Split remove old examples

2024-11-23 20:22:51 +01:00 · 2023-04-14 21:53:56 +02:00 · 2023-04-14 21:53:56 +02:00 · 5a9135961f
commit 5a9135961f
parent ef8046b060
13 changed files with 505 additions and 0 deletions
--- a/examples/README.md
+++ b/examples/README.md
@ -0,0 +1,42 @@
 # `RTIC examples`
 > Here you can find examples on different aspects of the RTIC scheduler.
 ## Structure
 This repo does have example applications based on RTIC framework for popular hardware platforms (for example nRF series and Bluepill).
 ## Requirements
 To run these examples, you need to have working environment as described in [Installing the tools](https://rust-embedded.github.io/book/intro/install.html) chapter of **The Embedded Rust Book**.
 Short list:
 * Rust and cargo
 * Toolchain for your microcontroller
 * OpenOCD
 ## Contributing
 New examples are always welcome!
 ## External examples
 Some projects maintain RTIC examples in their own repository. Follow these links to find more RTIC examples.
 - The [`teensy4-rs` project](https://github.com/mciantyre/teensy4-rs) maintains `RTIC v1.0` examples that run on the Teensy 4.0 and 4.1.
 ## License
 Licensed under either of
 * Apache License, Version 2.0 ([LICENSE-APACHE](LICENSE-APACHE) or
  [http://www.apache.org/licenses/LICENSE-2.0](http://www.apache.org/licenses/LICENSE-2.0))
 * MIT license ([LICENSE-MIT](LICENSE-MIT) or [http://opensource.org/licenses/MIT](http://opensource.org/licenses/MIT))
 at your option.
 ### Contribution
 Unless you explicitly state otherwise, any contribution intentionally submitted for inclusion in the
 work by you, as defined in the Apache-2.0 license, shall be dual licensed as above, without any
 additional terms or conditions.
--- a/examples/rp2040_local_i2c_init/.cargo/config.toml
+++ b/examples/rp2040_local_i2c_init/.cargo/config.toml
@ -0,0 +1,45 @@
 [target.thumbv6m-none-eabi]
 # uncomment this to make `cargo run` execute programs on QEMU
 # runner = "qemu-system-arm -cpu cortex-m3 -machine lm3s6965evb -nographic -semihosting-config enable=on,target=native -kernel"
 [target.'cfg(all(target_arch = "arm", target_os = "none"))']
 # uncomment ONE of these three option to make `cargo run` start a GDB session
 # which option to pick depends on your system
 # runner = "arm-none-eabi-gdb -q -x openocd.gdb"
 # runner = "gdb-multiarch -q -x openocd.gdb"
 # runner = "gdb -q -x openocd.gdb"
 rustflags = [
  # This is needed if your flash or ram addresses are not aligned to 0x10000 in memory.x
  # See https://github.com/rust-embedded/cortex-m-quickstart/pull/95
  "-C", "link-arg=--nmagic",
  # LLD (shipped with the Rust toolchain) is used as the default linker
  "-C", "link-arg=-Tlink.x",
  # if you run into problems with LLD switch to the GNU linker by commenting out
  # this line
  # "-C", "linker=arm-none-eabi-ld",
  # if you need to link to pre-compiled C libraries provided by a C toolchain
  # use GCC as the linker by commenting out both lines above and then
  # uncommenting the three lines below
  # "-C", "linker=arm-none-eabi-gcc",
  # "-C", "link-arg=-Wl,-Tlink.x",
  # "-C", "link-arg=-nostartfiles",
 ]
 [build]
 # Pick ONE of these compilation targets
 target = "thumbv6m-none-eabi"        # Cortex-M0 and Cortex-M0+
 # target = "thumbv7m-none-eabi"        # Cortex-M3
 # target = "thumbv7em-none-eabi"       # Cortex-M4 and Cortex-M7 (no FPU)
 # target = "thumbv7em-none-eabihf"     # Cortex-M4F and Cortex-M7F (with FPU)
 # target = "thumbv8m.base-none-eabi"   # Cortex-M23
 # target = "thumbv8m.main-none-eabi"   # Cortex-M33 (no FPU)
 # target = "thumbv8m.main-none-eabihf" # Cortex-M33 (with FPU)
 # thumbv7m-none-eabi is not coming with core and alloc, compile myself
 [unstable]
