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https://github.com/embassy-rs/embassy.git
synced 2024-11-24 15:52:34 +00:00
stm32 adc: introduce blocking_read
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914d7c7919
commit
f851081e09
@ -258,7 +258,7 @@ impl<'d, T: Instance> Adc<'d, T> {
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}
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/// Read an ADC pin.
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pub fn read(&mut self, channel: &mut impl AdcChannel<T>) -> u16 {
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pub fn blocking_read(&mut self, channel: &mut impl AdcChannel<T>) -> u16 {
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channel.setup();
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self.read_channel(channel.channel())
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@ -97,10 +97,10 @@ impl<'d, T: Instance> Adc<'d, T> {
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/// The length of the `dma_buf` should be a multiple of the ADC channel count.
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/// For example, if 3 channels are measured, its length can be 3 * 40 = 120 measurements.
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///
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/// `read_exact` method is used to read out measurements from the DMA ring buffer, and its buffer should be exactly half of the `dma_buf` length.
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/// It is critical to call `read_exact` frequently to prevent DMA buffer overrun.
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/// `read` method is used to read out measurements from the DMA ring buffer, and its buffer should be exactly half of the `dma_buf` length.
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/// It is critical to call `read` frequently to prevent DMA buffer overrun.
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///
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/// [`read_exact`]: #method.read_exact
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/// [`read`]: #method.read
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pub fn into_ring_buffered(
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self,
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dma: impl Peripheral<P = impl RxDma<T>> + 'd,
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@ -331,7 +331,7 @@ impl<'d, T: Instance> RingBufferedAdc<'d, T> {
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///
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/// Receive in the background is terminated if an error is returned.
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/// It must then manually be started again by calling `start()` or by re-calling `read()`.
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pub fn read<const N: usize>(&mut self, buf: &mut [u16; N]) -> Result<usize, OverrunError> {
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pub fn blocking_read<const N: usize>(&mut self, buf: &mut [u16; N]) -> Result<usize, OverrunError> {
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let r = T::regs();
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// Start background receive if it was not already started
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@ -362,14 +362,14 @@ impl<'d, T: Instance> RingBufferedAdc<'d, T> {
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/// This method fills the provided `measurements` array with ADC readings from the DMA buffer.
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/// The length of the `measurements` array should be exactly half of the DMA buffer length. Because interrupts are only generated if half or full DMA transfer completes.
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///
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/// Each call to `read_exact` will populate the `measurements` array in the same order as the channels defined with `set_sample_sequence`.
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/// Each call to `read` will populate the `measurements` array in the same order as the channels defined with `set_sample_sequence`.
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/// There will be many sequences worth of measurements in this array because it only returns if at least half of the DMA buffer is filled.
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/// For example if 3 channels are sampled `measurements` contain: `[sq0 sq1 sq3 sq0 sq1 sq3 sq0 sq1 sq3 sq0 sq1 sq3..]`.
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///
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/// If an error is returned, it indicates a DMA overrun, and the process must be restarted by calling `start` or `read_exact` again.
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/// If an error is returned, it indicates a DMA overrun, and the process must be restarted by calling `start` or `read` again.
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///
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/// By default, the ADC fills the DMA buffer as quickly as possible. To control the sample rate, call `teardown_adc` after each readout, and then start the DMA again at the desired interval.
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/// Note that even if using `teardown_adc` to control the sample rate, with each call to `read_exact`, measurements equivalent to half the size of the DMA buffer are still collected.
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/// Note that even if using `teardown_adc` to control the sample rate, with each call to `read`, measurements equivalent to half the size of the DMA buffer are still collected.
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///
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/// Example:
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/// ```rust,ignore
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@ -383,7 +383,7 @@ impl<'d, T: Instance> RingBufferedAdc<'d, T> {
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///
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/// let mut measurements = [0u16; DMA_BUF_LEN / 2];
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/// loop {
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/// match adc.read_exact(&mut measurements).await {
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/// match adc.read(&mut measurements).await {
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/// Ok(_) => {
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/// defmt::info!("adc1: {}", measurements);
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/// // Only needed to manually control sample rate.
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@ -391,7 +391,7 @@ impl<'d, T: Instance> RingBufferedAdc<'d, T> {
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/// }
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/// Err(e) => {
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/// defmt::warn!("Error: {:?}", e);
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/// // DMA overrun, next call to `read_exact` restart ADC.
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/// // DMA overrun, next call to `read` restarts ADC.
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/// }
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/// }
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///
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@ -404,7 +404,7 @@ impl<'d, T: Instance> RingBufferedAdc<'d, T> {
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/// [`set_sample_sequence`]: #method.set_sample_sequence
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/// [`teardown_adc`]: #method.teardown_adc
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/// [`start`]: #method.start
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pub async fn read_exact<const N: usize>(&mut self, measurements: &mut [u16; N]) -> Result<usize, OverrunError> {
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pub async fn read<const N: usize>(&mut self, measurements: &mut [u16; N]) -> Result<usize, OverrunError> {
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assert_eq!(
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self.ring_buf.capacity() / 2,
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N,
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@ -178,7 +178,7 @@ where
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T::regs().dr().read().0 as u16
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}
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pub fn read(&mut self, channel: &mut impl AdcChannel<T>) -> u16 {
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pub fn blocking_read(&mut self, channel: &mut impl AdcChannel<T>) -> u16 {
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channel.setup();
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// Configure ADC
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@ -254,12 +254,36 @@ impl<'d, T: Instance> Adc<'d, T> {
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}
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/// Read an ADC channel.
