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<!DOCTYPE html><html lang="en"><head><meta charset="utf-8"><meta name="viewport" content="width=device-width, initial-scale=1.0"><meta name="generator" content="rustdoc"><meta name="description" content="A Hardware Abstraction Layer (HAL) for embedded systems"><title>embedded_hal - Rust</title><script>if(window.location.protocol!=="file:")document.head.insertAdjacentHTML("beforeend","SourceSerif4-Regular-46f98efaafac5295.ttf.woff2,FiraSans-Regular-018c141bf0843ffd.woff2,FiraSans-Medium-8f9a781e4970d388.woff2,SourceCodePro-Regular-562dcc5011b6de7d.ttf.woff2,SourceCodePro-Semibold-d899c5a5c4aeb14a.ttf.woff2".split(",").map(f=>`<link rel="preload" as="font" type="font/woff2" crossorigin href="../static.files/${f}">`).join(""))</script><link rel="stylesheet" href="../static.files/normalize-76eba96aa4d2e634.css"><link rel="stylesheet" href="../static.files/rustdoc-b0742ba02757f159.css"><meta name="rustdoc-vars" data-root-path="../" data-static-root-path="../static.files/" data-current-crate="embedded_hal" data-themes="" data-resource-suffix="" data-rustdoc-version="1.83.0 (90b35a623 2024-11-26)" data-channel="1.83.0" data-search-js="search-f0d225181b97f9a4.js" data-settings-js="settings-805db61a62df4bd2.js" ><script src="../static.files/storage-1d39b6787ed640ff.js"></script><script defer src="../crates.js"></script><script defer src="../static.files/main-f070b9041d14864c.js"></script><noscript><link rel="stylesheet" href="../static.files/noscript-0111fcff984fae8f.css"></noscript><link rel="alternate icon" type="image/png" href="../static.files/favicon-32x32-422f7d1d52889060.png"><link rel="icon" type="image/svg+xml" href="../static.files/favicon-2c020d218678b618.svg"></head><body class="rustdoc mod crate"><!--[if lte IE 11]><div class="warning">This old browser is unsupported and will most likely display funky things.</div><![endif]--><nav class="mobile-topbar"><button class="sidebar-menu-toggle" title="show sidebar"></button></nav><nav class="sidebar"><div class="sidebar-crate"><h2><a href="../embedded_hal/index.html">embedded_<wbr>hal</a><span class="version">0.2.7</span></h2></div><div class="sidebar-elems"><ul class="block"><li><a id="all-types" href="all.html">All Items</a></li></ul><section id="rustdoc-toc"><h3><a href="#">Sections</a></h3><ul class="block top-toc"><li><a href="#design-goals" title="Design goals">Design goals</a></li><li><a href="#out-of-scope" title="Out of scope">Out of scope</a></li><li><a href="#reference-implementation" title="Reference implementation">Reference implementation</a></li><li><a href="#platform-agnostic-drivers" title="Platform agnostic drivers">Platform agnostic drivers</a></li><li><a href="#detailed-design" title="Detailed design">Detailed design</a><ul><li><a href="#traits" title="Traits">Traits</a></li><li><a href="#suggested-implementation" title="Suggested implementation">Suggested implementation</a></li><li><a href="#intended-usage" title="Intended usage">Intended usage</a></li><li><a href="#generic-programming-and-higher-level-abstractions" title="Generic programming and higher level abstractions">Generic programming and higher level abstractions</a></li></ul></li></ul><h3><a href="#modules">Crate Items</a></h3><ul class="block"><li><a href="#modules" title="Modules">Modules</a></li><li><a href="#traits-1" title="Traits">Traits</a></li></ul></section><div id="rustdoc-modnav"></div></div></nav><div class="sidebar-resizer"></div><main><div class="width-limiter"><rustdoc-search></rustdoc-search><section id="main-content" class="content"><div class="main-heading"><h1>Crate <span>embedded_hal</span><button id="copy-path" title="Copy item path to clipboard">Copy item path</button></h1><rustdoc-toolbar></rustdoc-toolbar><span class="sub-heading"><a class="src" href="../src/embedded_hal/lib.rs.html#1-999">source</a> </span></div><details class="toggle top-doc" open><summary class="hideme"><span>Expand description</span></summary><div class="docblock"><p>A Hardware Abstraction Layer (HAL) for embedded systems</p>
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||
<p><strong>NOTE</strong> This HAL is still is active development. Expect the traits presented here to be
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tweaked, split or be replaced wholesale before being stabilized, i.e. before hitting the 1.0.0
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release. That being said there’s a part of the HAL that’s currently considered unproven and is
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||
hidden behind an “unproven” Cargo feature. This API is even more volatile and it’s exempt from
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semver rules: it can change in a non-backward compatible fashion or even disappear in between
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patch releases.</p>
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<h2 id="design-goals"><a class="doc-anchor" href="#design-goals">§</a>Design goals</h2>
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<p>The HAL</p>
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<ul>
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<li>
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<p>Must <em>erase</em> device specific details. Neither register, register blocks or magic values should
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appear in the API.</p>
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</li>
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<li>
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<p>Must be generic <em>within</em> a device and <em>across</em> devices. The API to use a serial interface must
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be the same regardless of whether the implementation uses the USART1 or UART4 peripheral of a
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device or the UART0 peripheral of another device.</p>
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</li>
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<li>
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<p>Where possible must <em>not</em> be tied to a specific asynchronous model. The API should be usable
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in blocking mode, with the <code>futures</code> model, with an async/await model or with a callback model.
