#![macro_use] use core::default::Default; use core::future::poll_fn; use core::marker::PhantomData; use core::ops::{Deref, DerefMut}; use core::task::Poll; use embassy_hal_internal::drop::OnDrop; use embassy_hal_internal::{into_ref, PeripheralRef}; use embassy_sync::waitqueue::AtomicWaker; use sdio_host::{BusWidth, CardCapacity, CardStatus, CurrentState, SDStatus, CID, CSD, OCR, SCR}; use crate::dma::NoDma; use crate::gpio::sealed::{AFType, Pin}; use crate::gpio::{AnyPin, Pull, Speed}; use crate::interrupt::typelevel::Interrupt; use crate::pac::sdmmc::Sdmmc as RegBlock; use crate::rcc::RccPeripheral; use crate::time::Hertz; use crate::{interrupt, peripherals, Peripheral}; /// Interrupt handler. pub struct InterruptHandler { _phantom: PhantomData, } impl InterruptHandler { fn data_interrupts(enable: bool) { let regs = T::regs(); regs.maskr().write(|w| { w.set_dcrcfailie(enable); w.set_dtimeoutie(enable); w.set_dataendie(enable); #[cfg(sdmmc_v1)] w.set_stbiterre(enable); #[cfg(sdmmc_v2)] w.set_dabortie(enable); }); } } impl interrupt::typelevel::Handler for InterruptHandler { unsafe fn on_interrupt() { Self::data_interrupts(false); T::state().wake(); } } /// Frequency used for SD Card initialization. Must be no higher than 400 kHz. const SD_INIT_FREQ: Hertz = Hertz(400_000); /// The signalling scheme used on the SDMMC bus #[non_exhaustive] #[derive(Debug, Copy, Clone, PartialEq, Eq)] #[cfg_attr(feature = "defmt", derive(defmt::Format))] pub enum Signalling { SDR12, SDR25, SDR50, SDR104, DDR50, } impl Default for Signalling { fn default() -> Self { Signalling::SDR12 } } #[repr(align(4))] #[derive(Debug, Clone, PartialEq, Eq)] #[cfg_attr(feature = "defmt", derive(defmt::Format))] pub struct DataBlock(pub [u8; 512]); impl Deref for DataBlock { type Target = [u8; 512]; fn deref(&self) -> &Self::Target { &self.0 } } impl DerefMut for DataBlock { fn deref_mut(&mut self) -> &mut Self::Target { &mut self.0 } } /// Errors #[non_exhaustive] #[derive(Debug, Copy, Clone, PartialEq, Eq)] #[cfg_attr(feature = "defmt", derive(defmt::Format))] pub enum Error { Timeout, SoftwareTimeout, UnsupportedCardVersion, UnsupportedCardType, Crc, DataCrcFail, RxOverFlow, NoCard, BadClock, SignalingSwitchFailed, PeripheralBusy, #[cfg(sdmmc_v1)] StBitErr, } /// A SD command struct Cmd { cmd: u8, arg: u32, resp: Response, } #[derive(Clone, Copy, Debug, Default)] /// SD Card pub struct Card { /// The type of this card pub card_type: CardCapacity, /// Operation Conditions Register pub ocr: OCR, /// Relative Card Address pub rca: u32, /// Card ID pub cid: CID, /// Card Specific Data pub csd: CSD, /// SD CARD Configuration Register pub scr: SCR, /// SD Status pub status: SDStatus, } impl Card { /// Size in bytes pub fn size(&self) -> u64 { // SDHC / SDXC / SDUC u64::from(self.csd.block_count()) * 512 } } #[repr(u8)] enum PowerCtrl { Off = 0b00, On = 0b11, } #[repr(u32)] #[allow(dead_code)] #[allow(non_camel_case_types)] enum CmdAppOper { VOLTAGE_WINDOW_SD = 0x8010_0000, HIGH_CAPACITY = 0x4000_0000, SDMMC_STD_CAPACITY = 0x0000_0000, SDMMC_CHECK_PATTERN = 0x0000_01AA, SD_SWITCH_1_8V_CAPACITY = 0x0100_0000, } #[derive(Eq, PartialEq, Copy, Clone)] enum Response { None = 0, Short = 1, Long = 3, } /// Calculate clock divisor. Returns a SDMMC_CK less than or equal to /// `sdmmc_ck` in Hertz. /// /// Returns `(bypass, clk_div, clk_f)`, where `bypass` enables clock divisor bypass (only sdmmc_v1), /// `clk_div` is the divisor register value and `clk_f` is the resulting new clock frequency. #[cfg(sdmmc_v1)] fn clk_div(ker_ck: Hertz, sdmmc_ck: u32) -> Result<(bool, u8, Hertz), Error> { // sdmmc_v1 maximum clock is 50 MHz if sdmmc_ck > 50_000_000 { return Err(Error::BadClock); } // bypass divisor if ker_ck.0 <= sdmmc_ck { return Ok((true, 0, ker_ck)); } // `ker_ck / sdmmc_ck` rounded up let clk_div = match (ker_ck.0 + sdmmc_ck - 1) / sdmmc_ck { 0 | 1 => Ok(0), x @ 2..=258 => Ok((x - 2) as u8), _ => Err(Error::BadClock), }?; // SDIO_CK frequency = SDIOCLK / [CLKDIV + 2] let clk_f = Hertz(ker_ck.0 / (clk_div as u32 + 2)); Ok((false, clk_div, clk_f)) } /// Calculate clock divisor. Returns a SDMMC_CK less than or equal to /// `sdmmc_ck` in Hertz. /// /// Returns `(bypass, clk_div, clk_f)`, where `bypass` enables clock divisor bypass (only sdmmc_v1), /// `clk_div` is the divisor register value and `clk_f` is the resulting new clock frequency. #[cfg(sdmmc_v2)] fn clk_div(ker_ck: Hertz, sdmmc_ck: u32) -> Result<(bool, u16, Hertz), Error> { // `ker_ck / sdmmc_ck` rounded up match (ker_ck.0 + sdmmc_ck - 1) / sdmmc_ck { 0 | 1 => Ok((false, 0, ker_ck)), x @ 2..=2046 => { // SDMMC_CK frequency = SDMMCCLK / [CLKDIV * 2] let clk_div = ((x + 1) / 2) as u16; let clk = Hertz(ker_ck.0 / (clk_div as u32 * 2)); Ok((false, clk_div, clk)) } _ => Err(Error::BadClock), } } #[cfg(sdmmc_v1)] type Transfer<'a, C> = crate::dma::Transfer<'a, C>; #[cfg(sdmmc_v2)] struct Transfer<'a, C> { _dummy: core::marker::PhantomData<&'a mut C>, } #[cfg(all(sdmmc_v1, dma))] const DMA_TRANSFER_OPTIONS: crate::dma::TransferOptions = crate::dma::TransferOptions { pburst: crate::dma::Burst::Incr4, mburst: crate::dma::Burst::Incr4, flow_ctrl: crate::dma::FlowControl::Peripheral, fifo_threshold: Some(crate::dma::FifoThreshold::Full), circular: false, half_transfer_ir: false, complete_transfer_ir: true, }; #[cfg(all(sdmmc_v1, not(dma)))] const DMA_TRANSFER_OPTIONS: crate::dma::TransferOptions = crate::dma::TransferOptions { circular: false, half_transfer_ir: false, complete_transfer_ir: true, }; /// SDMMC configuration /// /// Default values: /// data_transfer_timeout: 5_000_000 #[non_exhaustive] pub struct Config { /// The timeout to be set for data transfers, in card bus clock periods pub data_transfer_timeout: u32, } impl Default for Config { fn default() -> Self { Self { data_transfer_timeout: 5_000_000, } } } /// Sdmmc device pub struct Sdmmc<'d, T: Instance, Dma: SdmmcDma = NoDma> { _peri: PeripheralRef<'d, T>, #[allow(unused)] dma: PeripheralRef<'d, Dma>, clk: PeripheralRef<'d, AnyPin>, cmd: PeripheralRef<'d, AnyPin>, d0: PeripheralRef<'d, AnyPin>, d1: Option>, d2: Option>, d3: Option>, config: Config, /// Current clock to card clock: Hertz, /// Current signalling scheme to card signalling: Signalling, /// Card card: Option, } #[cfg(sdmmc_v1)] impl<'d, T: Instance, Dma: SdmmcDma> Sdmmc<'d, T, Dma> { pub fn new_1bit( sdmmc: impl Peripheral

