. Therefore, we picked a modem that supports the
MBIM standard for our line of work.
USB modem support
=================
In order to enable modem communication, we added the Linux USB modem driver for
MBIM to our _dde_linux_ device driver environment. This driver implements the
NCM and WDM interfaces for the modem and provides a network uplink session for
the NCM network interface and a terminal session for the WDM interface.
[image lte_mbim]
MBIM protocol
=============
MBIM is a binary protocol that is, for example, implemented by
[https://www.freedesktop.org/wiki/Software/libmbim/ - libmbim]. Therefore, we
ported _libmbim_ to Genode. Since it requires _glib_, we had to enable features
and improve our _glib_ support on Genode. The _libmbim_ library offers MBIM command handling only.
For actually triggering modem-communication, the _mbimcli_ tool is required. We
ported _mbimcli_ and changed its front end to trigger a modem packet-connection
sequence via _libmbim_ through the terminal session of the USB modem driver.
During this sequence, the SIM card is unlocked through the PIN, the packet
service is attached, and connection information (e.g., IP, gateway, DNS server)
is retrieved. The connection data is then used by _mbimcli_ to configure the
uplink of Genode's NIC router, which in turn makes the network connectivity available
to network applications. The holistic view is shown in image [lte_mbim].
Base framework and OS-level infrastructure
##########################################
NIC router
==========
The NIC router received two practical features, the consideration of
multiple DNS server entries on DHCP and an ARP-less mode for domains.
The latter was motivated by the fresh support for LTE modems (see Section
[LTE modem stack]). An LTE modem normally doesn't respond to ARP. So when
using it as uplink for the NIC router, the corresponding domain can't request
IP-to-MAC-address resolutions as usual. This is addressed through the new
optional attribute 'use_arp' in '<domain>' tags of the NIC router configuration.
By default, it is set to 'yes', which yields the same behavior as in the past.
However, when set to 'no' for a domain, this domain will prevent sending ARP
requests in general. This leaves the question how to determine the destination
MAC address for a packet that shall be sent at this domain when only the
destination IP address is known. This is solved by the router by simply using
the source MAC address also as destination MAC address, an approach that we
could observe also in other IP stacks and that worked just fine in our tests.
The ARP-less domain mode is demonstrated through the run script
_repos/os/run/nic_router_disable_arp.run_.
The consideration of multiple DNS-server entries on DHCP comes in two parts.
First, when acting as DHCP client at a domain, the router will now parse all
option 6 entries in DHCP ACK replies from the server and memorize them as part
of the resulting IP config of the domain. These entries will then also be
reported if '<report config="yes"/>' is set in the router's config. A router
report with multiple DNS server entries will look like this:
! <state>
! <domain name="uplink_1" ipv4="10.0.0.3/24" gw="10.0.0.1">
! <dns ip="10.0.0.2"/>
! <dns ip="1.1.1.1"/>
! <dns ip="8.8.8.8"/>
! ...
! </domain>
! <domain name="uplink_2" ipv4="168.192.0.200/24" gw="168.192.0.1">
! <dns ip="168.192.0.10"/>
! <dns ip="168.192.0.8"/>
! ...
! </domain>
! ...
! </state>
On the other hand, when acting as DHCP server at a domain, one has two
options. Option 1 is to configure the DHCP server to fetch DNS server entries
automatically from another domain:
! <domain name="downlink" interface="10.0.1.1/24">
! <dhcp-server dns_server_from="uplink_1" .../>
! </domain>
In this case, the router will now reflect not only one but all DNS server
entries from the source domain ("uplink") through the DHCP replies sent at the
destination domain ("downlink") without changing the entry order. This approach
is demonstrated through the new _repos/os/run/nic_router_dhcp_unmanaged.run_
run script.