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(cf. the <a href="https://crates.io/crates/nb"><code>nb</code></a> crate)</p>
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</li>
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<li>
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<p>Must be minimal, and thus easy to implement and zero cost, yet highly composable. People that
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want higher level abstraction should <em>prefer to use this HAL</em> rather than <em>re-implement</em>
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register manipulation code.</p>
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</li>
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<li>
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<p>Serve as a foundation for building an ecosystem of platform agnostic drivers. Here driver
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means a library crate that lets a target platform interface an external device like a digital
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sensor or a wireless transceiver. The advantage of this system is that by writing the driver as
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a generic library on top of <code>embedded-hal</code> driver authors can support any number of target
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platforms (e.g. Cortex-M microcontrollers, AVR microcontrollers, embedded Linux, etc.). The
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advantage for application developers is that by adopting <code>embedded-hal</code> they can unlock all
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these drivers for their platform.</p>
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</li>
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</ul>
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<h2 id="out-of-scope"><a class="doc-anchor" href="#out-of-scope">§</a>Out of scope</h2>
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<ul>
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<li>Initialization and configuration stuff like “ensure this serial interface and that SPI
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interface are not using the same pins”. The HAL will focus on <em>doing I/O</em>.</li>
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</ul>
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<h2 id="reference-implementation"><a class="doc-anchor" href="#reference-implementation">§</a>Reference implementation</h2>
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<p>The <a href="https://crates.io/crates/stm32f30x-hal/0.1.0"><code>stm32f30x-hal</code></a> crate contains a reference implementation of this HAL.</p>
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<h2 id="platform-agnostic-drivers"><a class="doc-anchor" href="#platform-agnostic-drivers">§</a>Platform agnostic drivers</h2>
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<p>You can find platform agnostic drivers built on top of <code>embedded-hal</code> on crates.io by <a href="https://crates.io/keywords/embedded-hal">searching
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for the <em>embedded-hal</em> keyword</a>.</p>
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<p>If you writing a platform agnostic driver yourself you are highly encouraged to <a href="https://doc.rust-lang.org/cargo/reference/manifest.html#package-metadata">add the
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embedded-hal keyword</a>
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to your crate before publishing it!</p>
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<h2 id="detailed-design"><a class="doc-anchor" href="#detailed-design">§</a>Detailed design</h2><h3 id="traits"><a class="doc-anchor" href="#traits">§</a>Traits</h3>
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<p>The HAL is specified as traits to allow generic programming. These traits make use of the
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<a href="https://crates.io/crates/nb"><code>nb</code></a> crate (<em>please go read that crate documentation before continuing</em>) to abstract over
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the asynchronous model and to also provide a blocking operation mode.</p>
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<p>Here’s how a HAL trait may look like:</p>
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<div class="example-wrap"><pre class="rust rust-example-rendered"><code><span class="kw">extern crate </span>nb;
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<span class="doccomment">/// A serial interface
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</span><span class="kw">pub trait </span>Serial {
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<span class="doccomment">/// Error type associated to this serial interface
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</span><span class="kw">type </span>Error;
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<span class="doccomment">/// Reads a single byte
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</span><span class="kw">fn </span>read(<span class="kw-2">&mut </span><span class="self">self</span>) -> nb::Result<u8, <span class="self">Self</span>::Error>;
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<span class="doccomment">/// Writes a single byte
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</span><span class="kw">fn </span>write(<span class="kw-2">&mut </span><span class="self">self</span>, byte: u8) -> nb::Result<(), <span class="self">Self</span>::Error>;
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}</code></pre></div>
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<p>The <code>nb::Result</code> enum is used to add a <a href="https://docs.rs/nb/0.1.0/nb/enum.Error.html"><code>WouldBlock</code></a> variant to the errors
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of the serial interface. As explained in the documentation of the <code>nb</code> crate this single API,
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when paired with the macros in the <code>nb</code> crate, can operate in a blocking manner, or in a
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non-blocking manner compatible with <code>futures</code> and with the <code>await!</code> operator.</p>
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<p>Some traits, like the one shown below, may expose possibly blocking APIs that can’t fail. In
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those cases <code>nb::Result<_, Void></code> is used.</p>
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<div class="example-wrap"><pre class="rust rust-example-rendered"><code><span class="kw">extern crate </span>nb;
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<span class="kw">extern crate </span>void;
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<span class="kw">use </span>void::Void;
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<span class="doccomment">/// A count down timer
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</span><span class="kw">pub trait </span>CountDown {
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<span class="comment">// ..
