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Moved content from the wiki to the docs
New: delaying_a_task.adoc, copied as-is from the wiki and placed in the navigation until we have a better place for it (or remove/replace it) index: Tweaked the structure, added some content from the wiki, and made some general copy edits to improve clarity. getting_started.adoc: Corrected various out-of-date information, added troubleshooting tips from the wiki, added some new information, various other small edits. basic_application.adoc: Corrected out-of-date information, various clarifications and edits. After these changes, IMO most of the content on the github wiki is no longer necessary and can be removed for clarity. The few sections I didn‘t integrate or copy over were either out of date or unfinished.
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@ -3,6 +3,7 @@
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** xref:project_structure.adoc[Project Structure]
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* xref:layer_by_layer.adoc[Bare metal to async]
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* xref:runtime.adoc[Executor]
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* xref:delaying_a_task.adoc[Delaying a Task]
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* xref:hal.adoc[HAL]
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** xref:nrf.adoc[nRF]
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** xref:stm32.adoc[STM32]
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@ -6,9 +6,11 @@ So you've got one of the xref:examples.adoc[examples] running, but what now? Let
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The full example can be found link:https://github.com/embassy-rs/embassy/tree/master/docs/modules/ROOT/examples/basic[here].
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NOTE: If you’re using VS Code and rust-analyzer to view and edit the examples, you may need to make some changes to `.vscode/settings.json` to tell it which project we’re working on. Follow the instructions commented in that file to get rust-analyzer working correctly.
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=== Bare metal
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The first thing you'll notice is a few declarations, two of which indicate that Embassy is suitable for bare metal development:
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The first thing you’ll notice are two attributes at the top of the file. These tells the compiler that program has no access to std, and that there is no main function (because it is not run by an OS).
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[source,rust]
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----
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@ -48,9 +50,9 @@ NOTE: Notice that there is no busy waiting going on in this task. It is using th
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=== Main
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The main entry point of an Embassy application is defined using the `#[embassy_executor::main]` macro. The entry point is also required to take a `Spawner` and a `Peripherals` argument.
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The main entry point of an Embassy application is defined using the `#[embassy_executor::main]` macro. The entry point is passed a `Spawner`, which it can use to spawn other tasks.
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The `Spawner` is the way the main application spawns other tasks. The `Peripherals` type comes from the HAL and holds all peripherals that the application may use. In this case, we want to configure one of the pins as a GPIO output driving the LED:
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We then initialize the HAL with a default config, which gives us a `Peripherals` struct we can use to access the MCU’s various peripherals. In this case, we want to configure one of the pins as a GPIO output driving the LED:
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[source,rust]
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----
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@ -60,7 +62,6 @@ include::example$basic/src/main.rs[lines="22..-1"]
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What happens when the `blinker` task has been spawned and main returns? Well, the main entry point is actually just like any other task, except that you can only have one and it takes some specific type arguments. The magic lies within the `#[embassy_executor::main]` macro. The macro does the following:
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. Creates an Embassy Executor
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. Initializes the microcontroller HAL to get the `Peripherals`
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. Defines a main task for the entry point
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. Runs the executor spawning the main task
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28
docs/modules/ROOT/pages/delaying_a_task.adoc
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28
docs/modules/ROOT/pages/delaying_a_task.adoc
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= Delaying a Task
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In an embedded program, delaying a task is one of the most common actions taken. In an event loop, delays will need to be inserted to ensure
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that other tasks have a chance to run before the next iteration of the loop is called, if no other I/O is performed. Embassy provides an abstraction
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to delay the current task for a specified interval of time.
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Timing is serviced by the `embassy::time::Timer` struct, which provides two timing methods.
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`Timer::at` creates a future that completes at the specified `Instant`, relative to the system boot time.
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`Timer::after` creates a future that completes after the specified `Duration`, relative to when the future was created.
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An example of a delay is provided as follows:
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[,rust]
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----
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use embassy::executor::{task, Executor};
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use embassy::time::{Duration, Timer};
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#[task]
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/// Task that ticks periodically
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async fn tick_periodic() -> ! {
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loop {
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rprintln!("tick!");
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// async sleep primitive, suspends the task for 500ms.
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Timer::after(Duration::from_millis(500)).await;
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}
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}
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----
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@ -9,7 +9,9 @@ If you don't have any supported board, don't worry: you can also run embassy on
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== Getting a board with examples
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Embassy supports many microcontroller families, but the easiest ways to get started is if you have one of the more common development kits.
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Embassy supports many microcontroller families, but the quickest way to get started is by using a board which Embassy has existing example code for.
