create input_capture

This commit is contained in:
Bruno Bousquet 2024-05-05 21:58:54 -04:00
parent 15c3ae8ef6
commit ad66dc3aab
10 changed files with 438 additions and 2 deletions

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//! Input capture driver.
use core::marker::PhantomData;
use embassy_hal_internal::{into_ref, PeripheralRef};
use embassy_sync::channel;
use super::low_level::{CountingMode, InputCaptureMode, InputTISelection, Timer};
use super::{Channel, Channel1Pin, Channel2Pin, Channel3Pin, Channel4Pin, GeneralInstance4Channel};
use crate::gpio::{AFType, AnyPin, Pull};
use crate::time::Hertz;
use crate::Peripheral;
/// Channel 1 marker type.
pub enum Ch1 {}
/// Channel 2 marker type.
pub enum Ch2 {}
/// Channel 3 marker type.
pub enum Ch3 {}
/// Channel 4 marker type.
pub enum Ch4 {}
/// Capture pin wrapper.
///
/// This wraps a pin to make it usable with capture.
pub struct CapturePin<'d, T, C> {
_pin: PeripheralRef<'d, AnyPin>,
phantom: PhantomData<(T, C)>,
}
macro_rules! channel_impl {
($new_chx:ident, $channel:ident, $pin_trait:ident) => {
impl<'d, T: GeneralInstance4Channel> CapturePin<'d, T, $channel> {
#[doc = concat!("Create a new ", stringify!($channel), " capture pin instance.")]
pub fn $new_chx(pin: impl Peripheral<P = impl $pin_trait<T>> + 'd, pull_type: Pull) -> Self {
into_ref!(pin);
critical_section::with(|_| {
pin.set_as_af_pull(pin.af_num(), AFType::Input, pull_type);
#[cfg(gpio_v2)]
pin.set_speed(crate::gpio::Speed::VeryHigh);
});
CapturePin {
_pin: pin.map_into(),
phantom: PhantomData,
}
}
}
};
}
channel_impl!(new_ch1, Ch1, Channel1Pin);
channel_impl!(new_ch2, Ch2, Channel2Pin);
channel_impl!(new_ch3, Ch3, Channel3Pin);
channel_impl!(new_ch4, Ch4, Channel4Pin);
/// Input capture driver.
pub struct InputCapture<'d, T: GeneralInstance4Channel> {
inner: Timer<'d, T>,
}
impl<'d, T: GeneralInstance4Channel> InputCapture<'d, T> {
/// Create a new input capture driver.
pub fn new(
tim: impl Peripheral<P = T> + 'd,
_ch1: Option<CapturePin<'d, T, Ch1>>,
_ch2: Option<CapturePin<'d, T, Ch2>>,
_ch3: Option<CapturePin<'d, T, Ch3>>,
_ch4: Option<CapturePin<'d, T, Ch4>>,
freq: Hertz,
counting_mode: CountingMode,
) -> Self {
Self::new_inner(tim, freq, counting_mode)
}
fn new_inner(tim: impl Peripheral<P = T> + 'd, freq: Hertz, counting_mode: CountingMode) -> Self {
let mut this = Self { inner: Timer::new(tim) };
this.inner.set_counting_mode(counting_mode);
this.set_tick_freq(freq);
this.inner.enable_outputs(); // Required for advanced timers, see GeneralInstance4Channel for details
this.inner.start();
[Channel::Ch1, Channel::Ch2, Channel::Ch3, Channel::Ch4]
.iter()
.for_each(|&channel| {
this.inner.set_input_capture_mode(channel, InputCaptureMode::Rising);
this.inner.set_input_ti_selection(channel, InputTISelection::Normal);
});
this
}
/// Enable the given channel.
pub fn enable(&mut self, channel: Channel) {
self.inner.enable_channel(channel, true);
}
/// Disable the given channel.
pub fn disable(&mut self, channel: Channel) {
self.inner.enable_channel(channel, false);
}
/// Check whether given channel is enabled
pub fn is_enabled(&self, channel: Channel) -> bool {
self.inner.get_channel_enable_state(channel)
}
/// Set tick frequency.
///
/// Note: when you call this, the max period value changes
pub fn set_tick_freq(&mut self, freq: Hertz) {
let f = freq;
assert!(f.0 > 0);
let timer_f = self.inner.get_clock_frequency();
let pclk_ticks_per_timer_period = timer_f / f;
let psc: u16 = unwrap!((pclk_ticks_per_timer_period - 1).try_into());
let regs = self.inner.regs_core();
regs.psc().write_value(psc);
// Generate an Update Request
regs.egr().write(|r| r.set_ug(true));
}
/// Set the input capture mode for a given channel.
pub fn set_input_capture_mode(&mut self, channel: Channel, mode: InputCaptureMode) {
self.inner.set_input_capture_mode(channel, mode);
}
/// Set input TI selection.
pub fn set_input_ti_selection(&mut self, channel: Channel, tisel: InputTISelection) {
self.inner.set_input_ti_selection(channel, tisel)
}
/// Get capture value for a channel.
pub fn get_capture_value(&self, channel: Channel) -> u32 {
self.inner.get_capture_value(channel)
}
}

