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

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//! Single Cycle Input and Output (SIO)
//!
//! To be able to partition parts of the SIO block to other modules:
//!
//! ```no_run
//! use rp2040_hal::{gpio::Pins, pac, sio::Sio};
//!
//! let mut peripherals = pac::Peripherals::take().unwrap();
//! let sio = Sio::new(peripherals.SIO);
//! ```
//!
//! And then for example
//!
//! ```no_run
//! # use rp2040_hal::{gpio::Pins, pac, sio::Sio};
//! # let mut peripherals = pac::Peripherals::take().unwrap();
//! # let sio = Sio::new(peripherals.SIO);
//! let pins = Pins::new(peripherals.IO_BANK0, peripherals.PADS_BANK0, sio.gpio_bank0, &mut peripherals.RESETS);
//! ```
use super::*;
/// Marker struct for ownership of SIO gpio bank0
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pub struct SioGpioBank0 {
_private: (),
}
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/// Marker struct for ownership of SIO FIFO
pub struct SioFifo {
_private: (),
}
/// Marker struct for ownership of SIO gpio qspi
pub struct SioGpioQspi {
_private: (),
}
/// Marker struct for ownership of divide/modulo module
pub struct HwDivider {
_private: (),
}
/// Result of divide/modulo operation
pub struct DivResult<T> {
/// The remainder of divide/modulo operation
pub remainder: T,
/// The quotient of divide/modulo operation
pub quotient: T,
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}
/// Struct containing ownership markers for managing ownership of the SIO registers.
pub struct Sio {
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_sio: pac::SIO,
/// GPIO Bank 0 registers
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pub gpio_bank0: SioGpioBank0,
/// GPIO QSPI registers
pub gpio_qspi: SioGpioQspi,
/// 8-cycle hardware divide/modulo module
pub hwdivider: HwDivider,
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/// Inter-core FIFO
pub fifo: SioFifo,
// we can hand out other things here, for example:
// interp0
// interp1
}
impl Sio {
/// Create `Sio` from the PAC.
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pub fn new(sio: pac::SIO) -> Self {
Self {
_sio: sio,
gpio_bank0: SioGpioBank0 { _private: () },
gpio_qspi: SioGpioQspi { _private: () },
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fifo: SioFifo { _private: () },
hwdivider: HwDivider { _private: () },
}
}
}
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impl SioFifo {
/// Check if the inter-core FIFO has valid data for reading.
///
/// Returning `true` means there is valid data, `false` means it is empty
/// and you must not read from it.
pub fn is_read_ready(&mut self) -> bool {
let sio = unsafe { &(*pac::SIO::ptr()) };
sio.fifo_st.read().vld().bit_is_set()
}
/// Check if the inter-core FIFO is ready to receive data.
///
/// Returning `true` means there is room, `false` means it is full and you
/// must not write to it.
pub fn is_write_ready(&mut self) -> bool {
let sio = unsafe { &(*pac::SIO::ptr()) };
sio.fifo_st.read().rdy().bit_is_set()
}
/// Return the FIFO status, as an integer.
pub fn status(&self) -> u32 {
let sio = unsafe { &(*pac::SIO::ptr()) };
sio.fifo_st.read().bits()
}
/// Write to the inter-core FIFO.
///
/// You must ensure the FIFO has space by calling `is_write_ready`
pub fn write(&mut self, value: u32) {
let sio = unsafe { &(*pac::SIO::ptr()) };
sio.fifo_wr.write(|w| unsafe { w.bits(value) });
}
/// Read from the inter-core FIFO.
///
/// Will return `Some(data)`, or `None` if the FIFO is empty.
pub fn read(&mut self) -> Option<u32> {
if self.is_read_ready() {
let sio = unsafe { &(*pac::SIO::ptr()) };
Some(sio.fifo_rd.read().bits())
} else {
None
}
}
/// Read from the FIFO until it is empty, throwing the contents away.
pub fn drain(&mut self) {
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while self.read().is_some() {
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// Spin until FIFO empty
}
}
/// Push to the FIFO, spinning if there's no space.
pub fn write_blocking(&mut self, value: u32) {
// We wait for the FIFO to have some space
while !self.is_write_ready() {
cortex_m::asm::wfe();
}
// Write the value to the FIFO - the other core will now be able to pop it
// off its end of the FIFO.
self.write(value as u32);
// Fire off an event to the other core
cortex_m::asm::sev();
}
/// Pop from the FIFO, spinning if there's currently no data.
pub fn read_blocking(&mut self) -> u32 {
// Spin until FIFO has data
loop {
if let Some(data) = self.read() {
return data;
}
}
}
}
impl HwDivider {
/// Perform hardware unsigned divide/modulo operation
pub fn unsigned(&self, dividend: u32, divisor: u32) -> DivResult<u32> {
let sio = unsafe { &(*pac::SIO::ptr()) };
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sio.div_udividend.write(|w| unsafe { w.bits(dividend) });
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sio.div_udivisor.write(|w| unsafe { w.bits(divisor) });
cortex_m::asm::delay(8);
// Note: quotient must be read last
let remainder = sio.div_remainder.read().bits();
let quotient = sio.div_quotient.read().bits();
DivResult {
remainder,
quotient,
}
}
/// Perform hardware signed divide/modulo operation
pub fn signed(&self, dividend: i32, divisor: i32) -> DivResult<i32> {
let sio = unsafe { &(*pac::SIO::ptr()) };
sio.div_sdividend
.write(|w| unsafe { w.bits(dividend as u32) });
sio.div_sdivisor
.write(|w| unsafe { w.bits(divisor as u32) });
cortex_m::asm::delay(8);
// Note: quotient must be read last
let remainder = sio.div_remainder.read().bits() as i32;
let quotient = sio.div_quotient.read().bits() as i32;
DivResult {
remainder,
quotient,
}
}
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}