Several nightly network-related tests fail currently on sel4/pc because the
new e1000 NIC driver requires more capabilities. The "drivers nic" package
was already adapted to the new requirement but some tests fail to provide
enough caps to the corresponding sub system. This commit tries to fix all
remaining tests.
Ref #4923
* During a session-close, the device-specific usb task and driver data
gets freed. Part of it was the RPC data. To prevent use-after-free
turn it into a pointer and leave it on the stack of the caller thread
* During a device release, URBs discards, and reset operation the Linux task
might get blocked, and then a RPC caller task might return if the RPC
operation was marked as finished already, although it hasn't succeeded yet
* USB devio RESET has to be done before a device release to be effective
Fixgenodelabs/genode#4969
* Within flush_transfer of the USB session a given entrypoint gets
resetted, to be effective al related URBs need to be discarded first
* Discarding URBs shall be done in reverse order, like libusb is doing it,
where it warns about potential races otherwise
Ref genodelabs/genode#4969
* Allow support for kernel configurations without CONFIG_IRQ_DOMAIN_HIERARCHY
* Export `irq_domain` instantiated for driver-specific extensions of the irqchip
Fixgenodelabs/genode#4964
This commit extends the Lx_kit initialization function by passing in
a signal handler that is used to perform the normally occurring
scheduler execution and is a follow-up change for the decoupling
scheduler execution commit.
Instead of burying the signal handler in the 'Lx_kit::Scheduler'
object it is provided by the main object where the driver is free
to perform any additional step before or after executing the scheduler.
Issue #4927Fixes#4952
Since the wireless LAN driver is actually a 'Libc::Component' due to
its incorporation of the 'wpa_spplicant' application, we have to
intercept its construction because we have to initialize the Lx_kit
environment before any static ctors are executed. Most Linux initcalls
are implemented as ctors that will be otherwise implicitly executed
before the controll is given to us in 'Libc::Component::construct'.
Issue #4927.
Prevent missing new RPC calls handed over to a Linux task
of a corresponding usb-device, while that task blocked
during enqueuing of asynchronous URBs.
Fixedgenodelabs/genode#4955
Decoupling the scheduler execution can lead to missed interrupts
because the current implementation only handles one pending
interrupt and requires immediate processing.
This commit introduces a helper object that is used to capture
any occuring interrupts that are then handled consecutively.
Issue #4927.
Prior to this commit, whenever an external event occurred, for example
timer or interrupt, the corresponding I/O signal handler was triggered.
This handler unblocked the task waiting for the event and initiated the
immediate execution of all unblocked tasks. Since these tasks may hit
serialization points, e.g. synchronously waiting for packet stream
operations, that require handling of other I/O signals this leads to
nested execution. This, however, is not supported and mixes application
and I/O level signal handling.
The flagging of the scheduling intent is now decoupled from its
execution by using an application level signal handler that is run in
the context of the components main entrypoint. The I/O signal handler
now triggers the scheduling execution by sending a local signal to
the EP.
Since it might be necessary to execute a pending schedule from the EP
directly the scheduler is extended with the 'execute' member function
that performs the check that the scheduler is called from within the
EP and triggers the execution afterwards.
Issue #4927.
With these options enabled comparative testing between pc_linux drivers
and bzImages becomes much easier on EFI-only machines. The impact on the
actual Genode drivers is minimal.
USB devices that are never associated to client sessions lack
usb_per_dev_data (and a kernel thread). Therefore, the devices should be
discontinued directly on unplug as no URBs can be pending.
Issue genodelabs/genode#4795
This back end can be used in place of the existing jitterentropy based
on in case random is not strictly needed by the component but one
wants to use the available 'shadow/drivers/char/random.c'
implementation.
Issue genodelabs/genode-allwinner#21.
The implementation was already part of the Zynq's sd_card driver and
since other ARM drivers need it as well, promote it to the common
shadow library.
Issue genodelabs/genode-allwinner#21.
On platforms different than x86 the subsys initcall `pci_subsys_init`
is not available. Therefore, we choose an alternative one here.
Fixgenodelabs/genode#4907
This commit introduces preliminary support for joining networks secured
via WPA3-personal. So far it was only tested with the one OpenWRT AP
configured for WPA3 (see excerpt below) where it WPA3-only as well as
WPA2/WPA3 mixed worked fine.
Scan results excerpt:
00:11:22:33:44:55 5180 -45 [WPA2-SAE-CCMP][SAE-H2E][ESS][UTF-8] PewPew
00:11:22:33:44:55 2412 -67 [WPA2-PSK+SAE+PSK-SHA256-CCMP][SAE-H2E][ESS][UTF-8] PewPew2
Issue #4861.
It turns out solely relying on the name of the compilation-unit
is not enough. In at least one multi-device driver, e.g. rtlwifi,
an equally called compilation-unit is found in several different
directories. There KBUILD_MODNAME is used to name the driver,
which fails later on as the driver framework refuses to register
an equally named driver twice.
Instead of only considering the name of the compilation-unit also
include the last element of the path to generate differentiating
KBUILD_MODNAME value.
Issue #4861.
The supplicant is updated to the current release and is now downloaded
as archive rather than pulled from git. For the time being 'libnl' is
still kept at 3.2.25 as the current 3.7.0 release relies on more Linux
infrastructure that our integration does not provide.
Issue #4861.
This commit changes the firmware handling from requesting each
firmware file as a ROM module that is checked against a list of
known images (including their size) to requesting each file via
the local VFS of the 'wifi_drv'. This allows for using the original
probing mechanism that tries to select a matching firmware version.
The 'repos/dde_linux/src/drivers/wifi/README' file contains more
detailed information on how to configure the driver.
Issue #4861.
The bulk of the driver code now lives in the 'dde_linux' repository,
which is available on all platforms, from where it can be referenced by
other repositories.
The 'wifi_drv' binary was delegated to a generic harness that includes
all configuration and management functionality shared by all wireless
device driver components, e.g., the wpa_supplicant. The code of the
device driver emulation environment is located in 'src/lib/wifi'. It
is referenced by the platform-specific driver library that resides in
the corresponding platform repository. The runtime configuration needs
to point the driver to proper driver library.
The platform-specific library is in charge of orchestrating the contrib
source utilized by the driver as well as providing the 'source.list'
and 'dep.list' files. It must include the generic library snippet
'repos/dde_linux/lib/wifi.inc' that deals with managing the emulation
environment code.
The 'repos/dde_linux/src/drivers/wifi/README' file contains more
detailed information on how to deploy the driver.
Issue #4861.