Option 2 is to configure the DNS server entries manually at the DHCP
server:
! <domain name="downlink" interface="10.0.1.1/24">
! <dhcp-server ...>
! <dns-server ip="10.0.0.2"/>
! <dns-server ip="1.1.1.1"/>
! <dns-server ip="8.8.8.8"/>
! </dhcp-server>
! </domain>
The order of the '<dns-server>' tags determines the order of
option 6 entries in the replies of the DHCP server. Besides its use for static
DNS server configurations, this option can also be used for more sophisticated
forwarding of DNS server entries through a separate management component. The
management component could listen to the reported IP config of the source
domains, apply custom policies like address filters to the result, and
re-configure the DHCP servers of the destination domains accordingly. This
approach is demonstrated in the new _repos/os/run/nic_router_dhcp_managed.run_
run script.
Please note that the former 'dns_server' attribute of the '<dhcp-server>' tag
is no longer considered by the router as the new '<dns-server>' tag replaces it.
Thus, you might want to adapt your NIC router scenarios accordingly.
VFS support for named pipes
===========================
The VFS-pipe plugin received new support for named pipes. The main motivation was to
easily stream data from pure Genode components to libc components via
file-system sessions that can be attached to stdin, stdout, and stderr. This
feature further makes it possible to chain the data flow between several components together,
similarly to how it is done on Unix. Additionally, the thread synchronization
has been improved so that large data chunks can be transferred without
blocking.
A named pipe can be created by adding a '<fifo>' sub node to the '<pipe>' node
of the VFS:
! <vfs>
! <pipe>
! <fifo name="upstream"/>
! </pipe>
! ...
! </vfs>
Each pipe is exposed as a set of pseudo files.
! /upstream
! /.upstream/in/in
! /.upstream/out/out
The _/upstream_ pseudo file can be opened either as read-only or write-only
file. It allows for the access of both ends of the pipe. In contrast, each of
the pseudo files _/.upstream/in/in_ and _/.upstream/out/out_ represents only
one end of the pipe, which can be subjected to an individual directory-based
access-control policy.
Thanks to Sid Hussmann for contributing this valuable feature!
Terminal
========
While
[https://genode.org/documentation/release-notes/20.08#The_GUI_stack__restacked - revising the GUI stack]
in Genode 20.08, we largely abolished the use of the framebuffer and input
session interfaces. The graphical terminal, however, still relied on those
interfaces instead of the GUI session. In practice, there was always a gui_fb
component needed as an intermediate between the terminal and the GUI server.
To complete the GUI-stack transition, we changed the terminal to use the GUI
session directly and adjusted all current scenarios that use the terminal.
One useful feature of the gui_fb component was the definition of an initial
window size. This enabled packages such as Sculpt's system shell to present
terminal windows with a reasonable default size smaller than the entire
screen.
To accommodate this special case, the initial terminal size can now be
explicitly configured in the terminal configuration.
! <config>
! <initial width="800" height="600"/>
! ...
! </config>
While we were at it, we also enhanced the terminal with the ability to
dynamically respond to font changes. So the adjustment of the global font
settings in Sculpt OS takes immediate effect on all terminal windows.
OpenSSL 1.1.1i, curl 7.70.0
===========================
OpenSSL experienced some quite important security updates during the last
months. This prompted us to update our port to version 1.1.1i. During
the porting work, we kept an eye on performance and enabled CPU-specific
optimizations where feasible. Optimizations are enabled by default on
x86 and ARMv8. For ARMv7, we enable NEON-based functions only when the
build SPECS include "neon" to support common SoCs that lack these
capabilities in the default configuration. Please note, the updated
port does only provide one combined depot archive "openssl" that
replaces the former "libcrypto" and "libssl" archives. The libraries
are still distinct for compatibility with existing applications and
build systems. As a side effect, we also updated the curl library to
version 7.70, which is compatible with recent OpenSSL versions.
Thanks to Pirmin Duss for his valuable contribution to this update.
Virtualization
##############
VirtualBox 6.1.14
=================
Genode supports virtualization with VirtualBox
[https://genode.org/documentation/release-notes/14.02#VirtualBox_on_top_of_the_NOVA_microhypervisor - since 2014].
Back then, we enabled VirtualBox version 4 to support use cases with unmodified
Linux and Windows guests like Sculpt's predecessor
[https://genode.org/documentation/release-notes/15.11#Genode_as_desktop_OS - "Turmvilla"].
