use embassy_hal_common::{into_ref, PeripheralRef}; use pac::clocks::vals::*; use crate::{pac, reset, Peripheral}; // TODO fix terrible use of global here static mut XIN_HZ: u32 = 0; #[repr(u8)] #[non_exhaustive] #[derive(Clone, Copy, Debug, PartialEq, Eq)] pub enum PeriClkSrc { Sys = ClkPeriCtrlAuxsrc::CLK_SYS.0, PllSys = ClkPeriCtrlAuxsrc::CLKSRC_PLL_SYS.0, PllUsb = ClkPeriCtrlAuxsrc::CLKSRC_PLL_USB.0, Rosc = ClkPeriCtrlAuxsrc::ROSC_CLKSRC_PH.0, Xosc = ClkPeriCtrlAuxsrc::XOSC_CLKSRC.0, Gpin0 = ClkPeriCtrlAuxsrc::CLKSRC_GPIN0.0, Gpin1 = ClkPeriCtrlAuxsrc::CLKSRC_GPIN1.0, } #[non_exhaustive] pub struct ClockConfig { pub rosc: Option, pub xosc: Option, pub ref_clk: RefClkConfig, pub sys_clk: SysClkConfig, pub peri_clk_src: Option, pub usb_clk: Option, pub adc_clk: Option, pub rtc_clk: Option, } impl ClockConfig { pub fn crystal(crystal_hz: u32) -> Self { Self { rosc: Some(RoscConfig { range: RoscRange::Medium, drive_strength: [0; 8], div: 16, }), xosc: Some(XoscConfig { hz: crystal_hz, sys_pll: Some(PllConfig { refdiv: 1, fbdiv: 125, post_div1: 6, post_div2: 2, }), usb_pll: Some(PllConfig { refdiv: 1, fbdiv: 120, post_div1: 6, post_div2: 5, }), }), ref_clk: RefClkConfig { src: RefClkSrc::Xosc, div: 1, }, sys_clk: SysClkConfig { src: SysClkSrc::PllSys, div_int: 1, div_frac: 0, }, peri_clk_src: Some(PeriClkSrc::Sys), usb_clk: Some(UsbClkConfig { src: UsbClkSrc::PllUsb, div: 1, phase: 0, }), adc_clk: Some(AdcClkConfig { src: AdcClkSrc::PllUsb, div: 1, phase: 0, }), rtc_clk: Some(RtcClkConfig { src: RtcClkSrc::PllUsb, div_int: 1024, div_frac: 0, phase: 0, }), } } pub fn rosc() -> Self { Self { rosc: Some(RoscConfig { range: RoscRange::High, drive_strength: [0; 8], div: 1, }), xosc: None, ref_clk: RefClkConfig { src: RefClkSrc::Rosc, div: 1, }, sys_clk: SysClkConfig { src: SysClkSrc::Rosc, div_int: 1, div_frac: 0, }, peri_clk_src: Some(PeriClkSrc::Rosc), usb_clk: None, adc_clk: Some(AdcClkConfig { src: AdcClkSrc::Rosc, div: 1, phase: 0, }), rtc_clk: Some(RtcClkConfig { src: RtcClkSrc::Rosc, div_int: 1024, div_frac: 0, phase: 0, }), } } } #[repr(u16)] #[non_exhaustive] #[derive(Clone, Copy, Debug, PartialEq, Eq)] pub enum RoscRange { Low = pac::rosc::vals::FreqRange::LOW.0, Medium = pac::rosc::vals::FreqRange::MEDIUM.0, High = pac::rosc::vals::FreqRange::HIGH.0, TooHigh = pac::rosc::vals::FreqRange::TOOHIGH.0, } pub struct RoscConfig { pub range: RoscRange, pub drive_strength: [u8; 8], pub div: u16, } pub struct XoscConfig { pub hz: u32, pub sys_pll: Option, pub usb_pll: Option, } pub struct PllConfig { pub refdiv: u32, pub fbdiv: u16, pub