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4719dcc430
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e148a1ec5e
Author | SHA1 | Date | |
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e148a1ec5e | ||
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f45b9e5748 | ||
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810a3677de | ||
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71fabde385 |
@ -3,148 +3,149 @@ extern crate ether_dream;
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use ether_dream::dac;
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fn main() {
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println!("Listening for an Ether Dream DAC...");
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println!("Listening for an Ether Dream DAC...");
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let (dac_broadcast, source_addr) = ether_dream::recv_dac_broadcasts()
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.expect("failed to bind to UDP socket")
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.filter_map(Result::ok)
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.next()
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.unwrap();
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let mac_address = dac::MacAddress(dac_broadcast.mac_address);
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let (dac_broadcast, source_addr) = ether_dream::recv_dac_broadcasts()
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.expect("failed to bind to UDP socket")
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.filter_map(Result::ok)
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.next()
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.unwrap();
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let mac_address = dac::MacAddress(dac_broadcast.mac_address);
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println!(
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"Discovered DAC \"{}\" at \"{}\"! Connecting...",
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mac_address, source_addr
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);
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println!(
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"Discovered DAC \"{}\" at \"{}\"! Connecting...",
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mac_address, source_addr
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);
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// Establish the TCP connection.
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let mut stream = dac::stream::connect(&dac_broadcast, source_addr.ip().clone()).unwrap();
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// Establish the TCP connection.
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let mut stream = dac::stream::connect(&dac_broadcast, source_addr.ip().clone()).unwrap();
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// If we want to create an animation (in our case a moving sine wave) we need a frame rate.
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let frames_per_second = 60.0;
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// Lets use the DAC at an eighth the maximum scan rate.
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let points_per_second = stream.dac().max_point_rate / 32;
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// Determine the number of points per frame given our target frame and point rates.
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let points_per_frame = (points_per_second as f32 / frames_per_second) as u16;
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// If we want to create an animation (in our case a moving sine wave) we need a frame rate.
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let frames_per_second = 60.0;
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// Lets use the DAC at an eighth the maximum scan rate.
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let points_per_second = stream.dac().max_point_rate / 32;
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// Determine the number of points per frame given our target frame and point rates.
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let points_per_frame = (points_per_second as f32 / frames_per_second) as u16;
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println!(
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"Preparing for playback:\n\tframe_hz: {}\n\tpoint_hz: {}\n\tpoints_per_frame: {}\n",
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frames_per_second, points_per_second, points_per_frame
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);
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println!(
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"Preparing for playback:\n\tframe_hz: {}\n\tpoint_hz: {}\n\tpoints_per_frame: {}\n",
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frames_per_second, points_per_second, points_per_frame
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);
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// Prepare the DAC's playback engine and await the repsonse.
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stream
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.queue_commands()
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.prepare_stream()
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.submit()
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.err()
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.map(|err| {
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eprintln!(
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"err occurred when submitting PREPARE_STREAM \
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// Prepare the DAC's playback engine and await the repsonse.
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stream
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.queue_commands()
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.prepare_stream()
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.submit()
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.err()
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.map(|err| {
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eprintln!(
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"err occurred when submitting PREPARE_STREAM \
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command and listening for response: {}",
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err
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);
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});
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err
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);
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});
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println!("Beginning playback!");
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println!("Beginning playback!");
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// The sine wave used to generate points.
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let mut sine_wave = SineWave {
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point: 0,
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points_per_frame,
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frames_per_second,
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};
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// The sine wave used to generate points.
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let mut sine_wave = SineWave {
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point: 0,
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points_per_frame,
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frames_per_second,
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};
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// Queue the initial frame and tell the DAC to begin producing output.
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let n_points = points_to_generate(stream.dac());
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stream
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.queue_commands()
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.data(sine_wave.by_ref().take(n_points))
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.begin(0, points_per_second)
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.submit()
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.err()
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.map(|err| {
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eprintln!(
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"err occurred when submitting initial DATA and BEGIN \
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// Queue the initial frame and tell the DAC to begin producing output.
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let n_points = points_to_generate(stream.dac());
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stream
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.queue_commands()
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.data(sine_wave.by_ref().take(n_points))
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.begin(0, points_per_second)
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.submit()
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.err()
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.map(|err| {
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eprintln!(
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"err occurred when submitting initial DATA and BEGIN \
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commands and listening for response: {}",
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err
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);
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});
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err
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);
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});
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eprintln!("Stream dac{:?}", stream.dac());
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// Loop and continue to send points forever.
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loop {
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// Determine how many points the DAC can currently receive.
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let n_points = points_to_generate(stream.dac());
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if let Err(err) = stream
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.queue_commands()
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.data(sine_wave.by_ref().take(n_points))
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.submit()
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{
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eprintln!(
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"err occurred when submitting DATA command and listening \
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// Loop and continue to send points forever.