+ 'd, _irq: impl interrupt::typelevel::Binding> + 'd, dma: impl Peripheral

+ 'd, clk: impl Peripheral

> + 'd, cmd: impl Peripheral

> + 'd, d0: impl Peripheral

> + 'd, config: Config, ) -> Self { into_ref!(clk, cmd, d0); critical_section::with(|_| { clk.set_as_af_pull(clk.af_num(), AFType::OutputPushPull, Pull::None); cmd.set_as_af_pull(cmd.af_num(), AFType::OutputPushPull, Pull::Up); d0.set_as_af_pull(d0.af_num(), AFType::OutputPushPull, Pull::Up); clk.set_speed(Speed::VeryHigh); cmd.set_speed(Speed::VeryHigh); d0.set_speed(Speed::VeryHigh); }); Self::new_inner( sdmmc, dma, clk.map_into(), cmd.map_into(), d0.map_into(), None, None, None, config, ) } pub fn new_4bit( sdmmc: impl Peripheral

+ 'd, _irq: impl interrupt::typelevel::Binding> + 'd, dma: impl Peripheral

+ 'd, clk: impl Peripheral

> + 'd, cmd: impl Peripheral

> + 'd, d0: impl Peripheral

> + 'd, d1: impl Peripheral

> + 'd, d2: impl Peripheral

> + 'd, d3: impl Peripheral

> + 'd, config: Config, ) -> Self { into_ref!(clk, cmd, d0, d1, d2, d3); critical_section::with(|_| { clk.set_as_af_pull(clk.af_num(), AFType::OutputPushPull, Pull::None); cmd.set_as_af_pull(cmd.af_num(), AFType::OutputPushPull, Pull::Up); d0.set_as_af_pull(d0.af_num(), AFType::OutputPushPull, Pull::Up); d1.set_as_af_pull(d1.af_num(), AFType::OutputPushPull, Pull::Up); d2.set_as_af_pull(d2.af_num(), AFType::OutputPushPull, Pull::Up); d3.set_as_af_pull(d3.af_num(), AFType::OutputPushPull, Pull::Up); clk.set_speed(Speed::VeryHigh); cmd.set_speed(Speed::VeryHigh); d0.set_speed(Speed::VeryHigh); d1.set_speed(Speed::VeryHigh); d2.set_speed(Speed::VeryHigh); d3.set_speed(Speed::VeryHigh); }); Self::new_inner( sdmmc, dma, clk.map_into(), cmd.map_into(), d0.map_into(), Some(d1.map_into()), Some(d2.map_into()), Some(d3.map_into()), config, ) } } #[cfg(sdmmc_v2)] impl<'d, T: Instance> Sdmmc<'d, T, NoDma> { pub fn new_1bit( sdmmc: impl Peripheral

+ 'd, _irq: impl interrupt::typelevel::Binding> + 'd, clk: impl Peripheral

> + 'd, cmd: impl Peripheral

> + 'd, d0: impl Peripheral

> + 'd, config: Config, ) -> Self { into_ref!(clk, cmd, d0); critical_section::with(|_| { clk.set_as_af_pull(clk.af_num(), AFType::OutputPushPull, Pull::None); cmd.set_as_af_pull(cmd.af_num(), AFType::OutputPushPull, Pull::Up); d0.set_as_af_pull(d0.af_num(), AFType::OutputPushPull, Pull::Up); clk.set_speed(Speed::VeryHigh); cmd.set_speed(Speed::VeryHigh); d0.set_speed(Speed::VeryHigh); }); Self::new_inner( sdmmc, NoDma.into_ref(), clk.map_into(), cmd.map_into(), d0.map_into(), None, None, None, config, ) } pub fn new_4bit( sdmmc: impl Peripheral

