This was kept in the kernel as a way to keep exercising the code, but it
doesn't belong there. This moves it to init, which doesn't do anything
but probe for devices currently - but at least it's executing the code
in userspace now.
init still uses a custom _start to set up the stack, but then jumps to
_libc_crt0_start. The modules data passed to it is taken from the
j6_init_args instead of having it stashed into a global variable.
Also replace several uses of snprintf/j6_log with j6::syslog.
In order to pass along arguments like the framebuffer, it's far simpler
to have that data stored along with the modules than mapping new pages
for every structure. Also now optionally pass a module's data to a
driver as init starts it.
This commit changes the add_user_thunk to point to a new routine,
initialize_user_cpu, which sets all the registers that were previously
unset when starting a new user thread. The values for rdi and rsi are
popped off the initial stack values that add_user_thunk sets up, so that
user thread procs can take up to two arguments.
To suppor this, j6_thread_create gained two new arguments, which are
passed on to the thread.
This also let me finally get rid of the hack of passing an argument in
rsp when starting init.
Previously we were hard-coding loading specific files (the UART driver
and logging server) from the initrd. Now j6romfs has a for_each() method
to allow iterating all files in a directory, and init loads all programs
from /jsix/drivers and /jsix/services. Eventually this will need more
dynamic loading decisions for drivers but for now it's fine.
The symbol table needs to be passed to the panic handler very early in
the kernel, loading it in init is far less useful. Return it to the boot
directory and remove it from the initrd.
Load drv.uart.elf and srv.logger.elf from the initrd and start them.
It's extremely manual and hard-coded at the moment, but it works and
they run, getting us back to where we were pre-initrd branch.
The initrd image is now created by the build system, loaded by the
bootloader, and passed to srv.init, which loads it (but doesn't do
anything with it yet, so this is actually a functional regression).
This simplifies a lot of the modules code between boot and init as well:
Gone are the many subclasses of module and all the data being inline
with the module structs, except for any loaded files. Now the only
modules loaded and passed will be the initrd, and any devices only the
bootloader has knowledge of, like the UEFI framebuffer.
Instead of handles / capabilities having numeric ids that are only valid
for the owning process, they are now global in a system capabilities
table. This will allow for specifying capabilities in IPC that doesn't
need to be kernel-controlled.
Processes will still need to be granted access to given capabilities,
but that can become a simpler system call than the current method of
sending them through mailbox messages (and worse, having to translate
every one into a new capability like was the case before). In order to
track which handles a process has access to, a new node_set based on
node_map allows for an efficient storage and lookup of handles.
The init process now serves as a service locator for its children,
passing all children a mailbox handle on which it is serving the service
locator protocol.
In preparation for the new mailbox IPC model, blocking threads needed an
overhaul. The `wait_on_*` and `wake_on_*` methods are gone, and the
`block()` and `wake()` calls on threads now pass a value between the
waker and the blocked thread.
As part of this change, the concept of signals on the base kobject class
was removed, along with the queue of blocked threads waiting on any
given object. Signals are now exclusively the domain of the event object
type, and the new wait_queue utility class helps manage waiting threads
when an object does actually need this functionality. In some cases (eg,
logger) an event object is used instead of the lower-level wait_queue.
Since this change has a lot of ramifications, this large commit includes
the following additional changes:
- The j6_object_wait, j6_object_wait_many, and j6_thread_pause syscalls
have been removed.
- The j6_event_clear syscall has been removed - events are "cleared" by
reading them now. A new j6_event_wait syscall has been added to read
events.
- The generic close() method on kobject has been removed.
- The on_no_handles() method on kobject now deletes the object by
default, and needs to be overridden by classes that should not be.
- The j6_system_bind_irq syscall now takes an event handle, as well as a
signal that the IRQ should set on the event. IRQs will cause a waiting
thread to be woken with the appropriate bit set.
- Threads waking due to timeout is simplified to just having a
wake_timeout() accessor that returns a timestamp.
- The new wait_queue uses util::deque, which caused the disovery of two
bugs in the deque implementation: empty deques could still have a
single array allocated and thus return true for empty(), and new
arrays getting allocated were not being zeroed first.
- Exposed a new erase() method on util::map that takes a node pointer
instead of a key, skipping lookup.