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loop {
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// Determine how many points the DAC can currently receive.
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let n_points = points_to_generate(stream.dac());
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if let Err(err) = stream
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.queue_commands()
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.data(sine_wave.by_ref().take(n_points))
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.submit()
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{
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eprintln!(
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"err occurred when submitting DATA command and listening \
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for response: {}",
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err
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);
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break;
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}
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}
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err
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);
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break;
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}
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}
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// Tell the DAC to stop producing output and return to idle. Wait for the response.
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//
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// Note that the DAC is commanded to stop on `Drop` if this is not called and any errors
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// produced are ignored.
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stream
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.queue_commands()
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.stop()
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.submit()
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.expect("err occurred when submitting STOP command and listening for response");
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// Tell the DAC to stop producing output and return to idle. Wait for the response.
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//
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// Note that the DAC is commanded to stop on `Drop` if this is not called and any errors
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// produced are ignored.
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stream
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.queue_commands()
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.stop()
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.submit()
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.expect("err occurred when submitting STOP command and listening for response");
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}
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// Determine the number of points needed to fill the DAC.
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fn points_to_generate(dac: ðer_dream::dac::Dac) -> usize {
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dac.buffer_capacity as usize - 1 - dac.status.buffer_fullness as usize
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dac.buffer_capacity as usize - 1 - dac.status.buffer_fullness as usize
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}
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// An iterator that endlessly generates a sine wave of DAC points.
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//
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// The sine wave oscillates at a rate of once per second.
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struct SineWave {
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point: u32,
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points_per_frame: u16,
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frames_per_second: f32,
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point: u32,
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points_per_frame: u16,
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frames_per_second: f32,
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}
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impl Iterator for SineWave {
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type Item = ether_dream::protocol::DacPoint;
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fn next(&mut self) -> Option<Self::Item> {
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let coloured_points_per_frame = self.points_per_frame - 1;
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let i = (self.point % self.points_per_frame as u32) as u16;
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let hz = 1.0;
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let fract = i as f32 / coloured_points_per_frame as f32;
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let phase = (self.point as f32 / coloured_points_per_frame as f32) / self.frames_per_second;
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let amp = (hz * (fract + phase) * 2.0 * std::f32::consts::PI).sin();
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let (r, g, b) = match i {
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i if i == coloured_points_per_frame || i < 13 => (0, 0, 0),
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_ => (std::u16::MAX, std::u16::MAX, std::u16::MAX),
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};
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let x_min = std::i16::MIN;
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let x_max = std::i16::MAX;
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let x = (x_min as f32 + fract * (x_max as f32 - x_min as f32)) as i16;
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let y = (amp * x_max as f32) as i16;
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let control = 0;
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let (u1, u2) = (0, 0);
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let p = ether_dream::protocol::DacPoint {
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control,
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x,
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y,
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i,
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r,
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g,
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b,
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u1,
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u2,
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};
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self.point += 1;
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Some(p)
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}
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type Item = ether_dream::protocol::DacPoint;
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fn next(&mut self) -> Option<Self::Item> {
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let coloured_points_per_frame = self.points_per_frame - 1;
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let i = (self.point % self.points_per_frame as u32) as u16;
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let hz = 1.0;
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let fract = i as f32 / coloured_points_per_frame as f32;
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let phase = (self.point as f32 / coloured_points_per_frame as f32) / self.frames_per_second;
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let amp = (hz * (fract + phase) * 2.0 * std::f32::consts::PI).sin();
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let (r, g, b) = match i {
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i if i == coloured_points_per_frame || i < 13 => (0, 0, 0),
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_ => (std::u16::MAX, std::u16::MAX, std::u16::MAX),
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};
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let x_min = std::i16::MIN;
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let x_max = std::i16::MAX;
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let x = (x_min as f32 + fract * (x_max as f32 - x_min as f32)) as i16;
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let y = (amp * x_max as f32) as i16;
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let control = 0;
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let (u1, u2) = (0, 0);
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let p = ether_dream::protocol::DacPoint {
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control,
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x,
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y,
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i,
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r,
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g,
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b,
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u1,
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u2,
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};
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self.point += 1;
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Some(p)
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}
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}
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@ -22,7 +22,7 @@ fn do_something() -> redis::RedisResult<()> {
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let _ = con.set("/EDH/0", "[[1.0, 0.0, 0.0],\n [ 0.0, 1.0, 0.0],\n [ 0.0, 0.0, 1.0]]")?;
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let _ = con.set("/kpps/0", "5000")?;
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let _ = con.set("/intensity/0", "255")?;
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let _ = con.set("/pl/0/0", "[(-300, 300, 0), (-300, -300, 65280), (300, -300, 65280), (300, 300, 65280), (-300, 300, 65280)]")?;
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let _ = con.set("/pl/0/0", "[(1000, 2000, 0), (1000, 1000, 65535), (2000, 1000, 65535), (2000, 2000, 65535), (1000, 2000, 65535)]")?;
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Ok(())
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}
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@ -9,7 +9,7 @@ use crate::conf::EtherDreamConf;
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use crate::device::{Device, Status, PlaybackState};
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use crate::errors::{LJError, LJResult};
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use crate::point::{Color, Point};
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use ether_dream::protocol::{DacBroadcast, DacPoint, DacResponse};
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use ether_dream::protocol::{DacBroadcast, DacResponse};
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use log::{debug, info, warn};
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#[warn(dead_code)]
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@ -71,6 +71,7 @@ impl EtherdreamDevice {
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Err(Box::new(LJError::EtherdreamConnectError(err)))
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}
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Ok((dac, source_addr)) => {
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info!("Trying to open TCP stream...");
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let stream = EtherdreamDevice::get_tcp_stream(&dac, &source_addr)?;
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info!("Finished configuring DAC and TCP stream.");
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Ok((dac, source_addr, stream))
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@ -87,18 +88,29 @@ impl EtherdreamDevice {
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Err(err) => warn!("err occurred when submitting PREPARE_STREAM command and listening for response: {}",err),
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Ok(_) => info!("Prepared Stream.")
