Rename Mask to RegisterBits

This is much more intuitive.
This commit is contained in:
Dylan McKay 2018-11-05 23:05:34 +13:00
parent f90d5b2d0b
commit aecd4edb36
8 changed files with 191 additions and 156 deletions

View File

@ -52,6 +52,7 @@ fn generate_config_module() -> Result<(), io::Error> {
let mut f = File::create(&path)?;
let clock = env!("AVR_CPU_FREQUENCY_HZ");
writeln!(f, "/// The clock frequency of device being targeted in Hertz.")?;
writeln!(f, "pub const CPU_FREQUENCY_HZ: u32 = {};", clock)?;
Ok(())
}
@ -81,7 +82,7 @@ fn generate_cores_mod_rs(mcus: &[Mcu]) -> Result<(), io::Error> {
fn write_core_module(mcu: &Mcu, w: &mut Write) -> Result<(), io::Error> {
writeln!(w, "//! Core for {}.", mcu.device.name)?;
writeln!(w)?;
writeln!(w, "use {{Mask, Register}};")?;
writeln!(w, "use {{RegisterBits, Register}};")?;
writeln!(w, "use modules;")?;
writeln!(w)?;

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@ -15,7 +15,7 @@ pub fn write_registers(mcu: &Mcu, w: &mut Write) -> Result<(), io::Error> {
writeln!(w, "impl {} {{", register.name)?;
for bitfield in register.bitfields.iter() {
// Create a mask for the whole bitset.
writeln!(w, " pub const {}: Mask<Self> = Mask::new(0x{:x});", bitfield.name, bitfield.mask)?;
writeln!(w, " pub const {}: RegisterBits<Self> = RegisterBits::new(0x{:x});", bitfield.name, bitfield.mask)?;
// We create masks for the individual bits in the field if there
// is more than one bit in the field.
@ -23,7 +23,7 @@ pub fn write_registers(mcu: &Mcu, w: &mut Write) -> Result<(), io::Error> {
let mut current_mask_bit_num = 0;
for current_register_bit_num in 0..15 {
if (current_mask & 0b1) == 0b1 {
writeln!(w, " pub const {}{}: Mask<Self> = Mask::new(1<<{});",
writeln!(w, " pub const {}{}: RegisterBits<Self> = RegisterBits::new(1<<{});",
bitfield.name, current_mask_bit_num, current_register_bit_num)?;
current_mask_bit_num += 1;
}
@ -182,13 +182,13 @@ pub fn write_timers(mcu: &Mcu, w: &mut Write) -> Result<(), io::Error> {
writeln!(w, " type ControlB = {};", find_reg_suffix("TCCR", "B").name)?;
writeln!(w, " type InterruptMask = {};", find_reg("TIMSK").name)?;
writeln!(w, " type InterruptFlag = {};", find_reg("TIFR").name)?;
writeln!(w, " const CS0: Mask<Self::ControlB> = Self::ControlB::CS00;")?;
writeln!(w, " const CS1: Mask<Self::ControlB> = Self::ControlB::CS01;")?;
writeln!(w, " const CS2: Mask<Self::ControlB> = Self::ControlB::CS02;")?;
writeln!(w, " const WGM0: Mask<Self::ControlA> = Self::ControlA::WGM00;")?;
writeln!(w, " const WGM1: Mask<Self::ControlA> = Self::ControlA::WGM01;")?;
writeln!(w, " const WGM2: Mask<Self::ControlB> = Self::ControlB::WGM020;")?;
writeln!(w, " const OCIEA: Mask<Self::InterruptMask> = Self::InterruptMask::OCIE{}A;", timer_number)?;
writeln!(w, " const CS0: RegisterBits<Self::ControlB> = Self::ControlB::CS00;")?;
writeln!(w, " const CS1: RegisterBits<Self::ControlB> = Self::ControlB::CS01;")?;
writeln!(w, " const CS2: RegisterBits<Self::ControlB> = Self::ControlB::CS02;")?;
writeln!(w, " const WGM0: RegisterBits<Self::ControlA> = Self::ControlA::WGM00;")?;
writeln!(w, " const WGM1: RegisterBits<Self::ControlA> = Self::ControlA::WGM01;")?;
writeln!(w, " const WGM2: RegisterBits<Self::ControlB> = Self::ControlB::WGM020;")?;
writeln!(w, " const OCIEA: RegisterBits<Self::InterruptMask> = Self::InterruptMask::OCIE{}A;", timer_number)?;
writeln!(w, "}}")?;
}
@ -218,14 +218,14 @@ pub fn write_timers(mcu: &Mcu, w: &mut Write) -> Result<(), io::Error> {
