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lennlouisgeek
2026-03-30 02:59:56 +08:00
commit eec9927ae6
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6
src-tauri/src/serial_core/codec.rs Normal file
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use crate::serial_core::error::CodecError;
use std::time::Instant;
pub trait Codec<F> {
fn decode(&mut self, input: &[u8], session_started_at: Instant) -> Result<Vec<F>, CodecError>;
fn encode(&self, frame: &F) -> Result<Vec<u8>, CodecError>;
}

4
src-tauri/src/serial_core/codecs/mod.rs Normal file
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use crate::serial_core::{frame::TestFrame, record::Recording};
pub mod test;
pub type TestRecording = Recording<TestFrame>;

258
src-tauri/src/serial_core/codecs/test.rs Normal file
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use std::io::Read;
use std::time::Instant;
use crate::serial_core::frame::{crc8, usize_to_u16_be_bytes, FrameHandler};
use crate::serial_core::{codec::Codec, error::CodecError, frame::TestFrame};
use anyhow::anyhow;
use async_trait::async_trait;
use chrono::Local;
use csv::StringRecord;
use crate::serial_core::record::{write_csv, CsvExporter, CsvImporter, RecordedFrame, Recording};
pub struct TestCodec {
buffer: Vec<u8>,
}
pub struct TestHandler;
impl TestCodec {
pub fn new() -> TestCodec {
Self { buffer: Vec::new() }
}
}
impl Codec<TestFrame> for TestCodec {
fn decode(&mut self, input: &[u8], session_started_at: Instant) -> Result<Vec<TestFrame>, CodecError> {
self.buffer.extend_from_slice(input);
let mut frames = Vec::new();
loop {
if self.buffer.len() < 6 {
break;
}
let header_pos = self.buffer.windows(2).position(|w| w == [0xAA, 0x55]);
let Some(pos) = header_pos else {
self.buffer.clear();
break;
};
if pos > 0 {
self.buffer.drain(0..pos);
}
if self.buffer.len() < 6 {
break;
}
let cmd = self.buffer[2];
let length_bytes = [self.buffer[3], self.buffer[4]];
let length = u16::from_be_bytes(length_bytes) as usize;
let frame_length = (length + 6) as usize;
if self.buffer.len() < frame_length {
break;
}
let payload = self.buffer[5..5 + length].to_vec();
let checksum = crc8(payload.as_slice());
if self.buffer[frame_length - 1] != checksum {
self.buffer.drain(0..1);
continue;
}
let dts = elapsed_millis(session_started_at);
println!("dts_ms: {dts}");
frames.push(TestFrame {
header: [0xAA, 0x55],
cmd: cmd,
length: length,
payload: payload,
checksum: checksum,
dts_ms: dts,
});
self.buffer.drain(0..frame_length);
}
Ok(frames)
}
fn encode(&self, frame: &TestFrame) -> Result<Vec<u8>, CodecError> {
let _ = u16::try_from(frame.payload.len()).map_err(|_| CodecError::PayloadTooLarge)?;
let mut out = Vec::with_capacity(6 + frame.length);
out.extend_from_slice(&frame.header);
out.push(frame.cmd);
out.extend_from_slice(&usize_to_u16_be_bytes(frame.length));
out.extend_from_slice(&frame.payload);
out.push(frame.checksum);
Ok(out)
}
}
#[async_trait]
impl FrameHandler<TestFrame, i32> for TestHandler {
async fn on_frame(&mut self, frame: &TestFrame) -> anyhow::Result<Option<Vec<i32>>> {
match frame.cmd {
0x01 => {
let vals = parse_data_frame(&frame.payload)?;
Ok(Some(vals))
}
_ => Ok(None),
}
}
}
fn parse_data_frame(data: &[u8]) -> Result<Vec<i32>, CodecError> {
if data.len() % 2 != 0 {
return Err(CodecError::InvalidLength);
}
let vals: Vec<i32> = data
.chunks_exact(2)
.map(|chunk| u16::from_be_bytes([chunk[0], chunk[1]]) as i32)
.collect::<Vec<i32>>();
Ok(vals)
}
fn elapsed_millis(start_at: Instant) -> u64 {
