Support fan PWM settings #73

Merged
sb10q merged 16 commits from esavkin/thermostat:69-fan_pwm into master 2023-03-22 17:15:49 +08:00
5 changed files with 22 additions and 174 deletions
Showing only changes of commit a645bfb6e8 - Show all commits

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@ -125,9 +125,10 @@ formatted as line-delimited JSON.
| `dfu` | Reset device and enters USB device firmware update (DFU) mode | | `dfu` | Reset device and enters USB device firmware update (DFU) mode |
| `ipv4 <X.X.X.X/L> [Y.Y.Y.Y]` | Configure IPv4 address, netmask length, and optional default gateway | | `ipv4 <X.X.X.X/L> [Y.Y.Y.Y]` | Configure IPv4 address, netmask length, and optional default gateway |
| `fan` | Show current fan settings and sensors' measurements | | `fan` | Show current fan settings and sensors' measurements |
| `fan <value>` | Set fan power with values from 0 to 100, where 0 is auto mode | | `fan <value>` | Set fan power with values from 1 to 100 |
| `fan auto` | Enable automatic fan speed control |
| `fcurve <a> <b> <c>` | Set fan controller curve coefficients (see *Fan control* section) | | `fcurve <a> <b> <c>` | Set fan controller curve coefficients (see *Fan control* section) |
| `fcurve-restore` | Set fan controller curve coefficients to defaults (see *Fan control* section) | | `fcurve default` | Set fan controller curve coefficients to defaults (see *Fan control* section) |
## USB ## USB
@ -277,13 +278,11 @@ The thermostat implements a PID control loop for each of the TEC channels, more
## Fan control ## Fan control
sb10q marked this conversation as resolved
Review

Why is it so approximate?

Why is it so approximate?
Review

Mostly because I cannot guarantee it is precise and would not like to see how someone would tie something-very-important to its value.

Mostly because I cannot guarantee it is precise and would not like to see how someone would tie something-very-important to its value.
Fan control is available for the thermostat revisions with integrated fan system. For this purpose four commands are available: Fan control is available for the thermostat revisions with integrated fan system. For this purpose four commands are available:
1. `fan` - show fan stats: `fan_pwm`, `tacho`, `abs_max_tec_i`, `auto_mode`. Please note that `tacho` shows *approximate* value, which 1. `fan` - show fan stats: `fan_pwm`, `abs_max_tec_i`, `auto_mode`, `k_a`, `k_b`, `k_c`.
linearly correlates with the actual fan speed. 2. `fan auto` - enable auto speed controller mode, which correlates with the square of the TEC's current.
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Review

Doesn't the motor stall at low powers?

Doesn't the motor stall at low powers?

No, the minimum I tried was 0.008 PWM, anything below that makes the circuit consider there is no signal and it runs at full power. 0.008-0.04 values are working quite fine, though there is specific noise on low speed.

No, the minimum I tried was 0.008 PWM, anything below that makes the circuit consider there is no signal and it runs at full power. 0.008-0.04 values are working quite fine, though there is specific noise on low speed.
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Review

"correlates with the square of the TEC's current" is incorrect

"correlates with the square of the TEC's current" is incorrect
2. `fan <value>` - set the fan power with the value from `0` to `100`. Since there is no hardware way to disable the fan, 3. `fan <value>` - set the fan power with the value from `1` to `100` and disable auto mode. There is no way to disable the fan.
`0` value is used for enabling automatic fan control mode, which correlates with the square of the TEC's current.
Values from `1` to `100` are used for setting the power from minimum to maximum respectively.
Please note that power doesn't correlate with the actual speed linearly. Please note that power doesn't correlate with the actual speed linearly.
3. `fcurve <a> <b> <c>` - set coefficients of the controlling curve `a*x^2 + b*x + c`, where `x` is `abs_max_tec_i/MAX_TEC_I`, 4. `fcurve <a> <b> <c>` - set coefficients of the controlling curve `a*x^2 + b*x + c`, where `x` is `abs_max_tec_i/MAX_TEC_I`,
i.e. receives values from 0 to 1 linearly tied to the maximum current. The controlling curve should produce values from 0 to 1, i.e. receives values from 0 to 1 linearly tied to the maximum current. The controlling curve should produce values from 0 to 1,
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Review

Why is it "fcurve" and "fan-restore"? Don't you see the issue here?