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pub fn read(&mut self, channel: &mut impl AdcChannel<T>) -> u16 {
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pub fn blocking_read(&mut self, channel: &mut impl AdcChannel<T>) -> u16 {
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self.read_channel(channel)
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}
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/// Asynchronously read from sequence of ADC channels.
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pub async fn read_async(
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/// Read one or multiple ADC channels using DMA.
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///
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/// `sequence` iterator and `readings` must have the same length.
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///
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/// Example
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/// ```rust,ignore
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/// use embassy_stm32::adc::{Adc, AdcChannel}
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///
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/// let mut adc = Adc::new(p.ADC1);
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/// let mut adc_pin0 = p.PA0.degrade_adc();
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/// let mut adc_pin1 = p.PA1.degrade_adc();
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/// let mut measurements = [0u16; 2];
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///
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/// adc.read_async(
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/// p.DMA1_CH2,
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/// [
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/// (&mut *adc_pin0, SampleTime::CYCLES160_5),
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/// (&mut *adc_pin1, SampleTime::CYCLES160_5),
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/// ]
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/// .into_iter(),
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/// &mut measurements,
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/// )
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/// .await;
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/// defmt::info!("measurements: {}", measurements);
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/// ```
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pub async fn read(
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&mut self,
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rx_dma: &mut impl RxDma<T>,
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sequence: impl ExactSizeIterator<Item = (&mut AnyAdcChannel<T>, SampleTime)>,
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@ -318,12 +318,36 @@ impl<'d, T: Instance> Adc<'d, T> {
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}
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/// Read an ADC channel.
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pub fn read(&mut self, channel: &mut impl AdcChannel<T>) -> u16 {
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pub fn blocking_read(&mut self, channel: &mut impl AdcChannel<T>) -> u16 {
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self.read_channel(channel)
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}
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/// Asynchronously read from sequence of ADC channels.
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pub async fn read_async(
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/// Read one or multiple ADC channels using DMA.
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///
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/// `sequence` iterator and `readings` must have the same length.
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///
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/// Example
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/// ```rust,ignore
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/// use embassy_stm32::adc::{Adc, AdcChannel}
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///
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/// let mut adc = Adc::new(p.ADC1);
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/// let mut adc_pin0 = p.PA0.degrade_adc();
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/// let mut adc_pin2 = p.PA2.degrade_adc();
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/// let mut measurements = [0u16; 2];
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///
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/// adc.read_async(
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/// p.DMA2_CH0,
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/// [
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/// (&mut *adc_pin0, SampleTime::CYCLES112),
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/// (&mut *adc_pin2, SampleTime::CYCLES112),
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/// ]
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/// .into_iter(),
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/// &mut measurements,
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/// )
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/// .await;
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/// defmt::info!("measurements: {}", measurements);
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/// ```
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pub async fn read(
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&mut self,
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rx_dma: &mut impl RxDma<T>,
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sequence: impl ExactSizeIterator<Item = (&mut AnyAdcChannel<T>, SampleTime)>,
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@ -23,7 +23,7 @@ async fn main(_spawner: Spawner) {
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// Startup delay can be combined to the maximum of either
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delay.delay_us(Temperature::start_time_us().max(VrefInt::start_time_us()));
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let vrefint_sample = adc.read(&mut vrefint);
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let vrefint_sample = adc.blocking_read(&mut vrefint);
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let convert_to_millivolts = |sample| {
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// From http://www.st.com/resource/en/datasheet/DM00071990.pdf
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@ -50,16 +50,16 @@ async fn main(_spawner: Spawner) {
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loop {
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// Read pin
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let v = adc.read(&mut pin);
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let v = adc.blocking_read(&mut pin);
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info!("PC1: {} ({} mV)", v, convert_to_millivolts(v));
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// Read internal temperature
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let v = adc.read(&mut temp);
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let v = adc.blocking_read(&mut temp);
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let celcius = convert_to_celcius(v);
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info!("Internal temp: {} ({} C)", v, celcius);
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// Read internal voltage reference
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let v = adc.read(&mut vrefint);
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let v = adc.blocking_read(&mut vrefint);
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info!("VrefInt: {}", v);
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Timer::after_millis(100).await;
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@ -44,7 +44,7 @@ async fn adc_task(mut p: Peripherals) {
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let _ = adc.start();
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let _ = adc2.start();
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loop {
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match adc.read_exact(&mut buffer1).await {
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match adc.read(&mut buffer1).await {
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Ok(_data) => {
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let toc = Instant::now();
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info!(
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@ -62,7 +62,7 @@ async fn adc_task(mut p: Peripherals) {
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}
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}
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match adc2.read_exact(&mut buffer2).await {
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match adc2.read(&mut buffer2).await {
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Ok(_data) => {
