vasilito 7fc8bbf057 kernel: apply P8-initial-placement, P9-numa-topology, P9-proc-lock-ordering
Phase 0c, plan orders #5, #10, #11.

  P8-initial-placement: context::Context::spawn() now picks the
    least-loaded CPU for new threads based on PercpuSched.balance,
    replacing the old 'pin to birth CPU' default.

  P9-numa-topology: adds src/numa.rs (NumaTopology, NumaHint types and
    MAX_NUMA_NODES constant) and threads the get_percpu_block import
    through context/mod.rs. NUMA discovery is performed by userspace
    numad via /scheme/acpi/ and pushed to the kernel via scheme:numa;
    the kernel stores a lightweight copy for O(1) scheduler lookups.

  P9-proc-lock-ordering: fix to scheme/proc.rs acquire order to
    prevent deadlock between proc scheme handles and the per-CPU
    sched lock. Required after P8-percpu-wiring moved the scheduler
    state to per-CPU.

After this commit, three more of the plan's eleven P5–P9 patches are
landed. Remaining unlanded: P5-sched-rt-policy, P6-vruntime-switch,
P7-cache-affine-switch (all touch switch.rs which now diverges from
the patch baselines), and P5-scheme-sched-id/P5-proc-setschedpolicy/
P7-proc-setname/P7-proc-setpriority (overlap on scheme/proc.rs:10X-14X
context handle enum).

cargo check: 1 error remaining (pre-existing src/acpi/fadt.rs:110
unrelated to threading work).
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Kernel

Redox OS Microkernel

docs SLOCs counter MIT licensed

Requirements

  • nasm needs to be available on the PATH at build time.

Building The Documentation

Use this command:

cargo doc --open --target x86_64-unknown-none

Debugging

QEMU

Running QEMU with the -s flag will set up QEMU to listen on port 1234 for a GDB client to connect to it. To debug the redox kernel run.

make qemu gdb=yes

This will start a virtual machine with and listen on port 1234 for a GDB or LLDB client.

GDB

If you are going to use GDB, run these commands to load debug symbols and connect to your running kernel:

(gdb) symbol-file build/kernel.sym
(gdb) target remote localhost:1234

LLDB

If you are going to use LLDB, run these commands to start debugging:

(lldb) target create -s build/kernel.sym build/kernel
(lldb) gdb-remote localhost:1234

After connecting to your kernel you can set some interesting breakpoints and continue the process. See your debuggers man page for more information on useful commands to run.

Notes

  • Always use foo.get(n) instead of foo[n] and try to cover for the possibility of Option::None. Doing the regular way may work fine for applications, but never in the kernel. No possible panics should ever exist in kernel space, because then the whole OS would just stop working.

  • If you receive a kernel panic in QEMU, use pkill qemu-system to kill the frozen QEMU process.

How To Contribute

To learn how to contribute to this system component you need to read the following document:

Development

To learn how to do development with this system component inside the Redox build system you need to read the Build System and Coding and Building pages.

How To Build

To build this system component you need to download the Redox build system, you can learn how to do it on the Building Redox page.

This is necessary because they only work with cross-compilation to a Redox virtual machine, but you can do some testing from Linux.

Funding - Unix-style Signals and Process Management

This project is funded through NGI Zero Core, a fund established by NLnet with financial support from the European Commission's Next Generation Internet program. Learn more at the NLnet project page.

NLnet foundation logo NGI Zero Logo

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Description
RedBear Operating System, based on RedoxOS. Licenced under MIT license.
https://redbearos.org
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