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</span><span class="doccomment">/// "waits" until the count down is over
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</span><span class="kw">fn </span>wait(<span class="kw-2">&mut </span><span class="self">self</span>) -> nb::Result<(), Void>;
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}
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</code></pre></div>
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<h3 id="suggested-implementation"><a class="doc-anchor" href="#suggested-implementation">§</a>Suggested implementation</h3>
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<p>The HAL traits should be implemented for device crates generated via <a href="https://crates.io/crates/svd2rust"><code>svd2rust</code></a> to maximize
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code reuse.</p>
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<p>Shown below is an implementation of some of the HAL traits for the <a href="https://crates.io/crates/stm32f30x"><code>stm32f30x</code></a> crate. This
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single implementation will work for <em>any</em> microcontroller in the STM32F30x family.</p>
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<div class="example-wrap"><pre class="rust rust-example-rendered"><code><span class="comment">// crate: stm32f30x-hal
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// An implementation of the `embedded-hal` traits for STM32F30x microcontrollers
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</span><span class="kw">extern crate </span>embedded_hal <span class="kw">as </span>hal;
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<span class="kw">extern crate </span>nb;
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<span class="comment">// device crate
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</span><span class="kw">extern crate </span>stm32f30x;
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<span class="kw">use </span>stm32f30x::USART1;
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<span class="doccomment">/// A serial interface
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</span><span class="comment">// NOTE generic over the USART peripheral
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</span><span class="kw">pub struct </span>Serial<USART> { usart: USART }
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<span class="comment">// convenience type alias
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</span><span class="kw">pub type </span>Serial1 = Serial<USART1>;
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<span class="doccomment">/// Serial interface error
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</span><span class="kw">pub enum </span>Error {
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<span class="doccomment">/// Buffer overrun
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</span>Overrun,
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<span class="comment">// omitted: other error variants
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</span>}
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<span class="kw">impl </span>hal::serial::Read<u8> <span class="kw">for </span>Serial<USART1> {
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<span class="kw">type </span>Error = Error;
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<span class="kw">fn </span>read(<span class="kw-2">&mut </span><span class="self">self</span>) -> nb::Result<u8, Error> {
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<span class="comment">// read the status register
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</span><span class="kw">let </span>isr = <span class="self">self</span>.usart.isr.read();
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<span class="kw">if </span>isr.ore().bit_is_set() {
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<span class="comment">// Error: Buffer overrun
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</span><span class="prelude-val">Err</span>(nb::Error::Other(Error::Overrun))
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}
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<span class="comment">// omitted: checks for other errors
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</span><span class="kw">else if </span>isr.rxne().bit_is_set() {
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<span class="comment">// Data available: read the data register
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</span><span class="prelude-val">Ok</span>(<span class="self">self</span>.usart.rdr.read().bits() <span class="kw">as </span>u8)
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} <span class="kw">else </span>{
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<span class="comment">// No data available yet
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</span><span class="prelude-val">Err</span>(nb::Error::WouldBlock)
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}
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}
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}
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<span class="kw">impl </span>hal::serial::Write<u8> <span class="kw">for </span>Serial<USART1> {
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<span class="kw">type </span>Error = Error;
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<span class="kw">fn </span>write(<span class="kw-2">&mut </span><span class="self">self</span>, byte: u8) -> nb::Result<(), Error> {
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<span class="comment">// Similar to the `read` implementation
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</span>}
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<span class="kw">fn </span>flush(<span class="kw-2">&mut </span><span class="self">self</span>) -> nb::Result<(), Error> {
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<span class="comment">// Similar to the `read` implementation
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</span>}
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}
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</code></pre></div>
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<h3 id="intended-usage"><a class="doc-anchor" href="#intended-usage">§</a>Intended usage</h3>
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<p>Thanks to the <a href="https://crates.io/crates/nb"><code>nb</code></a> crate the HAL API can be used in a blocking manner,
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with <code>futures</code> or with the <code>await</code> operator using the <a href="https://docs.rs/nb/0.1.0/nb/macro.block.html"><code>block!</code></a>,
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<a href="https://docs.rs/nb/0.1.0/nb/index.html#how-to-use-this-crate"><code>try_nb!</code></a> and <a href="https://docs.rs/nb/0.1.0/nb/index.html#how-to-use-this-crate"><code>await!</code></a> macros respectively.</p>
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<h4 id="blocking-mode"><a class="doc-anchor" href="#blocking-mode">§</a>Blocking mode</h4>
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<p>An example of sending a string over the serial interface in a blocking
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fashion:</p>
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<div class="example-wrap"><pre class="rust rust-example-rendered"><code><span class="kw">extern crate </span>embedded_hal;
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<span class="attr">#[macro_use(block)]
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</span><span class="kw">extern crate </span>nb;
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||
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<span class="kw">use </span>stm32f30x_hal::Serial1;
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<span class="kw">use </span>embedded_hal::serial::Write;
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<span class="kw">let </span><span class="kw-2">mut </span>serial: Serial1 = {
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<span class="comment">// ..