In 2016, we updated VirtualBox to version 5 to enable recent guest OS
versions notably Ubuntu 16.04 and Windows 10. VirtualBox 5 is an
integral part of Sculpt OS since its first release.
As VirtualBox 5 is no longer maintained upstream and also shows its age
when running recent versions of Windows 10, we accepted the challenge
to once again enable a new version of this VMM. This time we did not
go for a NOVA-specific port but exclusively use the kernel-agnostic
virtualization interfaces introduced in
[https://genode.org/documentation/release-notes/19.05#Kernel-agnostic_virtual-machine_monitors - Genode 19.05].
This way, VirtualBox 6 is prepared to run on NOVA, seL4, and Fiasco.OC alike with
minimal extra efforts.
The first development snapshot we publish with this release is ready to
run Linux and Windows guests with limited support for multiple cores,
integrates network and USB-passthrough as well as preliminary support
for Guest Additions like mouse integration and display. We are
committed to finalize the feature set and optimize the performance of
VirtualBox 6 until the upcoming Sculpt release but do not plan to replace
version 5 completely yet. In fact, the update paves the way to explore
more experimental grounds like enablement of GPU-based
acceleration of guest OSes.
As a starting point for exploring VirtualBox 6 on Genode, we recommend the run script
_ports/run/virtualbox6.run_.
VirtualBox 5
============
With this release, we extended our VirtualBox port and made USB
pass-through more robust.
So far, we most prominently use VirtualBox on Intel systems that feature
VT-x. This release enables support for also running 64bit guests on AMD
systems with SVM.
When it comes to USB pass-through support, we rely on the xHCI device-model
ported from Qemu. With this release, we updated the 3rd-party sources to
version 5.2.0 and the type of the exposed device has changed to QEMU xHCI. Due to
this change, older guest OSes - namely Windows 7 - that relied on the NEC
xHCI device will no longer work.
Thanks to the update, it becomes possible to use USB devices requiring isochronous
transfers, in particular audio devices, with Windows 10 guests. For now
we focused on USB-Audio-Class v1 devices using adaptive
synchronisation, which enables a variety of popular USB headsets for
the passthrough use case.
A glimpse into our USB machinery unveils that fine-tuned buffering and USB
transfer configuration is the key to robust USB passthrough. On one hand, the
handling of isochronous OUT transfers in our host connection batches multiple
packets and queues transfers, which helps to smoothen out playback in case other
Genode components utilize the CPU concurrently. On the other hand, the number of
IN requests queued is increased but the number of packets per request set to 1.
We obtained the best results by following this configuration observed in Linux
and Windows guests alike.
VirtIO block devices for virtual machines on ARM
================================================
With release
[https://genode.org/documentation/release-notes/20.02#Custom_virtual_machine_monitor_on_ARM - 20.02],
the first VirtIO device models entered Genode's virtual
machine monitor for ARM. They enabled a virtual machine to access network and
terminal services. This time, the VMM got extended with a block device model,
which again is compliant to the VirtIO 1.1 specification. Moreover, the generic
model implementation, which is common to all VirtIO devices, got polished fairly.
The new block device model is not configurable yet. By now, the VMM is
hard-coded to provide exactly one block device. Consequently, one route to a
Block service needs to be provided to the VMM component.
The execution of the test run-script in _repos/os/run/vmm_arm.run_ shows
the new VirtIO block device in action.
Device drivers
##############
Power-gating of PCI devices on x86
==================================
PCI devices have several PCI capabilities that describe the feature set
the device supports, as defined by the PCI specification. The platform driver - which
is the gatekeeper of devices on Genode - got extended to power on and power off
devices whenever the PCI power capability is supported. When powering on, a device reset
is issued if it is supported by the PCI device. During release of a driver from a
device, all DMA memory associated to the device is
flushed from the IO-MMU TLB to avoid any further access.
Additionally, the platform driver has become able to respond to configuration
changes. Special care must be taken if the configuration of a running device
driver changes. If the configuration re-evaluation concludes that a driver is no longer
permitted to use an already assigned PCI device, the Platform session
will be closed forcefully, making the device inaccessible to the driver.