+ 'd, _irq: impl interrupt::typelevel::Binding> + 'd, clk: impl Peripheral

> + 'd, cmd: impl Peripheral

> + 'd, d0: impl Peripheral

> + 'd, d1: impl Peripheral

> + 'd, d2: impl Peripheral

> + 'd, d3: impl Peripheral

> + 'd, config: Config, ) -> Self { into_ref!(clk, cmd, d0, d1, d2, d3); critical_section::with(|_| { clk.set_as_af_pull(clk.af_num(), AFType::OutputPushPull, Pull::None); cmd.set_as_af_pull(cmd.af_num(), AFType::OutputPushPull, Pull::Up); d0.set_as_af_pull(d0.af_num(), AFType::OutputPushPull, Pull::Up); d1.set_as_af_pull(d1.af_num(), AFType::OutputPushPull, Pull::Up); d2.set_as_af_pull(d2.af_num(), AFType::OutputPushPull, Pull::Up); d3.set_as_af_pull(d3.af_num(), AFType::OutputPushPull, Pull::Up); clk.set_speed(Speed::VeryHigh); cmd.set_speed(Speed::VeryHigh); d0.set_speed(Speed::VeryHigh); d1.set_speed(Speed::VeryHigh); d2.set_speed(Speed::VeryHigh); d3.set_speed(Speed::VeryHigh); }); Self::new_inner( sdmmc, NoDma.into_ref(), clk.map_into(), cmd.map_into(), d0.map_into(), Some(d1.map_into()), Some(d2.map_into()), Some(d3.map_into()), config, ) } } impl<'d, T: Instance, Dma: SdmmcDma + 'd> Sdmmc<'d, T, Dma> { fn new_inner( sdmmc: impl Peripheral