writeln!(w, " type ControlC = {};", find_reg_suffix("TCCR", "C").name)?;
writeln!(w, " type InterruptMask = {};", find_reg("TIMSK").name)?;
writeln!(w, " type InterruptFlag = {};", find_reg("TIFR").name)?;
writeln!(w, " const CS0: Mask<Self::ControlB> = Self::ControlB::CS10;")?;
writeln!(w, " const CS1: Mask<Self::ControlB> = Self::ControlB::CS11;")?;
writeln!(w, " const CS2: Mask<Self::ControlB> = Self::ControlB::CS12;")?;
writeln!(w, " const WGM0: Mask<Self::ControlA> = Self::ControlA::WGM10;")?;
writeln!(w, " const WGM1: Mask<Self::ControlA> = Self::ControlA::WGM11;")?;
writeln!(w, " const WGM2: Mask<Self::ControlB> = Self::ControlB::WGM10;")?;
writeln!(w, " const WGM3: Mask<Self::ControlB> = Self::ControlB::WGM11;")?;
writeln!(w, " const OCIEA: Mask<Self::InterruptMask> = Self::InterruptMask::OCIE{}A;", timer_number)?;
writeln!(w, " const CS0: RegisterBits<Self::ControlB> = Self::ControlB::CS10;")?;
writeln!(w, " const CS1: RegisterBits<Self::ControlB> = Self::ControlB::CS11;")?;
writeln!(w, " const CS2: RegisterBits<Self::ControlB> = Self::ControlB::CS12;")?;
writeln!(w, " const WGM0: RegisterBits<Self::ControlA> = Self::ControlA::WGM10;")?;
writeln!(w, " const WGM1: RegisterBits<Self::ControlA> = Self::ControlA::WGM11;")?;
writeln!(w, " const WGM2: RegisterBits<Self::ControlB> = Self::ControlB::WGM10;")?;
writeln!(w, " const WGM3: RegisterBits<Self::ControlB> = Self::ControlB::WGM11;")?;
writeln!(w, " const OCIEA: RegisterBits<Self::InterruptMask> = Self::InterruptMask::OCIE{}A;", timer_number)?;
writeln!(w, "}}")?;
}

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@ -14,7 +14,7 @@
#![no_std]
pub use self::register::{Mask, Register, RegisterValue};
pub use self::register::{Register, RegisterBits, RegisterValue};
pub use self::pin::{DataDirection, Pin};
pub mod prelude;

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@ -56,87 +56,87 @@ pub trait HardwareSpi {
/// Sets the clock speed.
fn set_clock(clock: u32) {
let mask = clock::ClockMask::with_clock(clock);
Self::ControlRegister::set_raw(mask.control_register_mask());
Self::StatusRegister::set_raw(mask.status_register_mask());
Self::ControlRegister::set_mask_raw(mask.control_register_mask());
Self::StatusRegister::set_mask_raw(mask.status_register_mask());
}
/// Enables interrupts for the spi module.
#[inline(always)]
fn enable_interrupt() {
Self::ControlRegister::set_raw(settings::control_register::INTERRUPT_ENABLE);
Self::ControlRegister::set_mask_raw(settings::control_register::INTERRUPT_ENABLE);
}
/// Disables interrupts for the spi module.
#[inline(always)]
fn disable_interrupt() {
Self::ControlRegister::unset_raw(settings::control_register::INTERRUPT_ENABLE);
Self::ControlRegister::unset_mask_raw(settings::control_register::INTERRUPT_ENABLE);
}
/// Enables the SPI.
#[inline(always)]
fn enable() {
Self::ControlRegister::set_raw(settings::control_register::ENABLE);
Self::ControlRegister::set_mask_raw(settings::control_register::ENABLE);
}
/// Disables the SPI.
#[inline(always)]
fn disable() {
Self::ControlRegister::unset_raw(settings::control_register::ENABLE);
Self::ControlRegister::unset_mask_raw(settings::control_register::ENABLE);
}
/// Enables least-significant-bit first.
#[inline(always)]
fn set_lsb() {
Self::ControlRegister::set_raw(settings::control_register::DATA_ORDER_LSB);
Self::ControlRegister::set_mask_raw(settings::control_register::DATA_ORDER_LSB);
}
/// Enables most-significant-bit first.