 mtime-on-use = true
 build-std = ["core", "alloc"]
--- a/examples/rp2040_local_i2c_init/Cargo.toml
+++ b/examples/rp2040_local_i2c_init/Cargo.toml
@ -0,0 +1,32 @@
 [package]
 name = "rp2040_local_i2c_init"
 categories = ["embedded", "no-std"]
 description = "Example task local initialized resources for Raspberry Pi Pico"
 license = "MIT OR Apache-2.0"
 version = "0.1.0"
 edition = "2021"
 [dependencies]
 cortex-m = "0.7"
 rtic = { git = "https://github.com/rtic-rs/rtic", features = [
  "thumbv6-backend",
 ] }
 rtic-monotonics = { git = "https://github.com/rtic-rs/rtic", features = [
  "rp2040",
 ] }
 embedded-hal = { version = "0.2.7", features = ["unproven"] }
 fugit = "0.3"
 rp-pico = "0.7.0"
 panic-probe = "0.3"
 [profile.dev]
 opt-level = 1
 codegen-units = 16
 debug = true
 lto = false
 [profile.release]
 opt-level = "s"   # optimize for size
 codegen-units = 1 # better optimizations
 debug = true      # symbols are nice and they don't increase the size on Flash
 lto = true        # better optimzations
--- a/examples/rp2040_local_i2c_init/Embed.toml
+++ b/examples/rp2040_local_i2c_init/Embed.toml
@ -0,0 +1,39 @@
 [default.probe]
 protocol = "Swd"
 speed = 20000
 # If you only have one probe cargo embed will pick automatically
 # Otherwise: add your probe's VID/PID/serial to filter
 ## rust-dap
 # usb_vid = "6666"
 # usb_pid = "4444"
 # serial = "test"
 [default.flashing]
 enabled = true
 [default.reset]
 enabled = true
 halt_afterwards = false
 [default.general]
 chip = "RP2040"
 log_level = "WARN"
 # RP2040 does not support connect_under_reset
 connect_under_reset = false
 [default.rtt]
 enabled = true
 up_mode = "NoBlockSkip"
 channels = [
    { up = 0, down = 0, name = "name", up_mode = "NoBlockSkip", format = "Defmt" },
 ]
 timeout = 3000
 show_timestamps = true
 log_enabled = false
 log_path = "./logs"
 [default.gdb]
 enabled = true
 gdb_connection_string = "127.0.0.1:2345"
--- a/examples/rp2040_local_i2c_init/build.rs
+++ b/examples/rp2040_local_i2c_init/build.rs
@ -0,0 +1,31 @@
 //! This build script copies the `memory.x` file from the crate root into
 //! a directory where the linker can always find it at build time.
 //! For many projects this is optional, as the linker always searches the
 //! project root directory -- wherever `Cargo.toml` is. However, if you
 //! are using a workspace or have a more complicated build setup, this
 //! build script becomes required. Additionally, by requesting that
 //! Cargo re-run the build script whenever `memory.x` is changed,
 //! updating `memory.x` ensures a rebuild of the application with the
 //! new memory settings.
 use std::env;
 use std::fs::File;
 use std::io::Write;
 use std::path::PathBuf;
 fn main() {
    // Put `memory.x` in our output directory and ensure it's
    // on the linker search path.
    let out = &PathBuf::from(env::var_os("OUT_DIR").unwrap());
    File::create(out.join("memory.x"))
        .unwrap()
        .write_all(include_bytes!("memory.x"))
        .unwrap();
    println!("cargo:rustc-link-search={}", out.display());
    // By default, Cargo will re-run a build script whenever
    // any file in the project changes. By specifying `memory.x`
    // here, we ensure the build script is only re-run when
    // `memory.x` is changed.
