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stm32: u5: implement >55 MHz clock speeds

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This commit allows STM32U5 devices to operate at 160 MHz.

On STM32U5, MSIS can run at 48 MHz and HSE can reach 50 MHz. Faster
clocks require using PLL1's R output, though PLL1 can serve other
functions besides using the R output for the system clock. This commit
extracts a public `PllConfig` struct, primarily to place associated
constructors on that type, but also with an eye towards enabling the P
and Q outputs in a later commit.

STM32U5 PLLs have various frequency requirements on each stage: after
the `m` prescaler, after the `n` multiplier, and after the `r` divider.
This commit implements the associated checks as assertions.

This commit fixes clock calculation and PLL register configuration
errors in PLL initialization.

STM32U5 has a PWR peripheral which can be configured to push Vcore into
different voltage ranges. System clocks exceeding 55 MHz require range
2, and system clocks exceeding 110 MHz require range 1. This commit
adds `voltage_range` to `Config` and configures PWR as directed.

The voltage range implies different performance limits on various clock
signals, including inside a PLL. This commit implements voltage range
<-> frequency range checks as assertions, and extracts the
otherwise-repeated MSIS, HSI16, and HSE initialization into private
methods on `Config`.

STM32U5 frequencies above 55 MHz require using the PWR EPOD booster.
The EPOD booster requires configuring a second `m` term for PLL1,
`mboost`, such that it falls in a particular range. (Recall that >50
MHz cannot be reached without PLL1, so there is no scenario where EPOD
is needed but PLL1 is not.) This commit configures and enables the EPOD
booster automatically as required.
This commit is contained in:
Will Glynn 2023-10-05 22:05:05 -05:00
parent 65ed19aae2
commit 38e7709a24
2 changed files with 274 additions and 93 deletions
Show Stats Download Patch File Download Diff File Expand all files Collapse all files