#[inline(always)]
fn set_msb() {
Self::ControlRegister::unset_raw(settings::control_register::DATA_ORDER_LSB);
Self::ControlRegister::unset_mask_raw(settings::control_register::DATA_ORDER_LSB);
}
/// Enables master mode.
#[inline(always)]
fn set_master() {
Self::ControlRegister::set_raw(settings::control_register::MASTER);
Self::ControlRegister::set_mask_raw(settings::control_register::MASTER);
}
/// Enables slave mode.
#[inline(always)]
fn set_slave() {
Self::ControlRegister::unset_raw(settings::control_register::MASTER);
Self::ControlRegister::unset_mask_raw(settings::control_register::MASTER);
}
/// Enables double speed mode.
#[inline(always)]
fn enable_double_speed() {
Self::StatusRegister::set_raw(settings::status_register::SPI2X);
Self::StatusRegister::set_mask_raw(settings::status_register::SPI2X);
}
/// Disables double speed mode.
#[inline(always)]
fn disable_double_speed() {
Self::StatusRegister::unset_raw(settings::status_register::SPI2X);
Self::StatusRegister::unset_mask_raw(settings::status_register::SPI2X);
}
/// Checks if there is a write collision.
#[inline(always)]
fn is_write_collision() -> bool {
Self::StatusRegister::is_set_raw(settings::status_register::WCOL)
Self::StatusRegister::is_mask_set_raw(settings::status_register::WCOL)
}
/// Sends a byte through the serial.
#[inline(always)]
fn send_byte(byte: u8) {
Self::DataRegister::write(byte);
Self::StatusRegister::wait_until_set_raw(settings::status_register::SPIF);
Self::StatusRegister::wait_until_mask_set_raw(settings::status_register::SPIF);
}
/// Reads a byte from the serial.
#[inline(always)]
fn receive_byte() -> u8 {
Self::StatusRegister::wait_until_set_raw(settings::status_register::SPIF);
Self::StatusRegister::wait_until_mask_set_raw(settings::status_register::SPIF);
Self::DataRegister::read()
}
@ -144,7 +144,7 @@ pub trait HardwareSpi {
#[inline(always)]
fn send_receive(byte: u8) -> u8 {
Self::DataRegister::write(byte);
Self::StatusRegister::wait_until_set_raw(settings::status_register::SPIF);
Self::StatusRegister::wait_until_mask_set_raw(settings::status_register::SPIF);
Self::DataRegister::read()
}
}

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@ -1,4 +1,4 @@
use {Mask, Register};
use {RegisterBits, Register};
use core::marker;
/// A 16-bit timer.
@ -41,16 +41,16 @@ pub trait Timer16 : Sized {
/// For example, TIFR0.
type InterruptFlag: Register<T=u8>;
const CS0: Mask<Self::ControlB>;
const CS1: Mask<Self::ControlB>;
const CS2: Mask<Self::ControlB>;
const CS0: RegisterBits<Self::ControlB>;
const CS1: RegisterBits<Self::ControlB>;
const CS2: RegisterBits<Self::ControlB>;
const WGM0: Mask<Self::ControlA>;
const WGM1: Mask<Self::ControlA>;
const WGM2: Mask<Self::ControlB>;
const WGM3: Mask<Self::ControlB>;
const WGM0: RegisterBits<Self::ControlA>;
const WGM1: RegisterBits<Self::ControlA>;
const WGM2: RegisterBits<Self::ControlB>;
const WGM3: RegisterBits<Self::ControlB>;
const OCIEA: Mask<Self::InterruptMask>;