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This list is non-exhaustive. If your board isn’t included here, check the link:https://github.com/embassy-rs/embassy/tree/main/examples[examples folder] to see if example code has been written for it.
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=== nRF kits
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@ -36,7 +38,7 @@ Embassy supports many microcontroller families, but the easiest ways to get star
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== Running an example
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First you need to clone the [github repository];
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First you need to clone the link:https://github.com/embassy-rs/embassy[github repository];
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[source, bash]
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----
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@ -44,17 +46,80 @@ git clone https://github.com/embassy-rs/embassy.git
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cd embassy
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----
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You can run an example by opening a terminal and entering the following commands:
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Once you have a copy of the repository, find examples folder for your board and, and build an example program. `blinky` is a good choice as all it does is blink an LED – the embedded world’s equivalent of “Hello World”.
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[source, bash]
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----
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cd examples/nrf52840
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cargo build --bin blinky --release
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----
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Once you’ve confirmed you can build the example, connect your computer to your board with a debug probe and run it on hardware:
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[source, bash]
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----
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cargo run --bin blinky --release
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----
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If everything worked correctly, you should see a blinking LED on your board, and debug output similar to this on your computer:
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[source]
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----
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Finished dev [unoptimized + debuginfo] target(s) in 1m 56s
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Running `probe-run --chip STM32F407VGTx target/thumbv7em-none-eabi/debug/blinky`
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(HOST) INFO flashing program (71.36 KiB)
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(HOST) INFO success!
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────────────────────────────────────────────────────────────────────────────────
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0 INFO Hello World!
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└─ blinky::__embassy_main::task::{generator#0} @ src/bin/blinky.rs:18
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1 INFO high
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└─ blinky::__embassy_main::task::{generator#0} @ src/bin/blinky.rs:23
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2 INFO low
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└─ blinky::__embassy_main::task::{generator#0} @ src/bin/blinky.rs:27
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3 INFO high
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└─ blinky::__embassy_main::task::{generator#0} @ src/bin/blinky.rs:23
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4 INFO low
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└─ blinky::__embassy_main::task::{generator#0} @ src/bin/blinky.rs:27
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----
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NOTE: How does the `cargo run` command know how to connect to our board and program it? In each `examples` folder, there’s a `.cargo/config.toml` file which tells cargo to use link:https://probe.rs/[probe-rs] as the runner for ARM binaries in that folder. probe-rs handles communication with the debug probe and MCU. In order for this to work, probe-rs needs to know which chip it’s programming, so you’ll have to edit this file if you want to run examples on other chips.
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=== It didn’t work!
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If you hare having issues when running `cargo run --release`, please check the following:
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* You are specifying the correct `--chip on the command line``, OR
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* You have set `.cargo/config.toml`'s run line to the correct chip, AND
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* You have changed `examples/Cargo.toml`'s HAL (e.g. embassy-stm32) dependency's feature to use the correct chip (replace the existing stm32xxxx feature)
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At this point the project should run. If you do not see a blinky LED for blinky, for example, be sure to check the code is toggling your board's LED pin.
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If you are trying to run an example with `cargo run --release` and you see the following output:
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[source]
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----
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0.000000 INFO Hello World!
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└─ <invalid location: defmt frame-index: 14>
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0.000000 DEBUG rcc: Clocks { sys: Hertz(80000000), apb1: Hertz(80000000), apb1_tim: Hertz(80000000), apb2: Hertz(80000000), apb2_tim: Hertz(80000000), ahb1: Hertz(80000000), ahb2: Hertz(80000000), ahb3: Hertz(80000000) }
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└─ <invalid location: defmt frame-index: 124>
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0.000061 TRACE allocating type=Interrupt mps=8 interval_ms=255, dir=In
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└─ <invalid location: defmt frame-index: 68>
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0.000091 TRACE index=1
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└─ <invalid location: defmt frame-index: 72>
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----
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To get rid of the frame-index error add the following to your `Cargo.toml`:
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[source,toml]
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----
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[profile.release]
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debug = 2
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----
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If you’re still having problems, check the link:https://embassy.dev/book/dev/faq.html[FAQ], or ask for help in the link:https://matrix.to/#/#embassy-rs:matrix.org[Embassy Chat Room].
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== What's next?
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Congratulations, you have your first Embassy application running! Here are some alternatives on where to go from here:
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Congratulations, you have your first Embassy application running! Here are some suggestions for where to go from here:
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* Read more about the xref:runtime.adoc[executor].
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* Read more about the xref:hal.adoc[HAL].
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== What is async?