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</span>};
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<span class="kw">for </span>byte <span class="kw">in </span><span class="string">b"Hello, world!" </span>{
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<span class="comment">// NOTE `block!` blocks until `serial.write()` completes and returns
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// `Result<(), Error>`
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</span><span class="macro">block!</span>(serial.write(<span class="kw-2">*</span>byte)).unwrap();
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}
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</code></pre></div>
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<h4 id="futures"><a class="doc-anchor" href="#futures">§</a><code>futures</code></h4>
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<p>An example of running two tasks concurrently. First task: blink an LED every
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second. Second task: loop back data over the serial interface.</p>
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<div class="example-wrap"><pre class="rust rust-example-rendered"><code><span class="kw">extern crate </span>embedded_hal <span class="kw">as </span>hal;
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<span class="kw">extern crate </span>futures;
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<span class="kw">extern crate </span>void;
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||
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<span class="attr">#[macro_use(try_nb)]
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</span><span class="kw">extern crate </span>nb;
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<span class="kw">use </span>hal::prelude::<span class="kw-2">*</span>;
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<span class="kw">use </span>futures::{
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future,
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Async,
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Future,
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};
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<span class="kw">use </span>futures::future::Loop;
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<span class="kw">use </span>stm32f30x_hal::{Led, Serial1, Timer6};
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<span class="kw">use </span>void::Void;
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||
|
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<span class="doccomment">/// `futures` version of `CountDown.wait`
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///
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/// This returns a future that must be polled to completion
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</span><span class="kw">fn </span>wait<T>(<span class="kw-2">mut </span>timer: T) -> <span class="kw">impl </span>Future<Item = T, Error = Void>
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<span class="kw">where
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</span>T: hal::timer::CountDown,
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||
{
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<span class="kw">let </span><span class="kw-2">mut </span>timer = <span class="prelude-val">Some</span>(timer);
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||
future::poll_fn(<span class="kw">move </span>|| {
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<span class="macro">try_nb!</span>(timer.as_mut().unwrap().wait());
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||
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<span class="prelude-val">Ok</span>(Async::Ready(timer.take().unwrap()))
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||
})
|
||
}
|
||
|
||
<span class="doccomment">/// `futures` version of `Serial.read`
|
||
///
|
||
/// This returns a future that must be polled to completion
|
||
</span><span class="kw">fn </span>read<S>(<span class="kw-2">mut </span>serial: S) -> <span class="kw">impl </span>Future<Item = (S, u8), Error = S::Error>
|
||
<span class="kw">where
|
||
</span>S: hal::serial::Read<u8>,
|
||
{
|
||
<span class="kw">let </span><span class="kw-2">mut </span>serial = <span class="prelude-val">Some</span>(serial);
|
||
future::poll_fn(<span class="kw">move </span>|| {
|
||
<span class="kw">let </span>byte = <span class="macro">try_nb!</span>(serial.as_mut().unwrap().read());
|
||
|
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<span class="prelude-val">Ok</span>(Async::Ready((serial.take().unwrap(), byte)))
|
||
})
|
||
}
|
||
|
||
<span class="doccomment">/// `futures` version of `Serial.write`
|
||
///
|
||
/// This returns a future that must be polled to completion
|
||
</span><span class="kw">fn </span>write<S>(<span class="kw-2">mut </span>serial: S, byte: u8) -> <span class="kw">impl </span>Future<Item = S, Error = S::Error>
|
||
<span class="kw">where
|
||
</span>S: hal::serial::Write<u8>,
|
||
{
|
||
<span class="kw">let </span><span class="kw-2">mut </span>serial = <span class="prelude-val">Some</span>(serial);
|
||
future::poll_fn(<span class="kw">move </span>|| {
|
||
<span class="macro">try_nb!</span>(serial.as_mut().unwrap().write(byte));
|
||
|
||
<span class="prelude-val">Ok</span>(Async::Ready(serial.take().unwrap()))
|
||
})
|
||
}
|
||
|
||
<span class="kw">fn </span>main() {
|
||
<span class="comment">// HAL implementers
|
||
</span><span class="kw">let </span>timer: Timer6 = {
|
||
<span class="comment">// ..