    println!("cargo:rerun-if-changed=memory.x");
 }
--- a/examples/rp2040_local_i2c_init/memory.x
+++ b/examples/rp2040_local_i2c_init/memory.x
@ -0,0 +1,15 @@
 MEMORY {
    BOOT2 : ORIGIN = 0x10000000, LENGTH = 0x100
    FLASH : ORIGIN = 0x10000100, LENGTH = 2048K - 0x100
    RAM   : ORIGIN = 0x20000000, LENGTH = 256K
 }
 EXTERN(BOOT2_FIRMWARE)
 SECTIONS {
    /* ### Boot loader */
    .boot2 ORIGIN(BOOT2) :
    {
        KEEP(*(.boot2));
    } > BOOT2
 } INSERT BEFORE .text;
--- a/examples/rp2040_local_i2c_init/src/main.rs
+++ b/examples/rp2040_local_i2c_init/src/main.rs
@ -0,0 +1,114 @@
 #![no_std]
 #![no_main]
 #![feature(type_alias_impl_trait)]
 #[rtic::app(
    device = rp_pico::hal::pac,
    dispatchers = [TIMER_IRQ_1]
 )]
 mod app {
    use rp_pico::hal::{
        clocks, gpio,
        gpio::pin::bank0::{Gpio2, Gpio25, Gpio3},
        gpio::pin::PushPullOutput,
        pac,
        sio::Sio,
        watchdog::Watchdog,
        I2C,
    };
    use rp_pico::XOSC_CRYSTAL_FREQ;
    use core::mem::MaybeUninit;
    use embedded_hal::digital::v2::{OutputPin, ToggleableOutputPin};
    use fugit::RateExtU32;
    use rtic_monotonics::rp2040::*;
    use panic_probe as _;
    rtic_monotonics::make_rp2040_monotonic_handler!();
    type I2CBus = I2C<
        pac::I2C1,
        (
            gpio::Pin<Gpio2, gpio::FunctionI2C>,
            gpio::Pin<Gpio3, gpio::FunctionI2C>,
        ),
    >;
    #[shared]
    struct Shared {}
    #[local]
    struct Local {
        led: gpio::Pin<Gpio25, PushPullOutput>,
        i2c: &'static mut I2CBus,
    }
    #[init(local=[
        // Task local initialized resources are static
        // Here we use MaybeUninit to allow for initialization in init()
        // This enables its usage in driver initialization
        i2c_ctx: MaybeUninit<I2CBus> = MaybeUninit::uninit()
    ])]
    fn init(mut ctx: init::Context) -> (Shared, Local) {
        // Configure the clocks, watchdog - The default is to generate a 125 MHz system clock
        Timer::start(ctx.device.TIMER, &mut ctx.device.RESETS); // default rp2040 clock-rate is 125MHz
        let mut watchdog = Watchdog::new(ctx.device.WATCHDOG);
        let clocks = clocks::init_clocks_and_plls(
            XOSC_CRYSTAL_FREQ,
            ctx.device.XOSC,
            ctx.device.CLOCKS,
            ctx.device.PLL_SYS,
            ctx.device.PLL_USB,
            &mut ctx.device.RESETS,
            &mut watchdog,
        )
        .ok()
        .unwrap();
        // Init LED pin
        let sio = Sio::new(ctx.device.SIO);
        let gpioa = rp_pico::Pins::new(
            ctx.device.IO_BANK0,
            ctx.device.PADS_BANK0,
            sio.gpio_bank0,
            &mut ctx.device.RESETS,
        );
        let mut led = gpioa.led.into_push_pull_output();
        led.set_low().unwrap();
        // Init I2C pins
        let sda_pin = gpioa.gpio2.into_mode::<gpio::FunctionI2C>();
        let scl_pin = gpioa.gpio3.into_mode::<gpio::FunctionI2C>();
        // Init I2C itself, using MaybeUninit to overwrite the previously
        // uninitialized i2c_ctx variable without dropping its value
        // (i2c_ctx definined in init local resources above)
        let i2c_tmp: &'static mut _ = ctx.local.i2c_ctx.write(I2C::i2c1(
            ctx.device.I2C1,
            sda_pin,
            scl_pin,
            100.kHz(),
            &mut ctx.device.RESETS,
            &clocks.system_clock,
        ));
        // Spawn heartbeat task
        heartbeat::spawn().ok();
        // Return resources and timer
        (Shared {}, Local { led, i2c: i2c_tmp })
    }
    #[task(local = [i2c, led])]
    async fn heartbeat(ctx: heartbeat::Context) {
        // Flicker the built-in LED
        _ = ctx.local.led.toggle();
        // Congrats, you can use your i2c and have access to it here,
        // now to do something with it!