+ 'd, dma: impl Peripheral

+ 'd, clk: PeripheralRef<'d, AnyPin>, cmd: PeripheralRef<'d, AnyPin>, d0: PeripheralRef<'d, AnyPin>, d1: Option>, d2: Option>, d3: Option>, config: Config, ) -> Self { into_ref!(sdmmc, dma); T::reset_and_enable(); T::Interrupt::unpend(); unsafe { T::Interrupt::enable() }; let regs = T::regs(); regs.clkcr().write(|w| { w.set_pwrsav(false); w.set_negedge(false); // Hardware flow control is broken on SDIOv1 and causes clock glitches, which result in CRC errors. // See chip erratas for more details. #[cfg(sdmmc_v1)] w.set_hwfc_en(false); #[cfg(sdmmc_v2)] w.set_hwfc_en(true); #[cfg(sdmmc_v1)] w.set_clken(true); }); // Power off, writen 00: Clock to the card is stopped; // D[7:0], CMD, and CK are driven high. regs.power().modify(|w| w.set_pwrctrl(PowerCtrl::Off as u8)); Self { _peri: sdmmc, dma, clk, cmd, d0, d1, d2, d3, config, clock: SD_INIT_FREQ, signalling: Default::default(), card: None, } } /// Data transfer is in progress #[inline(always)] fn data_active() -> bool { let regs = T::regs(); let status = regs.star().read(); #[cfg(sdmmc_v1)] return status.rxact() || status.txact(); #[cfg(sdmmc_v2)] return status.dpsmact(); } /// Coammand transfer is in progress #[inline(always)] fn cmd_active() -> bool { let regs = T::regs(); let status = regs.star().read(); #[cfg(sdmmc_v1)] return status.cmdact(); #[cfg(sdmmc_v2)] return status.cpsmact(); } /// Wait idle on CMDACT, RXACT and TXACT (v1) or DOSNACT and CPSMACT (v2) #[inline(always)] fn wait_idle() { while Self::data_active() || Self::cmd_active() {} } /// # Safety /// /// `buffer` must be valid for the whole transfer and word aligned fn prepare_datapath_read<'a>( &'a mut self, buffer: &'a mut [u32], length_bytes: u32, block_size: u8, ) -> Transfer<'a, Dma> { assert!(block_size <= 14, "Block size up to 2^14 bytes"); let regs = T::regs(); // Command AND Data state machines must be idle Self::wait_idle(); Self::clear_interrupt_flags(); regs.dtimer() .write(|w| w.set_datatime(self.config.data_transfer_timeout)); regs.dlenr().write(|w| w.set_datalength(length_bytes)); #[cfg(sdmmc_v1)] let transfer = unsafe { let request = self.dma.request(); Transfer::new_read( &mut self.dma, request, regs.fifor().as_ptr() as *mut u32, buffer, DMA_TRANSFER_OPTIONS, ) }; #[cfg(sdmmc_v2)] let transfer = { regs.idmabase0r().write(|w| w.set_idmabase0(buffer.as_mut_ptr() as u32)); regs.idmactrlr().modify(|w| w.set_idmaen(true)); Transfer { _dummy: core::marker::PhantomData, } }; regs.dctrl().modify(|w| { w.set_dblocksize(block_size); w.set_dtdir(true); #[cfg(sdmmc_v1)] { w.set_dmaen(true); w.set_dten(true); } }); transfer } /// # Safety /// /// `buffer` must be valid for the whole transfer and word aligned fn prepare_datapath_write<'a>( &'a mut self, buffer: &'a [u32], length_bytes: u32, block_size: u8, ) -> Transfer<'a, Dma> { assert!(block_size <= 14, "Block size up to 2^14 bytes"); let regs = T::regs(); // Command AND Data state machines must be idle Self::wait_idle(); Self::clear_interrupt_flags(); regs.dtimer() .write(|w| w.set_datatime(self.config.data_transfer_timeout)); regs.dlenr().write(|w| w.set_datalength(length_bytes)); #[cfg(sdmmc_v1)] let transfer = unsafe { let request = self.dma.request(); Transfer::new_write( &mut self.dma, request, buffer, regs.fifor().as_ptr() as *mut u32, DMA_TRANSFER_OPTIONS, ) }; #[cfg(sdmmc_v2)] let transfer = { regs.idmabase0r().write(|w| w.set_idmabase0(buffer.as_ptr() as u32)); regs.idmactrlr().modify(|w| w.set_idmaen(true)); Transfer { _dummy: core::marker::PhantomData, } }; regs.dctrl().modify(|w| { w.set_dblocksize(block_size); w.set_dtdir(false); #[cfg(sdmmc_v1)] { w.set_dmaen(true); w.set_dten(true); } }); transfer } /// Stops the DMA datapath fn stop_datapath() { let regs = T::regs(); #[cfg(sdmmc_v1)] regs.dctrl().modify(|w| { w.set_dmaen(false); w.set_dten(false); }); #[cfg(sdmmc_v2)] regs.idmactrlr().modify(|w| w.set_idmaen(false)); } /// Sets the CLKDIV field in CLKCR. Updates clock field in self fn clkcr_set_clkdiv(&mut self, freq: u32, width: BusWidth) -> Result<(), Error> { let regs = T::regs(); let width_u32 = match width { BusWidth::One => 1u32, BusWidth::Four => 4u32, BusWidth::Eight => 8u32, _ => panic!("Invalid Bus Width"), }; let ker_ck = T::kernel_clk(); let (_bypass, clkdiv, new_clock) = clk_div(ker_ck, freq)?; // Enforce AHB and SDMMC_CK clock relation. See RM0433 Rev 7 // Section 55.5.8 let sdmmc_bus_bandwidth = new_clock.0 * width_u32; assert!(ker_ck.0 > 3 * sdmmc_bus_bandwidth / 32); self.clock = new_clock; // CPSMACT and DPSMACT must be 0 to set CLKDIV Self::wait_idle(); regs.clkcr().modify(|w| { w.set_clkdiv(clkdiv); #[cfg(sdmmc_v1)] w.set_bypass(_bypass); }); Ok(()) } /// Switch mode using CMD6. /// /// Attempt to set a new signalling mode. The selected /// signalling mode is returned. Expects the current clock /// frequency to be > 12.5MHz. async fn switch_signalling_mode(&mut self, signalling: Signalling) -> Result { // NB PLSS v7_10 4.3.10.4: "the use of SET_BLK_LEN command is not // necessary" let set_function = 0x8000_0000 | match signalling { // See PLSS v7_10 Table 4-11 Signalling::DDR50 => 0xFF_FF04, Signalling::SDR104 => 0xFF_1F03, Signalling::SDR50 => 0xFF_1F02, Signalling::SDR25 => 0xFF_FF01, Signalling::SDR12 => 0xFF_FF00, }; let mut status = [0u32; 16]; // Arm `OnDrop` after the buffer, so it will be dropped first let regs = T::regs(); let on_drop = OnDrop::new(|| Self::on_drop()); let transfer = self.prepare_datapath_read(&mut status, 64, 6); InterruptHandler::::data_interrupts(true); Self::cmd(Cmd::cmd6(set_function), true)?; // CMD6 let res = poll_fn(|cx| { T::state().register(cx.waker()); let status = regs.star().read(); if status.dcrcfail() { return Poll::Ready(Err(Error::Crc)); } if status.dtimeout() { return Poll::Ready(Err(Error::Timeout)); } #[cfg(sdmmc_v1)] if status.stbiterr() { return Poll::Ready(Err(Error::StBitErr)); } if status.dataend() { return Poll::Ready(Ok(())); } Poll::Pending }) .await; Self::clear_interrupt_flags(); // Host is allowed to use the new functions at least 8 // clocks after the end of the switch command // transaction. We know the current clock period is < 80ns, // so a total delay of 640ns is required here for _ in 0..300 { cortex_m::asm::nop(); } match res { Ok(_) => { on_drop.defuse(); Self::stop_datapath(); drop(transfer); // Function Selection of Function Group 1 let selection = (u32::from_be(status[4]) >> 24) & 0xF; match selection { 0 => Ok(Signalling::SDR12), 1 => Ok(Signalling::SDR25), 2 => Ok(Signalling::SDR50), 3 => Ok(Signalling::SDR104), 4 => Ok(Signalling::DDR50), _ => Err(Error::UnsupportedCardType), } } Err(e) => Err(e), } } /// Query the card status (CMD13, returns R1) fn read_status(&self, card: &Card) -> Result { let regs = T::regs(); let rca = card.rca; Self::cmd(Cmd::card_status(rca << 16), false)?; // CMD13 let r1 = regs.respr(0).read().cardstatus(); Ok(r1.into()) } /// Reads the SD Status (ACMD13) async fn read_sd_status(&mut self) -> Result<(), Error> { let card = self.card.as_mut().ok_or(Error::NoCard)?; let rca = card.rca; Self::cmd(Cmd::set_block_length(64), false)?; // CMD16 