const OCIEA: RegisterBits<Self::InterruptMask>;
fn setup() -> Timer16Setup<Self> { Timer16Setup::new() }
}
@ -67,23 +67,23 @@ pub enum ClockSource {
}
impl ClockSource {
fn bits<T: Timer16>(&self) -> Mask<T::ControlB> {
fn bits<T: Timer16>(&self) -> RegisterBits<T::ControlB> {
use self::ClockSource::*;
match *self {
None => Mask::zero() | Mask::zero() | Mask::zero(),
Prescale1 => Mask::zero() | Mask::zero() | T::CS0,
Prescale8 => Mask::zero() | T::CS1 | Mask::zero(),
Prescale64 => Mask::zero() | T::CS1 | T::CS0,
Prescale256 => T::CS2 | Mask::zero() | Mask::zero(),
Prescale1024 => T::CS2 | Mask::zero() | T::CS0,
ExternalFalling => T::CS2 | T::CS1 | Mask::zero(),
None => RegisterBits::zero() | RegisterBits::zero() | RegisterBits::zero(),
Prescale1 => RegisterBits::zero() | RegisterBits::zero() | T::CS0,
Prescale8 => RegisterBits::zero() | T::CS1 | RegisterBits::zero(),
Prescale64 => RegisterBits::zero() | T::CS1 | T::CS0,
Prescale256 => T::CS2 | RegisterBits::zero() | RegisterBits::zero(),
Prescale1024 => T::CS2 | RegisterBits::zero() | T::CS0,
ExternalFalling => T::CS2 | T::CS1 | RegisterBits::zero(),
ExternalRising => T::CS2 | T::CS1 | T::CS0,
}
}
#[inline]
fn mask<T: Timer16>() -> Mask<T::ControlB> {
fn mask<T: Timer16>() -> RegisterBits<T::ControlB> {
!(T::CS2 | T::CS1 | T::CS0)
}
}
@ -109,45 +109,46 @@ pub enum WaveformGenerationMode {
impl WaveformGenerationMode {
/// Returns bits for TCCR1A, TCCR1B
#[inline]
fn bits<T: Timer16>(&self) -> (Mask<T::ControlA>, Mask<T::ControlB>) {
fn bits<T: Timer16>(&self) -> (RegisterBits<T::ControlA>, RegisterBits<T::ControlB>) {
use self::WaveformGenerationMode::*;
use RegisterBits as B;
// It makes more sense to return bytes (A,B), but the manual
// lists the table as (B,A). We match the manual here for
// inspection purposes and flip the values for sanity
// purposes.
let (b, a) = match *self {
Normal => (Mask::zero() | Mask::zero(), Mask::zero() | Mask::zero()),
PwmPhaseCorrect8Bit => (Mask::zero() | Mask::zero(), Mask::zero() | T::WGM0),
PwmPhaseCorrect9Bit => (Mask::zero() | Mask::zero(), T::WGM1 | Mask::zero()),
PwmPhaseCorrect10Bit => (Mask::zero() | Mask::zero(), T::WGM1 | T::WGM0),
ClearOnTimerMatchOutputCompare => (Mask::zero() | T::WGM2, Mask::zero() | Mask::zero()),
FastPwm8Bit => (Mask::zero() | T::WGM2, Mask::zero() | T::WGM0),
FastPwm9Bit => (Mask::zero() | T::WGM2, T::WGM1 | Mask::zero()),
FastPwm10Bit => (Mask::zero() | T::WGM2, T::WGM1 | T::WGM0),
PwmPhaseAndFrequencyCorrectInputCapture => (T::WGM3 | Mask::zero(), Mask::zero() | Mask::zero()),
PwmPhaseAndFrequencyCorrectOutputCompare => (T::WGM3 | Mask::zero(), Mask::zero() | T::WGM0),
PwmPhaseCorrectInputCapture => (T::WGM3 | Mask::zero(), T::WGM1 | Mask::zero()),
PwmPhaseCorrectOutputCompare => (T::WGM3 | Mask::zero(), T::WGM1 | T::WGM0),
ClearOnTimerMatchInputCapture => (T::WGM3 | T::WGM2, Mask::zero() | Mask::zero()),
// Reserved => (T::WGM3 | T::WGM2, Mask::zero() | T::WGM0),