start_at.elapsed().as_millis() as u64
}
pub struct TestCsvExporter;
pub struct TestCsvImporter {
channels: usize,
data_row: usize,
packets: Vec<TestDataPacket>,
}
#[derive(Clone)]
pub struct TestDataPacket {
pub data: Vec<i32>,
pub dts_ms: u64
}
impl TryFrom<&TestFrame> for TestDataPacket {
type Error = CodecError;
fn try_from(frame: &TestFrame) -> Result<TestDataPacket, Self::Error> {
let data = parse_data_frame(&frame.payload)?;
let dts = frame.dts_ms;
Ok(TestDataPacket { data: data, dts_ms: dts })
}
}
// impl From<TestFrame> for TestDataPacket {
// fn from(frame: TestFrame) -> Self {
// let data = parse_data_frame(&frame.payload)?;
// let dts = frame.dts_ms;
// TestDataPacket { data: data, dts_ms: dts }
// }
// }
impl CsvExporter<TestFrame> for TestCsvExporter {
type Error = CodecError;
fn csv_header(&self, recording: &Recording<TestFrame>) -> Vec<String> {
let channel_nb = recording
.frames
.iter()
.find_map(|frame| parse_data_frame(&frame.frame.payload).ok().map(|vals| vals.len()))
.unwrap_or(0);
let mut header: Vec<String> = Vec::new();
for i in 0..channel_nb {
header.push(format!("channel{}", i + 1));
}
header.push("dts".to_string());
header
}
fn csv_row(&self, item: &RecordedFrame<TestFrame>) -> anyhow::Result<Vec<String>> {
let packet: TestDataPacket = TestDataPacket::try_from(&item.frame)?;
let mut row: Vec<String> = packet.data.iter().map(|&x| x.to_string()).collect();
row.push(packet.dts_ms.to_string());
Ok(row)
}
}
impl TestCsvImporter {
pub fn new(_path: &str) -> TestCsvImporter {
Self {
channels: 0,
data_row: 0,
packets: Vec::new(),
}
}
fn parse_record(&mut self, record: StringRecord) -> anyhow::Result<TestDataPacket>{
if self.channels == 0 {
return Err(anyhow!("csv header is missing channel columns"));
}
if record.len() < self.channels + 1 {
return Err(anyhow!("csv row has insufficient columns"));
}
let mut data = Vec::with_capacity(self.channels);
for index in 0..self.channels {
let cell = record.get(index).ok_or_else(|| anyhow!("missing channel cell"))?;
data.push(cell.parse::<i32>()?);
}
let dts_cell = record
.get(self.channels)
.ok_or_else(|| anyhow!("missing dts cell"))?;
let dts_ms = dts_cell.parse::<u64>()?;
Ok(TestDataPacket {
data: data,
dts_ms: dts_ms,
})
}
}
impl CsvImporter<TestDataPacket> for TestCsvImporter {
fn load<R: Read>(&mut self, reader: R) -> anyhow::Result<Vec<TestDataPacket>> {
let mut rdr = csv::Reader::from_reader(reader);
let headers = rdr.headers()?.clone();
self.channels = headers.len().saturating_sub(1);
self.data_row = 0;
self.packets.clear();
for record in rdr.records() {
let record = record?;
let packet = self.parse_record(record)?;
self.packets.push(packet);
self.data_row += 1;
}
Ok(self.packets.clone())
}
}
pub fn export_recording_csv<W>(recording: &Recording<TestFrame>, writer: W) -> anyhow::Result<()>
where
W: std::io::Write,
{
let now = Local::now();
let filename = format!("joyson_{}", now.format("%Y%m%d_%H%M%S"));
write_csv(recording, &TestCsvExporter, &filename)
}
#[cfg(test)]
mod tests {
use super::*;
use csv::Reader;
use std::io::Cursor;
#[test]
fn test_read_csv_basic() -> anyhow::Result<()> {
let mut rdr = Reader::from_path("recording_20260329_125238.csv")?;
let headers = rdr.headers()?;
println!("headers: {:?}", headers);
for result in rdr.records() {
let record = result?;
println!("record: {:?}", record);
}
Ok(())
}
}

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src-tauri/src/serial_core/error.rs Normal file
