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//! Nested Vector Interrupt Controller
#[cfg(not(armv6m))]
use volatile_register::RO;
use volatile_register::RW;
use interrupt::Nr;
use peripheral::NVIC;
/// Register block
#[repr(C)]
pub struct RegisterBlock {
/// Interrupt Set-Enable
pub iser: [RW<u32>; 16],
_reserved0: [u32; 16],
/// Interrupt Clear-Enable
pub icer: [RW<u32>; 16],
_reserved1: [u32; 16],
/// Interrupt Set-Pending
pub ispr: [RW<u32>; 16],
_reserved2: [u32; 16],
/// Interrupt Clear-Pending
pub icpr: [RW<u32>; 16],
_reserved3: [u32; 16],
/// Interrupt Active Bit (not present on Cortex-M0 variants)
#[cfg(not(armv6m))]
pub iabr: [RO<u32>; 16],
#[cfg(armv6m)]
_reserved4: [u32; 16],
_reserved5: [u32; 48],
#[cfg(not(armv6m))]
/// Interrupt Priority
///
/// On ARMv7-M, 124 word-sized registers are available. Each of those
/// contains of 4 interrupt priorities of 8 byte each.The architecture
/// specifically allows accessing those along byte boundaries, so they are
/// represented as 496 byte-sized registers, for convenience, and to allow
/// atomic priority updates.
///
/// On ARMv6-M, the registers must only be accessed along word boundaries,
/// so convenient byte-sized representation wouldn't work on that
/// architecture.
pub ipr: [RW<u8>; 496],
#[cfg(armv6m)]
/// Interrupt Priority
///
/// On ARMv7-M, 124 word-sized registers are available. Each of those
/// contains of 4 interrupt priorities of 8 byte each.The architecture
/// specifically allows accessing those along byte boundaries, so they are
/// represented as 496 byte-sized registers, for convenience, and to allow
/// atomic priority updates.
///
/// On ARMv6-M, the registers must only be accessed along word boundaries,
/// so convenient byte-sized representation wouldn't work on that
/// architecture.
pub ipr: [RW<u32>; 8],
}
impl NVIC {
/// Clears `interrupt`'s pending state
#[deprecated(since = "0.5.8", note = "Use `NVIC::unpend`")]
pub fn clear_pending<I>(&mut self, interrupt: I)
where
I: Nr,
{
Self::unpend(interrupt)
}
/// Disables `interrupt`
pub fn disable<I>(&mut self, interrupt: I)
where
I: Nr,
{
let nr = interrupt.nr();
unsafe { self.icer[usize::from(nr / 32)].write(1 << (nr % 32)) }
}
/// Enables `interrupt`
pub fn enable<I>(&mut self, interrupt: I)
where
I: Nr,
{
let nr = interrupt.nr();
unsafe { self.iser[usize::from(nr / 32)].write(1 << (nr % 32)) }
}
/// Returns the NVIC priority of `interrupt`
///
/// *NOTE* NVIC encodes priority in the highest bits of a byte so values like `1` and `2` map
/// to the same priority. Also for NVIC priorities, a lower value (e.g. `16`) has higher
/// priority (urgency) than a larger value (e.g. `32`).
pub fn get_priority<I>(interrupt: I) -> u8
where
I: Nr,
{
#[cfg(not(armv6m))]
{
let nr = interrupt.nr();
// NOTE(unsafe) atomic read with no side effects
unsafe { (*Self::ptr()).ipr[usize::from(nr)].read() }
}
#[cfg(armv6m)]
{
// NOTE(unsafe) atomic read with no side effects
let ipr_n = unsafe { (*Self::ptr()).ipr[Self::ipr_index(&interrupt)].read() };
let prio = (ipr_n >> Self::ipr_shift(&interrupt)) & 0x000000ff;
prio as u8
}
}
/// Is `interrupt` active or pre-empted and stacked
#[cfg(not(armv6m))]
pub fn is_active<I>(interrupt: I) -> bool
where
I: Nr,
{
let nr = interrupt.nr();
let mask = 1 << (nr % 32);
// NOTE(unsafe) atomic read with no side effects
unsafe { ((*Self::ptr()).iabr[usize::from(nr / 32)].read() & mask) == mask }
}
/// Checks if `interrupt` is enabled
pub fn is_enabled<I>(interrupt: I) -> bool
where
I: Nr,
{
let nr = interrupt.nr();
let mask = 1 << (nr % 32);
// NOTE(unsafe) atomic read with no side effects
unsafe { ((*Self::ptr()).iser[usize::from(nr / 32)].read() & mask) == mask }
}
/// Checks if `interrupt` is pending
pub fn is_pending<I>(interrupt: I) -> bool
where
I: Nr,
{
let nr = interrupt.nr();
let mask = 1 << (nr % 32);
// NOTE(unsafe) atomic read with no side effects
unsafe { ((*Self::ptr()).ispr[usize::from(nr / 32)].read() & mask) == mask }
}
/// Forces `interrupt` into pending state
pub fn pend<I>(interrupt: I)
where
I: Nr,
{
let nr = interrupt.nr();
// NOTE(unsafe) atomic stateless write; ICPR doesn't store any state
unsafe { (*Self::ptr()).ispr[usize::from(nr / 32)].write(1 << (nr % 32)) }
}
/// Forces `interrupt` into pending state
#[deprecated(since = "0.5.8", note = "Use `NVIC::pend`")]
pub fn set_pending<I>(&mut self, interrupt: I)
where
I: Nr,
{
Self::pend(interrupt)
}
/// Sets the "priority" of `interrupt` to `prio`
///
/// *NOTE* See [`get_priority`](struct.NVIC.html#method.get_priority) method for an explanation
/// of how NVIC priorities work.
///
/// On ARMv6-M, updating an interrupt priority requires a read-modify-write operation. On
/// ARMv7-M, the operation is performed in a single atomic write operation.
///
/// # Unsafety
///
/// Changing priority levels can break priority-based critical sections (see
/// [`register::basepri`](../register/basepri/index.html)) and compromise memory safety.
pub unsafe fn set_priority<I>(&mut self, interrupt: I, prio: u8)
where
I: Nr,
{
#[cfg(not(armv6m))]
{
let nr = interrupt.nr();
self.ipr[usize::from(nr)].write(prio)
}
#[cfg(armv6m)]
{
self.ipr[Self::ipr_index(&interrupt)].modify(|value| {
let mask = 0x000000ff << Self::ipr_shift(&interrupt);
let prio = u32::from(prio) << Self::ipr_shift(&interrupt);
(value & !mask) | prio
})
}
}
/// Clears `interrupt`'s pending state
pub fn unpend<I>(interrupt: I)
where
I: Nr,
{
let nr = interrupt.nr();
// NOTE(unsafe) atomic stateless write; ICPR doesn't store any state
unsafe { (*Self::ptr()).icpr[usize::from(nr / 32)].write(1 << (nr % 32)) }
}
#[cfg(armv6m)]
fn ipr_index<I>(interrupt: &I) -> usize
where
I: Nr,
{
usize::from(interrupt.nr()) / 4
}
#[cfg(armv6m)]
fn ipr_shift<I>(interrupt: &I) -> usize
where
I: Nr,
{
(usize::from(interrupt.nr()) % 4) * 8
}
}