Why is it "fcurve" and "fan-restore"? Don't you see the issue here?
as below and beyond values would be substituted by 0 and 1 respectively. as below and beyond values would be substituted by 0 and 1 respectively.
4. `fcurve-restore` - restore fan settings to defaults: `auto = true, a = 1.0, b = 0.0, c = 0.00`. 5. `fcurve default` - restore fan curve settings to defaults: `a = 1.0, b = 0.0, c = 0.0`.
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Review

Those defaults are naive.

Those defaults are naive.

Though they are naive, they work OK - 50% full speed is achieved on 1A, 90% on 2A (see the table of tacho measurements at various pwm).

user input scaled tacho
0 4 431
1 5 466
2 6 492
3 7 515
4 8 536
5 9 554
6 10 571
7 11 584
8 12 598
9 13 606
10 14 618
20 23 671
30 33 704
40 42 729
50 52 740
60 62 760
70 71 773
80 81 791
90 90 791
100 100 791
Though they are naive, they work OK - 50% full speed is achieved on 1A, 90% on 2A (see the table of tacho measurements at various pwm). | user input | scaled | tacho | | -------- | -------- | -------- | 0|4|431 1|5|466 2|6|492 3|7|515 4|8|536 5|9|554 6|10|571 7|11|584 8|12|598 9|13|606 10|14|618 20|23|671 30|33|704 40|42|729 50|52|740 60|62|760 70|71|773 80|81|791 90|90|791 100|100|791
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Review

Though they are naive, they work OK

I don't know how you can say that without testing the board inside the enclosure and with loads on both channels.

> Though they are naive, they work OK I don't know how you can say that without testing the board inside the enclosure and with loads on both channels.

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@ -342,7 +342,7 @@ impl Handler {
Ok(Handler::Reset) Ok(Handler::Reset)
} }
fn fan(socket: &mut TcpSocket, fan_pwm: u32, fan_ctrl: &mut FanCtrl) -> Result<Handler, Error> { fn set_fan(socket: &mut TcpSocket, fan_pwm: u32, fan_ctrl: &mut FanCtrl) -> Result<Handler, Error> {
fan_ctrl.set_auto_mode(false); fan_ctrl.set_auto_mode(false);
fan_ctrl.set_pwm(fan_pwm); fan_ctrl.set_pwm(fan_pwm);
send_line(socket, b"{}"); send_line(socket, b"{}");
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Review

This behavior is inconsistent with the pwm command, the latter uses pwm i_set <current> / pwm pid, not pwm i_set 0 to enable PID.

This behavior is inconsistent with the ``pwm`` command, the latter uses ``pwm i_set <current> / pwm pid``, not ``pwm i_set 0`` to enable PID.
@ -404,7 +404,7 @@ impl Handler {
Command::Ipv4(config) => Handler::set_ipv4(socket, store, config), Command::Ipv4(config) => Handler::set_ipv4(socket, store, config),
Command::Reset => Handler::reset(&mut fan_ctrl.channels), Command::Reset => Handler::reset(&mut fan_ctrl.channels),
Command::Dfu => Handler::dfu(&mut fan_ctrl.channels), Command::Dfu => Handler::dfu(&mut fan_ctrl.channels),
Command::FanSet {fan_pwm} => Handler::fan(socket, fan_pwm, fan_ctrl), Command::FanSet {fan_pwm} => Handler::set_fan(socket, fan_pwm, fan_ctrl),
Command::ShowFan => Handler::show_fan(socket, fan_ctrl), Command::ShowFan => Handler::show_fan(socket, fan_ctrl),
Command::FanAuto => Handler::fan_auto(socket, fan_ctrl), Command::FanAuto => Handler::fan_auto(socket, fan_ctrl),
Command::FanCurve { k_a, k_b, k_c } => Handler::fan_curve(socket, fan_ctrl, k_a, k_b, k_c), Command::FanCurve { k_a, k_b, k_c } => Handler::fan_curve(socket, fan_ctrl, k_a, k_b, k_c),