|
||
</span>};
|
||
<span class="kw">let </span>serial: Serial1 = {
|
||
<span class="comment">// ..
|
||
</span>};
|
||
<span class="kw">let </span>led: Led = {
|
||
<span class="comment">// ..
|
||
</span>};
|
||
|
||
<span class="comment">// Tasks
|
||
</span><span class="kw">let </span><span class="kw-2">mut </span>blinky = future::loop_fn::<<span class="kw">_</span>, (), <span class="kw">_</span>, <span class="kw">_</span>>(
|
||
(led, timer, <span class="bool-val">true</span>),
|
||
|(<span class="kw-2">mut </span>led, <span class="kw-2">mut </span>timer, state)| {
|
||
wait(timer).map(<span class="kw">move </span>|timer| {
|
||
<span class="kw">if </span>state {
|
||
led.on();
|
||
} <span class="kw">else </span>{
|
||
led.off();
|
||
}
|
||
|
||
Loop::Continue((led, timer, !state))
|
||
})
|
||
});
|
||
|
||
<span class="kw">let </span><span class="kw-2">mut </span>loopback = future::loop_fn::<<span class="kw">_</span>, (), <span class="kw">_</span>, <span class="kw">_</span>>(serial, |<span class="kw-2">mut </span>serial| {
|
||
read(serial).and_then(|(serial, byte)| {
|
||
write(serial, byte)
|
||
}).map(|serial| {
|
||
Loop::Continue(serial)
|
||
})
|
||
});
|
||
|
||
<span class="comment">// Event loop
|
||
</span><span class="kw">loop </span>{
|
||
blinky.poll().unwrap(); <span class="comment">// NOTE(unwrap) E = Void
|
||
</span>loopback.poll().unwrap();
|
||
}
|
||
}
|
||
</code></pre></div>
|
||
<h4 id="await"><a class="doc-anchor" href="#await">§</a><code>await</code></h4>
|
||
<p>Same example as above but using <code>await!</code> instead of <code>futures</code>.</p>
|
||
|
||
<div class="example-wrap"><pre class="rust rust-example-rendered"><code><span class="attr">#![feature(generator_trait)]
|
||
#![feature(generators)]
|
||
|
||
</span><span class="kw">extern crate </span>embedded_hal <span class="kw">as </span>hal;
|
||
|
||
<span class="attr">#[macro_use(<span class="kw">await</span>)]
|
||
</span><span class="kw">extern crate </span>nb;
|
||
|
||
<span class="kw">use </span>std::ops::Generator;
|
||
<span class="kw">use </span>std::pin::Pin;
|
||
|
||
<span class="kw">use </span>hal::prelude::<span class="kw-2">*</span>;
|
||
<span class="kw">use </span>stm32f30x_hal::{Led, Serial1, Timer6};
|
||
|
||
<span class="kw">fn </span>main() {
|
||
<span class="comment">// HAL implementers
|
||
</span><span class="kw">let </span><span class="kw-2">mut </span>timer: Timer6 = {
|
||
<span class="comment">// ..
|
||
</span>};
|
||
<span class="kw">let </span><span class="kw-2">mut </span>serial: Serial1 = {
|
||
<span class="comment">// ..
|
||
</span>};
|
||
<span class="kw">let </span><span class="kw-2">mut </span>led: Led = {
|
||
<span class="comment">// ..
