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2 Commits

Author SHA1 Message Date
alban
89d38f51ec fix: etherdream: use sleep instead of ping 2024-08-14 13:16:18 +02:00
alban
650a3ed521 wip: dirty state for debugging etherdream 2023-08-05 19:11:33 +02:00
10 changed files with 196 additions and 196 deletions

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@ -22,10 +22,10 @@ redis_url = "redis://127.0.0.1:6379/"
# [dac.etherdream]
# ip = "192.168.1.68"
[[transformers]]
[transformers.translate]
x = 2000
y = 2000
#[[transformers]]
#[transformers.translate]
#x = 20
#y = 20
[[transformers]]
[transformers.replicate]

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@ -23,7 +23,7 @@ fn main() {
// If we want to create an animation (in our case a moving sine wave) we need a frame rate.
let frames_per_second = 60.0;
// Lets use the DAC at an eighth the maximum scan rate.
let points_per_second = stream.dac().max_point_rate / 32;
let points_per_second = 20_000;
// Determine the number of points per frame given our target frame and point rates.
let points_per_frame = (points_per_second as f32 / frames_per_second) as u16;
@ -70,7 +70,6 @@ fn main() {
err
);
});
eprintln!("Stream dac{:?}", stream.dac());
// Loop and continue to send points forever.
loop {
@ -129,7 +128,7 @@ impl Iterator for SineWave {
_ => (std::u16::MAX, std::u16::MAX, std::u16::MAX),
};
let x_min = std::i16::MIN;
let x_max = std::i8::MAX as i16;
let x_max = std::i16::MAX;
let x = (x_min as f32 + fract * (x_max as f32 - x_min as f32)) as i16;
let y = (amp * x_max as f32) as i16;
let control = 0;

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@ -78,7 +78,7 @@ impl Conf {
TransformConf::Intensity(r) => Box::new(*r),
TransformConf::Replicate(r) => Box::new(*r),
TransformConf::Rotate(r) => Box::new(*r),
TransformConf::Translate(t) => Box::new(*t),
TransformConf::Translate(r) => Box::new(*r),
};
v.push(t);
}

