Our implementation for Jails resembles much of how FreeBSD jails are
working - it's essentially only a matter of using a RefPtr in the
Process class to a Jail object. Then, when we iterate over all processes
in various cases, we could ensure if either the current process is in
jail and therefore should be restricted what is visible in terms of
PID isolation, and also to be able to expose metadata about Jails in
/sys/kernel/jails node (which does not reveal anything to a process
which is in jail).
A lifetime model for the Jail object is currently plain simple - there's
simpy no way to manually delete a Jail object once it was created. Such
feature should be carefully designed to allow safe destruction of a Jail
without the possibility of releasing a process which is in Jail from the
actual jail. Each process which is attached into a Jail cannot leave it
until the end of a Process (i.e. when finalizing a Process). All jails
are kept being referenced in the JailManagement. When a last attached
process is finalized, the Jail is automatically destroyed.
This decreases the number of bytes necessary to capture the variables
for this lambda. The next step will be to remove dynamic allocations
from AK::Function which depends on this change to keep the size of
AK::Function objects reasonable.
The kernel image grew so much that it wasn't possible to jump to the C++
symbol anymore, since this generated a 'relocation truncated' error when
linking.
Having this function return `nullptr` explicitly triggers the compiler's
inbuilt checker, as it knows the destination is null. Having this as a
static (scoped) variable for now circumvents this problem.
This sets up the RPi::Timer to trigger an interurpt every 4ms using one
of the comparators. The actual time is calculated by looking at the main
counter of the RPi::Timer using the Timer::update_time function.
A stub for Scheduler::timer_tick is also added, since the TimeManagement
code now calls the function.
This makes it easier to differentiate between cases where certain
functionality is not implemented vs. cases where a code location
should really be unreachable.
In a few places we check `!Processor::in_critical()` to validate
that the current processor doesn't hold any kernel spinlocks.
Instead lets provide it a first class name for readability.
I'll also be adding more of these, so I would rather add more
usages of a nice API instead of this implicit/assumed logic.
This change ensures that the scheduler doesn't depend on a platform
specific or arch-specific code when it initializes itself, but rather we
ensure that in compile-time we will generate the appropriate code to
find the correct arch-specific current time methods.
For some odd reason we used to return PhysicalPtr for a page_table_base
result, but when setting it we accepted only a 32 bit value, so we
truncated valid 64 bit addresses into 32 bit addresses by doing that.
With this commit being applied, now PageDirectories can be located
beyond the 4 GiB barrier.
This was found by sin-ack, therefore he should be credited with this fix
appropriately with Co-authored-by sign.
Co-authored-by: sin-ack <sin-ack@users.noreply.github.com>
There is no particular reason why this section should be marked as
`NOBITS` (as it might very well include initialized values), and it
resolves 90% of the mismatches between the input and output sections,
which LLD now warns about when linking.
Doesn't use them in libc headers so that those don't have to pull in
AK/Platform.h.
AK_COMPILER_GCC is set _only_ for gcc, not for clang too. (__GNUC__ is
defined in clang builds as well.) Using AK_COMPILER_GCC simplifies
things some.
AK_COMPILER_CLANG isn't as much of a win, other than that it's
consistent with AK_COMPILER_GCC.
The BootFramebufferConsole class maps the framebuffer using the
MemoryManager, so to be able to draw the logo, we need to get this
mapped framebuffer. This commit adds a unsafe API for that.
The MemoryManager now works, so we can use the same code as on x86 to
map the framebuffer. Since it uses the MemoryManager, the initialization
of the BootFramebufferConsole has to happen after the MemoryManager is
working.
For the initial page tables we only need to identity map the kernel
image, the rest of the memory will be managed by the MemoryManager. The
linker script is updated to get the kernel image start and end
addresses.
The page table and page directory formats are architecture specific, so
move the headers into the Arch directory. Also move the aarch64 page
table constants from aarch64/MMU.cpp to aarch64/PageDirectory.h.
When an exception happens it is sometimes hard to figure out where
exactly the exception happened, so use the frame pointer of the trap
frame to print a backtrace.