Self::cmd(Cmd::app_cmd(rca << 16), false)?; // APP let mut status = [0u32; 16]; // Arm `OnDrop` after the buffer, so it will be dropped first let regs = T::regs(); let on_drop = OnDrop::new(|| Self::on_drop()); let transfer = self.prepare_datapath_read(&mut status, 64, 6); InterruptHandler::::data_interrupts(true); Self::cmd(Cmd::card_status(0), true)?; let res = poll_fn(|cx| { T::state().register(cx.waker()); let status = regs.star().read(); if status.dcrcfail() { return Poll::Ready(Err(Error::Crc)); } if status.dtimeout() { return Poll::Ready(Err(Error::Timeout)); } #[cfg(sdmmc_v1)] if status.stbiterr() { return Poll::Ready(Err(Error::StBitErr)); } if status.dataend() { return Poll::Ready(Ok(())); } Poll::Pending }) .await; Self::clear_interrupt_flags(); if res.is_ok() { on_drop.defuse(); Self::stop_datapath(); drop(transfer); for byte in status.iter_mut() { *byte = u32::from_be(*byte); } self.card.as_mut().unwrap().status = status.into(); } res } /// Select one card and place it into the _Tranfer State_ /// /// If `None` is specifed for `card`, all cards are put back into /// _Stand-by State_ fn select_card(&self, card: Option<&Card>) -> Result<(), Error> { // Determine Relative Card Address (RCA) of given card let rca = card.map(|c| c.rca << 16).unwrap_or(0); let r = Self::cmd(Cmd::sel_desel_card(rca), false); match (r, rca) { (Err(Error::Timeout), 0) => Ok(()), _ => r, } } /// Clear flags in interrupt clear register #[inline(always)] fn clear_interrupt_flags() { let regs = T::regs(); regs.icr().write(|w| { w.set_ccrcfailc(true); w.set_dcrcfailc(true); w.set_ctimeoutc(true); w.set_dtimeoutc(true); w.set_txunderrc(true); w.set_rxoverrc(true); w.set_cmdrendc(true); w.set_cmdsentc(true); w.set_dataendc(true); w.set_dbckendc(true); w.set_sdioitc(true); #[cfg(sdmmc_v1)] w.set_stbiterrc(true); #[cfg(sdmmc_v2)] { w.set_dholdc(true); w.set_dabortc(true); w.set_busyd0endc(true); w.set_ackfailc(true); w.set_acktimeoutc(true); w.set_vswendc(true); w.set_ckstopc(true); w.set_idmatec(true); w.set_idmabtcc(true); } }); } async fn get_scr(&mut self, card: &mut Card) -> Result<(), Error> { // Read the the 64-bit SCR register Self::cmd(Cmd::set_block_length(8), false)?; // CMD16 Self::cmd(Cmd::app_cmd(card.rca << 16), false)?; let mut scr = [0u32; 2]; // Arm `OnDrop` after the buffer, so it will be dropped first let regs = T::regs(); let on_drop = OnDrop::new(|| Self::on_drop()); let transfer = self.prepare_datapath_read(&mut scr[..], 8, 3); InterruptHandler::::data_interrupts(true); Self::cmd(Cmd::cmd51(), true)?; let res = poll_fn(|cx| { T::state().register(cx.waker()); let status = regs.star().read(); if status.dcrcfail() { return Poll::Ready(Err(Error::Crc)); } if status.dtimeout() { return Poll::Ready(Err(Error::Timeout)); } #[cfg(sdmmc_v1)] if status.stbiterr() { return Poll::Ready(Err(Error::StBitErr)); } if status.dataend() { return Poll::Ready(Ok(())); } Poll::Pending }) .await; Self::clear_interrupt_flags(); if res.is_ok() { on_drop.defuse(); Self::stop_datapath(); drop(transfer); unsafe { let scr_bytes = &*(&scr as *const [u32; 2] as *const [u8; 8]); card.scr = SCR(u64::from_be_bytes(*scr_bytes)); } } res } /// Send command to card #[allow(unused_variables)] fn cmd(cmd: Cmd, data: bool) -> Result<(), Error> { let regs = T::regs(); Self::clear_interrupt_flags(); // CP state machine must be idle while Self::cmd_active() {} // Command arg regs.argr().write(|w| w.set_cmdarg(cmd.arg)); // Command index and start CP State Machine regs.cmdr().write(|w| { w.set_waitint(false); w.set_waitresp(cmd.resp as u8); w.set_cmdindex(cmd.cmd); w.set_cpsmen(true); #[cfg(sdmmc_v2)] { // Special mode in CP State Machine // CMD12: Stop Transmission let cpsm_stop_transmission = cmd.cmd == 12; w.set_cmdstop(cpsm_stop_transmission); w.set_cmdtrans(data); } }); let mut status; if cmd.resp == Response::None { // Wait for CMDSENT or a timeout while { status = regs.star().read(); !