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@ -1,5 +1,5 @@
#[warn(unused_imports)]
use log::{ debug, info, warn};
use log::{debug, info, warn};
use std::net::SocketAddr;
use std::thread::sleep;
@ -14,6 +14,7 @@ use crate::device::{Device, Status, PlaybackState};
use crate::errors::{LJError, LJResult};
use crate::point::{Color, Point};
use ether_dream::protocol::{DacBroadcast, DacResponse};
use crate::device::PlaybackState::PLAYING;
#[warn(dead_code)]
@ -21,18 +22,6 @@ pub struct EtherdreamDevice {
pub conf: EtherDreamConf,
dac: DacBroadcast,
stream: Stream,
// "a": ACK "F": Full "I": invalid. 64 or 35 for no connection.
// /// The previous command was accepted.
// pub const ACK: u8 = 0x61;
// /// The write command could not be performed because there was not enough buffer space when it
// /// was received.
// pub const NAK_FULL: u8 = 0x46;
// /// The command contained an invalid `command` byte or parameters.
// pub const NAK_INVALID: u8 = 0x49;
// /// An emergency-stop condition still exists.
// pub const NAK_STOP_CONDITION: u8 = 0x21;
// }
dac_response: u8,
}
@ -52,7 +41,7 @@ impl EtherdreamDevice {
dac_broadcast.set_timeout(Some(time::Duration::new(10, 0)))?;
info!("Attempting to get DAC broadcast...");
let broadcast = dac_broadcast
.take(3)
.take(5)
.filter_map(|result| {
match result {
Err(err) => {
@ -62,15 +51,8 @@ impl EtherdreamDevice {
}
Ok((dac, source_addr)) => {
info!("Valid broadcast, source_addr: {}", source_addr);
if source_addr.is_ipv6() {
warn!("Broadcast ignored: ipv6 address.");
return None;
}
let src_ip = source_addr.ip().to_string();
if &src_ip != ip {
warn!("Broadcast ignored: expected {ip}, got: {src_ip} ");
return None;
}
if source_addr.is_ipv6() { return None; }
if &source_addr.ip().to_string() != ip { return None; }
Some(Ok((dac, source_addr)))
}
}
@ -92,6 +74,20 @@ impl EtherdreamDevice {
fn get_tcp_stream(dac: &DacBroadcast, source_address: &SocketAddr) -> LJResult<Stream> {
let mut stream = connect(dac, source_address.ip())?;
debug!("Stream dac BEFORE PREPARE {:?}", stream.dac());
debug!("Playback State BEFORE PREPARE {:?}, {:?}", stream.dac().dac.status.playback, Playback::Playing );
if stream.dac().dac.status.playback == Playback::Playing {
warn!("DAC was in playback PLAYING, attempting to stop");
match stream
.queue_commands()
.stop()
.submit() {
Err(err) => warn!("err occurred when submitting STOP command: {}",err),
Ok(_) => info!("Prepared Stream.")
}
}
if stream.dac().dac.status.playback != Playback::Prepared {
warn!("DAC was not in playback state PREPARED, attempting to prepare");
match stream
.queue_commands()
.prepare_stream()
@ -99,10 +95,13 @@ impl EtherdreamDevice {
Err(err) => warn!("err occurred when submitting PREPARE_STREAM command and listening for response: {}",err),
Ok(_) => info!("Prepared Stream.")
}
}
// If we want to create an animation (in our case a moving sine wave) we need a frame rate.
let frames_per_second = 60.0;
// Lets use the DAC at an eighth the maximum scan rate.
let points_per_second = stream.dac().max_point_rate / 32;
let points_per_second = 20_000;
// let points_per_second = 30_000;
debug!("points per second {:?}", points_per_second);
// Determine the number of points per frame given our target frame and point rates.
let points_per_frame = (points_per_second as f32 / frames_per_second) as u16;
@ -111,6 +110,7 @@ impl EtherdreamDevice {
points_per_frame,
frames_per_second,
};
debug!("Stream dac BEFORE BEGIN {:?}", stream.dac());
match stream
.queue_commands()
@ -129,15 +129,15 @@ impl EtherdreamDevice {
/***
Determine the number of points needed to fill the DAC.
***/
// Fixme thread 'main' panicked at 'attempt to subtract with overflow', src/device/etherdream.rs:144:24
let n_points = self.dac.buffer_capacity as usize - self.stream.dac().dac.status.buffer_fullness as usize - 1;
let cap = self.dac.buffer_capacity as usize;
let fullness = self.stream.dac().dac.status.buffer_fullness as usize;
// Sometimes we had thread 'main' panicked at 'attempt to subtract with overflow', src/device/etherdream.rs:144:24
let n_points = if cap > fullness { cap - fullness } else { 0 };
n_points
}
fn ping(&mut self) -> LJResult<()> {
Ok(self.stream.queue_commands().ping().submit()?)
}
}
@ -151,6 +151,9 @@ impl Device for EtherdreamDevice {
let now = SystemTime::now();
let now: DateTime<Utc> = now.into();
let now = now.to_rfc3339();
// debug!("Dac Status: {:?} ", status );
// debug!("Etherdream Dac {:?} ", self.dac );
debug!("Stream dac{:?}", self.stream.dac());
Status {
last_traced_at: now,
@ -159,9 +162,6 @@ impl Device for EtherdreamDevice {
capacity: self.points_capacity(),
lack: self.dac_response.to_string(),
}
// debug!("Dac Status: {:?} ", status );
// debug!("Etherdream Dac {:?} ", self.dac );
// debug!("Stream dac{:?}", self.stream.dac());
// status
}
@ -169,28 +169,30 @@ impl Device for EtherdreamDevice {
line: Vec<Point>,
_speed: u32,
) -> LJResult<()> {
let chunk_size = 64;
let chunk_size = 512;
let points_iter = line.into_iter();
for chunk in points_iter.as_slice().chunks(chunk_size){
for chunk in points_iter.as_slice().chunks(chunk_size) {
debug!("New chunk length: {:?}", chunk.len());
loop {
let capacity = self.points_capacity();
if chunk.len() > capacity {
debug!("Sleep, capacity : {:?}", capacity);
debug!("capacity : {:?}", capacity);
loop {
if chunk.len() > capacity as usize {
debug!("Sleep");
// Sleep for 1/100th of a sec
sleep(Duration::new( 0, 10000000));
self.ping()?;
sleep(Duration::new(0, 100_000_000));
break;
// self.ping();
} else {
break;
}
}
debug!("drawing");
debug!("Drawing");
match self.stream
.queue_commands()
.data(
chunk.iter()
chunk.into_iter()
.map(|point| (*point).into())
.take(chunk_size)
.take(chunk_size as usize)
)
.submit() {
Err(err) => {
@ -223,6 +225,7 @@ impl Device for EtherdreamDevice {
fn stop(&mut self) -> LJResult<()> {
info!("Stopping Etherdream device...");
info!("Stream dac{:?}", self.stream.dac());
match self.stream
.queue_commands()
.stop()
@ -240,8 +243,8 @@ impl Device for EtherdreamDevice {
}
fn grid(&mut self) -> Vec<Point> {
let dim_mid = 16000.0;
let dim_max = 32000.0;
let dim_mid = 16000 as f32;
let dim_max = 32000 as f32;
let col_min = Color { r: 0, g: 0, b: 0 };
let col_max = Color { r: 255, g: 255, b: 255 };
@ -282,10 +285,10 @@ impl Iterator for SineWave {
let amp = (hz * (fract + phase) * 2.0 * std::f32::consts::PI).sin();
let (r, g, b) = match i {
i if i == coloured_points_per_frame || i < 13 => (0, 0, 0),
_ => (u16::MAX, u16::MAX, u16::MAX),
_ => (std::u16::MAX, std::u16::MAX, std::u16::MAX),
};
let x_min = i16::MIN;
let x_max = i16::MAX;
let x_min = std::i16::MIN;
let x_max = std::i16::MAX;
let x = (x_min as f32 + fract * (x_max as f32 - x_min as f32)) as i16;
let y = (amp * x_max as f32) as i16;
let control = 0;