post_div1: u8, pub post_div2: u8, } pub struct RefClkConfig { pub src: RefClkSrc, pub div: u8, } #[non_exhaustive] #[derive(Clone, Copy, Debug, PartialEq, Eq)] pub enum RefClkSrc { // main sources Xosc, Rosc, // aux sources PllUsb, Gpin0, Gpin1, } #[non_exhaustive] #[derive(Clone, Copy, Debug, PartialEq, Eq)] pub enum SysClkSrc { // main sources Ref, // aux sources PllSys, PllUsb, Rosc, Xosc, Gpin0, Gpin1, } pub struct SysClkConfig { pub src: SysClkSrc, pub div_int: u32, pub div_frac: u8, } #[repr(u8)] #[non_exhaustive] #[derive(Clone, Copy, Debug, PartialEq, Eq)] pub enum UsbClkSrc { PllUsb = ClkUsbCtrlAuxsrc::CLKSRC_PLL_USB.0, PllSys = ClkUsbCtrlAuxsrc::CLKSRC_PLL_SYS.0, Rosc = ClkUsbCtrlAuxsrc::ROSC_CLKSRC_PH.0, Xosc = ClkUsbCtrlAuxsrc::XOSC_CLKSRC.0, Gpin0 = ClkUsbCtrlAuxsrc::CLKSRC_GPIN0.0, Gpin1 = ClkUsbCtrlAuxsrc::CLKSRC_GPIN1.0, } pub struct UsbClkConfig { pub src: UsbClkSrc, pub div: u8, pub phase: u8, } #[repr(u8)] #[non_exhaustive] #[derive(Clone, Copy, Debug, PartialEq, Eq)] pub enum AdcClkSrc { PllUsb = ClkAdcCtrlAuxsrc::CLKSRC_PLL_USB.0, PllSys = ClkAdcCtrlAuxsrc::CLKSRC_PLL_SYS.0, Rosc = ClkAdcCtrlAuxsrc::ROSC_CLKSRC_PH.0, Xosc = ClkAdcCtrlAuxsrc::XOSC_CLKSRC.0, Gpin0 = ClkAdcCtrlAuxsrc::CLKSRC_GPIN0.0, Gpin1 = ClkAdcCtrlAuxsrc::CLKSRC_GPIN1.0, } pub struct AdcClkConfig { pub src: AdcClkSrc, pub div: u8, pub phase: u8, } #[repr(u8)] #[non_exhaustive] #[derive(Clone, Copy, Debug, PartialEq, Eq)] pub enum RtcClkSrc { PllUsb = ClkRtcCtrlAuxsrc::CLKSRC_PLL_USB.0, PllSys = ClkRtcCtrlAuxsrc::CLKSRC_PLL_SYS.0, Rosc = ClkRtcCtrlAuxsrc::ROSC_CLKSRC_PH.0, Xosc = ClkRtcCtrlAuxsrc::XOSC_CLKSRC.0, Gpin0 = ClkRtcCtrlAuxsrc::CLKSRC_GPIN0.0, Gpin1 = ClkRtcCtrlAuxsrc::CLKSRC_GPIN1.0, } pub struct RtcClkConfig { pub src: RtcClkSrc, pub div_int: u32, pub div_frac: u8, pub phase: u8, } /// safety: must be called exactly once at bootup pub(crate) unsafe fn init(config: ClockConfig) { // Reset everything except: // - QSPI (we're using it to run this code!) // - PLLs (it may be suicide if that's what's clocking us) // - USB, SYSCFG (breaks usb-to-swd on core1) let mut peris = reset::ALL_PERIPHERALS; peris.set_io_qspi(false); peris.set_pads_qspi(false); peris.set_pll_sys(false); peris.set_pll_usb(false); // TODO investigate if usb should be unreset here peris.set_usbctrl(false); peris.set_syscfg(false); reset::reset(peris); // Disable resus that may be enabled from previous software let c = pac::CLOCKS; c.clk_sys_resus_ctrl() .write_value(pac::clocks::regs::ClkSysResusCtrl(0)); // Before we touch PLLs, switch sys and ref cleanly away from