use stm32_metapac::flash::vals::Latency; use stm32_metapac::rcc::vals::{Hpre, Pllsrc, Ppre, Sw}; use stm32_metapac::FLASH; pub use super::common::{AHBPrescaler, APBPrescaler}; use crate::pac::{PWR, RCC}; use crate::rcc::sealed::RccPeripheral; use crate::rcc::{set_freqs, Clocks}; use crate::time::Hertz; /// HSI speed pub const HSI_FREQ: Hertz = Hertz(16_000_000); /// LSI speed pub const LSI_FREQ: Hertz = Hertz(32_000); /// System clock mux source #[derive(Clone, Copy)] pub enum ClockSrc { HSE(Hertz), HSI16, PLL, } impl Into for APBPrescaler { fn into(self) -> u8 { match self { PllSrc::HSE(..) => Pllsrc::HSE, PllSrc::HSI16 => Pllsrc::HSI16, } } } seq_macro::seq!(P in 2..=31 { /// Output divider for the PLL P output. #[derive(Clone, Copy)] pub enum PllP { // Note: If PLL P is set to 0 the PLLP bit controls the output division. There does not seem to // a good reason to do this so the API does not support it. // Div1 is invalid #( Div~P, )* } impl From for u8 { /// Returns the register value for the P output divider. fn from(val: PllP) -> u8 { match val { #( PllP::Div~P => P, )* } } } }); impl PllP { /// Returns the numeric value of the P output divider. pub fn to_div(self) -> u32 { let val: u8 = self.into(); val as u32 } } /// Output divider for the PLL Q output. #[derive(Clone, Copy)] pub enum PllQ { Div2, Div4, Div6, Div8, } impl PllQ { /// Returns the numeric value of the Q output divider. pub fn to_div(self) -> u32 { let val: u8 = self.into(); (val as u32 + 1) * 2 } } impl From for u8 { /// Returns the register value for the Q output divider. fn from(val: PllQ) -> u8 { match val { PllQ::Div2 => 0b00, PllQ::Div4 => 0b01, PllQ::Div6 => 0b10, PllQ::Div8 => 0b11, } } } /// Output divider for the PLL R output. #[derive(Clone, Copy)] pub enum PllR { Div2, Div4, Div6, Div8, } impl PllR { /// Returns the numeric value of the R output divider. pub fn to_div(self) -> u32 { let val: u8 = self.into(); (val as u32 + 1) * 2 } } impl From for u8 { /// Returns the register value for the R output divider. fn from(val: PllR) -> u8 { match val { PllR::Div2 => 0b00, PllR::Div4 => 0b01, PllR::Div6 => 0b10, PllR::Div8 => 0b11, } } } seq_macro::seq!(N in 8..=127 { /// Multiplication factor for the PLL VCO input clock. #[derive(Clone, Copy)] pub enum PllN { #( Mul~N, )* } impl From for u8 { /// Returns the register value for the N multiplication factor. fn from(val: PllN) -> u8 { match val { #( PllN::Mul~N => N, )* } } } impl PllN { /// Returns the numeric value of the N multiplication factor. pub fn to_mul(self) -> u32 { match self { #( PllN::Mul~N => N, )* } } } }); /// PLL Pre-division. This must be set such that the PLL input is between 2.66 MHz and 16 MHz. #[derive(Copy, Clone)] pub enum PllM { Div1, Div2, Div3, Div4, Div5, Div6, Div7, Div8, Div9, Div10, Div11, Div12, Div13, Div14, Div15, Div16, } impl PllM { /// Returns the numeric value of the M pre-division. pub fn to_div(self) -> u32 { let val: u8 = self.into(); val as u32 + 1 } } impl From for u8 { /// Returns the register value for the M