|
||
</span>};
|
||
|
||
<span class="comment">// Tasks
|
||
</span><span class="kw">let </span><span class="kw-2">mut </span>blinky = (<span class="kw">move </span>|| {
|
||
<span class="kw">let </span><span class="kw-2">mut </span>state = <span class="bool-val">false</span>;
|
||
<span class="kw">loop </span>{
|
||
<span class="comment">// `await!` means "suspend / yield here" instead of "block until
|
||
// completion"
|
||
</span><span class="macro">await!</span>(timer.wait()).unwrap(); <span class="comment">// NOTE(unwrap) E = Void
|
||
|
||
</span>state = !state;
|
||
|
||
<span class="kw">if </span>state {
|
||
led.on();
|
||
} <span class="kw">else </span>{
|
||
led.off();
|
||
}
|
||
}
|
||
});
|
||
|
||
<span class="kw">let </span><span class="kw-2">mut </span>loopback = (<span class="kw">move </span>|| {
|
||
<span class="kw">loop </span>{
|
||
<span class="kw">let </span>byte = <span class="macro">await!</span>(serial.read()).unwrap();
|
||
<span class="macro">await!</span>(serial.write(byte)).unwrap();
|
||
}
|
||
});
|
||
|
||
<span class="comment">// Event loop
|
||
</span><span class="kw">loop </span>{
|
||
Pin::new(<span class="kw-2">&mut </span>blinky).resume(());
|
||
Pin::new(<span class="kw-2">&mut </span>loopback).resume(());
|
||
}
|
||
}
|
||
</code></pre></div>
|
||
<h3 id="generic-programming-and-higher-level-abstractions"><a class="doc-anchor" href="#generic-programming-and-higher-level-abstractions">§</a>Generic programming and higher level abstractions</h3>
|
||
<p>The core of the HAL has been kept minimal on purpose to encourage building <strong>generic</strong> higher
|
||
level abstractions on top of it. Some higher level abstractions that pick an asynchronous model
|
||
or that have blocking behavior and that are deemed useful to build other abstractions can be
|
||
found in the <code>blocking</code> module and, in the future, in the <code>futures</code> and <code>async</code> modules.</p>
|
||
<p>Some examples:</p>
|
||
<p><strong>NOTE</strong> All the functions shown below could have been written as trait
|
||
methods with default implementation to allow specialization, but they have
|
||
been written as functions to keep things simple.</p>
|
||
<ul>
|
||
<li>Write a whole buffer to a serial device in blocking a fashion.</li>
|
||
</ul>
|
||
|
||
<div class="example-wrap"><pre class="rust rust-example-rendered"><code><span class="kw">extern crate </span>embedded_hal <span class="kw">as </span>hal;
|
||
<span class="attr">#[macro_use(block)]
|
||
</span><span class="kw">extern crate </span>nb;
|
||
|
||
<span class="kw">use </span>hal::prelude::<span class="kw-2">*</span>;
|
||
|
||
<span class="kw">fn </span>write_all<S>(serial: <span class="kw-2">&mut </span>S, buffer: <span class="kw-2">&</span>[u8]) -> <span class="prelude-ty">Result</span><(), S::Error>
|
||
<span class="kw">where
|
||
</span>S: hal::serial::Write<u8>
|
||
{
|
||
<span class="kw">for </span><span class="kw-2">&</span>byte <span class="kw">in </span>buffer {
|
||
<span class="macro">block!</span>(serial.write(byte))<span class="question-mark">?</span>;
|
||
}
|
||
|
||
<span class="prelude-val">Ok</span>(())
|
||
}
|
||
</code></pre></div>
|
||
<ul>
|
||
<li>Blocking serial read with timeout</li>
|
||
</ul>
|
||
|
||
<div class="example-wrap"><pre class="rust rust-example-rendered"><code><span class="kw">extern crate </span>embedded_hal <span class="kw">as </span>hal;
|
||
<span class="kw">extern crate </span>nb;
|
||
|
||
<span class="kw">use </span>hal::prelude::<span class="kw-2">*</span>;
|
||
|
||
<span class="kw">enum </span>Error<E> {
|
||
<span class="doccomment">/// Serial interface error
|
||
</span>Serial(E),
|
||
TimedOut,
|
||
}
|
||
|
||
<span class="kw">fn </span>read_with_timeout<S, T>(
|
||
serial: <span class="kw-2">&mut </span>S,
|
||
timer: <span class="kw-2">&mut </span>T,
|
||
timeout: T::Time,
|
||
) -> <span class="prelude-ty">Result</span><u8, Error<S::Error>>
|
||
<span class="kw">where
|
||
</span>T: hal::timer::CountDown,
|
||
S: hal::serial::Read<u8>,
|
||
{
|
||
timer.start(timeout);
|
||
|
||
<span class="kw">loop </span>{
|
||
<span class="kw">match </span>serial.read() {
|
||
<span class="comment">// raise error
|
||
</span><span class="prelude-val">Err</span>(nb::Error::Other(e)) => <span class="kw">return </span><span class="prelude-val">Err</span>(Error::Serial(e)),
|
||
<span class="prelude-val">Err</span>(nb::Error::WouldBlock) => {
|
||
<span class="comment">// no data available yet, check the timer below
|
||
</span>},
|
||
<span class="prelude-val">Ok</span>(byte) => <span class="kw">return </span><span class="prelude-val">Ok</span>(byte),
|
||
}
|
||
|
||
<span class="kw">match </span>timer.wait() {
|
||
<span class="prelude-val">Err</span>(nb::Error::Other(e)) => {
|
||
<span class="comment">// The error type specified by `timer.wait()` is `!`, which
|
||
// means no error can actually occur. The Rust compiler
|
||
// still forces us to provide this match arm, though.