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When handling I/O, software must call functions that block program execution until the I/O operation completes. When running inside of an OS such as Linux, such functions generally transfer control to the kernel so that another task, known as a thread, can be executed if available, or the CPU can be put to sleep until another such task is ready to perform more work. Because an OS cannot presume that threads will behave cooperatively, threads are relatively resource-intensive, and may be forcibly interrupted they do not transfer control back to the kernel within an allotted time. But if tasks could be presumed to behave cooperatively, or at least not maliciously, it would be possible to create tasks that appear to be almost free when compared to a traditional OS thread. In Rust, these lightweight tasks, known as 'coroutines' or 'goroutines' in other languages, are implemented with async.
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When handling I/O, software must call functions that block program execution until the I/O operation completes. When running inside of an OS such as Linux, such functions generally transfer control to the kernel so that another task (known as a “thread”) can be executed if available, or the CPU can be put to sleep until another task is ready.
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Async-await works by transforming each async function into an object called a future. When a future blocks on I/O the future yields, and the scheduler, called an executor, can select a different future to execute. Compared to alternatives such as an RTOS, async can yield better performance and lower power consumption because the executor doesn't have to guess when a future is ready to execute. However, program size may be higher than other alternatives, which may be a problem for certain space-constrained devices with very low memory. On the devices Embassy supports, such as stm32 and nrf, memory is generally large enough to accommodate the modestly-increased program size.
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Because an OS cannot presume that threads will behave cooperatively, threads are relatively resource-intensive, and may be forcibly interrupted they do not transfer control back to the kernel within an allotted time. If tasks could be presumed to behave cooperatively, or at least not maliciously, it would be possible to create tasks that appear to be almost free when compared to a traditional OS thread.
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In other programming languages, these lightweight tasks are known as “coroutines” or ”goroutines”. In Rust, they are implemented with async. Async-await works by transforming each async function into an object called a future. When a future blocks on I/O the future yields, and the scheduler, called an executor, can select a different future to execute.
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Compared to alternatives such as an RTOS, async can yield better performance and lower power consumption because the executor doesn't have to guess when a future is ready to execute. However, program size may be higher than other alternatives, which may be a problem for certain space-constrained devices with very low memory. On the devices Embassy supports, such as stm32 and nrf, memory is generally large enough to accommodate the modestly-increased program size.
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== What is Embassy?
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The Embassy project consists of several crates that you can use together or independently:
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* **Executor** - The link:https://docs.embassy.dev/embassy-executor/[embassy-executor] is an async/await executor that generally executes a fixed number of tasks, allocated at startup, though more can be added later. The HAL is an API that you can use to access peripherals, such as USART, UART, I2C, SPI, CAN, and USB. Embassy provides implementations of both async and blocking APIs where it makes sense. DMA (Direct Memory Access) is an example where async is a good fit, whereas GPIO states are a better fit for a blocking API. The executor may also provide a system timer that you can use for both async and blocking delays. For less than one microsecond, blocking delays should be used because the cost of context-switching is too high and the executor will be unable to provide accurate timing.
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=== Executor
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The link:https://docs.embassy.dev/embassy-executor/[embassy-executor] is an async/await executor that generally executes a fixed number of tasks, allocated at startup, though more can be added later. The executor may also provide a system timer that you can use for both async and blocking delays. For less than one microsecond, blocking delays should be used because the cost of context-switching is too high and the executor will be unable to provide accurate timing.
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=== Hardware Abstraction Layers
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HALs implement safe Rust API which let you use peripherals such as USART, UART, I2C, SPI, CAN, and USB without having to directly manipulate registers.
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Embassy provides implementations of both async and blocking APIs where it makes sense. DMA (Direct Memory Access) is an example where async is a good fit, whereas GPIO states are a better fit for a blocking API.
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The Embassy project maintains HALs for select hardware, but you can still use HALs from other projects with Embassy.
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* link:https://docs.embassy.dev/embassy-stm32/[embassy-stm32], for all STM32 microcontroller families.
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* link:https://docs.embassy.dev/embassy-nrf/[embassy-nrf], for the Nordic Semiconductor nRF52, nRF53, nRF91 series.
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* link:https://docs.embassy.dev/embassy-rp/[embassy-rp], for the Raspberry Pi RP2040 microcontroller.
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* link:https://github.com/esp-rs[esp-rs], for the Espressif Systems ESP32 series of chips.
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* **Hardware Abstraction Layers** - HALs implement safe, idiomatic Rust APIs to use the hardware capabilities, so raw register manipulation is not needed. The Embassy project maintains HALs for select hardware, but you can still use HALs from other projects with Embassy.
