rp-hal-boards/rp2040-hal/src/multicore.rs

215 lines
6.2 KiB
Rust
Raw Normal View History

//! Multicore support
// See [Chapter ?? Section ??](https://datasheets.raspberrypi.org/rp2040/rp2040_datasheet.pdf) for more details
use crate::pac;
#[cfg(feature = "alloc")]
extern crate alloc;
/// Errors for multicore operations.
#[derive(Debug)]
pub enum Error {
/// Operation is invalid on this core.
InvalidCore,
/// Core was unresposive to commands.
Unresponsive,
}
// We pass data to cores via the stack, so we read
// the data off the stack and into parameters that
// rust can read here. Ideally this would be a
// #[naked] function but that is not stable yet.
static MULTICORE_TRAMPOLINE: [u16; 2] = [
0xbd03, // pop {r0, r1, pc} - call wrapper (pc) with r0 and r1
0x46c0, // nop - pad this out to 32 bits long
];
#[inline(always)]
fn install_stack_guard(stack_bottom: *mut usize) {
let core = unsafe { pac::CorePeripherals::steal() };
// Trap if MPU is already configured
if core.MPU.ctrl.read() != 0 {
cortex_m::asm::udf();
}
// The minimum we can protect is 32 bytes on a 32 byte boundary, so round up which will
// just shorten the valid stack range a tad.
let addr = (stack_bottom as u32 + 31) & !31;
// Mask is 1 bit per 32 bytes of the 256 byte range... clear the bit for the segment we want
let subregion_select = 0xff ^ (1 << ((addr >> 5) & 7));
unsafe {
core.MPU.ctrl.write(5); // enable mpu with background default map
core.MPU.rbar.write((addr & !0xff) | 0x8);
core.MPU.rasr.write(
1 // enable region
| (0x7 << 1) // size 2^(7 + 1) = 256
| (subregion_select << 8)
| 0x10000000, // XN = disable instruction fetch; no other bits means no permissions
);
}
}
#[inline(always)]
fn core1_setup(stack_bottom: *mut usize) {
install_stack_guard(stack_bottom);
// TODO: irq priorities
}
/// Multicore execution management.
pub struct Multicore<'p> {
cores: [Core<'p>; 2],
}
impl<'p> Multicore<'p> {
/// Create a new |Multicore| instance.
pub fn new(psm: &'p mut pac::PSM, ppb: &'p mut pac::PPB, sio: &'p mut crate::sio::Sio) -> Self {
Self {
cores: [
Core { inner: None },
Core {
inner: Some((psm, ppb, sio)),
},
],
}
}
/// Get the available |Core| instances.
pub fn cores(&mut self) -> &'p mut [Core] {
&mut self.cores
}
}
/// A handle for controlling a logical core.
pub struct Core<'p> {
inner: Option<(&'p mut pac::PSM, &'p mut pac::PPB, &'p mut crate::sio::Sio)>,
}
impl<'p> Core<'p> {
/// Get the id of this core.
pub fn id(&self) -> u8 {
match self.inner {
None => 0,
Some(..) => 1,
}
}
fn inner_spawn(
&mut self,
wrapper: *mut (),
entry: *mut (),
stack: &'static mut [usize],
) -> Result<(), Error> {
if let Some((psm, ppb, sio)) = self.inner.as_mut() {
// Reset the core
psm.frce_off.modify(|_, w| w.proc1().set_bit());
while !psm.frce_off.read().proc1().bit_is_set() {
cortex_m::asm::nop();
}
psm.frce_off.modify(|_, w| w.proc1().clear_bit());
// Set up the stack
let mut stack_ptr = unsafe { stack.as_mut_ptr().add(stack.len()) };
let mut push = |v: usize| unsafe {
stack_ptr = stack_ptr.sub(1);
stack_ptr.write(v);
};
push(wrapper as usize);
push(stack.as_mut_ptr() as usize);
push(entry as usize);
let vector_table = ppb.vtor.read().bits();
// After reset, core 1 is waiting to receive commands over FIFO.
// This is the sequence to have it jump to some code.
let cmd_seq = [
0,
0,
1,
vector_table as usize,
stack_ptr as usize,
MULTICORE_TRAMPOLINE.as_ptr() as usize + 1,
];
let mut seq = 0;
let mut fails = 0;
loop {
let cmd = cmd_seq[seq] as u32;
if cmd == 0 {
sio.fifo.drain();
cortex_m::asm::sev();
}
sio.fifo.write_blocking(cmd);
let response = sio.fifo.read_blocking();
if cmd == response {
seq += 1;
} else {
seq = 0;
fails += 1;
if fails > 16 {
return Err(Error::Unresponsive);
}
}
if seq >= cmd_seq.len() {
break;
}
}
Ok(())
} else {
Err(Error::InvalidCore)
}
}
/// Spawn a function on this core.
#[cfg(not(feature = "alloc"))]
pub fn spawn(&mut self, entry: fn() -> !, stack: &'static mut [usize]) -> Result<(), Error> {
#[allow(improper_ctypes_definitions)]
extern "C" fn core1_no_alloc(entry: fn() -> !, stack_bottom: *mut usize) -> ! {
core1_setup(stack_bottom);
entry();
}
self.inner_spawn(core1_no_alloc as _, entry as _, stack)
}
/// Spawn a function on this core.
#[cfg(feature = "alloc")]
pub fn spawn<F>(&mut self, entry: F, stack: &'static mut [usize]) -> Result<(), Error>
where
F: FnOnce() -> bad::Never,
F: Send + 'static,
{
use alloc::boxed::Box;
let main: Box<dyn FnOnce() -> bad::Never> = Box::new(move || entry());
let p = Box::into_raw(Box::new(main));
extern "C" fn core1_alloc(entry: *mut (), stack_bottom: *mut usize) -> ! {
core1_setup(stack_bottom);
let main = unsafe { Box::from_raw(entry as *mut Box<dyn FnOnce() -> bad::Never>) };
main();
}
self.inner_spawn(core1_alloc as _, p as _, stack)
}
}
// https://github.com/nvzqz/bad-rs/blob/master/src/never.rs
#[cfg(feature = "alloc")]
mod bad {
pub(crate) type Never = <F as HasOutput>::Output;
pub trait HasOutput {
type Output;
}
impl<O> HasOutput for fn() -> O {
type Output = O;
}
type F = fn() -> !;
}