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}
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let begin_list = vec![
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DacPoint { control: 0, x: 0, y: 0, i: 255, r: 0, g: 0, b: 0, u1: 0, u2: 0 },
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];
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// If we want to create an animation (in our case a moving sine wave) we need a frame rate.
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let frames_per_second = 60.0;
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// Lets use the DAC at an eighth the maximum scan rate.
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let points_per_second = stream.dac().max_point_rate / 32;
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// Determine the number of points per frame given our target frame and point rates.
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let points_per_frame = (points_per_second as f32 / frames_per_second) as u16;
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let mut sine_wave = SineWave {
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point: 0,
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points_per_frame,
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frames_per_second,
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};
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match stream
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.queue_commands()
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.data(begin_list.into_iter().take(1 as usize))
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.data(sine_wave.by_ref().take(400))
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// .data(begin_list.into_iter().take(400 as usize))
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.begin(0, points_per_second)
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.submit() {
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Err(err) => warn!("err occurred when submitting first data: {}",err),
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Ok(_) => info!("Sent first data to Etherdream.")
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}
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Ok(stream)
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}
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@ -130,9 +142,9 @@ impl Device for EtherdreamDevice {
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capacity: self.points_capacity(),
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lack: self.dac_response.to_string(),
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};
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// info!("Dac Status: {:?} ", status );
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// info!("Etherdream Dac {:?} ", self.dac );
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// info!("Stream dac{:?}", self.stream.dac());
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// debug!("Dac Status: {:?} ", status );
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// debug!("Etherdream Dac {:?} ", self.dac );
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debug!("Stream dac{:?}", self.stream.dac());
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status
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}
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@ -143,14 +155,17 @@ impl Device for EtherdreamDevice {
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let n_points = self.points_capacity();
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// let n_points = &line.len();
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debug!("Etherdream::device draw Generating {:?} points", n_points);
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match self.stream
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.queue_commands()
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.data(
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line.into_iter()
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.map(|point| point.into())
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// .take(line.len() as usize)
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.take(n_points as usize)
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)
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// .data(sine_wave.by_ref().take(n_points as usize))
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.submit() {
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Err(err) => {
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// We should account for
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@ -170,7 +185,6 @@ impl Device for EtherdreamDevice {
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err.response.response
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}
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};
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}
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Ok(_) => {
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self.dac_response = DacResponse::ACK;
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@ -220,3 +234,48 @@ impl Device for EtherdreamDevice {
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]
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}
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}
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// An iterator that endlessly generates a sine wave of DAC points.
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//
|
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// The sine wave oscillates at a rate of once per second.