their aux sources. c.clk_sys_ctrl().modify(|w| w.set_src(ClkSysCtrlSrc::CLK_REF)); while c.clk_sys_selected().read() != 1 {} c.clk_ref_ctrl().modify(|w| w.set_src(ClkRefCtrlSrc::ROSC_CLKSRC_PH)); while c.clk_ref_selected().read() != 1 {} // Reset the PLLs let mut peris = reset::Peripherals(0); peris.set_pll_sys(true); peris.set_pll_usb(true); reset::reset(peris); reset::unreset_wait(peris); if let Some(config) = config.rosc { configure_rosc(config); } if let Some(config) = config.xosc { XIN_HZ = config.hz; pac::WATCHDOG.tick().write(|w| { w.set_cycles((config.hz / 1_000_000) as u16); w.set_enable(true); }); // start XOSC // datasheet mentions support for clock inputs into XIN, but doesn't go into // how this is achieved. pico-sdk doesn't support this at all. start_xosc(config.hz); if let Some(sys_pll_config) = config.sys_pll { configure_pll(pac::PLL_SYS, config.hz, sys_pll_config); } if let Some(usb_pll_config) = config.usb_pll { configure_pll(pac::PLL_USB, config.hz, usb_pll_config); } } let (ref_src, ref_aux) = { use {ClkRefCtrlAuxsrc as Aux, ClkRefCtrlSrc as Src}; match config.ref_clk.src { RefClkSrc::Xosc => (Src::XOSC_CLKSRC, Aux::CLKSRC_PLL_USB), RefClkSrc::Rosc => (Src::ROSC_CLKSRC_PH, Aux::CLKSRC_PLL_USB), RefClkSrc::PllUsb => (Src::CLKSRC_CLK_REF_AUX, Aux::CLKSRC_PLL_USB), RefClkSrc::Gpin0 => (Src::CLKSRC_CLK_REF_AUX, Aux::CLKSRC_GPIN0), RefClkSrc::Gpin1 => (Src::CLKSRC_CLK_REF_AUX, Aux::CLKSRC_GPIN1), } }; c.clk_ref_ctrl().write(|w| { w.set_src(ref_src); w.set_auxsrc(ref_aux); }); while c.clk_ref_selected().read() != 1 << ref_src.0 {} c.clk_ref_div().write(|w| { w.set_int(config.ref_clk.div); }); pac::WATCHDOG.tick().write(|w| { w.set_cycles((clk_ref_freq() / 1_000_000) as u16); w.set_enable(true); }); let (sys_src, sys_aux) = { use {ClkSysCtrlAuxsrc as Aux, ClkSysCtrlSrc as Src}; match config.sys_clk.src { SysClkSrc::Ref => (Src::CLK_REF, Aux::CLKSRC_PLL_SYS), SysClkSrc::PllSys => (Src::CLKSRC_CLK_SYS_AUX, Aux::CLKSRC_PLL_SYS), SysClkSrc::PllUsb => (Src::CLKSRC_CLK_SYS_AUX, Aux::CLKSRC_PLL_USB), SysClkSrc::Rosc => (Src::CLKSRC_CLK_SYS_AUX, Aux::ROSC_CLKSRC), SysClkSrc::Xosc => (Src::CLKSRC_CLK_SYS_AUX, Aux::XOSC_CLKSRC), SysClkSrc::Gpin0 => (Src::CLKSRC_CLK_SYS_AUX, Aux::CLKSRC_GPIN0), SysClkSrc::Gpin1 => (Src::CLKSRC_CLK_SYS_AUX, Aux::CLKSRC_GPIN1), } }; if sys_src != ClkSysCtrlSrc::CLK_REF { c.clk_sys_ctrl().write(|w| w.set_src(ClkSysCtrlSrc::CLK_REF)); while c.clk_sys_selected().read() != 1 << ClkSysCtrlSrc::CLK_REF.0 {} } c.clk_sys_ctrl().write(|w| { w.set_auxsrc(sys_aux); w.set_src(sys_src); }); while