pre-division. fn from(val: PllM) -> u8 { match val { PllM::Div1 => 0b0000, PllM::Div2 => 0b0001, PllM::Div3 => 0b0010, PllM::Div4 => 0b0011, PllM::Div5 => 0b0100, PllM::Div6 => 0b0101, PllM::Div7 => 0b0110, PllM::Div8 => 0b0111, PllM::Div9 => 0b1000, PllM::Div10 => 0b1001, PllM::Div11 => 0b1010, PllM::Div12 => 0b1011, PllM::Div13 => 0b1100, PllM::Div14 => 0b1101, PllM::Div15 => 0b1110, PllM::Div16 => 0b1111, } } } /// PLL Configuration /// /// Use this struct to configure the PLL source, input frequency, multiplication factor, and output /// dividers. Be sure to keep check the datasheet for your specific part for the appropriate /// frequency ranges for each of these settings. pub struct Pll { /// PLL Source clock selection. pub source: PllSrc, /// PLL pre-divider pub prediv_m: PllM, /// PLL multiplication factor for VCO pub mul_n: PllN, /// PLL division factor for P clock (ADC Clock) pub div_p: Option, /// PLL division factor for Q clock (USB, I2S23, SAI1, FDCAN, QSPI) pub div_q: Option, /// PLL division factor for R clock (SYSCLK) pub div_r: Option, } impl AHBPrescaler { const fn div(self) -> u32 { match self { AHBPrescaler::NotDivided => 1, AHBPrescaler::Div2 => 2, AHBPrescaler::Div4 => 4, AHBPrescaler::Div8 => 8, AHBPrescaler::Div16 => 16, AHBPrescaler::Div64 => 64, AHBPrescaler::Div128 => 128, AHBPrescaler::Div256 => 256, AHBPrescaler::Div512 => 512, } } } impl APBPrescaler { const fn div(self) -> u32 { match self { APBPrescaler::NotDivided => 1, APBPrescaler::Div2 => 2, APBPrescaler::Div4 => 4, APBPrescaler::Div8 => 8, APBPrescaler::Div16 => 16, } } } impl Into for APBPrescaler { fn into(self) -> Ppre { match self { APBPrescaler::NotDivided => Ppre::DIV1, APBPrescaler::Div2 => Ppre::DIV2, APBPrescaler::Div4 => Ppre::DIV4, APBPrescaler::Div8 => Ppre::DIV8, APBPrescaler::Div16 => Ppre::DIV16, } } } impl Into for AHBPrescaler { fn into(self) -> Hpre { match self { AHBPrescaler::NotDivided => Hpre::DIV1, AHBPrescaler::Div2 => Hpre::DIV2, AHBPrescaler::Div4 => Hpre::DIV4, AHBPrescaler::Div8 => Hpre::DIV8, AHBPrescaler::Div16 => Hpre::DIV16, AHBPrescaler::Div64 => Hpre::DIV64, AHBPrescaler::Div128 => Hpre::DIV128, AHBPrescaler::Div256 => Hpre::DIV256, AHBPrescaler::Div512 => Hpre::DIV512, } } } /// Sets the source for the 48MHz clock to the USB and RNG peripherals. pub enum Clock48MhzSrc { /// Use the High Speed Internal Oscillator. For USB usage, the CRS must be used to calibrate the /// oscillator to comply with the USB specification for oscillator tolerance. Hsi48(Option), /// Use the PLLQ output. The PLL must be configured to output a 48MHz clock. For USB usage the /// PLL needs to be using the HSE source to comply with the USB specification for oscillator /// tolerance. PllQ, } /// Sets the sync source for the Clock Recovery System (CRS). pub enum CrsSyncSource { /// Use an external GPIO to sync the CRS. Gpio, /// Use the Low Speed External oscillator to sync the CRS. Lse, /// Use the USB SOF to sync the CRS. Usb, } /// Clocks configutation pub struct Config { pub mux: ClockSrc, pub