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let toc = Instant::now();
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info!(
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@ -16,7 +16,7 @@ async fn main(_spawner: Spawner) {
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let mut pin = p.PA3;
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let mut vrefint = adc.enable_vrefint();
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let vrefint_sample = adc.read(&mut vrefint);
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let vrefint_sample = adc.blocking_read(&mut vrefint);
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let convert_to_millivolts = |sample| {
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// From http://www.st.com/resource/en/datasheet/DM00273119.pdf
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// 6.3.27 Reference voltage
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@ -26,7 +26,7 @@ async fn main(_spawner: Spawner) {
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};
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loop {
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let v = adc.read(&mut pin);
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let v = adc.blocking_read(&mut pin);
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info!("--> {} - {} mV", v, convert_to_millivolts(v));
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Timer::after_millis(100).await;
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}
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@ -17,7 +17,7 @@ async fn main(_spawner: Spawner) {
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let mut pin = p.PA1;
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let mut vrefint = adc.enable_vrefint();
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let vrefint_sample = adc.read(&mut vrefint);
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let vrefint_sample = adc.blocking_read(&mut vrefint);
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let convert_to_millivolts = |sample| {
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// From https://www.st.com/resource/en/datasheet/stm32g031g8.pdf
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// 6.3.3 Embedded internal reference voltage
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@ -27,7 +27,7 @@ async fn main(_spawner: Spawner) {
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};
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loop {
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let v = adc.read(&mut pin);
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let v = adc.blocking_read(&mut pin);
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info!("--> {} - {} mV", v, convert_to_millivolts(v));
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Timer::after_millis(100).await;
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}
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@ -24,7 +24,7 @@ async fn main(_spawner: Spawner) {
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let mut pa0 = p.PA0.degrade_adc();
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loop {
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adc.read_async(
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adc.read(
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&mut dma,
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[
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(&mut vrefint_channel, SampleTime::CYCLES160_5),
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@ -36,7 +36,7 @@ async fn main(_spawner: Spawner) {
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adc.oversampling_enable(true);
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loop {
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let v = adc.read(&mut pin);
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let v = adc.blocking_read(&mut pin);
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info!("--> {} ", v); //max 65520 = 0xFFF0
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Timer::after_millis(100).await;
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}
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@ -32,7 +32,7 @@ async fn main(_spawner: Spawner) {
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adc.set_sample_time(SampleTime::CYCLES24_5);
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loop {
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let measured = adc.read(&mut p.PA7);
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let measured = adc.blocking_read(&mut p.PA7);
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info!("measured: {}", measured);
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Timer::after_millis(500).await;
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}
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@ -51,9 +51,9 @@ async fn main(_spawner: Spawner) {
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let mut vrefint_channel = adc.enable_vrefint();
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loop {
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let vrefint = adc.read(&mut vrefint_channel);
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let vrefint = adc.blocking_read(&mut vrefint_channel);
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info!("vrefint: {}", vrefint);
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let measured = adc.read(&mut p.PC0);
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let measured = adc.blocking_read(&mut p.PC0);
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info!("measured: {}", measured);
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Timer::after_millis(500).await;
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}
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@ -56,7 +56,7 @@ async fn main(_spawner: Spawner) {
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let mut pc0 = p.PC0.degrade_adc();
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loop {
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adc.read_async(
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adc.read(
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&mut dma,
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[
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(&mut vrefint_channel, SampleTime::CYCLES387_5),
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@ -23,7 +23,7 @@ fn main() -> ! {
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let mut channel = p.PC0;
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loop {
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let v = adc.read(&mut channel);
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let v = adc.blocking_read(&mut channel);
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info!("--> {}", v);
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}
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}
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@ -23,7 +23,7 @@ fn main() -> ! {
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let mut channel = p.PC0;
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loop {
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let v = adc.read(&mut channel);
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let v = adc.blocking_read(&mut channel);
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info!("--> {}", v);
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embassy_time::block_for(Duration::from_millis(200));
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}
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@ -38,7 +38,7 @@ async fn main(_spawner: Spawner) {
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dac.set(Value::Bit8(0));
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// Now wait a little to obtain a stable value
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Timer::after_millis(30).await;
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let offset = adc.read(&mut adc_pin);
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let offset = adc.blocking_read(&mut adc_pin);
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for v in 0..=255 {
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// First set the DAC output value
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@ -49,7 +49,7 @@ async fn main(_spawner: Spawner) {
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Timer::after_millis(30).await;
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// Need to steal the peripherals here because PA4 is obviously in use already
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let measured = adc.read(&mut unsafe { embassy_stm32::Peripherals::steal() }.PA4);
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let measured = adc.blocking_read(&mut unsafe { embassy_stm32::Peripherals::steal() }.PA4);
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// Calibrate and normalize the measurement to get close to the dac_output_val
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let measured_normalized = ((measured as i32 - offset as i32) / normalization_factor) as i16;
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