c.clk_sys_selected().read() != 1 << sys_src.0 {} c.clk_sys_div().write(|w| { w.set_int(config.sys_clk.div_int); w.set_frac(config.sys_clk.div_frac); }); let mut peris = reset::ALL_PERIPHERALS; if let Some(src) = config.peri_clk_src { c.clk_peri_ctrl().write(|w| { w.set_enable(true); w.set_auxsrc(ClkPeriCtrlAuxsrc(src as _)); }); } else { peris.set_spi0(false); peris.set_spi1(false); peris.set_uart0(false); peris.set_uart1(false); } if let Some(conf) = config.usb_clk { // CLK USB = PLL USB (48MHz) / 1 = 48MHz c.clk_usb_div().write(|w| w.set_int(conf.div)); c.clk_usb_ctrl().write(|w| { w.set_phase(conf.phase); w.set_enable(true); w.set_auxsrc(ClkUsbCtrlAuxsrc(conf.src as _)); }); } else { peris.set_usbctrl(false); } if let Some(conf) = config.adc_clk { // CLK ADC = PLL USB (48MHZ) / 1 = 48MHz c.clk_adc_div().write(|w| w.set_int(conf.div)); c.clk_adc_ctrl().write(|w| { w.set_phase(conf.phase); w.set_enable(true); w.set_auxsrc(ClkAdcCtrlAuxsrc(conf.src as _)); }); } else { peris.set_adc(false); } if let Some(conf) = config.rtc_clk { // CLK RTC = PLL USB (48MHz) / 1024 = 46875Hz c.clk_rtc_ctrl().modify(|w| { w.set_enable(false); }); c.clk_rtc_div().write(|w| { w.set_int(conf.div_int); w.set_frac(conf.div_frac); }); c.clk_rtc_ctrl().write(|w| { w.set_phase(conf.phase); w.set_enable(true); w.set_auxsrc(ClkRtcCtrlAuxsrc(conf.src as _)); }); } else { peris.set_rtc(false); } // Peripheral clocks should now all be running reset::unreset_wait(peris); } unsafe fn configure_rosc(config: RoscConfig) { let p = pac::ROSC; p.freqa().write(|w| { w.set_passwd(pac::rosc::vals::Passwd::PASS); w.set_ds0(config.drive_strength[0]); w.set_ds1(config.drive_strength[1]); w.set_ds2(config.drive_strength[2]); w.set_ds3(config.drive_strength[3]); }); p.freqb().write(|w| { w.set_passwd(pac::rosc::vals::Passwd::PASS); w.set_ds4(config.drive_strength[4]); w.set_ds5(config.drive_strength[5]); w.set_ds6(config.drive_strength[6]); w.set_ds7(config.drive_strength[7]); }); p.div().write(|w| { w.set_div(pac::rosc::vals::Div(config.div + pac::rosc::vals::Div::PASS.0)); }); p.ctrl().write(|w| { w.set_enable(pac::rosc::vals::Enable::ENABLE); w.set_freq_range(pac::rosc::vals::FreqRange(config.range as u16)); }); } pub fn estimate_rosc_freq() -> u32 { let p = pac::ROSC; let base = match unsafe { p.ctrl().read().freq_range() } { pac::rosc::vals::FreqRange::LOW => 84_000_000, pac::rosc::vals::FreqRange::MEDIUM => 104_000_000, pac::rosc::vals::FreqRange::HIGH => 140_000_000, pac::rosc::vals::FreqRange::TOOHIGH => 208_000_000, _ => unreachable!