FastPwmInputCapture => (T::WGM3 | T::WGM2, T::WGM1 | Mask::zero()),
FastPwmOutputCompare => (T::WGM3 | T::WGM2, T::WGM1 | T::WGM0),
Normal => (B::zero() | B::zero(), B::zero() | B::zero()),
PwmPhaseCorrect8Bit => (B::zero() | B::zero(), B::zero() | T::WGM0),
PwmPhaseCorrect9Bit => (B::zero() | B::zero(), T::WGM1 | B::zero()),
PwmPhaseCorrect10Bit => (B::zero() | B::zero(), T::WGM1 | T::WGM0),
ClearOnTimerMatchOutputCompare => (B::zero() | T::WGM2, B::zero() | B::zero()),
FastPwm8Bit => (B::zero() | T::WGM2, B::zero() | T::WGM0),
FastPwm9Bit => (B::zero() | T::WGM2, T::WGM1 | B::zero()),
FastPwm10Bit => (B::zero() | T::WGM2, T::WGM1 | T::WGM0),
PwmPhaseAndFrequencyCorrectInputCapture => (T::WGM3 | B::zero(), B::zero() | B::zero()),
PwmPhaseAndFrequencyCorrectOutputCompare => (T::WGM3 | B::zero(), B::zero() | T::WGM0),
PwmPhaseCorrectInputCapture => (T::WGM3 | B::zero(), T::WGM1 | B::zero()),
PwmPhaseCorrectOutputCompare => (T::WGM3 | B::zero(), T::WGM1 | T::WGM0),
ClearOnTimerMatchInputCapture => (T::WGM3 | T::WGM2, B::zero() | B::zero()),
// Reserved => (T::WGM3 | T::WGM2, B::zero() | T::WGM0),
FastPwmInputCapture => (T::WGM3 | T::WGM2, T::WGM1 | B::zero()),
FastPwmOutputCompare => (T::WGM3 | T::WGM2, T::WGM1 | T::WGM0),
};
(a, b)
}
#[inline]
fn mask<T: Timer16>() -> (Mask<T::ControlA>, Mask<T::ControlB>) {
fn mask<T: Timer16>() -> (RegisterBits<T::ControlA>, RegisterBits<T::ControlB>) {
(!(T::WGM0 | T::WGM1), !(T::WGM2 | T::WGM3))
}
}
pub struct Timer16Setup<T: Timer16> {
a: Mask<T::ControlA>,
b: Mask<T::ControlB>,
c: Mask<T::ControlC>,
a: RegisterBits<T::ControlA>,
b: RegisterBits<T::ControlB>,
c: RegisterBits<T::ControlC>,
output_compare_1: Option<u16>,
_phantom: marker::PhantomData<T>,
}
@ -156,9 +157,9 @@ impl<T: Timer16> Timer16Setup<T> {
#[inline]
fn new() -> Self {
Timer16Setup {
a: Mask::zero(),
b: Mask::zero(),
c: Mask::zero(),
a: RegisterBits::zero(),
b: RegisterBits::zero(),
c: RegisterBits::zero(),
output_compare_1: None,
_phantom: marker::PhantomData,
}

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@ -1,4 +1,4 @@
use {Mask, Register};
use {RegisterBits, Register};
use core::marker;
/// A 8-bit timer.
@ -37,21 +37,21 @@ pub trait Timer8 : Sized {
type InterruptFlag: Register<T=u8>;
/// Bit 0 of the clock select mask.
const CS0: Mask<Self::ControlB>;
const CS0: RegisterBits<Self::ControlB>;
/// Bit 1 of the clock select mask.
const CS1: Mask<Self::ControlB>;
const CS1: RegisterBits<Self::ControlB>;
/// Bit 2 of the clock select mask.
const CS2: Mask<Self::ControlB>;
const CS2: RegisterBits<Self::ControlB>;
/// Bit 0 of the waveform generation mode mask.
const WGM0: Mask<Self::ControlA>;
const WGM0: RegisterBits<Self::ControlA>;
/// Bit 1 of the waveform generation mode mask.
const WGM1: Mask<Self::ControlA>;
const WGM1: RegisterBits<Self::ControlA>;
/// Bit 2 of the waveform generation mode mask.
const WGM2: Mask<Self::ControlB>;
const WGM2: RegisterBits<Self::ControlB>;
/// Output compare interrupt enable flag.