        // Re-spawn this task after 1 second
        Timer::delay(1000.millis()).await;
    }
 }
--- a/examples/stm32f3_blinky/.cargo/config.toml
+++ b/examples/stm32f3_blinky/.cargo/config.toml
@ -0,0 +1,45 @@
 [target.thumbv7m-none-eabi]
 # uncomment this to make `cargo run` execute programs on QEMU
 # runner = "qemu-system-arm -cpu cortex-m3 -machine lm3s6965evb -nographic -semihosting-config enable=on,target=native -kernel"
 [target.'cfg(all(target_arch = "arm", target_os = "none"))']
 # uncomment ONE of these three option to make `cargo run` start a GDB session
 # which option to pick depends on your system
 # runner = "arm-none-eabi-gdb -q -x openocd.gdb"
 # runner = "gdb-multiarch -q -x openocd.gdb"
 # runner = "gdb -q -x openocd.gdb"
 rustflags = [
  # This is needed if your flash or ram addresses are not aligned to 0x10000 in memory.x
  # See https://github.com/rust-embedded/cortex-m-quickstart/pull/95
  "-C", "link-arg=--nmagic",
  # LLD (shipped with the Rust toolchain) is used as the default linker
  "-C", "link-arg=-Tlink.x",
  # if you run into problems with LLD switch to the GNU linker by commenting out
  # this line
  # "-C", "linker=arm-none-eabi-ld",
  # if you need to link to pre-compiled C libraries provided by a C toolchain
  # use GCC as the linker by commenting out both lines above and then
  # uncommenting the three lines below
  # "-C", "linker=arm-none-eabi-gcc",
  # "-C", "link-arg=-Wl,-Tlink.x",
  # "-C", "link-arg=-nostartfiles",
 ]
 [build]
 # Pick ONE of these compilation targets
 # target = "thumbv6m-none-eabi"        # Cortex-M0 and Cortex-M0+
 target = "thumbv7m-none-eabi"        # Cortex-M3
 # target = "thumbv7em-none-eabi"       # Cortex-M4 and Cortex-M7 (no FPU)
 # target = "thumbv7em-none-eabihf"     # Cortex-M4F and Cortex-M7F (with FPU)
 # target = "thumbv8m.base-none-eabi"   # Cortex-M23
 # target = "thumbv8m.main-none-eabi"   # Cortex-M33 (no FPU)
 # target = "thumbv8m.main-none-eabihf" # Cortex-M33 (with FPU)
 # thumbv7m-none-eabi is not coming with core and alloc, compile myself
 [unstable]
 mtime-on-use = true
 build-std = ["core", "alloc"]
--- a/examples/stm32f3_blinky/Cargo.toml
+++ b/examples/stm32f3_blinky/Cargo.toml
@ -0,0 +1,35 @@
 [package]
 authors = ["Simsys <winfried.simon@gmail.com>"]
 edition = "2021"
 readme = "README.md"
 name = "stm32f3-blinky"
 version = "0.1.0"
 [dependencies]
 embedded-hal = "0.2.7"
 rtic = { git = "https://github.com/rtic-rs/rtic", features = ["thumbv7-backend"] }
 rtic-monotonics = { git = "https://github.com/rtic-rs/rtic", features = ["cortex-m-systick"] }
 panic-rtt-target = { version = "0.1.2", features = ["cortex-m"] }
 rtt-target = { version = "0.3.1", features = ["cortex-m"] }
 [dependencies.stm32f3xx-hal]
 features = ["stm32f303xc", "rt"]
 version = "0.9.2"