360
embassy-stm32/src/rcc/u5.rs
View File

@ -1,7 +1,7 @@
use stm32_metapac::rcc::vals::{Msirange, Msirgsel, Pllm, Pllsrc, Sw};
use stm32_metapac::rcc::vals::{Msirange, Msirgsel, Pllm, Pllmboost, Pllrge, Pllsrc, Sw};
pub use super::bus::{AHBPrescaler, APBPrescaler};
use crate::pac::{FLASH, RCC};
use crate::pac::{FLASH, PWR, RCC};
use crate::rcc::{set_freqs, Clocks};
use crate::time::Hertz;
@ -15,23 +15,86 @@ pub use crate::pac::pwr::vals::Vos as VoltageScale;
#[derive(Copy, Clone)]
pub enum ClockSrc {
/// Use an internal medium speed oscillator (MSIS) as the system clock.
MSI(MSIRange),
/// Use the external high speed clock as the system clock.
///
/// HSE clocks faster than 25 MHz require at least `VoltageScale::RANGE3`, and HSE clocks must
/// never exceed 50 MHz.
HSE(Hertz),
/// Use the 16 MHz internal high speed oscillator as the system clock.
HSI16,
PLL1R(PllSrc, PllM, PllN, PllClkDiv),
/// Use PLL1 as the system clock.
PLL1R(PllConfig),
}
impl Default for ClockSrc {
fn default() -> Self {
// The default system clock source is MSIS @ 4 MHz, per RM0456 § 11.4.9
ClockSrc::MSI(MSIRange::Range4mhz)
}
}
#[derive(Clone, Copy, Debug)]
pub struct PllConfig {
/// The clock source for the PLL.
pub source: PllSrc,
/// The PLL prescaler.
///
/// The clock speed of the `source` divided by `m` must be between 4 and 16 MHz.
pub m: PllM,
/// The PLL multiplier.
///
/// The multiplied clock `source` divided by `m` times `n` must be between 128 and 544
/// MHz. The upper limit may be lower depending on the `Config { voltage_range }`.
pub n: PllN,
/// The divider for the R output.
///
/// When used to drive the system clock, `source` divided by `m` times `n` divided by `r`
/// must not exceed 160 MHz. System clocks above 55 MHz require a non-default
/// `Config { voltage_range }`.
pub r: PllClkDiv,
}
impl PllConfig {
/// A configuration for HSI16 / 1 * 10 / 1 = 160 MHz
pub const fn hsi16_160mhz() -> Self {
PllConfig {
source: PllSrc::HSI16,
m: PllM::NotDivided,
n: PllN::Mul10,
r: PllClkDiv::NotDivided,
}
}
/// A configuration for MSIS @ 48 MHz / 3 * 10 / 1 = 160 MHz
pub const fn msis_160mhz() -> Self {
PllConfig {
source: PllSrc::MSIS(MSIRange::Range48mhz),
m: PllM::Div3,
n: PllN::Mul10,
r: PllClkDiv::NotDivided,
}
}
}
#[derive(Clone, Copy, Debug)]
pub enum PllSrc {
MSI(MSIRange),
/// Use an internal medium speed oscillator as the PLL source.
MSIS(MSIRange),
/// Use the external high speed clock as the system PLL source.
///
/// HSE clocks faster than 25 MHz require at least `VoltageScale::RANGE3`, and HSE clocks must
/// never exceed 50 MHz.
HSE(Hertz),
/// Use the 16 MHz internal high speed oscillator as the PLL source.
HSI16,
}
impl Into<Pllsrc> for PllSrc {
fn into(self) -> Pllsrc {
match self {
PllSrc::MSI(..) => Pllsrc::MSIS,
PllSrc::MSIS(..) => Pllsrc::MSIS,
PllSrc::HSE(..) => Pllsrc::HSE,
PllSrc::HSI16 => Pllsrc::HSI16,
}
@ -41,57 +104,45 @@ impl Into<Pllsrc> for PllSrc {
seq_macro::seq!(N in 2..=128 {
#[derive(Copy, Clone, Debug)]
pub enum PllClkDiv {
NotDivided,
NotDivided = 1,
#(
Div~N = (N-1),
Div~N = N,
)*
}
impl PllClkDiv {
fn to_div(&self) -> u8 {
match self {
PllClkDiv::NotDivided => 1,
PllClkDiv::NotDivided => 0,
#(
PllClkDiv::Div~N => N + 1,
PllClkDiv::Div~N => N - 1,
)*
}
}
}
});
impl Into<u8> for PllClkDiv {
fn into(self) -> u8 {
(self as u8) + 1
}
}
seq_macro::seq!(N in 4..=512 {
#[derive(Copy, Clone, Debug)]
pub enum PllN {
NotMultiplied,
NotMultiplied = 1,
#(
Mul~N = N-1,
Mul~N = N,
)*
}
impl PllN {
fn to_mul(&self) -> u16 {
match self {
PllN::NotMultiplied => 1,
PllN::NotMultiplied => 0,
#(
PllN::Mul~N => N + 1,
PllN::Mul~N => N - 1,
)*
}
}
}
});
impl Into<u16> for PllN {
fn into(self) -> u16 {
(self as u16) + 1
}
}
// Pre-division
#[derive(Copy, Clone, Debug)]
pub enum PllM {
@ -132,6 +183,7 @@ impl Into<Sw> for ClockSrc {
#[derive(Debug, Copy, Clone)]
pub enum MSIRange {
/// The 48 MHz MSI speed is unavailable in `VoltageScale::RANGE4`.
Range48mhz = 48_000_000,
Range24mhz = 24_000_000,
Range16mhz = 16_000_000,
@ -179,12 +231,6 @@ impl Into<Msirange> for MSIRange {
}
}
impl Default for MSIRange {
fn default() -> Self {
MSIRange::Range4mhz
}
}
#[derive(Copy, Clone)]
pub struct Config {
pub mux: ClockSrc,
