tesla-charge-controller/src/pl_interface.rs

240 lines
7.2 KiB
Rust

use std::{
io::Write,
sync::{Arc, RwLock},
time::Duration,
};
use anyhow::Context;
use metrics::{describe_gauge, gauge, Gauge};
use serde::{Deserialize, Serialize};
use serialport::SerialPort;
use termcolor::WriteColor;
pub struct Pli {
pub state: Arc<RwLock<PlState>>,
port: Box<dyn SerialPort>,
voltage_gauge: Gauge,
duty_cycle: Gauge,
internal_charge_current: Gauge,
internal_load_current: Gauge,
regulator_gauges: RegulatorGauges,
}
#[derive(Debug, Clone, Copy, Serialize, Deserialize)]
pub struct PlState {
pub battery_voltage: f64,
pub duty_cycle: f64,
pub internal_charge_current: f64,
pub internal_load_current: f64,
pub regulator_state: RegulatorState,
}
impl Default for PlState {
fn default() -> Self {
Self {
battery_voltage: Default::default(),
duty_cycle: Default::default(),
internal_charge_current: Default::default(),
internal_load_current: Default::default(),
regulator_state: RegulatorState::Absorption,
}
}
}
#[derive(Debug, Clone, Copy, Serialize, Deserialize)]
pub enum RegulatorState {
Boost,
Equalise,
Absorption,
Float,
}
impl From<u8> for RegulatorState {
fn from(value: u8) -> Self {
match value & 0b11 {
0b00 => Self::Boost,
0b01 => Self::Equalise,
0b10 => Self::Absorption,
0b11 => Self::Float,
_ => unreachable!(),
}
}
}
struct RegulatorGauges {
boost: Gauge,
equalise: Gauge,
absorption: Gauge,
float: Gauge,
}
impl RegulatorGauges {
fn new() -> Self {
describe_gauge!("pl_regulator", "Regulator state");
let boost = gauge!("pl_regulator", "state" => "boost");
let equalise = gauge!("pl_regulator", "state" => "equalise");
let absorption = gauge!("pl_regulator", "state" => "absorption");
let float = gauge!("pl_regulator", "state" => "float");
Self {
boost,
equalise,
absorption,
float,
}
}
fn set(&mut self, state: &RegulatorState) {
match state {
RegulatorState::Boost => {
self.boost.set(1.);
self.equalise.set(0.);
self.absorption.set(0.);
self.float.set(0.);
}
RegulatorState::Equalise => {
self.boost.set(0.);
self.equalise.set(1.);
self.absorption.set(0.);
self.float.set(0.);
}
RegulatorState::Absorption => {
self.boost.set(0.);
self.equalise.set(0.);
self.absorption.set(1.);
self.float.set(0.);
}
RegulatorState::Float => {
self.boost.set(0.);
self.equalise.set(0.);
self.absorption.set(0.);
self.float.set(1.);
}
}
}
}
#[derive(Debug, Clone, Copy)]
pub enum PliRequest {
ReadRam(u8),
}
impl Pli {
pub fn new(serial_port: String, baud_rate: u32) -> anyhow::Result<Self> {
let port = serialport::new(serial_port, baud_rate)
.timeout(Duration::from_millis(250))
.open()?;
describe_gauge!("pl_battery_voltage", "Battery voltage");
let voltage_gauge = gauge!("pl_battery_voltage");
describe_gauge!("pl_duty_cycle", "Duty cycle");
let duty_cycle = gauge!("pl_duty_cycle");
describe_gauge!("pl_internal_charge_current", "Internal charge current");
let internal_charge_current = gauge!("pl_internal_charge_current");
describe_gauge!("pl_internal_load_current", "Internal load current");
let internal_load_current = gauge!("pl_internal_load_current");
Ok(Self {
state: Arc::new(RwLock::new(Default::default())),
port,
voltage_gauge,
duty_cycle,
internal_charge_current,
internal_load_current,
regulator_gauges: RegulatorGauges::new(),
})
}
pub fn refresh(&mut self) {
if let Ok(new_state) = self.read_state() {
self.voltage_gauge.set(new_state.battery_voltage);
self.duty_cycle.set(new_state.duty_cycle);
self.internal_charge_current
.set(new_state.internal_charge_current);
self.internal_load_current
.set(new_state.internal_load_current);
self.regulator_gauges.set(&new_state.regulator_state);
*self.state.write().expect("PLI state handler panicked!!") = new_state;
}
}
pub fn process_request(&mut self, message: PliRequest) {
match message {
PliRequest::ReadRam(address) => match self.read_ram(address) {
Ok(data) => {
let mut stdout =
termcolor::StandardStream::stdout(termcolor::ColorChoice::Always);
let _ = stdout.set_color(
termcolor::ColorSpec::new().set_fg(Some(termcolor::Color::Green)),
);
if writeln!(&mut stdout, "Read RAM at {address}: data {data}").is_err() {
log::warn!(
"Failed to set stdout colour\nRead RAM at {address}: data {data}"
);
};
}
Err(e) => log::error!("RAM read error: {e:?}"),
},
}
}
fn read_state(&mut self) -> anyhow::Result<PlState> {
Ok(PlState {
battery_voltage: (self.read_ram(PlRamAddress::Batv)? as f64) * (4. / 10.),
duty_cycle: (self.read_ram(PlRamAddress::Dutycyc)? as f64) / 255.,
internal_charge_current: (self.read_ram(PlRamAddress::Cint)? as f64) * (4. / 10.),
internal_load_current: (self.read_ram(PlRamAddress::Lint)? as f64) * (4. / 10.),
regulator_state: self.read_ram(PlRamAddress::Rstate)?.into(),
})
}
fn send_command(&mut self, req: [u8; 4]) {
self.port
.write_all(&req)
.expect("failed to write to serial port");
}
fn receive<const LENGTH: usize>(&mut self) -> [u8; LENGTH] {
let mut buf = [0; LENGTH];
match self.port.read_exact(&mut buf) {
Ok(_) => {}
Err(e) => log::error!("PLI serial read error: {e:#?}"),
}
buf
}
fn read_ram<T>(&mut self, address: T) -> anyhow::Result<u8>
where
T: Into<u8>,
{
self.send_command(command(20, address.into(), 0));
let buf: [u8; 2] = self.receive();
if buf[0] == 200 { Some(buf[1]) } else { None }
.context(format!("Error from PLI: {}", buf[0]))
}
}
enum PlRamAddress {
Dutycyc,
Batv,
Rstate,
Cint,
Lint,
}
impl From<PlRamAddress> for u8 {
fn from(value: PlRamAddress) -> Self {
match value {
PlRamAddress::Dutycyc => 39,
PlRamAddress::Batv => 50,
PlRamAddress::Rstate => 101,
PlRamAddress::Cint => 213,
PlRamAddress::Lint => 217,
}
}
}
fn command(operation: u8, address: u8, data: u8) -> [u8; 4] {
[operation, address, data, !operation]
}