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@ -2,23 +2,14 @@ use serde::Serialize;
use stm32f4xx_hal::{ use stm32f4xx_hal::{
pwm::{self, PwmChannels}, pwm::{self, PwmChannels},
pac::TIM8, pac::TIM8,
gpio::{
Floating, Input, ExtiPin,
gpioc::PC8, Edge,
},
stm32::EXTI,
syscfg::{SysCfg},
}; };
use smoltcp::time::Instant;
use crate::{ use crate::{
pins::HWRevPins, pins::HWRevPins,
channels::{Channels, JsonBuffer}, channels::{Channels, JsonBuffer},
timer
}; };
pub type FanPin = PwmChannels<TIM8, pwm::C4>; pub type FanPin = PwmChannels<TIM8, pwm::C4>;
pub type TachoPin = PC8<Input<Floating>>;
// as stated in the schematics // as stated in the schematics
const MAX_TEC_I: f64 = 3.0; const MAX_TEC_I: f64 = 3.0;
@ -26,27 +17,13 @@ const MAX_TEC_I: f64 = 3.0;
const MAX_USER_FAN_PWM: f64 = 100.0; const MAX_USER_FAN_PWM: f64 = 100.0;
const MIN_USER_FAN_PWM: f64 = 1.0; const MIN_USER_FAN_PWM: f64 = 1.0;
const MAX_FAN_PWM: f64 = 1.0; const MAX_FAN_PWM: f64 = 1.0;
// below this value, motor pulse signal is too weak to be registered by tachometer // below this value, motor pulse signal is too weak
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Review

"weak" suggests amplitude, which is incorrect.
-> "frequency is too low"

"weak" suggests amplitude, which is incorrect. -> "frequency is too low"

no, not the frequency. The near-zero freq is the consequence of weak signal.

no, not the frequency. The near-zero freq is the consequence of weak signal.
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Review

Do you have an oscilloscope picture demonstrating this, and how was it measured?

Do you have an oscilloscope picture demonstrating this, and how was it measured?

We used pulse counter to measure the tacho values, for PWM 0.04-1.0 it was ok, but for lower the tacho signal disappears

We used pulse counter to measure the tacho values, for PWM 0.04-1.0 it was ok, but for lower the tacho signal disappears
const MIN_FAN_PWM: f64 = 0.05; const MIN_FAN_PWM: f64 = 0.05;
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Review

According to ?

According to ?

Internal experiments

Internal experiments
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Review

Please say so in the code comments.

Please say so in the code comments.
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Review

Also we can probably expect this to be hardware revision dependent. When the fan has proper PWM support this shouldn't be an issue I guess.

Also we can probably expect this to be hardware revision dependent. When the fan has proper PWM support this shouldn't be an issue I guess.

Made this (and others) value coming from hwrev

Made this (and others) value coming from hwrev
const TACHO_MEASURE_MS: i64 = 2500;
// by default up to 2 cycles are skipped on changes in PWM output,
// and the halt threshold will help detect the failure during these skipped cycles
const TACHO_HALT_THRESHOLD: u32 = 250;
const TACHO_SKIP_CYCLES: u8 = 2;
const DEFAULT_K_A: f64 = 1.0; const DEFAULT_K_A: f64 = 1.0;
const DEFAULT_K_B: f64 = 0.0; const DEFAULT_K_B: f64 = 0.0;
const DEFAULT_K_C: f64 = 0.0; const DEFAULT_K_C: f64 = 0.0;
Review

Those naive values will need proper testing and determination at some point.

Those naive values will need proper testing and determination at some point.
// This regression is from 6% to 25% lower than values registered in the experiments.
// Actual values would be better estimated by logarithmic regression, but that would require more
// runtime computation, and wouldn't give significant correlation difference
// (0.996 for log and 0.966 for quadratic regression).
const TACHO_REGRESSION_A: f64 = -0.04135128436;
const TACHO_REGRESSION_B: f64 = 6.23015531;
const TACHO_REGRESSION_C: f64 = 403.6833577;
#[derive(Serialize, Copy, Clone)] #[derive(Serialize, Copy, Clone)]
pub struct HWRev { pub struct HWRev {
@ -54,83 +31,46 @@ pub struct HWRev {
pub minor: u8, pub minor: u8,
} }
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Review

Where are those default K_A/B/C from? Certainly not from the schematics so the comment is misleading.
Have you tested those defaults and how?