const OCIEA: Mask<Self::InterruptMask>;
const OCIEA: RegisterBits<Self::InterruptMask>;
}
pub enum ClockSource {
@ -66,23 +66,23 @@ pub enum ClockSource {
}
impl ClockSource {
fn bits<T: Timer8>(&self) -> Mask<T::ControlB> {
fn bits<T: Timer8>(&self) -> RegisterBits<T::ControlB> {
use self::ClockSource::*;
match *self {
None => Mask::zero() | Mask::zero() | Mask::zero(),
Prescale1 => Mask::zero() | Mask::zero() | T::CS0,
Prescale8 => Mask::zero() | T::CS1 | Mask::zero(),
Prescale64 => Mask::zero() | T::CS1 | T::CS0,
Prescale256 => T::CS2 | Mask::zero() | Mask::zero(),
Prescale1024 => T::CS2 | Mask::zero() | T::CS0,
ExternalFalling => T::CS2 | T::CS1 | Mask::zero(),
None => RegisterBits::zero() | RegisterBits::zero() | RegisterBits::zero(),
Prescale1 => RegisterBits::zero() | RegisterBits::zero() | T::CS0,
Prescale8 => RegisterBits::zero() | T::CS1 | RegisterBits::zero(),
Prescale64 => RegisterBits::zero() | T::CS1 | T::CS0,
Prescale256 => T::CS2 | RegisterBits::zero() | RegisterBits::zero(),
Prescale1024 => T::CS2 | RegisterBits::zero() | T::CS0,
ExternalFalling => T::CS2 | T::CS1 | RegisterBits::zero(),
ExternalRising => T::CS2 | T::CS1 | T::CS0,
}
}
#[inline]
fn mask<T: Timer8>() -> Mask<T::ControlB> {
fn mask<T: Timer8>() -> RegisterBits<T::ControlB> {
!(T::CS2 | T::CS1 | T::CS0)
}
}
@ -99,7 +99,7 @@ pub enum WaveformGenerationMode {
impl WaveformGenerationMode {
/// Returns bits for TCCR0A, TCCR0B
#[inline]
fn bits<T: Timer8>(&self) -> (Mask<T::ControlA>, Mask<T::ControlB>) {
fn bits<T: Timer8>(&self) -> (RegisterBits<T::ControlA>, RegisterBits<T::ControlB>) {
use self::WaveformGenerationMode::*;
// It makes more sense to return bytes (A,B), but the manual
@ -107,13 +107,13 @@ impl WaveformGenerationMode {
// inspection purposes and flip the values for sanity
// purposes.
let (b, a) = match *self {
Normal => (Mask::zero(), Mask::zero() | Mask::zero()),
PwmPhaseCorrect => (Mask::zero(), Mask::zero() | T::WGM0),
ClearOnTimerMatchOutputCompare => (Mask::zero(), T::WGM1 | Mask::zero()),
FastPwm => (Mask::zero(), T::WGM1 | T::WGM0),
// Reserved => (T::WGM2, Mask::zero() | Mask::zero()),
PwmPhaseCorrectOutputCompare => (T::WGM2, Mask::zero() | T::WGM0),
// Reserved => (T::WGM2, T::WGM1 | Mask::zero())),
Normal => (RegisterBits::zero(), RegisterBits::zero() | RegisterBits::zero()),
PwmPhaseCorrect => (RegisterBits::zero(), RegisterBits::zero() | T::WGM0),
ClearOnTimerMatchOutputCompare => (RegisterBits::zero(), T::WGM1 | RegisterBits::zero()),
FastPwm => (RegisterBits::zero(), T::WGM1 | T::WGM0),
// Reserved => (T::WGM2, RegisterBits::zero() | RegisterBits::zero()),
PwmPhaseCorrectOutputCompare => (T::WGM2, RegisterBits::zero() | T::WGM0),
// Reserved => (T::WGM2, T::WGM1 | RegisterBits::zero())),
FastPwmOutputCompare => (T::WGM2, T::WGM1 | T::WGM0),
};
@ -121,14 +121,14 @@ impl WaveformGenerationMode {
}
#[inline]
fn mask<T: Timer8>() -> (Mask<T::ControlA>, Mask<T::ControlB>) {
fn mask<T: Timer8>() -> (RegisterBits<T::ControlA>, RegisterBits<T::ControlB>) {
(!(T::WGM0 | T::WGM1), !(T::WGM2))
}
}
pub struct Timer8Setup<T: Timer8> {
a: Mask<T::ControlA>,
b: Mask<T::ControlB>,
a: RegisterBits<T::ControlA>,
b: RegisterBits<T::ControlB>,
output_compare_1: Option<u8>,
_phantom: marker::PhantomData<T>,
}
@ -137,8 +137,8 @@ impl<T: Timer8> Timer8Setup<T> {
#[inline]
pub fn new() -> Self {
Timer8Setup {
a: Mask::zero(),
b: Mask::zero(),
a: RegisterBits::zero(),
b: RegisterBits::zero(),
output_compare_1: None,
_phantom: marker::PhantomData,
}

View File

@ -1,7 +1,10 @@
use Register;
/// Represents whether a pin is an input or an output.
pub enum DataDirection {
/// The pin is exclusively used for reading signals.