|
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struct SineWave {
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point: u32,
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points_per_frame: u16,
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frames_per_second: f32,
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}
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impl Iterator for SineWave {
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type Item = ether_dream::protocol::DacPoint;
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fn next(&mut self) -> Option<Self::Item> {
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let coloured_points_per_frame = self.points_per_frame - 1;
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let i = (self.point % self.points_per_frame as u32) as u16;
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let hz = 1.0;
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let fract = i as f32 / coloured_points_per_frame as f32;
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let phase = (self.point as f32 / coloured_points_per_frame as f32) / self.frames_per_second;
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let amp = (hz * (fract + phase) * 2.0 * std::f32::consts::PI).sin();
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let (r, g, b) = match i {
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i if i == coloured_points_per_frame || i < 13 => (0, 0, 0),
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_ => (std::u16::MAX, std::u16::MAX, std::u16::MAX),
|
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};
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let x_min = std::i16::MIN;
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let x_max = std::i16::MAX;
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let x = (x_min as f32 + fract * (x_max as f32 - x_min as f32)) as i16;
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let y = (amp * x_max as f32) as i16;
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let control = 0;
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let (u1, u2) = (0, 0);
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let p = ether_dream::protocol::DacPoint {
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control,
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x,
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y,
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i,
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r,
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g,
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b,
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u1,
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u2,
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};
|
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debug!("{:?}",p);
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self.point += 1;
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Some(p)
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}
|
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}
|
@ -1,3 +1,4 @@
|
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use std::time::SystemTime;
|
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///
|
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/// Configure udev:
|
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/// https://github.com/Grix/helios_dac/blob/master/docs/udev_rules_for_linux.md
|
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@ -14,7 +15,7 @@ use crate::conf::HeliosConf;
|
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use crate::device::{Device, Status, PlaybackState};
|
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use crate::errors::{LJError, LJResult};
|
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use crate::point::{Color, Point};
|
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use chrono::Utc;
|
||||
use chrono::{DateTime, Utc};
|
||||
|
||||
pub struct HeliosDevice {
|
||||
pub conf: HeliosConf,
|
||||
@ -34,13 +35,17 @@ impl HeliosDevice {
|
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return Err(Box::new(LJError::HeliosDeviceMissing));
|
||||
};
|
||||
let dac = device.open()?;
|
||||
let now = SystemTime::now();
|
||||
let now: DateTime<Utc> = now.into();
|
||||
let last_traced_at = now.to_rfc3339();
|
||||
|
||||
Ok(Self {
|
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conf: (*conf).clone(),
|
||||
dac,
|
||||
sent_points: 0,
|
||||
state: PlaybackState::PREPARE,
|
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lack: "".to_string(),
|
||||
last_traced_at: "1985-04-12T23:20:50.52Z".to_string(),
|
||||
last_traced_at,
|
||||
})
|
||||
}
|
||||
}
|
||||
|
21
src/point.rs
21
src/point.rs
@ -1,15 +1,5 @@
|
||||
use ether_dream::protocol::DacPoint;
|
||||
|
||||
fn clamp(val: f32, min: f32, max: f32) -> f32 {
|
||||
if val < min {
|
||||
return min;
|
||||
}
|
||||
if val > max {
|
||||
return max;
|
||||
}
|
||||
val
|
||||
}
|
||||
|
||||
#[derive(Debug, Clone, Copy, Default, PartialEq)]
|
||||
pub struct Point {
|
||||
pub x: f32,
|
||||
@ -55,21 +45,20 @@ impl From<Point> for helios_dac::Point {
|
||||
}
|
||||
|
||||
impl From<Point> for DacPoint {
|
||||
|
||||
fn from(pt: Point) -> DacPoint {
|
||||
let control = 0;
|
||||
let (u1, u2) = (0, 0);
|
||||
let i = 255;
|
||||
let x = clamp(pt.x, -32000 as f32, 32000 as f32);
|
||||
let y = clamp(pt.y, -32000 as f32, 32000 as f32);
|
||||
let x = pt.x.clamp(-32000.0, 32000.0);
|
||||
let y = pt.y.clamp(-32000.0, 32000.0);
|
||||
DacPoint {
|
||||
control,
|
||||
x: x as i16,
|
||||
y: y as i16,
|
||||
i,
|
||||
r: pt.color.r.into(),
|
||||
g: pt.color.g.into(),
|
||||
b: pt.color.b.into(),
|
||||
r: (pt.color.r as u16) * 255,
|
||||
g: (pt.color.g as u16) * 255,
|
||||
b: (pt.color.b as u16) * 255,
|
||||
u1,
|
||||
u2,
|
||||
}
|
||||
|
@ -17,6 +17,7 @@ pub enum Order {
|
||||
Intensity,
|
||||
Kpps,
|
||||
ColorBalance,
|
||||
PowerOff
|
||||
}
|
||||
|
||||
impl TryFrom<u8> for Order {
|
||||
@ -39,13 +40,14 @@ impl TryFrom<u8> for Order {
|
||||
6 => Intensity,
|
||||
7 => Kpps,
|
||||
8 => ColorBalance,
|
||||
9 => PowerOff,
|
||||
_ => unreachable!()
|
||||
})
|
||||
}
|
||||
}
|
||||
|
||||
pub type Line = Vec<(f32, f32, u32)>;
|
||||
pub type Resampler = Vec<(f32,f32)>;
|
||||
pub type Resampler = Vec<Vec<(f32,f32)>>;
|
||||
|
||||
pub struct RedisCtrl {
|
||||
pub client: Client,
|
||||
|
Loading…
Reference in New Issue
Block a user