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@ -5,6 +5,7 @@ pub mod complementary_pwm;
pub mod low_level;
pub mod qei;
pub mod simple_pwm;
pub mod input_capture;
use crate::interrupt;
use crate::rcc::RccPeripheral;

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[target.'cfg(all(target_arch = "arm", target_os = "none"))']
# replace STM32F429ZITx with your chip as listed in `probe-rs chip list`
runner = "probe-rs run --chip STM32F429ZITx"
# runner = "probe-rs run --chip STM32F429ZITx"
runner = "arm-none-eabi-gdb -q -x openocd.gdb"
[build]
target = "thumbv7em-none-eabi"
# Pick ONE of these default 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)
[env]
DEFMT_LOG = "trace"

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examples/stm32f4/.vscode/README.md vendored Normal file
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# VS Code Configuration
Example configurations for debugging programs in-editor with VS Code.
This directory contains configurations for two platforms:
- `LM3S6965EVB` on QEMU
- `STM32F303x` via OpenOCD
## Required Extensions
If you have the `code` command in your path, you can run the following commands to install the necessary extensions.
```sh
code --install-extension rust-lang.rust-analyzer
code --install-extension marus25.cortex-debug
```
Otherwise, you can use the Extensions view to search for and install them, or go directly to their marketplace pages and click the "Install" button.
- [Rust Language Server (rust-analyzer)](https://marketplace.visualstudio.com/items?itemName=rust-lang.rust-analyzer)
- [Cortex-Debug](https://marketplace.visualstudio.com/items?itemName=marus25.cortex-debug)
## Use
The quickstart comes with two debug configurations.
Both are configured to build the project, using the default settings from `.cargo/config`, prior to starting a debug session.
1. QEMU: Starts a debug session using an emulation of the `LM3S6965EVB` mcu.
- This works on a fresh `cargo generate` without modification of any of the settings described above.
- Semihosting output will be written to the Output view `Adapter Output`.
- `ITM` logging does not work with QEMU emulation.
2. OpenOCD: Starts a debug session for a `STM32F3DISCOVERY` board (or any `STM32F303x` running at 8MHz).
- Follow the instructions above for configuring the build with `.cargo/config` and the `memory.x` linker script.
- `ITM` output will be written to the Output view `SWO: ITM [port: 0, type: console]` output.
### Git
Files in the `.vscode/` directory are `.gitignore`d by default because many files that may end up in the `.vscode/` directory should not be committed and shared.
If you would like to save this debug configuration to your repository and share it with your team, you'll need to explicitly `git add` the files to your repository.
```sh
git add -f .vscode/launch.json
git add -f .vscode/tasks.json
git add -f .vscode/*.svd
```
## Customizing for other targets
For full documentation, see the [Cortex-Debug][cortex-debug] repository.
### Device
Some configurations use this to automatically find the SVD file.
Replace this with the part number for your device.
```json
"device": "STM32F303VCT6",
```
### OpenOCD Config Files
The `configFiles` property specifies a list of files to pass to OpenOCD.
```json
"configFiles": [
"interface/stlink-v2-1.cfg",
"target/stm32f3x.cfg"
],
```
See the [OpenOCD config docs][openocd-config] for more information and the [OpenOCD repository for available configuration files][openocd-repo].
### SVD
The SVD file is a standard way of describing all registers and peripherals of an ARM Cortex-M mCU.
Cortex-Debug needs this file to display the current register values for the peripherals on the device.
You can probably find the SVD for your device on the vendor's website.
For example, the STM32F3DISCOVERY board uses an mcu from the `STM32F303x` line of processors.
All the SVD files for the STM32F3 series are available on [ST's Website][stm32f3].
Download the [stm32f3 SVD pack][stm32f3-svd], and copy the `STM32F303.svd` file into `.vscode/`.
This line of the config tells the Cortex-Debug plug in where to find the file.
```json
"svdFile": "${workspaceRoot}/.vscode/STM32F303.svd",
```
For other processors, simply copy the correct `*.svd` file into the project and update the config accordingly.
### CPU Frequency
If your device is running at a frequency other than 8MHz, you'll need to modify this line of `launch.json` for the `ITM` output to work correctly.
```json
"cpuFrequency": 8000000,
```
### Other GDB Servers
For information on setting up GDB servers other than OpenOCD, see the [Cortex-Debug repository][cortex-debug].
[cortex-debug]: https://github.com/Marus/cortex-debug
[stm32f3]: https://www.st.com/content/st_com/en/products/microcontrollers-microprocessors/stm32-32-bit-arm-cortex-mcus/stm32-mainstream-mcus/stm32f3-series.html#resource
[stm32f3-svd]: https://www.st.com/resource/en/svd/stm32f3_svd.zip
[openocd-config]: http://openocd.org/doc/html/Config-File-Guidelines.html
[openocd-repo]: https://sourceforge.net/p/openocd/code/ci/master/tree/tcl/

