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update examples
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1 changed files with 43 additions and 42 deletions
85
src/lib.rs
85
src/lib.rs
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@ -1,22 +1,23 @@
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//! RTFM: Real Time For the Masses (ARM Cortex-M edition)
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//!
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//! RTFM is a framework for building embedded event-driven / real-time
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//! applications.
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//! RTFM is a framework for building event-driven applications for ARM Cortex-M
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//! microcontrollers.
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//!
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//! This crate is based on the RTFM framework created by [prof. Per
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//! Lindgren][per] and uses a simplified version of the Stack Resource Policy as
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//! scheduling policy. (Check the [references] for details)
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//! scheduling policy. Check the [references] for details.
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//!
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//! [per]: https://www.ltu.se/staff/p/pln-1.11258?l=en
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//! [references]: ./index.html#references
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//!
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//! # Features
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//!
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//! - Event triggered tasks as the unit of concurrency.
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//! - Supports prioritizing tasks and, thus, preemptive multitasking.
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//! - Data sharing through fine grained, *partial* critical sections.
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//! - Deadlock free execution guaranteed at compile time.
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//! - Minimal overhead as the scheduler has no software component / runtime; the
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//! - **Event triggered tasks** as the unit of concurrency.
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//! - Supports prioritization of tasks and, thus, **preemptive multitasking**.
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//! - **Data race free memory sharing** through fine grained *partial* critical
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//! sections.
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//! - **Deadlock free execution** guaranteed at compile time.
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//! - **Minimal overhead** as the scheduler has no software component / runtime; the
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//! hardware does all the scheduling.
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//! - Full support for all Cortex M3, M4 and M7 devices. M0(+) is also supported
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//! but the whole API is not available (due to missing hardware features).
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@ -26,11 +27,11 @@
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//! crate defaults to 16 as that's the most common scenario.
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//! - This task model is amenable to known WCET (Worst Case Execution Time)
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//! analysis and scheduling analysis techniques. (Though we haven't yet
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//! developed tooling for that.)
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//! developed Rust friendly tooling for that.)
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//!
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//! # Limitations
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//!
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//! - Task priority must remain constant at runtime.
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//! - Task priorities must remain constant at runtime.
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//!
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//! # Dependencies
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//!
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//! extern crate cortex_m_rtfm as rtfm;
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//!
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//! // device crate generated using svd2rust
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//! extern crate stm32f100xx;
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//! extern crate stm32f30x;
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//!
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//! use rtfm::{C16, P0};
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//!
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//! // Declare tasks. None in this example
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//! tasks!(stm32f100xx, {});
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//! // TASKS (None in this example)
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//! tasks!(stm32f30x, {});
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//!
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//! // INITIALIZATION PHASE
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//! fn init(_priority: P0, _ceiling: &C16) {
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//! The `tasks!` macro overrides the `main` function and imposes the following
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//! structure into your program:
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//!
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//! - `init`, the initialization phase, is run first. This function is executed
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//! - `init`, the initialization phase, runs first. This function is executed
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//! inside a *global* critical section and can't be preempted.
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//!
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//! - `idle`, a never ending function that runs after `init`.
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//! extern crate cortex_m_rt;
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//! #[macro_use]
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//! extern crate cortex_m_rtfm as rtfm;
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//! extern crate stm32f100xx;
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//! extern crate stm32f30x;
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//!
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//! use stm32f100xx::interrupt::Tim7Irq;
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//! use stm32f30x::interrupt::Tim7;
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//! use rtfm::{C16, Local, P0, P1};
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//!
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//! // INITIALIZATION PHASE
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//! }
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//!
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//! // TASKS
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//! tasks!(stm32f100xx, {
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//! periodic: (Tim7Irq, P1, true),
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//! tasks!(stm32f30x, {
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//! periodic: (Tim7, P1, true),
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//! });
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//!
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//! fn periodic(mut task: Tim7Irq, _priority: P1) {
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//! fn periodic(mut task: Tim7, _priority: P1) {
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//! // Task local data
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//! static STATE: Local<bool, Tim7Irq> = Local::new(false);
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//! static STATE: Local<bool, Tim7> = Local::new(false);
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//!
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//! let state = STATE.borrow_mut(&mut task);
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//!
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//! }
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//! ```
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//!
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//! Here we define a task named `periodic` and bind it to the `Tim7Irq`
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//! interrupt. The `periodic` task will run every time the `Tim7Irq` interrupt
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//! Here we define a task named `periodic` and bind it to the `Tim7`
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//! interrupt. The `periodic` task will run every time the `Tim7` interrupt
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//! is triggered. We assign to this task a priority of 1 (`P1`); this is the
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//! lowest priority that a task can have.