Input,
/// The pin is exclusively used for sending signals.
Output,
}
@ -11,7 +14,7 @@ pub trait Pin {
type DDR: Register<T=u8>;
/// The associated port register.
type PORT: Register<T=u8>;
/// The associated pin register.
///
/// Reads from the register will read input bits.
/// Writes to the register will toggle bits.
@ -31,13 +34,13 @@ pub trait Pin {
/// Sets the pin up as an input.
#[inline(always)]
fn set_input() {
Self::DDR::unset_raw(Self::MASK);
Self::DDR::unset_mask_raw(Self::MASK);
}
/// Sets the pin up as an output.
#[inline(always)]
fn set_output() {
Self::DDR::set_raw(Self::MASK);
Self::DDR::set_mask_raw(Self::MASK);
}
/// Set the pin to high.
@ -45,7 +48,7 @@ pub trait Pin {
/// The pin must be configured as an output.
#[inline(always)]
fn set_high() {
Self::PORT::set_raw(Self::MASK);
Self::PORT::set_mask_raw(Self::MASK);
}
/// Set the pin to low.
@ -53,7 +56,7 @@ pub trait Pin {
/// The pin must be configured as an output.
#[inline(always)]
fn set_low() {
Self::PORT::unset_raw(Self::MASK);
Self::PORT::unset_mask_raw(Self::MASK);
}
/// Toggles the pin.
@ -72,7 +75,7 @@ pub trait Pin {
/// The pin must be configured as an input.
#[inline(always)]
fn is_high() -> bool {
Self::PIN::is_set_raw(Self::MASK)
Self::PIN::is_mask_set_raw(Self::MASK)
}
/// Checks if the pin is currently low.

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@ -1,6 +1,8 @@
use core::{cmp, convert, marker, ops};
/// A value that a register can store.
///
/// All registers are either `u8` or `u16`.
pub trait RegisterValue : Copy + Clone +
ops::BitAnd<Output=Self> +
ops::BitAndAssign +
@ -16,8 +18,11 @@ pub trait RegisterValue : Copy + Clone +
/// A register.
pub trait Register : Sized {
/// The type that can represent the value of the register.
type T: RegisterValue;
type Mask = Mask<Self>;
/// The type representing a set of bits that may be manipulated
/// within the register.
type RegisterBits = RegisterBits<Self>;
/// The address of the register.
const ADDRESS: *mut Self::T;
@ -36,35 +41,44 @@ pub trait Register : Sized {
unsafe { *Self::ADDRESS }
}
fn set(mask: Mask<Self>) {
Self::set_raw(mask.mask);
/// Sets a set of bits to `1` in the register.
fn set(bits: RegisterBits<Self>) {
Self::set_mask_raw(bits.mask);
}
/// Sets a bitmask in a register.
///
/// This is equivalent to `r |= mask`.
#[inline(always)]
fn set_raw(mask: Self::T) {
fn set_mask_raw(mask: Self::T) {
unsafe {
*Self::ADDRESS |= mask;
}
}
fn unset(mask: Mask<Self>) {
Self::unset_raw(mask.mask);
/// Unsets a set of bits in the register.
///
/// All of the bits will be set to `0`.
fn unset(bits: RegisterBits<Self>) {
Self::unset_mask_raw(bits.mask);
}
/// Clears a bitmask from a register.
///
/// This is equivalent to `r &= !mask`.
#[inline(always)]
fn unset_raw(mask: Self::T) {
fn unset_mask_raw(mask: Self::T) {
unsafe {
*Self::ADDRESS &= !mask;
}
}
fn toggle(mask: Mask<Self>) {
/// Toggles a set of bits within the register.
///
/// All specified bits which were previously `0` will become
/// `1`, and all specified bits that were previous `1` will
/// become `0`.
fn toggle(mask: RegisterBits<Self>) {
Self::toggle_raw(mask.mask);
}
@ -78,21 +92,29 @@ pub trait Register : Sized {
}
}
fn is_set(mask: Mask<Self>) -> bool {
Self::is_set_raw(mask.mask)
/// Checks if a set of bits are enabled.
///
/// All specifed bits must be set for this function
/// to return `true`.
fn is_set(bits: RegisterBits<Self>) -> bool {
Self::is_mask_set_raw(bits.mask)
}
/// Checks if a mask is set in the register.
///
/// This is equivalent to `(r & mask) == mask`.