|
||
</span><span class="macro">unreachable!</span>()
|
||
},
|
||
<span class="comment">// no timeout yet, try again
|
||
</span><span class="prelude-val">Err</span>(nb::Error::WouldBlock) => <span class="kw">continue</span>,
|
||
<span class="prelude-val">Ok</span>(()) => <span class="kw">return </span><span class="prelude-val">Err</span>(Error::TimedOut),
|
||
}
|
||
}
|
||
}
|
||
</code></pre></div>
|
||
<ul>
|
||
<li>Asynchronous SPI transfer</li>
|
||
</ul>
|
||
|
||
<div class="example-wrap"><pre class="rust rust-example-rendered"><code><span class="attr">#![feature(conservative_impl_trait)]
|
||
#![feature(generators)]
|
||
#![feature(generator_trait)]
|
||
|
||
</span><span class="kw">extern crate </span>embedded_hal <span class="kw">as </span>hal;
|
||
<span class="attr">#[macro_use(<span class="kw">await</span>)]
|
||
</span><span class="kw">extern crate </span>nb;
|
||
|
||
<span class="kw">use </span>std::ops::Generator;
|
||
|
||
<span class="doccomment">/// Transfers a byte buffer of size N
|
||
///
|
||
/// Returns the same byte buffer but filled with the data received from the
|
||
/// slave device
|
||
</span><span class="kw">fn </span>transfer<S, B>(
|
||
<span class="kw-2">mut </span>spi: S,
|
||
<span class="kw-2">mut </span>buffer: [u8; <span class="number">16</span>], <span class="comment">// NOTE this should be generic over the size of the array
|
||
</span>) -> <span class="kw">impl </span>Generator<Return = <span class="prelude-ty">Result</span><(S, [u8; <span class="number">16</span>]), S::Error>, Yield = ()>
|
||
<span class="kw">where
|
||
</span>S: hal::spi::FullDuplex<u8>,
|
||
{
|
||
<span class="kw">move </span>|| {
|
||
<span class="kw">let </span>n = buffer.len();
|
||
<span class="kw">for </span>i <span class="kw">in </span><span class="number">0</span>..n {
|
||
<span class="macro">await!</span>(spi.send(buffer[i]))<span class="question-mark">?</span>;
|
||
buffer[i] = <span class="macro">await!</span>(spi.read())<span class="question-mark">?</span>;
|
||
}
|
||
|
||
<span class="prelude-val">Ok</span>((spi, buffer))
|
||
}
|
||
}
|
||
</code></pre></div>
|
||
<ul>
|
||
<li>Buffered serial interface with periodic flushing in interrupt handler</li>
|
||
</ul>
|
||
|
||
<div class="example-wrap"><pre class="rust rust-example-rendered"><code><span class="kw">extern crate </span>embedded_hal <span class="kw">as </span>hal;
|
||
<span class="kw">extern crate </span>nb;
|
||
<span class="kw">extern crate </span>void;
|
||
|
||
<span class="kw">use </span>hal::prelude::<span class="kw-2">*</span>;
|
||
<span class="kw">use </span>void::Void;
|
||
|
||
<span class="kw">fn </span>flush<S>(serial: <span class="kw-2">&mut </span>S, cb: <span class="kw-2">&mut </span>CircularBuffer)
|
||
<span class="kw">where
|
||
</span>S: hal::serial::Write<u8, Error = Void>,
|
||
{
|
||
<span class="kw">loop </span>{
|
||
<span class="kw">if let </span><span class="prelude-val">Some</span>(byte) = cb.peek() {
|
||
<span class="kw">match </span>serial.write(<span class="kw-2">*</span>byte) {
|
||
<span class="prelude-val">Err</span>(nb::Error::Other(<span class="kw">_</span>)) => <span class="macro">unreachable!</span>(),
|
||
<span class="prelude-val">Err</span>(nb::Error::WouldBlock) => <span class="kw">return</span>,
|
||
<span class="prelude-val">Ok</span>(()) => {}, <span class="comment">// keep flushing data
|
||
</span>}
|
||
}
|
||
|
||
cb.pop();
|
||
}
|
||
}
|
||
|
||
<span class="comment">// The stuff below could be in some other crate
|
||
|
||
</span><span class="doccomment">/// Global singleton
|
||
</span><span class="kw">pub struct </span>BufferedSerial1;
|
||
|
||
<span class="comment">// NOTE private
|
||
</span><span class="kw">static </span>BUFFER1: Mutex<CircularBuffer> = {
|
||
<span class="comment">// ..
