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Update delay.md file to be a bit easier to read, and add spoiler tags for the walls of code

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book/en/src/by-example/delay.md
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@ -1,18 +1,20 @@
# Tasks with delay # Tasks with delay
A convenient way to express *miniminal* timing requirements is by means of delaying progression. A convenient way to express miniminal timing requirements is by delaying progression.
This can be achieved by instantiating a monotonic timer: This can be achieved by instantiating a monotonic timer (for implementations, see [`rtic-monotonics`]):
[`rtic-monotonics`]: https://github.com/rtic-rs/rtic/tree/master/rtic-monotonics
[`rtic-time`]: https://github.com/rtic-rs/rtic/tree/master/rtic-time
``` rust ``` rust
... ...
rtic_monotonics::make_systick_handler!();
#[init] #[init]
fn init(cx: init::Context) -> (Shared, Local) { fn init(cx: init::Context) -> (Shared, Local) {
hprintln!("init"); hprintln!("init");
Systick::start(cx.core.SYST, 12_000_000); let token = rtic_monotonics::create_systick_token!();
Systick::start(cx.core.SYST, 12_000_000, token);
... ...
``` ```
@ -28,11 +30,14 @@ async fn foo(_cx: foo::Context) {
``` ```
Technically, the timer queue is implemented as a list based priority queue, where list-nodes are statically allocated as part of the underlying task `Future`. Thus, the timer queue is infallible at run-time (its size and allocation is determined at compile time). <!-- TODO: move technical explanation to internals -->
Technically, the timer queue is implemented as a list based priority queue, where list-nodes are statically allocated as part of the underlying task `Future`. Thus, the timer queue is infallible at run-time (its size and allocation are determined at compile time).
Similarly the channels implementation, the timer-queue implementation relies on a global *Critical Section* (CS) for race protection. For the examples a CS implementation is provided by adding `--features test-critical-section` to the build options. Similarly the channels implementation, the timer-queue implementation relies on a global *Critical Section* (CS) for race protection. For the examples a CS implementation is provided by adding `--features test-critical-section` to the build options.
For a complete example: <details>
<summary>A complete example</summary>
``` rust ``` rust
{{#include ../../../../rtic/examples/async-delay.rs}} {{#include ../../../../rtic/examples/async-delay.rs}}
@ -46,11 +51,15 @@ $ cargo run --target thumbv7m-none-eabi --example async-delay --features test-cr
{{#include ../../../../rtic/ci/expected/async-delay.run}} {{#include ../../../../rtic/ci/expected/async-delay.run}}
``` ```
</details>
## Timeout ## Timeout
Rust `Futures` (underlying Rust `async`/`await`) are composable. This makes it possible to `select` in between `Futures` that have completed. Rust [`Future`]s (underlying Rust `async`/`await`) are composable. This makes it possible to `select` in between `Futures` that have completed.
A common use case is transactions with associated timeout. In the examples shown below, we introduce a fake HAL device which performs some transaction. We have modelled the time it takes based on the input parameter (`n`) as `350ms + n * 100ms)`. [`Future`]: https://doc.rust-lang.org/std/future/trait.Future.html
A common use case is transactions with an associated timeout. In the examples shown below, we introduce a fake HAL device that performs some transaction. We have modelled the time it takes based on the input parameter (`n`) as `350ms + n * 100ms`.
Using the `select_biased` macro from the `futures` crate it may look like this: Using the `select_biased` macro from the `futures` crate it may look like this:
@ -62,19 +71,13 @@ select_biased! {
} }
``` ```
Assuming the `hal_get` will take 450ms to finish, a short timeout of 200ms will expire. Assuming the `hal_get` will take 450ms to finish, a short timeout of 200ms will expire before `hal_get` can complete.
``` rust Extending the timeout to 1000ms would cause `hal_get` will to complete first.
// Call hal with long relative timeout using `select_biased`
select_biased! {
v = hal_get(1).fuse() => hprintln!("hal returned {}", v), // hal finish first
_ = Systick::delay(1000.millis()).fuse() => hprintln!("timeout", ),
}
```
By extending the timeout to 1000ms, the `hal_get` will finish first. Using `select_biased` any number of futures can be combined, so its very powerful. However, as the timeout pattern is frequently used, more ergonomic support is baked into RTIC, provided by the [`rtic-monotonics`] and [`rtic-time`] crates.
Using `select_biased` any number of futures can be combined, so its very powerful. However, as the timeout pattern is frequently used, it is directly supported by the RTIC [rtc-monotonics] and [rtic-time] crates. The second example from above using `timeout_after`: Rewriting the second example from above using `timeout_after` gives:
``` rust ``` rust
// Call hal with long relative timeout using monotonic `timeout_after` // Call hal with long relative timeout using monotonic `timeout_after`
@ -84,7 +87,7 @@ match Systick::timeout_after(1000.millis(), hal_get(1)).await {
} }
``` ```
In cases you want exact control over time without drift. For this purpose we can use exact points in time using `Instance`, and spans of time using `Duration`. Operations on the `Instance` and `Duration` types are given by the [fugit] crate. In cases where you want exact control over time without drift we can use exact points in time using `Instant`, and spans of time using `Duration`. Operations on the `Instant` and `Duration` types come from the [`fugit`] crate.
[fugit]: https://crates.io/crates/fugit [fugit]: https://crates.io/crates/fugit
@ -109,10 +112,20 @@ for n in 0..3 {
} }
``` ```
`instant = Systick::now()` gives the baseline (i.e., the absolute current point in time). We want to call `hal_get` after 1000ms relative to this absolute point in time. This can be accomplished by `Systick::delay_until(instant).await;`. We define the absolute point in time for the `timeout`, and call `Systick::timeout_at(timeout, hal_get(n)).await`. For the first loop iteration `n == 0`, and the `hal_get` will take 350ms (and finishes before the timeout). For the second iteration `n == 1`, and `hal_get` will take 450ms (and again succeeds to finish before the timeout). For the third iteration `n == 2` (`hal_get` will take 5500ms to finish). In this case we will run into a timeout. `let mut instant = Systick::now()` sets the starting time of execution.
We want to call `hal_get` after 1000ms relative to this starting time. This can be accomplished by using `Systick::delay_until(instant).await`.
The complete example: Then, we define a point in time called `timeout`, and call `Systick::timeout_at(timeout, hal_get(n)).await`.
For the first iteration of the loop, with `n == 0`, the `hal_get` will take 350ms (and finishes before the timeout).
For the second iteration, with `n == 1`, the `hal_get` will take 450ms (and again succeeds to finish before the timeout).
For the third iteration, with `n == 2`, `hal_get` will take 550ms to finish, in which case we will run into a timeout.
<details>
<summary>A complete example</summary>
``` rust ``` rust
{{#include ../../../../rtic/examples/async-timeout.rs}} {{#include ../../../../rtic/examples/async-timeout.rs}}
@ -125,3 +138,4 @@ $ cargo run --target thumbv7m-none-eabi --example async-timeout --features test-
``` console ``` console
{{#include ../../../../rtic/ci/expected/async-timeout.run}} {{#include ../../../../rtic/ci/expected/async-timeout.run}}
``` ```
</details>