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use serde::Serialize;
use std::fmt;
#[derive(Debug, Serialize)]
pub enum SerialError {
OpenError,
CloseError,
ScanError,
InvalidConfig,
AlreadyConnected,
StateError,
NoRecordedData,
ExportError,
ImportError,
}
impl fmt::Display for SerialError {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
match self {
SerialError::OpenError => write!(f, "Opening Error"),
SerialError::CloseError => write!(f, "Closing Error"),
SerialError::ScanError => write!(f, "Scan Error"),
SerialError::InvalidConfig => write!(f, "Invalid Config"),
SerialError::AlreadyConnected => write!(f, "Already Connected"),
SerialError::StateError => write!(f, "State Error"),
SerialError::NoRecordedData => write!(f, "No Recorded Data"),
SerialError::ExportError => write!(f, "Export Error"),
SerialError::ImportError => write!(f, "Import Error"),
}
}
}
#[derive(Debug)]
pub enum CodecError {
InvalidHeader,
InvalidTail,
InvalidLength,
PayloadTooLarge,
}
impl fmt::Display for CodecError {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
match self {
CodecError::InvalidHeader => write!(f, "Invalid Header"),
CodecError::InvalidTail => write!(f, "Invalid Tail"),
CodecError::InvalidLength => write!(f, "Invalid Length"),
CodecError::PayloadTooLarge => write!(f, "Payload too large"),
}
}
}
impl std::error::Error for CodecError {}

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src-tauri/src/serial_core/frame.rs Normal file
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use anyhow::Result;
use async_trait::async_trait;
#[derive(Debug, Clone, PartialEq, Eq)]
pub struct TestFrame {
pub header: [u8; 2],
pub cmd: u8,
pub length: usize,
pub payload: Vec<u8>,
pub checksum: u8,
pub dts_ms: u64
}
#[async_trait]
pub trait FrameHandler<F, T>: Send {
async fn on_frame(&mut self, frame: &F) -> Result<Option<Vec<T>>>;
}
pub fn usize_to_u16_be_bytes(n: usize) -> [u8; 2] {
(n as u16).to_be_bytes()
}
pub fn usize_to_u16_le_bytes(n: usize) -> [u8; 2] {
(n as u16).to_be_bytes()
}
pub fn crc8(data: &[u8]) -> u8 {
let mut crc: u8 = 0x00;
for &byte in data {
crc ^= byte;
for _ in 0..8 {
if (crc & 0x80) != 0 {
crc = (crc << 1) ^ 0x07;
} else {
crc <<= 1;
}
}
}
crc
}

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src-tauri/src/serial_core/mod.rs Normal file
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use crate::serial_core::{frame::TestFrame, record::Recording};
pub mod codec;
pub mod codecs;
pub mod error;
pub mod frame;
pub mod model;
pub mod serial;
pub mod record;
pub type TestRecording = Recording<TestFrame>;
pub struct SerialConnection {
pub port: String,
}
pub fn connect(port: &str) -> Result<SerialConnection, String> {
let port = port.trim();
if port.is_empty() {
return Err("Serial port is required".to_string());
}
Ok(SerialConnection {
port: port.to_string(),
})
}

500
src-tauri/src/serial_core/model.rs Normal file
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use crate::serial_core::frame::TestFrame;
use std::collections::HashMap;
use std::time::{Duration, Instant, SystemTime, UNIX_EPOCH};
const MAX_POINTS: usize = 28;
const MAX_SUMMARY_POINTS: usize = 42;
const PANEL_STALE_AFTER: Duration = Duration::from_millis(2400);
#[derive(serde::Serialize, Clone)]
#[serde(rename_all = "camelCase")]
pub struct HudPacket {
pub ts: u64,
pub panels: Vec<HudSignalPanel>,
pub summary: HudSummary,
pub pressure_matrix: Option<Vec<f32>>,
}
#[derive(serde::Serialize, Clone)]
#[serde(rename_all = "camelCase")]
pub struct HudSummary {