Where are those default K_A/B/C from? Certainly not from the schematics so the comment is misleading. Have you tested those defaults and how?

Well, they are subject of change, but they come from the power formula P=I^2 * R

Well, they are subject of change, but they come from the power formula P=I^2 * R
#[derive(Serialize, Clone, Copy, PartialEq)]
pub enum FanStatus {
OK,
NotAvailable,
TooSlow,
Halted
}
struct TachoCtrl {
tacho: TachoPin,
tacho_cnt: u32,
tacho_value: Option<u32>,
prev_epoch: i64,
}
pub struct FanCtrl { pub struct FanCtrl {
fan: FanPin, fan: FanPin,
tacho: TachoCtrl,
fan_auto: bool, fan_auto: bool,
available: bool, available: bool,
k_a: f64, k_a: f64,
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Review

at the user's own risk

at the user's own risk
k_b: f64, k_b: f64,
k_c: f64, k_c: f64,
pub channels: Channels, pub channels: Channels,
last_status: FanStatus,
skip_cycles: u8,
} }
impl FanCtrl { impl FanCtrl {
pub fn new(mut fan: FanPin, tacho: TachoPin, channels: Channels, exti: &mut EXTI, syscfg: &mut SysCfg) -> Self { pub fn new(mut fan: FanPin, channels: Channels) -> Self {
let available = channels.hwrev.fan_available(); let available = channels.hwrev.fan_available();
let mut tacho_ctrl = TachoCtrl::new(tacho);
if available { if available {
fan.set_duty(0); fan.set_duty(0);
fan.enable(); fan.enable();
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Review

Did you double-check that this results in no PWM pulses being emitted at all, even short ones?

Did you double-check that this results in no PWM pulses being emitted at all, even short ones?

Fixed this and checked that there is no pulses by default. On oscilloscope there is pulse on fan 100 command, but no such pulse on reset command

Fixed this and checked that there is no pulses by default. On oscilloscope there is pulse on `fan 100` command, but no such pulse on `reset` command
tacho_ctrl.init(exti, syscfg);
} }
FanCtrl { FanCtrl {
fan, fan,
tacho: tacho_ctrl,
available, available,
fan_auto: true, fan_auto: true,
k_a: DEFAULT_K_A, k_a: DEFAULT_K_A,
k_b: DEFAULT_K_B, k_b: DEFAULT_K_B,
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Review

at user's own risk

at user's own risk
k_c: DEFAULT_K_C, k_c: DEFAULT_K_C,
channels, channels,
last_status: if available { FanStatus::OK } else { FanStatus::NotAvailable },
skip_cycles: 0
} }
} }
pub fn cycle(&mut self) -> Result<(), FanStatus> { pub fn cycle(&mut self) {
if self.available {
if self.tacho.cycle() {
self.skip_cycles >>= 1;
}
}
self.adjust_speed(); self.adjust_speed();
let diagnose = self.diagnose();
if (self.skip_cycles == 0 || diagnose == FanStatus::Halted) && diagnose != self.last_status {
self.last_status = diagnose;
Err(diagnose)
} else {
Ok(())
}
} }
Review