ahb_pre: AHBPrescaler, pub apb1_pre: APBPrescaler, pub apb2_pre: APBPrescaler, pub low_power_run: bool, /// Iff PLL is requested as the main clock source in the `mux` field then the PLL configuration /// MUST turn on the PLLR output. pub pll: Option, /// Sets the clock source for the 48MHz clock used by the USB and RNG peripherals. pub clock_48mhz_src: Option, } /// Configuration for the Clock Recovery System (CRS) used to trim the HSI48 oscillator. pub struct CrsConfig { /// Sync source for the CRS. pub sync_src: CrsSyncSource, } impl Default for Config { #[inline] fn default() -> Config { Config { mux: ClockSrc::HSI16, ahb_pre: AHBPrescaler::NotDivided, apb1_pre: APBPrescaler::NotDivided, apb2_pre: APBPrescaler::NotDivided, low_power_run: false, pll: None, clock_48mhz_src: None, } } } pub struct PllFreq { pub pll_p: Option, pub pll_q: Option, pub pll_r: Option, } pub(crate) unsafe fn init(config: Config) { let pll_freq = config.pll.map(|pll_config| { let src_freq = match pll_config.source { PllSrc::HSI16 => { RCC.cr().write(|w| w.set_hsion(true)); while !RCC.cr().read().hsirdy() {} HSI_FREQ.0 } PllSrc::HSE(freq) => { RCC.cr().write(|w| w.set_hseon(true)); while !RCC.cr().read().hserdy() {} freq.0 } }; // Disable PLL before configuration RCC.cr().modify(|w| w.set_pllon(false)); while RCC.cr().read().pllrdy() {} let internal_freq = src_freq / pll_config.prediv_m.to_div() * pll_config.mul_n.to_mul(); RCC.pllcfgr().write(|w| { w.set_plln(pll_config.mul_n.into()); w.set_pllm(pll_config.prediv_m.into()); w.set_pllsrc(pll_config.source.into()); }); let pll_p_freq = pll_config.div_p.map(|div_p| { RCC.pllcfgr().modify(|w| { w.set_pllpdiv(div_p.into()); w.set_pllpen(true); }); Hertz(internal_freq / div_p.to_div()) }); let pll_q_freq = pll_config.div_q.map(|div_q| { RCC.pllcfgr().modify(|w| { w.set_pllq(div_q.into()); w.set_pllqen(true); }); Hertz(internal_freq / div_q.to_div()) }); let pll_r_freq = pll_config.div_r.map(|div_r| { RCC.pllcfgr().modify(|w| { w.set_pllr(div_r.into()); w.set_pllren(true); }); Hertz(internal_freq / div_r.to_div()) }); // Enable the PLL RCC.cr().modify(|w| w.set_pllon(true)); while !RCC.cr().read().pllrdy() {} PllFreq { pll_p: pll_p_freq, pll_q: pll_q_freq, pll_r: pll_r_freq, } }); let (sys_clk, sw) = match config.mux { ClockSrc::HSI16 => { // Enable HSI16 RCC.cr().write(|w| w.set_hsion(true)); while !RCC.cr().read().hsirdy() {} (HSI_FREQ.0, Sw::HSI16) } ClockSrc::HSE(freq) => { // Enable HSE RCC.cr().write(|w| w.set_hseon(true)); while !RCC.cr().read().hserdy() {} (freq.0, Sw::HSE) } ClockSrc::PLL => { assert!(pll_freq.is_some()); assert!(pll_freq.as_ref().unwrap().pll_r.is_some()); let freq = pll_freq.as_ref().unwrap().pll_r.unwrap().0; assert!