|
||
</span>};
|
||
<span class="kw">static </span>SERIAL1: Mutex<Serial1> = {
|
||
<span class="comment">// ..
|
||
</span>};
|
||
|
||
<span class="kw">impl </span>BufferedSerial1 {
|
||
<span class="kw">pub fn </span>write(<span class="kw-2">&</span><span class="self">self</span>, byte: u8) {
|
||
<span class="self">self</span>.write_all(<span class="kw-2">&</span>[byte])
|
||
}
|
||
|
||
<span class="kw">pub fn </span>write_all(<span class="kw-2">&</span><span class="self">self</span>, bytes: <span class="kw-2">&</span>[u8]) {
|
||
<span class="kw">let </span><span class="kw-2">mut </span>buffer = BUFFER1.lock();
|
||
<span class="kw">for </span>byte <span class="kw">in </span>bytes {
|
||
buffer.push(<span class="kw-2">*</span>byte).expect(<span class="string">"buffer overrun"</span>);
|
||
}
|
||
<span class="comment">// omitted: pend / enable interrupt_handler
|
||
</span>}
|
||
}
|
||
|
||
<span class="kw">fn </span>interrupt_handler() {
|
||
<span class="kw">let </span><span class="kw-2">mut </span>serial = SERIAL1.lock();
|
||
<span class="kw">let </span><span class="kw-2">mut </span>buffer = BUFFER1.lock();
|
||
|
||
flush(<span class="kw-2">&mut *</span>serial, <span class="kw-2">&mut </span>buffer);
|
||
}
|
||
|
||
</code></pre></div>
|
||
</div></details><h2 id="modules" class="section-header">Modules<a href="#modules" class="anchor">§</a></h2><ul class="item-table"><li><div class="item-name"><a class="mod" href="adc/index.html" title="mod embedded_hal::adc">adc</a></div><div class="desc docblock-short">Analog-digital conversion traits</div></li><li><div class="item-name"><a class="mod" href="blocking/index.html" title="mod embedded_hal::blocking">blocking</a></div><div class="desc docblock-short">Blocking API</div></li><li><div class="item-name"><a class="mod" href="can/index.html" title="mod embedded_hal::can">can</a></div><div class="desc docblock-short">Controller Area Network</div></li><li><div class="item-name"><a class="mod" href="digital/index.html" title="mod embedded_hal::digital">digital</a></div><div class="desc docblock-short">Digital I/O</div></li><li><div class="item-name"><a class="mod" href="fmt/index.html" title="mod embedded_hal::fmt">fmt</a></div><div class="desc docblock-short">Implementation of <code>core::fmt::Write</code> for the HAL’s <code>serial::Write</code>.</div></li><li><div class="item-name"><a class="mod" href="prelude/index.html" title="mod embedded_hal::prelude">prelude</a></div><div class="desc docblock-short">The prelude is a collection of all the traits in this crate</div></li><li><div class="item-name"><a class="mod" href="serial/index.html" title="mod embedded_hal::serial">serial</a></div><div class="desc docblock-short">Serial interface</div></li><li><div class="item-name"><a class="mod" href="spi/index.html" title="mod embedded_hal::spi">spi</a></div><div class="desc docblock-short">Serial Peripheral Interface</div></li><li><div class="item-name"><a class="mod" href="timer/index.html" title="mod embedded_hal::timer">timer</a></div><div class="desc docblock-short">Timers</div></li><li><div class="item-name"><a class="mod" href="watchdog/index.html" title="mod embedded_hal::watchdog">watchdog</a></div><div class="desc docblock-short">Traits for interactions with a processors watchdog timer.</div></li></ul><h2 id="traits-1" class="section-header">Traits<a href="#traits-1" class="anchor">§</a></h2><ul class="item-table"><li><div class="item-name"><a class="trait" href="trait.PwmPin.html" title="trait embedded_hal::PwmPin">PwmPin</a></div><div class="desc docblock-short">A single PWM channel / pin</div></li></ul></section></div></main></body></html> |