pub label: String,
pub points: Vec<f32>,
pub latest: Option<f32>,
pub min: Option<f32>,
pub max: Option<f32>,
}
#[derive(serde::Serialize, Clone, Copy)]
#[serde(rename_all = "lowercase")]
pub enum HudPanelSide {
Left,
Right,
}
#[derive(serde::Serialize, Clone, Copy)]
#[serde(rename_all = "lowercase")]
pub enum HudTone {
Cyan,
Lime,
Orange,
Violet,
Gold,
Rose,
}
#[derive(serde::Serialize, Clone)]
#[serde(rename_all = "camelCase")]
pub struct HudSignalPanel {
pub id: String,
pub code: String,
pub title: String,
pub side: HudPanelSide,
pub active: bool,
pub series: Vec<HudSignalSeries>,
pub icons: Vec<HudSignalIcon>,
pub latest: Option<f32>,
pub min: Option<f32>,
pub max: Option<f32>,
}
#[derive(serde::Serialize, Clone)]
#[serde(rename_all = "camelCase")]
pub struct HudSignalSeries {
pub id: String,
pub tone: HudTone,
pub points: Vec<f32>,
}
#[derive(serde::Serialize, Clone)]
#[serde(rename_all = "camelCase")]
pub struct HudSignalIcon {
pub id: String,
pub label: String,
pub tone: HudTone,
}
struct HudPanelUpdate {
source_id: String,
values: Vec<f32>,
}
struct PanelEntry {
panel: HudSignalPanel,
last_seen: Instant,
}
pub struct HudChartState {
panels: HashMap<String, PanelEntry>,
order: Vec<String>,
summary_points: Vec<f32>,
pressure_matrix: Option<Vec<f32>>,
last_frame_seen: Option<Instant>,
}
impl HudChartState {
pub fn new() -> Self {
Self {
panels: HashMap::new(),
order: Vec::new(),
summary_points: Vec::new(),
pressure_matrix: None,
last_frame_seen: None,
}
}
pub fn record_summary(&mut self, value: f32) {
push_summary_point(&mut self.summary_points, value);
}
pub fn record_pressure_matrix(&mut self, values: &[i32]) {
if values.is_empty() {
return;
}
self.pressure_matrix = Some(values.iter().map(|value| *value as f32).collect());
}
pub fn apply_frame(&mut self, frame: &TestFrame, decoded_values: Option<&[i32]>) -> HudPacket {
let now = Instant::now();
self.last_frame_seen = Some(now);
for update in expand_frame_updates(frame, decoded_values) {
self.apply_update(update, now);
}
self.prune_stale_at(now);
self.snapshot()
}
pub fn prune_stale(&mut self) -> Option<HudPacket> {
let before = self.panels.len();
let summary_points_before = self.summary_points.len();
self.prune_stale_at(Instant::now());
if before == self.panels.len() && summary_points_before == self.summary_points.len() {
return None;
}
Some(self.snapshot())
}
fn apply_update(&mut self, update: HudPanelUpdate, now: Instant) {
if update.values.is_empty() {
return;
}
if !self.panels.contains_key(&update.source_id) {
let next_side = side_for_index(self.order.len());
self.order.push(update.source_id.clone());
self.panels.insert(
update.source_id.clone(),
PanelEntry {
panel: build_panel(&update.source_id, next_side, update.values.len()),
last_seen: now,
},
);
}
let entry = self
.panels
.get_mut(&update.source_id)
.expect("panel entry should exist after insertion");
entry.last_seen = now;
entry.panel.active = true;
ensure_panel_channels(&mut entry.panel, update.values.len());
for (index, value) in update.values.into_iter().enumerate() {
if let Some(series) = entry.panel.series.get_mut(index) {
push_point(&mut series.points, value);
}
}
refresh_panel_stats(&mut entry.panel);
}
fn prune_stale_at(&mut self, now: Instant) {
self.panels
.retain(|_, entry| now.duration_since(entry.last_seen) <= PANEL_STALE_AFTER);
self.order.retain(|id| self.panels.contains_key(id));
let summary_stale = self
.last_frame_seen
.map(|last_seen| now.duration_since(last_seen) > PANEL_STALE_AFTER)