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{
// See https://go.microsoft.com/fwlink/?LinkId=827846 to learn about workspace recommendations.
// Extension identifier format: ${publisher}.${name}. Example: vscode.csharp
// List of extensions which should be recommended for users of this workspace.
"recommendations": [
"rust-lang.rust-analyzer",
"marus25.cortex-debug",
"usernamehw.errorlens",
"tamasfe.even-better-toml",
"serayuzgur.crates"
],
// List of extensions recommended by VS Code that should not be recommended for users of this workspace.
"unwantedRecommendations": [
]
}

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examples/stm32f4/.vscode/launch.json vendored Normal file
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{
/*
* Requires the Rust Language Server (rust-analyzer) and Cortex-Debug extensions
* https://marketplace.visualstudio.com/items?itemName=rust-lang.rust-analyzer
* https://marketplace.visualstudio.com/items?itemName=marus25.cortex-debug
*/
"version": "0.2.0",
"configurations": [
{
/* Configuration for the STM32F446 Discovery board */
"type": "cortex-debug",
"request": "launch",
"name": "Debug (OpenOCD)",
"servertype": "openocd",
"cwd": "${workspaceRoot}",
"preLaunchTask": "Cargo Build (debug)",
"runToEntryPoint": "main",
"executable": "./target/thumbv7em-none-eabihf/debug/input_capture",
/* Run `cargo build --example itm` and uncomment this line to run itm example */
// "executable": "./target/thumbv7em-none-eabihf/debug/examples/itm",
"device": "STM32F446RET6",
"configFiles": [
"interface/stlink.cfg",
"target/stm32f4x.cfg"
],
"postLaunchCommands": [
"monitor arm semihosting enable"
],
"postRestartCommands": [],
"postResetCommands": [],
}
]
}

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examples/stm32f4/.vscode/tasks.json vendored Normal file
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{
// See https://go.microsoft.com/fwlink/?LinkId=733558
// for the documentation about the tasks.json format
"version": "2.0.0",
"tasks": [
{
/*
* This is the default cargo build task,
* but we need to provide a label for it,
* so we can invoke it from the debug launcher.
*/
"label": "Cargo Build (debug)",
"type": "process",
"command": "cargo",
"args": ["build", "--bin", "input_capture"],
"problemMatcher": [
"$rustc"
],
"group": {
"kind": "build",
"isDefault": true
}
},
{
"label": "Cargo Build (release)",
"type": "process",
"command": "cargo",
"args": ["build", "--release"],
"problemMatcher": [
"$rustc"
],
"group": "build"
},
{
"label": "Cargo Clean",
"type": "process",
"command": "cargo",
"args": ["clean"],
"problemMatcher": [],
"group": "build"
},
]
}

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# Sample OpenOCD configuration for the STM32F3DISCOVERY development board
source [find interface/stlink.cfg]
source [find target/stm32f4x.cfg]

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target extended-remote :3333
# print demangled symbols
set print asm-demangle on
# set backtrace limit to not have infinite backtrace loops
set backtrace limit 32
# detect unhandled exceptions, hard faults and panics
break DefaultHandler
break HardFault
break rust_begin_unwind
# # run the next few lines so the panic message is printed immediately
# # the number needs to be adjusted for your panic handler
# commands $bpnum
# next 4
# end
# *try* to stop at the user entry point (it might be gone due to inlining)
break main
monitor arm semihosting enable
# # send captured ITM to the file itm.fifo
# # (the microcontroller SWO pin must be connected to the programmer SWO pin)
# # 8000000 must match the core clock frequency
# monitor tpiu config internal itm.txt uart off 8000000
# # OR: make the microcontroller SWO pin output compatible with UART (8N1)
# # 8000000 must match the core clock frequency
# # 2000000 is the frequency of the SWO pin
# monitor tpiu config external uart off 8000000 2000000
# # enable ITM port 0
# monitor itm port 0 on
load
# start the process but immediately halt the processor
stepi

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#![no_std]
#![no_main]
use defmt::*;
use embassy_executor::Spawner;
use embassy_stm32::{
gpio::{self, Level, Output, Speed},
time::Hertz,
};
use embassy_time::Timer;
use {defmt_rtt as _, panic_probe as _};
use embassy_stm32::timer::{
input_capture::{CapturePin, InputCapture},
Channel,
};
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let p = embassy_stm32::init(Default::default());
info!("Hello World!");
let mut led = Output::new(p.PB2, Level::High, Speed::Low);
let ic = CapturePin::new_ch3(p.PB10, gpio::Pull::None);
let drv = InputCapture::new(p.TIM2, None, None, Some(ic), None, Hertz::mhz(1), Default::default());
let mut _last: u32;
loop {
info!("high");
led.set_high();
Timer::after_millis(300).await;
info!("low");
led.set_low();
Timer::after_millis(300).await;
_last = drv.get_capture_value(Channel::Ch1);
}
}