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@ -85,8 +85,8 @@ impl Device for HeliosDevice {
fn grid(&mut self) -> Vec<Point> {
let dim_min = 0 as f32;
let dim_mid = 2047.0;
let dim_max = 4095.0;
let dim_mid = 2047 as f32;
let dim_max = 4095 as f32;
let col_min = Color { r: 0, g: 0, b: 0 };
let col_max = Color { r: 255, g: 255, b: 255 };

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@ -76,7 +76,7 @@ fn run_all() -> LJResult<()> {
// Dispatch based on redis requests
while running.load(Ordering::SeqCst) {
rs.set_status(tracer.status())?;
framerate_handler.handle_time()?;
// let _ = framerate_handler.handle_time()?;
let order = rs.get_order(config.laser_id)?;
match order {
Order::Draw | Order::Black | Order::Grid => {

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@ -15,6 +15,7 @@ pub struct Color {
pub g: u8,
pub b: u8,
}
impl Mul<u8> for Color {
type Output = Self;

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@ -98,10 +98,10 @@ impl RedisCtrl {
pub fn init_world_state(&mut self) -> LJResult<WorldState> {
Ok(WorldState {
client_key: self.get_client_key()?,
edh: self.get_edh()?,
kpps: self.get_int("kpps")?.try_into()?,
intensity: self.get_int("intensity")?.try_into()?,
client_key: self.get_client_key().unwrap(),
edh: self.get_edh().unwrap(),
kpps: self.get_int("kpps").unwrap().try_into().unwrap(),
intensity: self.get_int("intensity").unwrap().try_into().unwrap(),
..WorldState::default()
})
}

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@ -7,16 +7,15 @@ use serde::{Serialize, Deserialize};
/// Converts helios Geometry to Helios
#[allow(dead_code)]
#[derive(Serialize, Deserialize, Debug, Clone, Copy)]
pub struct HeliosToEtherdream {
}
pub struct HeliosToEtherdream {}
impl Transformers for HeliosToEtherdream {
fn apply(&self, point_list: &[Point], _ws: &WorldState) -> Vec<Point> {
// debug!("list helios {:?}", point_list);
let out = point_list.iter().map(|pt| {
Point {
x: 8.0 * (pt.x - 2047.0),
y: 8.0 * (pt.y - 2047.0),
x: 50.0 * (320.0 - pt.x),
y: 40.0 * (240.0 - pt.y),
..*pt
}
}).collect();

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@ -8,20 +8,18 @@ use serde::{Serialize, Deserialize};
/// Converts helios Geometry to Helios
#[allow(dead_code)]
#[derive(Serialize, Deserialize, Debug, Clone, Copy)]
pub struct Intensity {
}
pub struct Intensity {}
impl Transformers for Intensity {
fn apply(&self, point_list: &[Point], ws: &WorldState) -> Vec<Point> {
// debug!("list helios {:?}", point_list);
let out = point_list.iter().map(|pt| {
Point {
x: pt.x,
y: pt.y,
color: pt.color * ws.intensity
color: pt.color * ws.intensity,
..*pt
}
}).collect();
debug!("list intensity {:?}", out);
// debug!("list intensity {:?}", out);
out
}
}