.unwrap_or(false);
if summary_stale {
self.summary_points.clear();
self.pressure_matrix = None;
self.last_frame_seen = None;
}
}
fn snapshot(&mut self) -> HudPacket {
self.rebalance_sides();
let panels = self
.order
.iter()
.filter_map(|id| self.panels.get(id).map(|entry| entry.panel.clone()))
.collect();
HudPacket {
ts: now_millis(),
panels,
summary: build_summary(&self.summary_points),
pressure_matrix: self.pressure_matrix.clone(),
}
}
fn rebalance_sides(&mut self) {
for (index, id) in self.order.iter().enumerate() {
if let Some(entry) = self.panels.get_mut(id) {
entry.panel.side = side_for_index(index);
}
}
}
}
impl Default for HudChartState {
fn default() -> Self {
Self::new()
}
}
fn build_panel(source_id: &str, side: HudPanelSide, channel_count: usize) -> HudSignalPanel {
HudSignalPanel {
id: format!("panel-{source_id}"),
code: source_id.to_string(),
title: format!("Source {source_id}"),
side,
active: true,
series: build_panel_series(source_id, channel_count, &[]),
icons: build_panel_icons(source_id, channel_count),
latest: None,
min: None,
max: None,
}
}
fn expand_frame_updates(frame: &TestFrame, decoded_values: Option<&[i32]>) -> Vec<HudPanelUpdate> {
if let Some(values) = decoded_values {
if values.is_empty() {
return Vec::new();
}
return vec![HudPanelUpdate {
source_id: format_source_id(frame.cmd),
values: values.iter().map(|value| *value as f32).collect(),
}];
}
let chunks = frame.payload.chunks_exact(4);
if !frame.payload.is_empty() && chunks.remainder().is_empty() {
return chunks.map(build_update_from_chunk).collect();
}
vec![HudPanelUpdate {
source_id: format_source_id(frame.cmd),
values: fallback_values(frame),
}]
}
fn build_update_from_chunk(chunk: &[u8]) -> HudPanelUpdate {
HudPanelUpdate {
source_id: format_source_id(chunk[0]),
values: chunk[1..]
.iter()
.enumerate()
.map(|(index, byte)| normalize_value(*byte, tone_for_index(index)))
.collect(),
}
}
fn fallback_values(frame: &TestFrame) -> Vec<f32> {
let mut bytes = frame.payload.clone();
if bytes.is_empty() {
bytes.extend([
frame.cmd,
frame.length as u8,
frame.checksum,
frame.cmd.wrapping_add(frame.checksum),
]);
}
while bytes.len() < 3 {
let previous = *bytes.last().unwrap_or(&frame.cmd);
bytes.push(
previous
.wrapping_add(frame.cmd)
.wrapping_add(bytes.len() as u8),
);
}
bytes
.into_iter()
.enumerate()
.map(|(index, byte)| normalize_value(byte, tone_for_index(index)))
.collect()
}
fn normalize_value(byte: u8, tone: HudTone) -> f32 {
let base = (byte as f32 / 255.0) * 100.0;
let offset = match tone {
HudTone::Cyan => 6.0,
HudTone::Lime => 0.0,
HudTone::Orange => -6.0,
HudTone::Violet => 10.0,
HudTone::Gold => -10.0,
HudTone::Rose => 3.0,
};
(base + offset).clamp(0.0, 100.0)
}
fn format_source_id(byte: u8) -> String {
if byte.is_ascii_alphanumeric() {
(byte as char).to_ascii_uppercase().to_string()
} else {
format!("CH{:02X}", byte)
}
}
fn side_for_index(index: usize) -> HudPanelSide {
if index % 2 == 0 {
HudPanelSide::Left
} else {
HudPanelSide::Right
}
}
fn push_point(points: &mut Vec<f32>, value: f32) {
if points.len() >= MAX_POINTS {
points.remove(0);
}
points.push((value * 10.0).round() / 10.0);
}
fn build_panel_series(
source_id: &str,
channel_count: usize,
previous: &[HudSignalSeries],
) -> Vec<HudSignalSeries> {
(0..channel_count)
.map(|index| HudSignalSeries {
id: format!("{source_id}-series-{}", index + 1),
tone: tone_for_index(index),
points: previous
.get(index)
.map(|series| series.points.clone())
.unwrap_or_default(),
})