(), }; let mut div = unsafe { p.div().read().0 - pac::rosc::vals::Div::PASS.0 as u32 }; if div == 0 { div = 32 } base / div } pub fn xosc_freq() -> u32 { unsafe { XIN_HZ } } pub fn gpin0_freq() -> u32 { todo!() } pub fn gpin1_freq() -> u32 { todo!() } pub fn pll_sys_freq() -> u32 { let p = pac::PLL_SYS; let input_freq = xosc_freq(); let cs = unsafe { p.cs().read() }; let refdiv = cs.refdiv() as u32; let fbdiv = unsafe { p.fbdiv_int().read().fbdiv_int() } as u32; let (postdiv1, postdiv2) = unsafe { let prim = p.prim().read(); (prim.postdiv1() as u32, prim.postdiv2() as u32) }; (((input_freq / refdiv) * fbdiv) / postdiv1) / postdiv2 } pub fn pll_usb_freq() -> u32 { let p = pac::PLL_USB; let input_freq = xosc_freq(); let cs = unsafe { p.cs().read() }; let refdiv = cs.refdiv() as u32; let fbdiv = unsafe { p.fbdiv_int().read().fbdiv_int() } as u32; let (postdiv1, postdiv2) = unsafe { let prim = p.prim().read(); (prim.postdiv1() as u32, prim.postdiv2() as u32) }; (((input_freq / refdiv) * fbdiv) / postdiv1) / postdiv2 } pub fn clk_sys_freq() -> u32 { let c = pac::CLOCKS; let ctrl = unsafe { c.clk_sys_ctrl().read() }; let base = match ctrl.src() { ClkSysCtrlSrc::CLK_REF => clk_ref_freq(), ClkSysCtrlSrc::CLKSRC_CLK_SYS_AUX => match ctrl.auxsrc() { ClkSysCtrlAuxsrc::CLKSRC_PLL_SYS => pll_sys_freq(), ClkSysCtrlAuxsrc::CLKSRC_PLL_USB => pll_usb_freq(), ClkSysCtrlAuxsrc::ROSC_CLKSRC => estimate_rosc_freq(), ClkSysCtrlAuxsrc::XOSC_CLKSRC => xosc_freq(), ClkSysCtrlAuxsrc::CLKSRC_GPIN0 => gpin0_freq(), ClkSysCtrlAuxsrc::CLKSRC_GPIN1 => gpin1_freq(), _ => unreachable!(), }, _ => unreachable!(), }; let div = unsafe { c.clk_sys_div().read() }; let int = if div.int() == 0 { 65536 } else { div.int() }; // TODO handle fractional clock div let _frac = div.frac(); base / int } pub fn clk_ref_freq() -> u32 { let c = pac::CLOCKS; let ctrl = unsafe { c.clk_ref_ctrl().read() }; let base = match ctrl.src() { ClkRefCtrlSrc::ROSC_CLKSRC_PH => estimate_rosc_freq(), ClkRefCtrlSrc::XOSC_CLKSRC => xosc_freq(), ClkRefCtrlSrc::CLKSRC_CLK_REF_AUX => match ctrl.auxsrc() { ClkRefCtrlAuxsrc::CLKSRC_PLL_USB => pll_usb_freq(), ClkRefCtrlAuxsrc::CLKSRC_GPIN0 => gpin0_freq(), ClkRefCtrlAuxsrc::CLKSRC_GPIN1 => gpin1_freq(), _ => unreachable!(), }, _ => unreachable!(), }; let div = unsafe { c.clk_ref_div().read() }; let int = if div.int() == 0 { 4 } else { div.int() as u32 }; base / int } pub fn clk_peri_freq() -> u32 { let c = pac::CLOCKS; let src = unsafe { c.clk_peri_ctrl().read().auxsrc() }; match src { ClkPeriCtrlAuxsrc::CLK_SYS => clk_sys_freq(), ClkPeriCtrlAuxsrc::CLKSRC_PLL_SYS => pll_sys_freq(), ClkPeriCtrlAuxsrc::CLKSRC_PLL_USB => pll_usb_freq(), ClkPeriCtrlAuxsrc::ROSC_CLKSRC_PH => estimate_rosc_freq(), ClkPeriCtrlAuxsrc::XOSC_CLKSRC => xosc_freq(), ClkPeriCtrlAuxsrc::CLKSRC_GPIN0 => gpin0_freq(), ClkPeriCtrlAuxsrc::CLKSRC_GPIN1 => gpin1_freq(), _ => unreachable!