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New VA108xx Rust workspace structure + dependency updates

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- The workspace is now a monorepo without submodules. The HAL, PAC and BSP
  are integrated directly
- Update all dependencies: embedded-hal v1 and RTIC v2
This commit is contained in:
Robin Müller
2024-06-16 16:16:45 +02:00
parent 05ef8e57e1
commit 94c6d91bae
253 changed files with 31172 additions and 100 deletions
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382
va108xx-hal/src/gpio/reg.rs Normal file
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use super::dynpins::{self, DynGroup, DynPinId, DynPinMode};
use super::pins::{FilterType, InterruptEdge, InterruptLevel, PinState};
use super::IsMaskedError;
use crate::clock::FilterClkSel;
use va108xx::{ioconfig, porta};
/// Type definition to avoid confusion: These register blocks are identical
type PortRegisterBlock = porta::RegisterBlock;
//==================================================================================================
// ModeFields
//==================================================================================================
/// Collect all fields needed to set the [`PinMode`](super::PinMode)
#[derive(Default)]
struct ModeFields {
dir: bool,
opendrn: bool,
pull_en: bool,
/// true for pullup, false for pulldown
pull_dir: bool,
funsel: u8,
enb_input: bool,
}
impl From<DynPinMode> for ModeFields {
#[inline]
fn from(mode: DynPinMode) -> Self {
let mut fields = Self::default();
use DynPinMode::*;
match mode {
Input(config) => {
use dynpins::DynInput::*;
fields.dir = false;
match config {
Floating => (),
PullUp => {
fields.pull_en = true;
fields.pull_dir = true;
}
PullDown => {
fields.pull_en = true;
}
}
}
Output(config) => {
use dynpins::DynOutput::*;
fields.dir = true;
match config {
PushPull => (),
OpenDrain => {
fields.opendrn = true;
}
ReadableOpenDrain => {
fields.enb_input = true;
fields.opendrn = true;
}
ReadablePushPull => {
fields.enb_input = true;
}
}
}
Alternate(config) => {
fields.funsel = config as u8;
}
}
fields
}
}
//==================================================================================================
// Register Interface
//==================================================================================================
pub type PortReg = ioconfig::Porta;
/*
pub type IocfgPort = ioconfig::Porta;
#[repr(C)]
pub(super) struct IocfgPortGroup {
port: [IocfgPort; 32],
}
*/
/// Provide a safe register interface for pin objects
///
/// [`PORTA`] and [`PORTB`], like every PAC `struct`, is [`Send`] but not [`Sync`], because it
/// points to a `RegisterBlock` of `VolatileCell`s. Unfortunately, such an
/// interface is quite restrictive. Instead, it would be ideal if we could split
/// the [`PORT`] into independent pins that are both [`Send`] and [`Sync`].
///
/// [`PORT`] is a single, zero-sized marker `struct` that provides access to
/// every [`PORT`] register. Instead, we would like to create zero-sized marker
/// `struct`s for every pin, where each pin is only allowed to control its own
/// registers. Furthermore, each pin `struct` should be a singleton, so that
/// exclusive access to the `struct` also guarantees exclusive access to the
/// corresponding registers. Finally, the pin `struct`s should not have any
/// interior mutability. Together, these requirements would allow the pin
/// `struct`s to be both [`Send`] and [`Sync`].
///
/// This trait creates a safe API for accomplishing these goals. Implementers
/// supply a pin ID through the [`id`] function. The remaining functions provide
/// a safe API for accessing the registers associated with that pin ID. Any
/// modification of the registers requires `&mut self`, which destroys interior
/// mutability.
///
/// # Safety
///
/// Users should only implement the [`id`] function. No default function
/// implementations should be overridden. The implementing type must also have
/// "control" over the corresponding pin ID, i.e. it must guarantee that a each
/// pin ID is a singleton.