.collect()
}
fn build_panel_icons(source_id: &str, channel_count: usize) -> Vec<HudSignalIcon> {
(0..channel_count)
.map(|index| HudSignalIcon {
id: format!("{source_id}-icon-{}", index + 1),
label: if channel_count == 1 {
"TOTAL".to_string()
} else {
format!("{source_id}-{}", index + 1)
},
tone: tone_for_index(index),
})
.collect()
}
fn ensure_panel_channels(panel: &mut HudSignalPanel, channel_count: usize) {
if panel.series.len() == channel_count && panel.icons.len() == channel_count {
return;
}
panel.series = build_panel_series(&panel.code, channel_count, &panel.series);
panel.icons = build_panel_icons(&panel.code, channel_count);
}
fn refresh_panel_stats(panel: &mut HudSignalPanel) {
let latest_values: Vec<f32> = panel
.series
.iter()
.filter_map(|series| series.points.last().copied())
.collect();
panel.latest = if latest_values.is_empty() {
None
} else {
Some(latest_values.iter().sum::<f32>() / latest_values.len() as f32)
};
panel.min = panel
.series
.iter()
.flat_map(|series| series.points.iter().copied())
.reduce(f32::min);
panel.max = panel
.series
.iter()
.flat_map(|series| series.points.iter().copied())
.reduce(f32::max);
}
fn tone_for_index(index: usize) -> HudTone {
match index % 6 {
0 => HudTone::Cyan,
1 => HudTone::Lime,
2 => HudTone::Orange,
3 => HudTone::Violet,
4 => HudTone::Gold,
_ => HudTone::Rose,
}
}
fn push_summary_point(points: &mut Vec<f32>, value: f32) {
if points.len() >= MAX_SUMMARY_POINTS {
points.remove(0);
}
points.push((value * 10.0).round() / 10.0);
}
fn build_summary(points: &[f32]) -> HudSummary {
HudSummary {
label: "TOTAL".to_string(),
points: points.to_vec(),
latest: points.last().copied(),
min: points.iter().copied().reduce(f32::min),
max: points.iter().copied().reduce(f32::max),
}
}
fn now_millis() -> u64 {
SystemTime::now()
.duration_since(UNIX_EPOCH)
.map(|duration| duration.as_millis() as u64)
.unwrap_or_default()
}
// #[cfg(test)]
// mod tests {
// use super::*;
//
// fn sample_frame() -> TestFrame {
// TestFrame {
// header: [0xAA, 0x55],
// cmd: 0x01,
// length: 4,
// payload: vec![0x00, 0x0A, 0x00, 0x14],
// checksum: 0,
//
// }
// }
//
// #[test]
// fn prune_stale_clears_panels_and_summary_after_timeout() {
// let mut state = HudChartState::new();
// let frame = sample_frame();
//
// state.record_summary(30.0);
// let _ = state.apply_frame(&frame, Some(&[10, 20]));
//
// let stale_now = Instant::now();
// let stale_seen = stale_now - PANEL_STALE_AFTER - Duration::from_millis(1);
//
// state.last_frame_seen = Some(stale_seen);
//
// for entry in state.panels.values_mut() {
// entry.last_seen = stale_seen;
// }
//
// let packet = state
// .prune_stale()
// .expect("stale data should emit an update");
//
// assert!(packet.panels.is_empty());
// assert!(packet.summary.points.is_empty());
// assert!(state.panels.is_empty());
// assert!(state.summary_points.is_empty());
// }
//
// #[test]
// fn prune_stale_keeps_recent_summary_points() {
// let mut state = HudChartState::new();
// let frame = sample_frame();
//
// state.record_summary(30.0);
// let _ = state.apply_frame(&frame, Some(&[10, 20]));
//
// state.last_frame_seen = Some(Instant::now());
//
// assert!(state.prune_stale().is_none());
// assert_eq!(state.summary_points, vec![30.0]);
// assert_eq!(state.panels.len(), 1);
// }
// }

64
src-tauri/src/serial_core/record.rs Normal file
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use std::fs::{write, File};
use std::io;
use anyhow::{Result, anyhow};
use csv::Reader;