(), } } pub fn clk_usb_freq() -> u32 { let c = pac::CLOCKS; let ctrl = unsafe { c.clk_usb_ctrl().read() }; let base = match ctrl.auxsrc() { ClkUsbCtrlAuxsrc::CLKSRC_PLL_SYS => pll_sys_freq(), ClkUsbCtrlAuxsrc::CLKSRC_PLL_USB => pll_usb_freq(), ClkUsbCtrlAuxsrc::ROSC_CLKSRC_PH => estimate_rosc_freq(), ClkUsbCtrlAuxsrc::XOSC_CLKSRC => xosc_freq(), ClkUsbCtrlAuxsrc::CLKSRC_GPIN0 => gpin0_freq(), ClkUsbCtrlAuxsrc::CLKSRC_GPIN1 => gpin1_freq(), _ => unreachable!(), }; let div = unsafe { c.clk_ref_div().read() }; let int = if div.int() == 0 { 4 } else { div.int() as u32 }; base / int } pub fn clk_adc_freq() -> u32 { let c = pac::CLOCKS; let ctrl = unsafe { c.clk_adc_ctrl().read() }; let base = match ctrl.auxsrc() { ClkAdcCtrlAuxsrc::CLKSRC_PLL_SYS => pll_sys_freq(), ClkAdcCtrlAuxsrc::CLKSRC_PLL_USB => pll_usb_freq(), ClkAdcCtrlAuxsrc::ROSC_CLKSRC_PH => estimate_rosc_freq(), ClkAdcCtrlAuxsrc::XOSC_CLKSRC => xosc_freq(), ClkAdcCtrlAuxsrc::CLKSRC_GPIN0 => gpin0_freq(), ClkAdcCtrlAuxsrc::CLKSRC_GPIN1 => gpin1_freq(), _ => unreachable!(), }; let div = unsafe { c.clk_adc_div().read() }; let int = if div.int() == 0 { 4 } else { div.int() as u32 }; base / int } pub fn clk_rtc_freq() -> u32 { let c = pac::CLOCKS; let src = unsafe { c.clk_rtc_ctrl().read().auxsrc() }; let base = match src { ClkRtcCtrlAuxsrc::CLKSRC_PLL_USB => pll_usb_freq(), ClkRtcCtrlAuxsrc::CLKSRC_PLL_SYS => pll_sys_freq(), ClkRtcCtrlAuxsrc::ROSC_CLKSRC_PH => estimate_rosc_freq(), ClkRtcCtrlAuxsrc::XOSC_CLKSRC => xosc_freq(), ClkRtcCtrlAuxsrc::CLKSRC_GPIN0 => gpin0_freq(), ClkRtcCtrlAuxsrc::CLKSRC_GPIN1 => gpin1_freq(), _ => unreachable!(), }; let div = unsafe { c.clk_rtc_div().read() }; let int = if div.int() == 0 { 65536 } else { div.int() }; // TODO handle fractional clock div let _frac = div.frac(); base / int } unsafe fn start_xosc(crystal_hz: u32) { pac::XOSC .ctrl() .write(|w| w.set_freq_range(pac::xosc::vals::CtrlFreqRange::_1_15MHZ)); let startup_delay = ((crystal_hz / 1000) + 128) / 256; pac::XOSC.startup().write(|w| w.set_delay(startup_delay as u16)); pac::XOSC.ctrl().write(|w| { w.set_freq_range(pac::xosc::vals::CtrlFreqRange::_1_15MHZ); w.set_enable(pac::xosc::vals::Enable::ENABLE); }); while !pac::XOSC.status().read().stable() {} } #[inline(always)] unsafe fn configure_pll(p: pac::pll::Pll, input_freq: u32, config: PllConfig) { let ref_freq = input_freq / config.refdiv; assert!