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//! Timer Peripheral
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// See [Chapter 4 Section 6](https://datasheets.raspberrypi.org/rp2040/rp2040_datasheet.pdf) for more details
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use embedded_time ::duration ::Microseconds ;
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use crate ::atomic_register_access ::{ write_bitmask_clear , write_bitmask_set } ;
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use crate ::pac ::{ RESETS , TIMER } ;
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use crate ::resets ::SubsystemReset ;
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use core ::marker ::PhantomData ;
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/// Timer peripheral
pub struct Timer {
timer : TIMER ,
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alarms : [ bool ; 4 ] ,
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}
impl Timer {
/// Create a new [`Timer`]
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pub fn new ( timer : TIMER , resets : & mut RESETS ) -> Self {
timer . reset_bring_up ( resets ) ;
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Self {
timer ,
alarms : [ true ; 4 ] ,
}
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}
/// Get the current counter value.
pub fn get_counter ( & self ) -> u64 {
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let mut hi0 = self . timer . timerawh . read ( ) . bits ( ) ;
loop {
let low = self . timer . timerawl . read ( ) . bits ( ) ;
let hi1 = self . timer . timerawh . read ( ) . bits ( ) ;
if hi0 = = hi1 {
break ( u64 ::from ( hi0 ) < < 32 ) | u64 ::from ( low ) ;
}
hi0 = hi1 ;
}
}
/// Get the value of the least significant word of the counter.
pub fn get_counter_low ( & self ) -> u32 {
self . timer . timerawl . read ( ) . bits ( )
}
/// Initialized a Count Down instance without starting it.
pub fn count_down ( & self ) -> CountDown < '_ > {
CountDown {
timer : self ,
period : Microseconds ::new ( 0 ) ,
next_end : None ,
}
}
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/// Retrieve a reference to alarm 0. Will only return a value the first time this is called
pub fn alarm_0 ( & mut self ) -> Option < Alarm0 > {
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cortex_m ::interrupt ::free ( | _ | {
if self . alarms [ 0 ] {
self . alarms [ 0 ] = false ;
Some ( Alarm0 ( PhantomData ) )
} else {
None
}
} )
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}
/// Retrieve a reference to alarm 1. Will only return a value the first time this is called
pub fn alarm_1 ( & mut self ) -> Option < Alarm1 > {
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cortex_m ::interrupt ::free ( | _ | {
if self . alarms [ 1 ] {
self . alarms [ 1 ] = false ;
Some ( Alarm1 ( PhantomData ) )
} else {
None
}
} )
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}
/// Retrieve a reference to alarm 2. Will only return a value the first time this is called
pub fn alarm_2 ( & mut self ) -> Option < Alarm2 > {
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cortex_m ::interrupt ::free ( | _ | {
if self . alarms [ 2 ] {
self . alarms [ 2 ] = false ;
Some ( Alarm2 ( PhantomData ) )
} else {
None
}
} )
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}
/// Retrieve a reference to alarm 3. Will only return a value the first time this is called
pub fn alarm_3 ( & mut self ) -> Option < Alarm3 > {
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cortex_m ::interrupt ::free ( | _ | {
if self . alarms [ 3 ] {
self . alarms [ 3 ] = false ;
Some ( Alarm3 ( PhantomData ) )
} else {
None
}
} )
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}
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}
/// Delay implementation
pub struct CountDown < ' timer > {
timer : & ' timer Timer ,
period : embedded_time ::duration ::Microseconds < u64 > ,
next_end : Option < u64 > ,
}
impl embedded_hal ::timer ::CountDown for CountDown < '_ > {
type Time = embedded_time ::duration ::Microseconds < u64 > ;
fn start < T > ( & mut self , count : T )
where
T : Into < Self ::Time > ,
{
self . period = count . into ( ) ;
self . next_end = Some ( self . timer . get_counter ( ) . wrapping_add ( self . period . 0 ) ) ;
}
fn wait ( & mut self ) -> nb ::Result < ( ) , void ::Void > {
if let Some ( end ) = self . next_end {
let ts = self . timer . get_counter ( ) ;
if ts > = end {
self . next_end = Some ( end . wrapping_add ( self . period . 0 ) ) ;
Ok ( ( ) )
} else {
Err ( nb ::Error ::WouldBlock )
}
} else {
panic! ( " CountDown is not running! " ) ;
}
}
}
impl embedded_hal ::timer ::Periodic for CountDown < '_ > { }
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impl embedded_hal ::timer ::Cancel for CountDown < '_ > {
type Error = & 'static str ;
fn cancel ( & mut self ) -> Result < ( ) , Self ::Error > {
if self . next_end . is_none ( ) {
Err ( " CountDown is not running. " )
} else {
self . next_end = None ;
Ok ( ( ) )
}
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}
}
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/// Alarm abstraction.
pub trait Alarm {
/// Clear the interrupt flag.
///
/// The interrupt is unable to trigger a 2nd time until this interrupt is cleared.
fn clear_interrupt ( & mut self ) ;
/// Enable this alarm to trigger an interrupt.
///
/// After this interrupt is triggered, make sure to clear the interrupt with [clear_interrupt].
///
/// [clear_interrupt]: #method.clear_interrupt
fn enable_interrupt ( & mut self ) ;
/// Disable this alarm, preventing it from triggering an interrupt.
fn disable_interrupt ( & mut self ) ;
/// Schedule the alarm to be finished after `countdown`. If [enable_interrupt] is called,
/// this will trigger interrupt whenever this time elapses.