@ -193,103 +239,220 @@ pub struct Config {
pub apb2_pre: APBPrescaler,
pub apb3_pre: APBPrescaler,
pub hsi48: bool,
/// The voltage range influences the maximum clock frequencies for different parts of the
/// device. In particular, system clocks exceeding 110 MHz require `RANGE1`, and system clocks
/// exceeding 55 MHz require at least `RANGE2`.
///
/// See RM0456 § 10.5.4 for a general overview and § 11.4.10 for clock source frequency limits.
pub voltage_range: VoltageScale,
}
impl Config {
unsafe fn init_hsi16(&self) -> Hertz {
RCC.cr().write(|w| w.set_hsion(true));
while !RCC.cr().read().hsirdy() {}
HSI_FREQ
}
unsafe fn init_hse(&self, frequency: Hertz) -> Hertz {
// Check frequency limits per RM456 § 11.4.10
match self.voltage_range {
VoltageScale::RANGE1 | VoltageScale::RANGE2 | VoltageScale::RANGE3 => {
assert!(frequency.0 <= 50_000_000);
}
VoltageScale::RANGE4 => {
assert!(frequency.0 <= 25_000_000);
}
}
// Enable HSE, and wait for it to stabilize
RCC.cr().write(|w| w.set_hseon(true));
while !RCC.cr().read().hserdy() {}
frequency
}
unsafe fn init_msis(&self, range: MSIRange) -> Hertz {
// Check MSI output per RM0456 § 11.4.10
match self.voltage_range {
VoltageScale::RANGE4 => {
assert!(range as u32 <= 24_000_000);
}
_ => {}
}
// RM0456 § 11.8.2: spin until MSIS is off or MSIS is ready before setting its range
loop {
let cr = RCC.cr().read();
if cr.msison() == false || cr.msisrdy() == true {
break;
}
}
RCC.icscr1().modify(|w| {
let bits: Msirange = range.into();
w.set_msisrange(bits);
w.set_msirgsel(Msirgsel::RCC_ICSCR1);
});
RCC.cr().write(|w| {
w.set_msipllen(false);
w.set_msison(true);
});
while !RCC.cr().read().msisrdy() {}
Hertz(range as u32)
}
}
impl Default for Config {
fn default() -> Self {
Self {
mux: ClockSrc::MSI(MSIRange::default()),
mux: ClockSrc::default(),
ahb_pre: AHBPrescaler::DIV1,
apb1_pre: APBPrescaler::DIV1,
apb2_pre: APBPrescaler::DIV1,
apb3_pre: APBPrescaler::DIV1,
hsi48: false,
voltage_range: VoltageScale::RANGE3,
}
}
}
pub(crate) unsafe fn init(config: Config) {
// Ensure PWR peripheral clock is enabled
RCC.ahb3enr().modify(|w| {
w.set_pwren(true);
});
RCC.ahb3enr().read(); // synchronize
// Set the requested power mode
PWR.vosr().modify(|w| {
w.set_vos(config.voltage_range);
});
while !PWR.vosr().read().vosrdy() {}
let sys_clk = match config.mux {
ClockSrc::MSI(range) => {
RCC.icscr1().modify(|w| {
let bits: Msirange = range.into();
w.set_msisrange(bits);
w.set_msirgsel(Msirgsel::RCC_ICSCR1);
});
RCC.cr().write(|w| {
w.set_msipllen(false);
w.set_msison(true);
});
while !RCC.cr().read().msisrdy() {}
range.into()
}
ClockSrc::HSE(freq) => {
RCC.cr().write(|w| w.set_hseon(true));
while !RCC.cr().read().hserdy() {}
freq.0
}
ClockSrc::HSI16 => {
RCC.cr().write(|w| w.set_hsion(true));
while !RCC.cr().read().hsirdy() {}
HSI_FREQ.0
}
ClockSrc::PLL1R(src, m, n, div) => {
let freq = match src {
PllSrc::MSI(_) => {
// TODO: enable MSI
MSIRange::default().into()
}
PllSrc::HSE(hertz) => {
// TODO: enable HSE
hertz.0
}
PllSrc::HSI16 => {
RCC.cr().write(|w| w.set_hsion(true));
while !RCC.cr().read().hsirdy() {}
HSI_FREQ.0
}
ClockSrc::MSI(range) => config.init_msis(range),
ClockSrc::HSE(freq) => config.init_hse(freq),
ClockSrc::HSI16 => config.init_hsi16(),
ClockSrc::PLL1R(pll) => {
// Configure the PLL source
let source_clk = match pll.source {
PllSrc::MSIS(range) => config.init_msis(range),
PllSrc::HSE(hertz) => config.init_hse(hertz),
PllSrc::HSI16 => config.init_hsi16(),
};
// disable
// Calculate the reference clock, which is the source divided by m
let reference_clk = source_clk / (pll.m as u8 as u32 + 1);
// Check limits per RM0456 § 11.4.6
assert!(Hertz::mhz(4) <= reference_clk && reference_clk <= Hertz::mhz(16));
// Calculate the PLL1 VCO clock and PLL1 R output clock
let pll1_clk = reference_clk * (pll.n as u8 as u32);
let pll1r_clk = pll1_clk / (pll.r as u8 as u32);
// Check system clock per RM0456 § 11.4.9
assert!(pll1r_clk <= Hertz::mhz(160));
// Check PLL clocks per RM0456 § 11.4.10
match config.voltage_range {
VoltageScale::RANGE1 => {
assert!(pll1_clk >= Hertz::mhz(128) && pll1_clk <= Hertz::mhz(544));
assert!(pll1r_clk <= Hertz::mhz(208));
}
VoltageScale::RANGE2 => {