(config.fbdiv >= 16 && config.fbdiv <= 320); assert!(config.post_div1 >= 1 && config.post_div1 <= 7); assert!(config.post_div2 >= 1 && config.post_div2 <= 7); assert!(config.post_div2 <= config.post_div1); assert!(ref_freq >= 5_000_000 && ref_freq <= 800_000_000); // Load VCO-related dividers before starting VCO p.cs().write(|w| w.set_refdiv(config.refdiv as _)); p.fbdiv_int().write(|w| w.set_fbdiv_int(config.fbdiv)); // Turn on PLL p.pwr().modify(|w| { w.set_pd(false); w.set_vcopd(false); w.set_postdivpd(true); }); // Wait for PLL to lock while !p.cs().read().lock() {} // Wait for PLL to lock p.prim().write(|w| { w.set_postdiv1(config.post_div1); w.set_postdiv2(config.post_div2); }); // Turn on post divider p.pwr().modify(|w| w.set_postdivpd(false)); } pub trait GpinPin: crate::gpio::Pin { fn number(&self) -> usize; } macro_rules! impl_gpinpin { ($name:ident, $pin_num:expr, $gpin_num:expr) => { impl GpinPin for crate::peripherals::$name { fn number(&self) -> usize { $gpin_num } } }; } impl_gpinpin!(PIN_20, 20, 0); impl_gpinpin!(PIN_22, 22, 1); pub struct Gpin<'d, T: GpinPin> { gpin: PeripheralRef<'d, T>, } impl<'d, T: GpinPin> Gpin<'d, T> { pub fn new(gpin: impl Peripheral

+ 'd) -> Self { into_ref!(gpin); unsafe { gpin.io().ctrl().write(|w| w.set_funcsel(0x08)); } Self { gpin } } } impl<'d, T: GpinPin> Drop for Gpin<'d, T> { fn drop(&mut self) { unsafe { self.gpin .io() .ctrl() .write(|w| w.set_funcsel(pac::io::vals::Gpio0ctrlFuncsel::NULL.0)); } } } pub trait GpoutPin: crate::gpio::Pin { fn number(&self) -> usize; } macro_rules! impl_gpoutpin { ($name:ident, $gpout_num:expr) => { impl GpoutPin for crate::peripherals::$name { fn number(&self) -> usize { $gpout_num } } }; } impl_gpoutpin!(PIN_21, 0); impl_gpoutpin!(PIN_23, 1); impl_gpoutpin!(PIN_24, 2); impl_gpoutpin!(PIN_25, 3); #[repr(u8)] pub enum GpoutSrc { PllSys = ClkGpoutCtrlAuxsrc::CLKSRC_PLL_SYS.0, Gpin0 = ClkGpoutCtrlAuxsrc::CLKSRC_GPIN0.0, Gpin1 = ClkGpoutCtrlAuxsrc::CLKSRC_GPIN1.0, PllUsb = ClkGpoutCtrlAuxsrc::CLKSRC_PLL_USB.0, Rosc = ClkGpoutCtrlAuxsrc::ROSC_CLKSRC.0, Xosc = ClkGpoutCtrlAuxsrc::XOSC_CLKSRC.0, Sys = ClkGpoutCtrlAuxsrc::CLK_SYS.0, Usb = ClkGpoutCtrlAuxsrc::CLK_USB.0, Adc = ClkGpoutCtrlAuxsrc::CLK_ADC.0, Rtc = ClkGpoutCtrlAuxsrc::CLK_RTC.0, Ref = ClkGpoutCtrlAuxsrc::CLK_REF.0, } pub struct Gpout<'d, T: GpoutPin> { gpout: PeripheralRef<'d, T>, } impl<'d, T: GpoutPin> Gpout<'d, T> { pub fn new(gpout: impl Peripheral