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//!
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//! task; this task local data will be preserved across runs of the `periodic`
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//! task. Note that `STATE` is owned by the `periodic` task, in the sense that
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//! no other task can access it; this is reflected in its type signature (the
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//! `Tim7Irq` type parameter).
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//! `Tim7` type parameter).
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//!
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//! # Two "serial" tasks
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//!
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//! extern crate cortex_m_rt;
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//! #[macro_use]
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//! extern crate cortex_m_rtfm as rtfm;
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//! extern crate stm32f100xx;
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//! extern crate stm32f30x;
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//!
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//! use core::cell::Cell;
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//!
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//! use stm32f100xx::interrupt::{Tim6DacIrq, Tim7Irq};
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//! use stm32f30x::interrupt::{Tim6Dacunder, Tim7};
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//! use rtfm::{C1, C16, P0, P1, Resource};
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//!
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//! // omitted: `idle`, `init`
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//!
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//! tasks!(stm32f100xx, {
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//! t1: (Tim6DacIrq, P1, true),
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//! t2: (Tim7Irq, P1, true),
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//! tasks!(stm32f30x, {
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//! t1: (Tim6Dacunder, P1, true),
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//! t2: (Tim7, P1, true),
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//! });
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//!
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//! // Data shared between tasks `t1` and `t2`
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//! static COUNTER: Resource<Cell<u32>, C1> = Resource::new(Cell::new(0));
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//!
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//! fn t1(_task: Tim6DacIrq, priority: P1) {
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//! fn t1(_task: Tim6Dacunder, priority: P1) {
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//! let ceiling = priority.as_ceiling();
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//!
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//! let counter = COUNTER.access(&priority, &ceiling);
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//! let counter = COUNTER.access(&priority, ceiling);
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//!
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//! counter.set(counter.get() + 1);
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//! }
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//!
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//! fn t2(_task: Tim7Irq, priority: P1) {
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//! fn t2(_task: Tim7, priority: P1) {
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//! let ceiling = priority.as_ceiling();
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//!
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//! let counter = COUNTER.access(&priority, &ceiling);
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//! let counter = COUNTER.access(&priority, ceiling);
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//!
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//! counter.set(counter.get() + 2);
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//! }
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//! extern crate cortex_m_rt;
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//! #[macro_use]
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//! extern crate cortex_m_rtfm as rtfm;
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//! extern crate stm32f100xx;
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//! extern crate stm32f30x;
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//!
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//! use core::cell::Cell;
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//!
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//! use stm32f100xx::interrupt::{Tim6DacIrq, Tim7Irq};
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//! use stm32f30x::interrupt::{Tim6Dacunder, Tim7};
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//! use rtfm::{C2, C16, P0, P1, P2, Resource};
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//!
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//! // omitted: `idle`, `init`
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//!
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//! tasks!(stm32f100xx, {
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//! t1: (Tim6DacIrq, P1, true),
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//! t2: (Tim7Irq, P2, true),
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//! tasks!(stm32f30x, {
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//! t1: (Tim6Dacunder, P1, true),
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//! t2: (Tim7, P2, true),
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//! });
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//!
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//! static COUNTER: Resource<Cell<u32>, C2> = Resource::new(Cell::new(0));
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//!
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//! fn t1(_task: Tim6DacIrq, priority: P1) {
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//! fn t1(_task: Tim6Dacunder, priority: P1) {
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//! // ..
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//!
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//! let ceiling: &C1 = priority.as_ceiling();
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//!
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//! ceiling.raise(&COUNTER, |ceiling: &C2| {
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//! let counter = COUNTER.access(&priority, &ceiling);
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//! let counter = COUNTER.access(&priority, ceiling);
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//!
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//! counter.set(counter.get() + 1);
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//! });
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//! // ..
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//! }
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//!
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//! fn t2(_task: Tim7Irq, priority: P2) {
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//! fn t2(_task: Tim7, priority: P2) {
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//! let ceiling = priority.as_ceiling();
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//!
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//! let counter = COUNTER.access(&priority, &ceiling);
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//! let counter = COUNTER.access(&priority, ceiling);
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//!
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//! counter.set(counter.get() + 2);
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//! }
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//!
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//! Now we have a variation of the previous example. Like before, `t1` has a
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//! priority of 1 (`P1`) but `t2` now has a priority of 2 (`P2`). This means
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//! that `t2` can preempt `t1` if a `Tim7Irq` interrupt occurs while `t1` is
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//! that `t2` can preempt `t1` if a `Tim7` interrupt occurs while `t1` is
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//! being executed.
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//!
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//! To avoid data races, `t1` must modify `COUNTER` in an atomic way; i.e. `t2`
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