inline

inline
pub fn summary(&mut self) -> Result<JsonBuffer, serde_json_core::ser::Error> { pub fn summary(&mut self) -> Result<JsonBuffer, serde_json_core::ser::Error> {
if self.available { if self.available {
let summary = FanSummary { let summary = FanSummary {
fan_pwm: self.get_pwm(), fan_pwm: self.get_pwm(),
tacho: self.tacho.get(),
abs_max_tec_i: self.channels.current_abs_max_tec_i(), abs_max_tec_i: self.channels.current_abs_max_tec_i(),
auto_mode: self.fan_auto, auto_mode: self.fan_auto,
status: self.diagnose(),
k_a: self.k_a, k_a: self.k_a,
k_b: self.k_b, k_b: self.k_b,
k_c: self.k_c, k_c: self.k_c,
@ -165,15 +105,11 @@ impl FanCtrl {
#[inline] #[inline]
pub fn restore_defaults(&mut self) { pub fn restore_defaults(&mut self) {
self.set_auto_mode(true);
self.set_curve(DEFAULT_K_A, DEFAULT_K_B, DEFAULT_K_C); self.set_curve(DEFAULT_K_A, DEFAULT_K_B, DEFAULT_K_C);
} }
pub fn set_pwm(&mut self, fan_pwm: u32) -> f64 { pub fn set_pwm(&mut self, fan_pwm: u32) -> f64 {
let fan_pwm = fan_pwm.min(MAX_USER_FAN_PWM as u32).max(MIN_USER_FAN_PWM as u32); let fan_pwm = fan_pwm.min(MAX_USER_FAN_PWM as u32).max(MIN_USER_FAN_PWM as u32);
self.skip_cycles = if (self.tacho.get() as f64) <= Self::threshold_for_pwm(fan_pwm as f64) {
TACHO_SKIP_CYCLES
} else { self.skip_cycles };
let duty = Self::scale_number(fan_pwm as f64, MIN_FAN_PWM, MAX_FAN_PWM, MIN_USER_FAN_PWM, MAX_USER_FAN_PWM); let duty = Self::scale_number(fan_pwm as f64, MIN_FAN_PWM, MAX_FAN_PWM, MIN_USER_FAN_PWM, MAX_USER_FAN_PWM);
let max = self.fan.get_max_duty(); let max = self.fan.get_max_duty();
let value = ((duty * (max as f64)) as u16).min(max); let value = ((duty * (max as f64)) as u16).min(max);
@ -181,31 +117,11 @@ impl FanCtrl {
value as f64 / (max as f64) value as f64 / (max as f64)
} }
#[inline]
fn threshold_for_pwm(fan_pwm: f64) -> f64 {
(TACHO_REGRESSION_A * fan_pwm + TACHO_REGRESSION_B) * fan_pwm + TACHO_REGRESSION_C
}
#[inline] #[inline]
fn scale_number(unscaled: f64, to_min: f64, to_max: f64, from_min: f64, from_max: f64) -> f64 { fn scale_number(unscaled: f64, to_min: f64, to_max: f64, from_min: f64, from_max: f64) -> f64 {
(to_max - to_min) * (unscaled - from_min) / (from_max - from_min) + to_min (to_max - to_min) * (unscaled - from_min) / (from_max - from_min) + to_min
} }
fn diagnose(&mut self) -> FanStatus {
if !self.available {
return FanStatus::NotAvailable;
}
let threshold = Self::threshold_for_pwm(self.get_pwm() as f64) as u32;
let tacho = self.tacho.get();
if tacho >= threshold {
FanStatus::OK
} else if tacho >= TACHO_HALT_THRESHOLD {
FanStatus::TooSlow
} else {
FanStatus::Halted
}
}
fn get_pwm(&self) -> u32 { fn get_pwm(&self) -> u32 {
Outdated
Review

this does not need to be a class member

this does not need to be a class member
let duty = self.fan.get_duty(); let duty = self.fan.get_duty();
let max = self.fan.get_max_duty(); let max = self.fan.get_max_duty();
@ -213,53 +129,6 @@ impl FanCtrl {
} }
} }
impl TachoCtrl {
fn new(tacho: TachoPin) -> Self {
TachoCtrl {
tacho,
tacho_cnt: 0,
tacho_value: None,
prev_epoch: 0,
}
}
fn init(&mut self, exti: &mut EXTI, syscfg: &mut SysCfg) {
// These lines do not cause NVIC to run the ISR,
// since the interrupt is masked in the cortex_m::peripheral::NVIC.
// Also using interrupt-related workaround is the best
// option for the current version of stm32f4xx-hal,
// since tying the IC's PC8 with the PWM's PC9 to the same TIM8 is not supported.
// The possible solution would be to update the library to >=v0.14.*,
// and use its Timer's counter functionality.
self.tacho.make_interrupt_source(syscfg);
self.tacho.trigger_on_edge(exti, Edge::Rising);
self.tacho.enable_interrupt(exti);
}
// returns whether the epoch elapsed
fn cycle(&mut self) -> bool {
let tacho_input = self.tacho.check_interrupt();
if tacho_input {
self.tacho.clear_interrupt_pending_bit();
self.tacho_cnt += 1;
}
let instant = Instant::from_millis(i64::from(timer::now()));
if instant.millis - self.prev_epoch >= TACHO_MEASURE_MS {
self.tacho_value = Some(self.tacho_cnt);
self.tacho_cnt = 0;
self.prev_epoch = instant.millis;
true
} else {
false
}
}
fn get(&self) -> u32 {
self.tacho_value.unwrap_or(u32::MAX)
}
}
impl HWRev { impl HWRev {
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Review