Another issue related to the bug fix in 3be4b10 - if the segment is
non-aligned, the size of the VMA needs to be seg.mem_size + the prologue
size.
Also renamed the variables from prelude/prologue to prologue/epilogue;
it must have been late at night that I wrote that...
The drv.uart ELF currently ends up with a segment vaddr starting at
0x215010, which includes .data and .bss. The old loader was mishandling
this in a few ways:
- Not zeroing out the leading 16 bytes, or the trailing .bss section
- Copying the segment data to the start of the page, so it was offset by
-16 bytes.
- Mapping the VMA into the child program at the non-page-aligned
address, which causes all sorts of trouble.
This has always been on the todo list, but it finally bit me. srv.init
re-uses load addresses when loading multiple programs, and collision
between reused addresses was causing corruption without the TLB flush.
Now srv.init also doesn't increment its load address for sections when
loading a single program either, since unmapping pages actually works.
Added the handle_clone syscall which allows for cloning a handle with
a subset of the original handle's capabilities.
Related changes:
- srv.init now calls handle_clone on its system handle, and load_program
was changed to allow this second system handle to be passed to loaded
programs instead. However, as drv.uart is still a driver AND a log
reader, this new handle is not actually passed yet.
- The definition parser was using a set for the cap list, which meant
the order (and thus values) of caps was not static.
- Some code in objects/handle.h was made more explicit about what bits
meant what.
This change finally adds capabilities to handles. Included changes:
- j6_handle_t is now again 64 bits, with the highest 8 bits being a type
code, and the next highest 24 bits being the capability mask, so that
programs can check type/caps without calling the kernel.
- The definitions grammar now includes a `capabilities [ ]` section on
objects, to list what capabilities are relevant.
- j6/caps.h is auto-generated from object capability lists
- init_libj6 again sets __handle_self and __handle_sys, this is a bit
of a hack.
- A new syscall, j6_handle_list, will return the list of existing
handles owned by the calling process.
- syscall_verify.cpp.cog now actually checks that the needed
capabilities exist on handles before allowing the call.
First attempt at a UART driver. I'm not sure it's the most stable. Now
that userspace is handling displaying logs, also removed serial and log
output support from the kernel.
This is a rather large commit that is widely focused on cleaning things
out of the 'junk drawer' that is src/include. Most notably, several
things that were put in there because they needed somewhere where both
the kernel, boot, and init could read them have been moved to a new lib,
'bootproto'.
- Moved kernel_args.h and init_args.h to bootproto as kernel.h and
init.h, respectively.
- Moved counted.h and pointer_manipulation.h into util, renaming the
latter to util/pointers.h.
- Created a new src/include/arch for very arch-dependent definitions,
and moved some kernel_memory.h constants like frame size, page table
entry count, etc to arch/amd64/memory.h. Also created arch/memory.h
which detects platform and includes the former.
- Got rid of kernel_memory.h entirely in favor of a new, cog-based
approach. The new definitions/memory_layout.csv lists memory regions
in descending order from the top of memory, their sizes, and whether
they are shared outside the kernel (ie, boot needs to know them). The
new header bootproto/memory.h exposes the addresses of the shared
regions, while the kernel's memory.h gains the start and size of all
the regions. Also renamed the badly-named page-offset area the linear
area.
- The python build scripts got a few new features: the ability to parse
the csv mentioned above in a new memory.py module; the ability to add
dependencies to existing source files (The list of files that I had to
pull out of the main list just to add them with the dependency on
memory.h was getting too large. So I put them back into the sources
list, and added the dependency post-hoc.); and the ability to
reference 'source_root', 'build_root', and 'module_root' variables in
.module files.
- Some utility functions that were in the kernel's memory.h got moved to
util/pointers.h and util/misc.h, and misc.h's byteswap was renamed
byteswap32 to be more specific.
Now that kutil has no kernel-specific code in it anymore, it can
actually be linked to by anything, so I'm renaming it 'util'.
Also, I've tried to unify the way that the system libraries from
src/libraries are #included using <> instead of "".
Other small change: util::bip_buffer got a spinlock to guard against
state corruption.
Add a simple ELF loader to srv.init to load and start any module_program
parameters passed from the bootloader. Also creates stacks for newly
created threads.
Also update thread creation in testapp to create stacks.