 # this lets you use `cargo fix`!
 [[bin]]
 name = "stm32f3-blinky"
 test = false
 bench = false
 [profile.dev]
 opt-level = 1
 codegen-units = 16
 debug = true
 lto = false
 [profile.release]
 opt-level = "s"   # optimize for size
 codegen-units = 1 # better optimizations
 debug = true      # symbols are nice and they don't increase the size on Flash
 lto = true        # better optimizations
--- a/examples/stm32f3_blinky/Embed.toml
+++ b/examples/stm32f3_blinky/Embed.toml
@ -0,0 +1,9 @@
 [default.general]
 chip = "stm32f303re"
 [default.rtt]
 enabled = true
 [default.gdb]
 enabled = false
--- a/examples/stm32f3_blinky/README.md
+++ b/examples/stm32f3_blinky/README.md
@ -0,0 +1,19 @@
 # STM32F3 RTIC Blink example
 Working example of simple LED blinking application for STM32 F303 Nucleo-64 board based on the STM32F303RE chip. Example uses schedule API and peripherials access. This example is based on blue-pill blinky example.
 ## How-to
 ### Build
 Run `cargo +nightly build` to compile the code. If you run it for the first time, it will take some time to download and compile dependencies.
 After that, you can use for example the cargo-embed tool to flash and run it
 ```bash
 $ cargo +nightly embed
 ```
 ### Setup environment, flash and run program
 In the [Discovery Book](https://rust-embedded.github.io/discovery) you find all needed informations to setup the environment, flash the controler and run the program.
--- a/examples/stm32f3_blinky/memory.x
+++ b/examples/stm32f3_blinky/memory.x
@ -0,0 +1,5 @@
 MEMORY
 {
    FLASH : ORIGIN = 0x08000000, LENGTH = 256K
    RAM : ORIGIN = 0x20000000, LENGTH = 40K
 }
--- a/examples/stm32f3_blinky/src/main.rs
+++ b/examples/stm32f3_blinky/src/main.rs
@ -0,0 +1,74 @@
 #![deny(unsafe_code)]
 #![deny(warnings)]
 #![no_main]
 #![no_std]
 #![feature(type_alias_impl_trait)]
 use panic_rtt_target as _;
 use rtic::app;
 use rtic_monotonics::systick::*;
 use rtt_target::{rprintln, rtt_init_print};
 use stm32f3xx_hal::gpio::{Output, PushPull, PA5};
 use stm32f3xx_hal::prelude::*;
 #[app(device = stm32f3xx_hal::pac, peripherals = true, dispatchers = [SPI1])]
 mod app {
    use super::*;
    rtic_monotonics::make_systick_handler!();
    #[shared]
    struct Shared {}
    #[local]
    struct Local {
        led: PA5<Output<PushPull>>,
        state: bool,
    }
    #[init]
    fn init(cx: init::Context) -> (Shared, Local) {
        // Setup clocks
        let mut flash = cx.device.FLASH.constrain();
        let mut rcc = cx.device.RCC.constrain();
        Systick::start(cx.core.SYST, 36_000_000); // default STM32F303 clock-rate is 36MHz
        rtt_init_print!();
        rprintln!("init");
        let _clocks = rcc
            .cfgr
            .use_hse(8.MHz())
            .sysclk(36.MHz())
            .pclk1(36.MHz())
            .freeze(&mut flash.acr);
        // Setup LED
        let mut gpioa = cx.device.GPIOA.split(&mut rcc.ahb);
        let mut led = gpioa
            .pa5
            .into_push_pull_output(&mut gpioa.moder, &mut gpioa.otyper);
        led.set_high().unwrap();
        // Schedule the blinking task
        blink::spawn().ok();
        (Shared {}, Local { led, state: false })
    }
    #[task(local = [led, state])]
    async fn blink(cx: blink::Context) {
        loop {
            rprintln!("blink");
            if *cx.local.state {
                cx.local.led.set_high().unwrap();
                *cx.local.state = false;
            } else {
                cx.local.led.set_low().unwrap();
                *cx.local.state = true;
            }
            Systick::delay(1000.millis()).await;
        }
    }
 }