///
/// The RP2040 has been observed to take a little while to schedule an alarm. For this
/// reason, the minimum time that this function accepts is `10.microseconds()`
///
/// [enable_interrupt]: #method.enable_interrupt
fn schedule < TIME : Into < Microseconds > > (
& mut self ,
countdown : TIME ,
) -> Result < ( ) , ScheduleAlarmError > ;
/// Return true if this alarm is finished.
fn finished ( & self ) -> bool ;
}
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macro_rules ! impl_alarm {
( $name :ident { rb : $timer_alarm :ident , int : $int_alarm :ident , int_name : $int_name :tt , armed_bit_mask : $armed_bit_mask : expr } ) = > {
/// An alarm that can be used to schedule events in the future. Alarms can also be configured to trigger interrupts.
pub struct $name ( PhantomData < ( ) > ) ;
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impl Alarm for $name {
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/// Clear the interrupt flag. This should be called after interrupt `
#[ doc = $int_name ]
/// ` is called.
///
/// The interrupt is unable to trigger a 2nd time until this interrupt is cleared.
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fn clear_interrupt ( & mut self ) {
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// safety: TIMER.intr is a write-clear register, so we can atomically clear our interrupt
// by writing its value to this field
// Only one instance of this alarm index can exist, and only this alarm interacts with this bit
// of the TIMER.inte register
unsafe {
let timer = & ( * pac ::TIMER ::ptr ( ) ) ;
timer . intr . write_with_zero ( | w | w . $int_alarm ( ) . set_bit ( ) ) ;
}
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}
/// Enable this alarm to trigger an interrupt. This alarm will trigger `
#[ doc = $int_name ]
/// `.
///
/// After this interrupt is triggered, make sure to clear the interrupt with [clear_interrupt].
///
/// [clear_interrupt]: #method.clear_interrupt
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fn enable_interrupt ( & mut self ) {
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// safety: using the atomic set alias means we can atomically set our interrupt enable bit.
// Only one instance of this alarm can exist, and only this alarm interacts with this bit
// of the TIMER.inte register
unsafe {
let timer = & ( * pac ::TIMER ::ptr ( ) ) ;
let reg = ( & timer . inte ) . as_ptr ( ) ;
write_bitmask_set ( reg , $armed_bit_mask ) ;
}
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}
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/// Disable this alarm, preventing it from triggering an interrupt.
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fn disable_interrupt ( & mut self ) {
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// safety: using the atomic set alias means we can atomically clear our interrupt enable bit.
// Only one instance of this alarm can exist, and only this alarm interacts with this bit
// of the TIMER.inte register
unsafe {
let timer = & ( * pac ::TIMER ::ptr ( ) ) ;
let reg = ( & timer . inte ) . as_ptr ( ) ;
write_bitmask_clear ( reg , $armed_bit_mask ) ;
}
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}
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/// Schedule the alarm to be finished after `countdown`. If [enable_interrupt] is called, this will trigger interrupt `
#[ doc = $int_name ]
/// ` whenever this time elapses.
///
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/// The RP2040 has been observed to take a little while to schedule an alarm. For this reason, the minimum time that this function accepts is `10.microseconds()`
///
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/// [enable_interrupt]: #method.enable_interrupt
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fn schedule < TIME : Into < Microseconds > > (
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& mut self ,
countdown : TIME ,
) -> Result < ( ) , ScheduleAlarmError > {
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let duration = countdown . into ( ) . 0 ;
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const MIN_MICROSECONDS : u32 = 10 ;
if duration < MIN_MICROSECONDS {
return Err ( ScheduleAlarmError ::AlarmTooSoon ) ;
} else {
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cortex_m ::interrupt ::free ( | _ | {
// safety: This is a read action and should not have any UB
let target_time = unsafe { & * TIMER ::ptr ( ) }
. timelr
. read ( )
. bits ( )
. wrapping_add ( duration ) ;
// safety: This is the only code in the codebase that accesses memory address $timer_alarm
unsafe { & * TIMER ::ptr ( ) }
. $timer_alarm
. write ( | w | unsafe { w . bits ( target_time ) } ) ;
} ) ;
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Ok ( ( ) )
}
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}
/// Return true if this alarm is finished.
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fn finished ( & self ) -> bool {
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// safety: This is a read action and should not have any UB
let bits : u32 = unsafe { & * TIMER ::ptr ( ) } . armed . read ( ) . bits ( ) ;
( bits & $armed_bit_mask ) = = 0
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}
}
} ;
}
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/// Errors that can be returned from any of the `AlarmX::schedule` methods.
#[ non_exhaustive ]
#[ derive(Copy, Clone, Debug, PartialEq, Eq, Hash) ]
pub enum ScheduleAlarmError {
/// Alarm time is too low. Should be at least 10 microseconds.
AlarmTooSoon ,
}
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impl_alarm! ( Alarm0 {
rb : alarm0 ,
int : alarm_0 ,
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int_name : " TIMER_IRQ_0 " ,
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armed_bit_mask : 0b0001
} ) ;
impl_alarm! ( Alarm1 {
rb : alarm1 ,
int : alarm_1 ,
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int_name : " TIMER_IRQ_1 " ,
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armed_bit_mask : 0b0010
} ) ;
impl_alarm! ( Alarm2 {
rb : alarm2 ,
int : alarm_2 ,
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int_name : " TIMER_IRQ_2 " ,
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armed_bit_mask : 0b0100
} ) ;
impl_alarm! ( Alarm3 {
rb : alarm3 ,
int : alarm_3 ,
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int_name : " TIMER_IRQ_3 " ,
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armed_bit_mask : 0b1000
} ) ;