///
/// [`id`]: Self::id
pub(super) unsafe trait RegisterInterface {
/// Provide a [`DynPinId`] identifying the set of registers controlled by
/// this type.
fn id(&self) -> DynPinId;
const PORTA: *const PortRegisterBlock = va108xx::Porta::ptr();
const PORTB: *const PortRegisterBlock = va108xx::Portb::ptr();
/// Change the pin mode
#[inline]
fn change_mode(&mut self, mode: DynPinMode) {
let ModeFields {
dir,
funsel,
opendrn,
pull_dir,
pull_en,
enb_input,
} = mode.into();
let (portreg, iocfg) = (self.port_reg(), self.iocfg_port());
iocfg.write(|w| {
w.opendrn().bit(opendrn);
w.pen().bit(pull_en);
w.plevel().bit(pull_dir);
w.iewo().bit(enb_input);
unsafe { w.funsel().bits(funsel) }
});
let mask = self.mask_32();
unsafe {
if dir {
portreg.dir().modify(|r, w| w.bits(r.bits() | mask));
// Clear output
portreg.clrout().write(|w| w.bits(mask));
} else {
portreg.dir().modify(|r, w| w.bits(r.bits() & !mask));
}
}
}
#[inline]
fn port_reg(&self) -> &PortRegisterBlock {
match self.id().group {
DynGroup::A => unsafe { &(*Self::PORTA) },
DynGroup::B => unsafe { &(*Self::PORTB) },
}
}
fn iocfg_port(&self) -> &PortReg {
let ioconfig = unsafe { va108xx::Ioconfig::ptr().as_ref().unwrap() };
match self.id().group {
DynGroup::A => ioconfig.porta(self.id().num as usize),
DynGroup::B => ioconfig.portb0(self.id().num as usize),
}
}
#[inline]
fn mask_32(&self) -> u32 {
1 << self.id().num
}
#[inline]
fn enable_irq(&self) {
self.port_reg()
.irq_enb()
.modify(|r, w| unsafe { w.bits(r.bits() | self.mask_32()) });
}
#[inline]
/// Read the logic level of an output pin
fn read_pin(&self) -> bool {
let portreg = self.port_reg();
((portreg.datainraw().read().bits() >> self.id().num) & 0x01) == 1
}
// Get DATAMASK bit for this particular pin
#[inline(always)]
fn datamask(&self) -> bool {
let portreg = self.port_reg();
(portreg.datamask().read().bits() >> self.id().num) == 1
}
/// Read a pin but use the masked version but check whether the datamask for the pin is
/// cleared as well
#[inline(always)]
fn read_pin_masked(&self) -> Result<bool, IsMaskedError> {
if !self.datamask() {
Err(IsMaskedError)
} else {
Ok(((self.port_reg().datain().read().bits() >> self.id().num) & 0x01) == 1)
}
}
/// Write the logic level of an output pin
#[inline(always)]
fn write_pin(&mut self, bit: bool) {
// Safety: SETOUT is a "mask" register, and we only write the bit for
// this pin ID
unsafe {
if bit {
self.port_reg().setout().write(|w| w.bits(self.mask_32()));
} else {
self.port_reg().clrout().write(|w| w.bits(self.mask_32()));
}
}
}
/// Write the logic level of an output pin but check whether the datamask for the pin is
/// cleared as well
#[inline]
fn write_pin_masked(&mut self, bit: bool) -> Result<(), IsMaskedError> {
if !self.datamask() {
Err(IsMaskedError)
} else {
// Safety: SETOUT is a "mask" register, and we only write the bit for
// this pin ID
unsafe {
if bit {
self.port_reg().setout().write(|w| w.bits(self.mask_32()));
} else {
self.port_reg().clrout().write(|w| w.bits(self.mask_32()));
}
Ok(())
}
}
}
/// Toggle the logic level of an output pin
#[inline(always)]
fn toggle(&mut self) {
// Safety: TOGOUT is a "mask" register, and we only write the bit for
// this pin ID