Move to separate file. This is not intrinsically linked to the fan.

Move to separate file. This is not intrinsically linked to the fan.
pub fn detect_hw_rev(hwrev_pins: &HWRevPins) -> Self { pub fn detect_hw_rev(hwrev_pins: &HWRevPins) -> Self {
let (h0, h1, h2, h3) = (hwrev_pins.hwrev0.is_high(), hwrev_pins.hwrev1.is_high(), let (h0, h1, h2, h3) = (hwrev_pins.hwrev0.is_high(), hwrev_pins.hwrev1.is_high(),
@ -280,26 +149,13 @@ impl HWRev {
#[derive(Serialize)] #[derive(Serialize)]
pub struct FanSummary { pub struct FanSummary {
fan_pwm: u32, fan_pwm: u32,
tacho: u32,
abs_max_tec_i: f64, abs_max_tec_i: f64,
auto_mode: bool, auto_mode: bool,
status: FanStatus,
k_a: f64, k_a: f64,
k_b: f64, k_b: f64,
k_c: f64, k_c: f64,
} }
impl FanStatus {
pub fn fmt_u8(&self) -> &'static [u8] {
match *self {
FanStatus::OK => "Fan is OK".as_bytes(),
FanStatus::NotAvailable => "Fan is not available".as_bytes(),
FanStatus::TooSlow => "Fan is too slow".as_bytes(),
FanStatus::Halted => "Fan is halted".as_bytes(),
}
}
}
#[cfg(test)] #[cfg(test)]
mod test { mod test {
use super::*; use super::*;

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@ -18,7 +18,6 @@ use stm32f4xx_hal::{
stm32::{CorePeripherals, Peripherals, SCB}, stm32::{CorePeripherals, Peripherals, SCB},
time::{U32Ext, MegaHertz}, time::{U32Ext, MegaHertz},
watchdog::IndependentWatchdog, watchdog::IndependentWatchdog,
syscfg::SysCfgExt
}; };
use smoltcp::{ use smoltcp::{
time::Instant, time::Instant,
@ -104,7 +103,7 @@ fn main() -> ! {
cp.SCB.enable_icache(); cp.SCB.enable_icache();
cp.SCB.enable_dcache(&mut cp.CPUID); cp.SCB.enable_dcache(&mut cp.CPUID);
let mut dp = Peripherals::take().unwrap(); let dp = Peripherals::take().unwrap();
let clocks = dp.RCC.constrain() let clocks = dp.RCC.constrain()
.cfgr .cfgr
.use_hse(HSE) .use_hse(HSE)
@ -120,7 +119,7 @@ fn main() -> ! {
timer::setup(cp.SYST, clocks); timer::setup(cp.SYST, clocks);
let (pins, mut leds, mut eeprom, eth_pins, usb, fan, tacho) = Pins::setup( let (pins, mut leds, mut eeprom, eth_pins, usb, fan) = Pins::setup(
clocks, dp.TIM1, dp.TIM3, dp.TIM8, clocks, dp.TIM1, dp.TIM3, dp.TIM8,
dp.GPIOA, dp.GPIOB, dp.GPIOC, dp.GPIOD, dp.GPIOE, dp.GPIOF, dp.GPIOG, dp.GPIOA, dp.GPIOB, dp.GPIOC, dp.GPIOD, dp.GPIOE, dp.GPIOF, dp.GPIOG,
dp.I2C1, dp.I2C1,
@ -151,7 +150,7 @@ fn main() -> ! {
} }
} }
let mut fan_ctrl = FanCtrl::new(fan, tacho, channels, &mut dp.EXTI, &mut dp.SYSCFG.constrain()); let mut fan_ctrl = FanCtrl::new(fan, channels);
// default net config: // default net config:
let mut ipv4_config = Ipv4Config { let mut ipv4_config = Ipv4Config {
esavkin marked this conversation as resolved Outdated
Outdated
Review

Highly suspicious. I doubt either mutex or unsafe is necessary.