#[inline(always)]
fn is_set_raw(mask: Self::T) -> bool {
fn is_mask_set_raw(mask: Self::T) -> bool {
unsafe {
(*Self::ADDRESS & mask) == mask
}
}
fn is_clear(mask: Mask<Self>) -> bool {
/// Checks if a set of bits are not set.
///
/// All specified bits must be `0` for this
/// function to return `true`.
fn is_clear(mask: RegisterBits<Self>) -> bool {
Self::is_clear_raw(mask.mask)
}
@ -106,92 +128,100 @@ pub trait Register : Sized {
}
}
/// Waits until some condition is true of the register.
#[inline(always)]
fn wait_until<F>(mut f: F)
where F: FnMut() -> bool {
loop {
if f() {
break;
}
}
/// Waits until a set of bits are set in the register.
///
/// This function will block until all bits that are set in
/// the mask are also set in the register.
fn wait_until_set(bits: RegisterBits<Self>) {
Self::wait_until_mask_set_raw(bits.mask);
}
fn wait_until_set(mask: Mask<Self>) {
Self::wait_until_set_raw(mask.mask);
}
/// Waits until a mask is set.
/// Waits until a bit mask is set in the register.
///
/// This function will block until all bits that are set in
/// the mask are also set in the register.
#[inline(always)]
fn wait_until_set_raw(mask: Self::T) {
Self::wait_until(|| Self::is_set_raw(mask))
fn wait_until_mask_set_raw(mask: Self::T) {
wait_until(|| Self::is_mask_set_raw(mask))
}
}
/// A register bitmask.
/// Represents a set of bits within a specific register.
#[derive(Copy, Clone, Debug, PartialEq, Eq, PartialOrd, Ord, Hash)]
pub struct Mask<R: Register> {
pub struct RegisterBits<R: Register> {
/// The raw bitmask.
mask: R::T,
_phantom: marker::PhantomData<R>,
}
impl<R> Mask<R> where R: Register {
impl<R> RegisterBits<R> where R: Register {
/// Creates a new register mask.
pub const fn new(mask: R::T) -> Self {
Mask { mask, _phantom: marker::PhantomData }
RegisterBits { mask, _phantom: marker::PhantomData }
}
pub fn zero() -> Self {
Mask::new(0u8.into())
RegisterBits::new(0u8.into())
}
}
impl<R> ops::BitOr for Mask<R> where R: Register
impl<R> ops::BitOr for RegisterBits<R> where R: Register
{
type Output = Self;
fn bitor(self, rhs: Self) -> Self {
Mask::new(self.mask | rhs.mask)
RegisterBits::new(self.mask | rhs.mask)
}
}
impl<R> ops::BitOrAssign for Mask<R> where R: Register {
impl<R> ops::BitOrAssign for RegisterBits<R> where R: Register {
fn bitor_assign(&mut self, rhs: Self) {
self.mask |= rhs.mask;
}
}
impl<R> ops::BitAnd for Mask<R> where R: Register
impl<R> ops::BitAnd for RegisterBits<R> where R: Register
{
type Output = Self;
fn bitand(self, rhs: Self) -> Self {
Mask::new(self.mask & rhs.mask)
RegisterBits::new(self.mask & rhs.mask)
}
}
impl<R> ops::BitAndAssign for Mask<R> where R: Register {
impl<R> ops::BitAndAssign for RegisterBits<R> where R: Register {
fn bitand_assign(&mut self, rhs: Self) {
self.mask &= rhs.mask;
}
}
impl<R> ops::Not for Mask<R> where R: Register {
impl<R> ops::Not for RegisterBits<R> where R: Register {
type Output = Self;
fn not(self) -> Self {
Mask::new(!self.mask)
RegisterBits::new(!self.mask)
}
}
impl<R> Into<u8> for Mask<R> where R: Register<T=u8> {
impl<R> Into<u8> for RegisterBits<R> where R: Register<T=u8> {
fn into(self) -> u8 { self.mask }
}
impl<R> Into<u16> for Mask<R> where R: Register<T=u16> {
impl<R> Into<u16> for RegisterBits<R> where R: Register<T=u16> {
fn into(self) -> u16 { self.mask }
}
impl RegisterValue for u8 { }
impl RegisterValue for u16 { }
/// Waits until some condition is true of the register.
#[inline(always)]
fn wait_until<F>(mut f: F)
where F: FnMut() -> bool {
loop {
if f() {
break;
}
}
}