The extended features of the platform driver supplement our previous work of
restarting respectively replacing a running graphics driver in Sculpt OS. The driver
manager, as used by Sculpt, uses Genode's heartbeat monitoring to check for the
liveliness of the Intel framebuffer driver and restarts it automatically if the
driver becomes unresponsive. Restarting
involves closing the Platform session, thereby powering off the Intel device,
and reopening the Platform session, thereby powering and resetting the
Intel device into a functional state.
This self-healing mechanism can be seen in action in the recording of our
[https://fosdem.org/2021/schedule/event/microkernel_pluggable_device_drivers_for_genode/ - FOSDEM talk]
about pluggable device drivers.
USB drivers
===========
Additional HID devices
~~~~~~~~~~~~~~~~~~~~~~
It's a sad truth that some popular USB keyboards and mice do not fully
comply with the USB HID standard. The Linux kernel comes with dozens
of special functions to fix up quirks and enable these devices
for Linux systems also. With the current release, we adopt quirk functions
for Apple HID devices and mice based on the Holtek chipset (e.g., the
Sharkoon Drakonia) that are applied automatically if one of these
devices is plugged.
USB robustness
~~~~~~~~~~~~~~
We improved the robustness of the USB HID driver with regard to device
reconnection, as well as the robustness of the DWC OTG host driver for
the Raspberry Pi when used with HID devices.
Isochronous transfers
~~~~~~~~~~~~~~~~~~~~~
While looking more closely into supporting isochronous transfers
driven by the USB pass-through use-case, we encountered and addressed shortcomings
in the current implementation in the USB host-controller driver
when dealing with IN transfers containing multiple isochronous frames.
However, this is only a first step as we identified significant potential for
optimization and robustness improvements.
Platforms
#########
Pine-A64-LTS single board computer
==================================
Our [https://genode.org/about/road-map - road map] envisions
the use of Genode on the Pinephone by the end of the year. As a first stepping
stone, the current release adds basic board support for the
[https://pine64.com/product-category/pine-a64-ltslong-term-supply/ - Pine-A64-LTS]
single-board computer. We take this line of work as a welcome opportunity to
thoroughly document the porting process. You can find the work explained in
great detail in the following article series.
# [https://genodians.org/nfeske/2020-12-10-pine-fun-warmup - Warming up for some Pine fun]
# [https://genodians.org/nfeske/2020-12-17-pine-fun-serial - Bare-metal serial output]
# [https://genodians.org/nfeske/2021-01-28-pine-fun-kernel-skeleton - Kernel skeleton]
# [https://genodians.org/nfeske/2021-02-11-pine-fun-debugging - How did we come here?]
# [https://genodians.org/nfeske/2021-02-18-pine-fun-user-land - Excursion to the user land]
The latest state of this line of work is available at a dedicated repository:
:Genode board support for Allwinner SoCs:
[https://github.com/nfeske/genode-allwinner]
RISC-V
======
RISC-V development has been on the hold at Genode Labs for a while. But with the
current release this has changed. One of the main goals we had for a long time
is the use of Qemu instead of the Spike emulator for our test infrastructure, since
every other platform runs on Qemu, Spike causes additional overhead at Genode
Labs.
By updating the privileged ISA specification support from 1.9.1 to 1.10,
we became able to use recent Qemu versions (e.g., 4.2.1).
Thanks to this change, we could remove the _spike_ board and add a new
_riscv_qemu_ board to our _base_hw_ kernel implementation.
As another nice side effect, Qemu ships its own OpenSBI machine binary, which
implements the machine mode and SBI calls. It can be enabled through the "-bios"
command line option. With a machine mode for ISA 1.10 in place, we were able to
remove the old [https://github.com/ssumpf/bbl-lite - BBL] machine mode
implementation from Genode.
For more information on this topic please refer to the corresponding
[https://genodians.org/ssumpf/2021-02-24-riscv - Genodians article].
In order to improve development speed, we were able to reduce the link time for
_core_ and its debugging variant from about 50 to 5 seconds. Additionally, we
fixed long standing link errors that were caused by mixing up soft float and
hard float objects as well as misconfigured linker scripts.