Highly suspicious. I doubt either mutex or unsafe is necessary.
@ -186,7 +185,7 @@ fn main() -> ! {
server.for_each(|_, session| session.set_report_pending(channel.into())); server.for_each(|_, session| session.set_report_pending(channel.into()));
} }
let fan_status = fan_ctrl.cycle(); fan_ctrl.cycle();
let instant = Instant::from_millis(i64::from(timer::now())); let instant = Instant::from_millis(i64::from(timer::now()));
cortex_m::interrupt::free(net::clear_pending); cortex_m::interrupt::free(net::clear_pending);
@ -239,12 +238,6 @@ fn main() -> ! {
} }
} }
} }
match fan_status {
Ok(_) => {}
Err(status) => {
send_line(&mut socket, status.fmt_u8());
}
};
} }
}); });
} else { } else {

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@ -33,7 +33,7 @@ use stm32_eth::EthPins;
use crate::{ use crate::{
channel::{Channel0, Channel1}, channel::{Channel0, Channel1},
leds::Leds, leds::Leds,
fan_ctrl::{TachoPin, FanPin} fan_ctrl::FanPin
}; };
const PWM_FREQ: KiloHertz = KiloHertz(20u32); const PWM_FREQ: KiloHertz = KiloHertz(20u32);
@ -131,7 +131,7 @@ impl Pins {
spi2: SPI2, spi4: SPI4, spi5: SPI5, spi2: SPI2, spi4: SPI4, spi5: SPI5,
adc1: ADC1, adc1: ADC1,
otg_fs_global: OTG_FS_GLOBAL, otg_fs_device: OTG_FS_DEVICE, otg_fs_pwrclk: OTG_FS_PWRCLK, otg_fs_global: OTG_FS_GLOBAL, otg_fs_device: OTG_FS_DEVICE, otg_fs_pwrclk: OTG_FS_PWRCLK,
) -> (Self, Leds, Eeprom, EthernetPins, USB, FanPin, TachoPin) { ) -> (Self, Leds, Eeprom, EthernetPins, USB, FanPin) {
let gpioa = gpioa.split(); let gpioa = gpioa.split();
let gpiob = gpiob.split(); let gpiob = gpiob.split();
let gpioc = gpioc.split(); let gpioc = gpioc.split();
@ -228,9 +228,9 @@ impl Pins {
hclk: clocks.hclk(), hclk: clocks.hclk(),
}; };
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Review

G99 is not a PWM fan.

G99 is not a PWM fan.
let fan = Timer::new(tim8, &clocks).pwm(gpioc.pc9.into_alternate(), 20u32.khz()); let fan = Timer::new(tim8, &clocks).pwm(gpioc.pc9.into_alternate(), PWM_FREQ);
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Review

Advised where? All the SUNON docs say PWM on this fan model isn't supported at all.

Advised where? All the SUNON docs say PWM on this fan model isn't supported at all.
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Review

And what "higher frequency" are you talking about?

And what "higher frequency" are you talking about?
(pins, leds, eeprom, eth_pins, usb, fan, gpioc.pc8) (pins, leds, eeprom, eth_pins, usb, fan)
} }
/// Configure the GPIO pins for SPI operation, and initialize SPI /// Configure the GPIO pins for SPI operation, and initialize SPI
@ -342,7 +342,7 @@ impl PwmPins {
PwmPins { PwmPins {
max_v0, max_v1, max_v0, max_v1,
max_i_pos0, max_i_pos1, max_i_pos0, max_i_pos1,
max_i_neg0, max_i_neg1 max_i_neg0, max_i_neg1,
} }
} }
} }