embassy/examples/stm32f4/src/bin/ws2812_pwm_dma.rs

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// Configure TIM3 in PWM mode, and start DMA Transfer(s) to send color data into ws2812.
// We assume the DIN pin of ws2812 connect to GPIO PB4, and ws2812 is properly powered.
//
// This demo is a combination of HAL, PAC, and manually invoke `dma::Transfer`
//
// Warning:
// DO NOT stare at ws2812 directy (especially after each MCU Reset), its (max) brightness could easily make your eyes feel burn.
#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use embassy_executor::Spawner;
2023-12-15 07:15:45 +01:00
use embassy_stm32::gpio::OutputType;
use embassy_stm32::pac;
use embassy_stm32::time::khz;
use embassy_stm32::timer::simple_pwm::{PwmPin, SimplePwm};
use embassy_stm32::timer::{Channel, CountingMode};
use embassy_time::Timer;
use {defmt_rtt as _, panic_probe as _};
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let mut device_config = embassy_stm32::Config::default();
// set SYSCLK/HCLK/PCLK2 to 20 MHz, thus each tick is 0.05 us,
// and ws2812 timings are integer multiples of 0.05 us
{
use embassy_stm32::rcc::*;
use embassy_stm32::time::*;
device_config.enable_debug_during_sleep = true;
device_config.rcc.hse = Some(Hse {
freq: mhz(12),
mode: HseMode::Oscillator,
});
device_config.rcc.sys = Sysclk::PLL1_P;
device_config.rcc.pll_src = PllSource::HSE;
device_config.rcc.pll = Some(Pll {
prediv: PllPreDiv::DIV6,
mul: PllMul::MUL80,
divp: Some(PllPDiv::DIV8),
divq: None,
divr: None,
});
}
let mut dp = embassy_stm32::init(device_config);
let mut ws2812_pwm = SimplePwm::new(
dp.TIM3,
Some(PwmPin::new_ch1(dp.PB4, OutputType::PushPull)),
None,
None,
None,
khz(800), // data rate of ws2812
CountingMode::EdgeAlignedUp,
);
// PAC level hacking,
// enable auto-reload preload, and enable timer-update-event trigger DMA
{
pac::TIM3.cr1().modify(|v| v.set_arpe(true));
pac::TIM3.dier().modify(|v| v.set_ude(true));
}
// construct ws2812 non-return-to-zero (NRZ) code bit by bit
let max_duty = ws2812_pwm.get_max_duty();
let n0 = 8 * max_duty / 25; // ws2812 Bit 0 high level timing
let n1 = 2 * n0; // ws2812 Bit 1 high level timing
let turn_off = [
n0, n0, n0, n0, n0, n0, n0, n0, // Green
n0, n0, n0, n0, n0, n0, n0, n0, // Red
n0, n0, n0, n0, n0, n0, n0, n0, // Blue
0, // keep PWM output low after a transfer
];
let dim_white = [
n0, n0, n0, n0, n0, n0, n1, n0, // Green
n0, n0, n0, n0, n0, n0, n1, n0, // Red
n0, n0, n0, n0, n0, n0, n1, n0, // Blue
0, // keep PWM output low after a transfer
];
let color_list = [&turn_off, &dim_white];
// make sure PWM output keep low on first start
ws2812_pwm.set_duty(Channel::Ch1, 0);
{
use embassy_stm32::dma::{Burst, FifoThreshold, Transfer, TransferOptions};
// configure FIFO and MBURST of DMA, to minimize DMA occupation on AHB/APB
let mut dma_transfer_option = TransferOptions::default();
dma_transfer_option.fifo_threshold = Some(FifoThreshold::Full);
dma_transfer_option.mburst = Burst::Incr8;
let mut color_list_index = 0;
loop {
// start PWM output
ws2812_pwm.enable(Channel::Ch1);
unsafe {
Transfer::new_write(
// with &mut, we can easily reuse same DMA channel multiple times
&mut dp.DMA1_CH2,
5,
color_list[color_list_index],
pac::TIM3.ccr(0).as_ptr() as *mut _,
dma_transfer_option,
)
.await;
// ws2812 need at least 50 us low level input to confirm the input data and change it's state
Timer::after_micros(50).await;
}
// stop PWM output for saving some energy
ws2812_pwm.disable(Channel::Ch1);
// wait another half second, so that we can see color change
Timer::after_millis(500).await;
// flip the index bit so that next round DMA transfer the other color data
color_list_index ^= 1;
}
}
}