Removal of Muen separation kernel support
=========================================
Since
[https://genode.org/documentation/release-notes/15.08#Genode_on_top_of_the_Muen_Separation_Kernel - version 15.08],
Genode supported the use of the [https://muen.sk - Muen] separation kernel as
underlying platform. The driving force behind the original development was the
joyful collaboration with the Muen developers Adrian-Ken Rueegsegger and Reto
Buerki and the prospect for products that combine the rigidity of a separation
kernel with the dynamic workloads enabled by Genode.
However, over the past 5 years, this potential synergy remained untapped.
In hindsight, the stacking of one microkernel-based system onto another
microkernel-based system is a tough sell. Hosting dynamic workloads in a Linux
VM atop Muen is certainly more relatable to Muen users. Vice versa, for Genode
users, Genode on bare hardware is less complex and more flexible than using
the framework atop a separation kernel.
Without adoption of the joint platform, neither of both teams can justify the
ongoing effort needed for the continued maintenance of Genode on Muen. Hence,
we [https://github.com/genodelabs/genode/issues/3995 - concluded] to remove
Muen as an officially supported platform.
Build system and tools
######################
Streamlined distinction of boards by build and run tools
========================================================
In
[https://genode.org/documentation/release-notes/20.05#Board_support_outside_the_Genode_main_repository - Genode 20.05],
we introduced the principle ability to decouple board-support packages from
the project's main repository. We thereby want to enable developers outside
the Genode core team to port Genode to diverse hardware platforms.
With the current release, we further refined the structure of the code base and
the tooling to largely eliminate remaining points of friction when hosting
board support in external repositories.
We ultimately removed the use of board-specific SPEC values throughout the
build system and run scripts. SPEC values are now solely used to refer to
aspects of an instruction-set architecture, e.g., x86, 64bit, or arm_v8a.
In run scripts, the new convenience function 'have_board' has become the
preferred way to distinguish the behavior of run scripts depending on the
targeted board now. It replaces all former uses of 'have_spec <board>'.
Moreover, the long deprecated option of the _create_builddir_ tool to create
board-specific build directories has been removed.
To simplify the hosting of board support in separate source-code repositories,
board-specific properties have moved from run-tool scripts to the new notion
of *board property directories*. Such directories named
_<repo>/board/<board>/_ contain files with board-specific information.
In particular, the 'image_link_address' file contains the physical
link address of the system image taking the board's physical memory
constraints into account, and the 'arch' file contains the CPU
architecture of the SoC. The run tool picks up this information
from the board-property files.
Furthermore, the *packaging* of the board-specific base-hw kernel has
become more formalized by leveraging the board-property directories.
This makes the packaging vastly simpler. Regardless of where the board-support
is hosted, the _content.mk_ file for a kernel source archive becomes as simple
as:
! include $(GENODE_DIR)/repos/base-hw/recipes/src/base-hw_content.inc
The board name is automatically inferred from the path of the src recipe. The
architecture is determined from _board/<name>/arch_ files. The attempt to
build a base-hw-<board> binary archive for the wrong architecture is now
gracefully handled by skipping all targets (using the REQUIRES mechanism).
Besides the improved convenience, the resulting depot archives
have become much closer tailored to the actual board by omitting files for
architectures that are not used by the board. E.g., the src/base-hw-pc
archive does not contain any ARM-related content.
Compiler cache
==============
The [https://ccache.dev - ccache] tool is a fantastic way to accelerate the
developer workflow when repeatedly building software. Since ccache is -
strictly speaking - orthogonal to the build system, configuring the Genode
build system for the use of ccache was left to each developer.
Setting up ccache is not straight-forward though. One must manually create
hooks (symlinks shadowing the compiler executables), tweak the PATH
environment variable, and customize the CROSS_DEV_PREFIX in
_etc/tools.conf_. In short, only seasoned developers jump through those hoops.
Many others may miss out on the joys of ccache.
With the current release, the build-system front end makes ccache easily
available by enabling a simple option in the _etc/build.conf_ file:
! CCACHE := yes