kprintf should not really care about the hardware-specific details of
each UART or serial port out there, so instead of using x86 specific
instructions, let's ensure that we will compile only the relevant code
for debug output for a targeted-specific platform.
Now that the Spinlock code is not dependent on architectural specific
code anymore, we can move it back to the Locking folder. This also means
that the Spinlock implemenation is now used for the aarch64 kernel.
This commit updates the lock function from Spinlock and
RecursiveSpinlock to return the InterruptsState of the processor,
instead of the processor flags. The unlock functions would only look at
the interrupt flag of the processor flags, so we now use the
InterruptsState enum to clarify the intent, and such that we can use the
same Spinlock code for the aarch64 build.
To not break the build, all the call sites are updated aswell.
By default these 2 fields were zero, which made it rely on
implementation defined behavior whether these fields internally would be
set to the correct value. The ARM processor in the Raspberry PI (and
QEMU 6.x) would actually fixup these values, whereas QEMU 7.x now does
not do that anymore, and a translation fault would be generated instead.
For more context see the relevant QEMU issue:
- https://gitlab.com/qemu-project/qemu/-/issues/1157Fixes#14856
Until now, our kernel has reimplemented a number of AK classes to
provide automatic internal locking:
- RefPtr
- NonnullRefPtr
- WeakPtr
- Weakable
This patch renames the Kernel classes so that they can coexist with
the original AK classes:
- RefPtr => LockRefPtr
- NonnullRefPtr => NonnullLockRefPtr
- WeakPtr => LockWeakPtr
- Weakable => LockWeakable
The goal here is to eventually get rid of the Lock* classes in favor of
using external locking.
Instead of having two separate implementations of AK::RefCounted, one
for userspace and one for kernelspace, there is now RefCounted and
AtomicRefCounted.
This makes sure that the debug message are properly aligned when running
the kernel bare-metal on a Raspberry Pi. While we are here, also move
the function out of line.
There's no real value in separating physical pages to supervisor and
user types, so let's remove the concept and just let everyone to use
"user" physical pages which can be allocated from any PhysicalRegion
we want to use. Later on, we will remove the "user" prefix as this
prefix is not needed anymore.
For an upcoming change to support interrupts in this driver, this class
has to inherit from IRQHandler. That in turn will make this class
virtual, which will then actually call the destructor of the class. We
don't want this to happen, thus we have to wrap the class in a
AK::NeverDestroyed.
These 2 classes currently contain much code that is x86(_64) specific.
Move them to the architecture specific directory. This also allows for a
simpler implementation for aarch64.
This register can be used to check whether the 4 different types of
interrupts are masked. A different variant can be used to set/clear
specific interrupt bits.
This requires us to add an Interrupts.h file in the Kernel/Arch
directory, which includes the architecture specific files.
The commit also stubs out the functions to be able to compile the
aarch64 Kernel.
Including signal.h would cause several ports to fail on build,
because it would end up including AK/Platform.h through these
mcontext headers. This is problematic because AK/Platform.h defines
several macros with very common names, such as `NAKED` (breaks radare2),
and `NO_SANITIZE_ADDRESS` and `ALWAYS_INLINE` (breaks ruby).
When disabling UBSAN, the compiler would complain that the constraints
of the inline assembly could not be met. By adding the alignas specifier
the compiler can now determine that the struct can be passed into a
register, and thus the constraints are met.
Instead of storing the current Processor into a core local register, we
currently just store it into a global, since we don't support SMP for
aarch64 anyway. This simplifies the initial implementation.