unsafe { self.port_reg().togout().write(|w| w.bits(self.mask_32())) };
}
/// Only useful for interrupt pins. Configure whether to use edges or level as interrupt soure
/// When using edge mode, it is possible to generate interrupts on both edges as well
#[inline]
fn interrupt_edge(&mut self, edge_type: InterruptEdge) {
unsafe {
self.port_reg()
.irq_sen()
.modify(|r, w| w.bits(r.bits() & !self.mask_32()));
match edge_type {
InterruptEdge::HighToLow => {
self.port_reg()
.irq_evt()
.modify(|r, w| w.bits(r.bits() & !self.mask_32()));
}
InterruptEdge::LowToHigh => {
self.port_reg()
.irq_evt()
.modify(|r, w| w.bits(r.bits() | self.mask_32()));
}
InterruptEdge::BothEdges => {
self.port_reg()
.irq_edge()
.modify(|r, w| w.bits(r.bits() | self.mask_32()));
}
}
}
}
/// Configure which edge or level type triggers an interrupt
#[inline]
fn interrupt_level(&mut self, level: InterruptLevel) {
unsafe {
self.port_reg()
.irq_sen()
.modify(|r, w| w.bits(r.bits() | self.mask_32()));
if level == InterruptLevel::Low {
self.port_reg()
.irq_evt()
.modify(|r, w| w.bits(r.bits() & !self.mask_32()));
} else {
self.port_reg()
.irq_evt()
.modify(|r, w| w.bits(r.bits() | self.mask_32()));
}
}
}
/// Only useful for input pins
#[inline]
fn filter_type(&self, filter: FilterType, clksel: FilterClkSel) {
self.iocfg_port().modify(|_, w| {
// Safety: Only write to register for this Pin ID
unsafe {
w.flttype().bits(filter as u8);
w.fltclk().bits(clksel as u8)
}
});
}
/// Set DATAMASK bit for this particular pin. 1 is the default
/// state of the bit and allows access of the corresponding bit
#[inline(always)]
fn set_datamask(&self) {
let portreg = self.port_reg();
unsafe {
portreg
.datamask()
.modify(|r, w| w.bits(r.bits() | self.mask_32()))
}
}
/// Clear DATAMASK bit for this particular pin. This prevents access
/// of the corresponding bit for output and input operations
#[inline(always)]
fn clear_datamask(&self) {
let portreg = self.port_reg();
unsafe {
portreg
.datamask()
.modify(|r, w| w.bits(r.bits() & !self.mask_32()))
}
}
/// Only useful for output pins
/// See p.52 of the programmers guide for more information.
/// When configured for pulse mode, a given pin will set the non-default state for exactly
/// one clock cycle before returning to the configured default state
fn pulse_mode(&self, enable: bool, default_state: PinState) {
let portreg = self.port_reg();
unsafe {
if enable {
portreg
.pulse()
.modify(|r, w| w.bits(r.bits() | self.mask_32()));
} else {
portreg
.pulse()
.modify(|r, w| w.bits(r.bits() & !self.mask_32()));
}
if default_state == PinState::Low {
portreg
.pulsebase()
.modify(|r, w| w.bits(r.bits() & !self.mask_32()));
} else {
portreg
.pulsebase()
.modify(|r, w| w.bits(r.bits() | self.mask_32()));
}
}
}
/// Only useful for output pins
fn delay(&self, delay_1: bool, delay_2: bool) {
let portreg = self.port_reg();
unsafe {
if delay_1 {
portreg
.delay1()
.modify(|r, w| w.bits(r.bits() | self.mask_32()));
} else {
portreg
.delay1()
.modify(|r, w| w.bits(r.bits() & !self.mask_32()));
}
if delay_2 {
portreg
.delay2()
.modify(|r, w| w.bits(r.bits() | self.mask_32()));
} else {
portreg
.delay2()
.modify(|r, w| w.bits(r.bits() & !self.mask_32()));
}
}
}
}