assert!(pll1_clk >= Hertz::mhz(128) && pll1_clk <= Hertz::mhz(544));
assert!(pll1r_clk <= Hertz::mhz(110));
}
VoltageScale::RANGE3 => {
assert!(pll1_clk >= Hertz::mhz(128) && pll1_clk <= Hertz::mhz(330));
assert!(pll1r_clk <= Hertz::mhz(55));
}
VoltageScale::RANGE4 => {
panic!("PLL is unavailable in voltage range 4");
}
}
// § 10.5.4: if we're targeting >= 55 MHz, we must configure PLL1MBOOST to a prescaler
// value that results in an output between 4 and 16 MHz for the PWR EPOD boost
let mboost = if pll1r_clk >= Hertz::mhz(55) {
// source_clk can be up to 50 MHz, so there's just a few cases:
if source_clk > Hertz::mhz(32) {
// Divide by 4, giving EPOD 8-12.5 MHz
Pllmboost::DIV4
} else if source_clk > Hertz::mhz(16) {
// Divide by 2, giving EPOD 8-16 MHz
Pllmboost::DIV2
} else {
// Bypass, giving EPOD 4-16 MHz
Pllmboost::BYPASS
}
} else {
// Nothing to do
Pllmboost::BYPASS
};
// Disable the PLL, and wait for it to disable
RCC.cr().modify(|w| w.set_pllon(0, false));
while RCC.cr().read().pllrdy(0) {}
let vco = freq * n as u8 as u32;
let pll_ck = vco / (div as u8 as u32 + 1);
// Configure the PLL
RCC.pll1cfgr().write(|w| {
w.set_pllm(m.into());
w.set_pllsrc(src.into());
// Configure PLL1 source and prescaler
w.set_pllsrc(pll.source.into());
w.set_pllm(pll.m.into());
// Configure PLL1 input frequncy range
let input_range = if reference_clk <= Hertz::mhz(8) {
Pllrge::FREQ_4TO8MHZ
} else {
Pllrge::FREQ_8TO16MHZ
};
w.set_pllrge(input_range);
// Set the prescaler for PWR EPOD
w.set_pllmboost(mboost);
// Enable PLL1R output
w.set_pllren(true);
});
// Configure the PLL divisors
RCC.pll1divr().modify(|w| {
w.set_pllr(div.to_div());
w.set_plln(n.to_mul());
// Set the VCO multiplier
w.set_plln(pll.n.to_mul());
// Set the R output divisor
w.set_pllr(pll.r.to_div());
});
// Enable PLL
// Do we need the EPOD booster to reach the target clock speed per § 10.5.4?
if pll1r_clk >= Hertz::mhz(55) {
// Enable the booster
PWR.vosr().modify(|w| {
w.set_boosten(true);
});
while !PWR.vosr().read().boostrdy() {}
}
// Enable the PLL
RCC.cr().modify(|w| w.set_pllon(0, true));
while !RCC.cr().read().pllrdy(0) {}
pll_ck
pll1r_clk
}
};
}
.0;
if config.hsi48 {
RCC.cr().modify(|w| w.set_hsi48on(true));
while !RCC.cr().read().hsi48rdy() {}
}
// TODO make configurable
let power_vos = VoltageScale::RANGE3;
// states and programming delay
let wait_states = match power_vos {
// The clock source is ready
// Calculate and set the flash wait states
let wait_states = match config.voltage_range {
// VOS 1 range VCORE 1.26V - 1.40V
VoltageScale::RANGE1 => {
if sys_clk < 32_000_000 {
@ -335,21 +498,34 @@ pub(crate) unsafe fn init(config: Config) {
}
}
};
FLASH.acr().modify(|w| {
w.set_latency(wait_states);
});
// Switch the system clock source
RCC.cfgr1().modify(|w| {
w.set_sw(config.mux.into());
});
// RM0456 § 11.4.9 specifies maximum bus frequencies per voltage range, but the maximum bus
// frequency for each voltage range exactly matches the maximum permitted PLL output frequency.
// Given that:
//
// 1. Any bus frequency can never exceed the system clock frequency;
// 2. We checked the PLL output frequency if we're using it as a system clock;
// 3. The maximum HSE frequencies at each voltage range are lower than the bus limits, and
// we checked the HSE frequency if configured as a system clock; and
// 4. The maximum frequencies from the other clock sources are lower than the lowest bus
// frequency limit
//
// ...then we do not need to perform additional bus-related frequency checks.
// Configure the bus prescalers
RCC.cfgr2().modify(|w| {
w.set_hpre(config.ahb_pre.into());
w.set_ppre1(config.apb1_pre.into());
w.set_ppre2(config.apb2_pre.into());
});
RCC.cfgr3().modify(|w| {
w.set_ppre3(config.apb3_pre.into());
});

7
examples/stm32u5/src/bin/usb_serial.rs
View File

@ -23,7 +23,12 @@ async fn main(_spawner: Spawner) {
info!("Hello World!");
let mut config = Config::default();
config.rcc.mux = ClockSrc::PLL1R(PllSrc::HSI16, PllM::Div2, PllN::Mul10, PllClkDiv::NotDivided);
config.rcc.mux = ClockSrc::PLL1R(PllConfig {
source: PllSrc::HSI16,
m: PllM::Div2,
n: PllN::Mul10,
r: PllClkDiv::NotDivided,
});
//config.rcc.mux = ClockSrc::MSI(MSIRange::Range48mhz);
config.rcc.hsi48 = true;