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** link:https://docs.embassy.dev/embassy-stm32/[embassy-stm32], for all STM32 microcontroller families.
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** link:https://docs.embassy.dev/embassy-nrf/[embassy-nrf], for the Nordic Semiconductor nRF52, nRF53, nRF91 series.
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** link:https://docs.embassy.dev/embassy-rp/[embassy-rp], for the Raspberry Pi RP2040 microcontroller.
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** link:https://github.com/esp-rs[esp-rs], for the Espressif Systems ESP32 series of chips.
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+
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NOTE: A common question is if one can use the Embassy HALs standalone. Yes, it is possible! There are no dependency on the executor within the HALs. You can even use them without async,
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as they implement both the link:https://github.com/rust-embedded/embedded-hal[Embedded HAL] blocking and async traits.
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* **Networking** - The link:https://docs.embassy.dev/embassy-net/[embassy-net] network stack implements extensive networking functionality, including Ethernet, IP, TCP, UDP, ICMP and DHCP. Async drastically simplifies managing timeouts and serving multiple connections concurrently. Several drivers for WiFi and Ethernet chips can be found.
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=== Networking
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The link:https://docs.embassy.dev/embassy-net/[embassy-net] network stack implements extensive networking functionality, including Ethernet, IP, TCP, UDP, ICMP and DHCP. Async drastically simplifies managing timeouts and serving multiple connections concurrently. Several drivers for WiFi and Ethernet chips can be found.
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* **Bluetooth** - The link:https://github.com/embassy-rs/nrf-softdevice[nrf-softdevice] crate provides Bluetooth Low Energy 4.x and 5.x support for nRF52 microcontrollers.
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=== Bluetooth
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The link:https://github.com/embassy-rs/nrf-softdevice[nrf-softdevice] crate provides Bluetooth Low Energy 4.x and 5.x support for nRF52 microcontrollers.
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* **LoRa** - link:https://github.com/embassy-rs/lora-phy[lora-phy] and link:https://docs.embassy.dev/embassy-lora/[embassy-lora] supports LoRa networking on a wide range of LoRa radios, fully integrated with a Rust link:https://github.com/ivajloip/rust-lorawan[LoRaWAN] implementation.
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=== LoRa
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link:https://github.com/embassy-rs/lora-phy[lora-phy] and link:https://docs.embassy.dev/embassy-lora/[embassy-lora] supports LoRa networking on a wide range of LoRa radios, fully integrated with a Rust link:https://github.com/ivajloip/rust-lorawan[LoRaWAN] implementation.
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* **USB** - link:https://docs.embassy.dev/embassy-usb/[embassy-usb] implements a device-side USB stack. Implementations for common classes such as USB serial (CDC ACM) and USB HID are available, and a rich builder API allows building your own.
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=== USB
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link:https://docs.embassy.dev/embassy-usb/[embassy-usb] implements a device-side USB stack. Implementations for common classes such as USB serial (CDC ACM) and USB HID are available, and a rich builder API allows building your own.
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* **Bootloader and DFU** - link:https://github.com/embassy-rs/embassy/tree/master/embassy-boot[embassy-boot] is a lightweight bootloader supporting firmware application upgrades in a power-fail-safe way, with trial boots and rollbacks.
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=== Bootloader and DFU
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link:https://github.com/embassy-rs/embassy/tree/master/embassy-boot[embassy-boot] is a lightweight bootloader supporting firmware application upgrades in a power-fail-safe way, with trial boots and rollbacks.
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== What is DMA?
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For most I/O in embedded devices, the peripheral doesn't directly support the transmission of multiple bits at once, with CAN being a notable exception. Instead, the MCU must write each byte, one at a time, and then wait until the peripheral is ready to send the next. For high I/O rates, this can pose a problem if the MCU must devote an increasing portion of its time handling each byte. The solution to this problem is to use the Direct Memory Access controller.
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The Direct Memory Access controller (DMA) is a controller that is present in MCUs that Embassy supports, including stm32 and nrf. The DMA allows the MCU to set up a transfer, either send or receive, and then wait for the transfer to complete. With DMA, once started, no MCU intervention is required until the transfer is complete, meaning that the MCU can perform other computation, or set up other I/O while the transfer is in progress. For high I/O rates, DMA can cut the time that the MCU spends handling I/O by over half. However, because DMA is more complex to set-up, it is less widely used in the embedded community. Embassy aims to change that by making DMA the first choice rather than the last. Using Embassy, there's no additional tuning required once I/O rates increase because your application is already set-up to handle them.
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== Resources
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