(freq <= 170_000_000); if freq >= 150_000_000 { // Enable Core Boost mode on freq >= 150Mhz ([RM0440] p234) PWR.cr5().modify(|w| w.set_r1mode(false)); // Set flash wait state in boost mode based on frequency ([RM0440] p191) if freq <= 36_000_000 { FLASH.acr().modify(|w| w.set_latency(Latency::WS0)); } else if freq <= 68_000_000 { FLASH.acr().modify(|w| w.set_latency(Latency::WS1)); } else if freq <= 102_000_000 { FLASH.acr().modify(|w| w.set_latency(Latency::WS2)); } else if freq <= 136_000_000 { FLASH.acr().modify(|w| w.set_latency(Latency::WS3)); } else { FLASH.acr().modify(|w| w.set_latency(Latency::WS4)); } } else { PWR.cr5().modify(|w| w.set_r1mode(true)); // Set flash wait state in normal mode based on frequency ([RM0440] p191) if freq <= 30_000_000 { FLASH.acr().modify(|w| w.set_latency(Latency::WS0)); } else if freq <= 60_000_000 { FLASH.acr().modify(|w| w.set_latency(Latency::WS1)); } else if freq <= 80_000_000 { FLASH.acr().modify(|w| w.set_latency(Latency::WS2)); } else if freq <= 120_000_000 { FLASH.acr().modify(|w| w.set_latency(Latency::WS3)); } else { FLASH.acr().modify(|w| w.set_latency(Latency::WS4)); } } (freq, Sw::PLLRCLK) } }; RCC.cfgr().modify(|w| { w.set_sw(sw); w.set_hpre(config.ahb_pre.into()); w.set_ppre1(config.apb1_pre.into()); w.set_ppre2(config.apb2_pre.into()); }); let ahb_freq: u32 = match config.ahb_pre { AHBPrescaler::NotDivided => sys_clk, pre => sys_clk / pre.div(), }; let (apb1_freq, apb1_tim_freq) = match config.apb1_pre { APBPrescaler::NotDivided => (ahb_freq, ahb_freq), pre => { let freq = ahb_freq / pre.div(); (freq, freq * 2) } }; let (apb2_freq, apb2_tim_freq) = match config.apb2_pre { APBPrescaler::NotDivided => (ahb_freq, ahb_freq), pre => { let freq = ahb_freq / pre.div(); (freq, freq * 2) } }; // Setup the 48 MHz clock if needed if let Some(clock_48mhz_src) = config.clock_48mhz_src { let source = match clock_48mhz_src { Clock48MhzSrc::PllQ => { // Make sure the PLLQ is enabled and running at 48Mhz let pllq_freq = pll_freq.as_ref().and_then(|f| f.pll_q); assert!(pllq_freq.is_some() && pllq_freq.unwrap().0 == 48_000_000); crate::pac::rcc::vals::Clk48sel::PLLQCLK } Clock48MhzSrc::Hsi48(crs_config) => { // Enable HSI48 RCC.crrcr().modify(|w| w.set_hsi48on(true)); // Wait for HSI48 to turn on while RCC.crrcr().read().hsi48rdy() == false {} // Enable and setup CRS if needed if let Some(crs_config) = crs_config { crate::peripherals::CRS::enable(); let sync_src = match crs_config.sync_src { CrsSyncSource::Gpio => crate::pac::crs::vals::Syncsrc::GPIO, CrsSyncSource::Lse => crate::pac::crs::vals::Syncsrc::LSE, CrsSyncSource::Usb => crate::pac::crs::vals::Syncsrc::USB, }; crate::pac::CRS.cfgr().modify(|w| { w.set_syncsrc(sync_src); }); // These are the correct settings for standard USB operation. If other settings // are needed there will need to be additional config options for the CRS. crate::pac::CRS.cr().modify(|w| { w.set_autotrimen(true); w.set_cen(true); }); } crate::pac::rcc::vals::Clk48sel::HSI48 } }; RCC.ccipr().modify(|w| w.set_clk48sel(source)); } if config.low_power_run { assert!(sys_clk <= 2_000_000); PWR.cr1().modify(|w| w.set_lpr(true)); } set_freqs(Clocks { sys: Hertz(sys_clk), ahb1: Hertz(ahb_freq), ahb2: Hertz(ahb_freq), apb1: Hertz(apb1_freq), apb1_tim: Hertz(apb1_tim_freq), apb2: Hertz(apb2_freq), apb2_tim: Hertz(apb2_tim_freq), }); }