+ 'd) -> Self { into_ref!(gpout); unsafe { gpout.io().ctrl().write(|w| w.set_funcsel(0x08)); } Self { gpout } } pub fn set_div(&self, int: u32, frac: u8) { unsafe { let c = pac::CLOCKS; c.clk_gpout_div(self.gpout.number()).write(|w| { w.set_int(int); w.set_frac(frac); }); } } pub fn set_src(&self, src: GpoutSrc) { unsafe { let c = pac::CLOCKS; c.clk_gpout_ctrl(self.gpout.number()).modify(|w| { w.set_auxsrc(ClkGpoutCtrlAuxsrc(src as _)); }); } } pub fn enable(&self) { unsafe { let c = pac::CLOCKS; c.clk_gpout_ctrl(self.gpout.number()).modify(|w| { w.set_enable(true); }); } } pub fn disable(&self) { unsafe { let c = pac::CLOCKS; c.clk_gpout_ctrl(self.gpout.number()).modify(|w| { w.set_enable(false); }); } } pub fn get_freq(&self) -> u32 { let c = pac::CLOCKS; let src = unsafe { c.clk_gpout_ctrl(self.gpout.number()).read().auxsrc() }; let base = match src { ClkGpoutCtrlAuxsrc::CLKSRC_PLL_SYS => pll_sys_freq(), ClkGpoutCtrlAuxsrc::CLKSRC_GPIN0 => gpin0_freq(), ClkGpoutCtrlAuxsrc::CLKSRC_GPIN1 => gpin1_freq(), ClkGpoutCtrlAuxsrc::CLKSRC_PLL_USB => pll_usb_freq(), ClkGpoutCtrlAuxsrc::ROSC_CLKSRC => estimate_rosc_freq(), ClkGpoutCtrlAuxsrc::XOSC_CLKSRC => xosc_freq(), ClkGpoutCtrlAuxsrc::CLK_SYS => clk_sys_freq(), ClkGpoutCtrlAuxsrc::CLK_USB => clk_usb_freq(), ClkGpoutCtrlAuxsrc::CLK_ADC => clk_adc_freq(), ClkGpoutCtrlAuxsrc::CLK_RTC => clk_rtc_freq(), ClkGpoutCtrlAuxsrc::CLK_REF => clk_ref_freq(), _ => unreachable!(), }; let div = unsafe { c.clk_gpout_div(self.gpout.number()).read() }; let int = if div.int() == 0 { 65536 } else { div.int() }; // TODO handle fractional clock div let _frac = div.frac(); base / int } } impl<'d, T: GpoutPin> Drop for Gpout<'d, T> { fn drop(&mut self) { self.disable(); unsafe { self.gpout .io() .ctrl() .write(|w| w.set_funcsel(pac::io::vals::Gpio0ctrlFuncsel::NULL.0)); } } } /// Random number generator based on the ROSC RANDOMBIT register. /// /// This will not produce random values if the ROSC is stopped or run at some /// harmonic of the bus frequency. With default clock settings these are not /// issues. pub struct RoscRng; impl RoscRng { fn next_u8() -> u8 { let random_reg = pac::ROSC.randombit(); let mut acc = 0; for _ in 0..u8::BITS { acc <<= 1; acc |= unsafe { random_reg.read().randombit() as u8 }; } acc } } impl rand_core::RngCore for RoscRng { fn try_fill_bytes(&mut self, dest: &mut [u8]) -> Result<(), rand_core::Error> { Ok(self.fill_bytes(dest)) } fn next_u32(&mut self) -> u32 { rand_core::impls::next_u32_via_fill(self) } fn next_u64(&mut self) -> u64 { rand_core::impls::next_u64_via_fill(self) } fn fill_bytes(&mut self, dest: &mut [u8]) { dest.fill_with(Self::next_u8) } }