#[derive(Clone)]
pub struct FrameTiming {
pub pts_ms: Option<u64>,
pub dts_ms: u64,
}
#[derive(Clone)]
pub struct RecordedFrame<F> {
pub timing: FrameTiming,
pub frame: F
}
#[derive(Clone, Default)]
pub struct Recording<F> {
pub frames: Vec<RecordedFrame<F>>
}
impl<F> Recording<F> {
pub fn new() -> Recording<F> { Self { frames: Vec::new() } }
pub fn push(&mut self, ite: RecordedFrame<F>) {
self.frames.push(ite);
}
}
pub trait CsvExporter<F> {
type Error: std::error::Error + Send + Sync + 'static;
fn csv_header(&self, recording: &Recording<F>) -> Vec<String>;
fn csv_row(&self, item: &RecordedFrame<F>) -> anyhow::Result<Vec<String>>;
}
// TODO: CsvImporter
pub trait CsvImporter<P> {
fn load<R: std::io::Read>(&mut self, reader: R) -> anyhow::Result<Vec<P>>;
}
pub fn write_csv<F, E>(
recording: &Recording<F>,
exporter: &E,
path: &str
// mut writer: W,
) -> anyhow::Result<()>
where
E: CsvExporter<F>,
// W: std::io::Write
{
let header = exporter.csv_header(&recording);
// let mut wrt = csv::Writer::from_writer(io::stdout());
let mut wrt = csv::Writer::from_path(format!("{}.csv", path))?;
wrt.write_record(header)?;
for f in &recording.frames {
let row = exporter.csv_row(f)?;
wrt.write_record(&row)?;
}
wrt.flush()?;
Ok(())
}

80
src-tauri/src/serial_core/serial.rs Normal file
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use crate::serial_core::codec::Codec;
use crate::serial_core::frame::{FrameHandler, TestFrame};
use crate::serial_core::model::HudChartState;
use anyhow::Result;
use tauri::{AppHandle, Emitter};
use tokio::io::AsyncReadExt;
use tokio::time::{self, Duration, MissedTickBehavior};
use tokio_serial::SerialStream;
use tokio_util::sync::CancellationToken;
use std::sync::{Arc, Mutex};
use std::time::Instant;
use log::info;
use crate::serial_core::record::{FrameTiming, RecordedFrame};
use crate::serial_core::TestRecording;
pub async fn run_serial<C, H, T>(
app: AppHandle,
mut port: SerialStream,
mut codec: C,
mut handler: H,
session_started_at: Instant,
recording: Arc<Mutex<TestRecording>>,
cancel: CancellationToken,
) -> Result<()>
where
C: Codec<TestFrame> + Send + 'static,
H: FrameHandler<TestFrame, T> + Send + 'static,
T: Into<i32>,
{
let mut chart_state = HudChartState::new();
let mut buffer = [0u8; 1024];
let mut prune_interval = time::interval(Duration::from_millis(450));
prune_interval.set_missed_tick_behavior(MissedTickBehavior::Delay);
loop {
tokio::select! {
_ = cancel.cancelled() => break,
_ = prune_interval.tick() => {
if let Some(packet) = chart_state.prune_stale() {
app.emit("hud_stream", packet)?;
}
}
read_result = port.read(&mut buffer) => {
let n = read_result?;
if n == 0 {
continue;
}
let frames = codec.decode(&buffer[..n], session_started_at)?;
for frame in frames {
let decode_res = handler
.on_frame(&frame)
.await?
.map(|vals| vals.into_iter().map(Into::into).collect::<Vec<i32>>());
let mut record = recording.lock().map_err(|_| anyhow::anyhow!("recording state poisoned"))?;
record.push(RecordedFrame{
timing: FrameTiming { pts_ms: None, dts_ms: frame.dts_ms },
frame: frame.clone(),
});
let display_values = if let Some(vals) = decode_res.as_ref() {
let summary = vals.iter().copied().sum::<i32>();
info!("dot value summary: {}", summary);
chart_state.record_summary(summary as f32);
chart_state.record_pressure_matrix(vals.as_slice());
Some(vec![summary])
} else {
None
};
let packet = chart_state.apply_frame(&frame, display_values.as_deref());
app.emit("hud_stream", packet)?;
}
}
}
}
Ok(())
}