(status.ctimeout() || status.cmdsent()) } {} } else { // Wait for CMDREND or CCRCFAIL or a timeout while { status = regs.star().read(); !(status.ctimeout() || status.cmdrend() || status.ccrcfail()) } {} } if status.ctimeout() { return Err(Error::Timeout); } else if status.ccrcfail() { return Err(Error::Crc); } Ok(()) } fn on_drop() { let regs = T::regs(); if Self::data_active() { Self::clear_interrupt_flags(); // Send abort // CP state machine must be idle while Self::cmd_active() {} // Command arg regs.argr().write(|w| w.set_cmdarg(0)); // Command index and start CP State Machine regs.cmdr().write(|w| { w.set_waitint(false); w.set_waitresp(Response::Short as u8); w.set_cmdindex(12); w.set_cpsmen(true); #[cfg(sdmmc_v2)] { w.set_cmdstop(true); w.set_cmdtrans(false); } }); // Wait for the abort while Self::data_active() {} } InterruptHandler::::data_interrupts(false); Self::clear_interrupt_flags(); Self::stop_datapath(); } /// Initializes card (if present) and sets the bus at the /// specified frequency. pub async fn init_card(&mut self, freq: Hertz) -> Result<(), Error> { let regs = T::regs(); let ker_ck = T::kernel_clk(); let bus_width = match self.d3.is_some() { true => BusWidth::Four, false => BusWidth::One, }; // While the SD/SDIO card or eMMC is in identification mode, // the SDMMC_CK frequency must be no more than 400 kHz. let (_bypass, clkdiv, init_clock) = unwrap!(clk_div(ker_ck, SD_INIT_FREQ.0)); self.clock = init_clock; // CPSMACT and DPSMACT must be 0 to set WIDBUS Self::wait_idle(); regs.clkcr().modify(|w| { w.set_widbus(0); w.set_clkdiv(clkdiv); #[cfg(sdmmc_v1)] w.set_bypass(_bypass); }); regs.power().modify(|w| w.set_pwrctrl(PowerCtrl::On as u8)); Self::cmd(Cmd::idle(), false)?; // Check if cards supports CMD8 (with pattern) Self::cmd(Cmd::hs_send_ext_csd(0x1AA), false)?; let r1 = regs.respr(0).read().cardstatus(); let mut card = if r1 == 0x1AA { // Card echoed back the pattern. Must be at least v2 Card::default() } else { return Err(Error::UnsupportedCardVersion); }; let ocr = loop { // Signal that next command is a app command Self::cmd(Cmd::app_cmd(0), false)?; // CMD55 let arg = CmdAppOper::VOLTAGE_WINDOW_SD as u32 | CmdAppOper::HIGH_CAPACITY as u32 | CmdAppOper::SD_SWITCH_1_8V_CAPACITY as u32; // Initialize card match Self::cmd(Cmd::app_op_cmd(arg), false) { // ACMD41 Ok(_) => (), Err(Error::Crc) => (), Err(err) => return Err(err), } let ocr: OCR = regs.respr(0).read().cardstatus().into(); if !ocr.is_busy() { // Power up done break ocr; } }; if ocr.high_capacity() { // Card is SDHC or SDXC or SDUC card.card_type = CardCapacity::SDHC; } else { card.card_type = CardCapacity::SDSC; } card.ocr = ocr; Self::cmd(Cmd::all_send_cid(), false)?; // CMD2 let cid0 = regs.respr(0).read().cardstatus() as u128; let cid1 = regs.respr(1).read().cardstatus() as u128; let cid2 = regs.respr(2).read().cardstatus() as u128; let cid3 = regs.respr(3).read().cardstatus() as u128; let cid = (cid0 << 96) | (cid1 << 64) | (cid2 << 32) | (cid3); card.cid = cid.into(); Self::cmd(Cmd::send_rel_addr(), false)?; card.rca = regs.respr(0).read().cardstatus() >> 16; Self::cmd(Cmd::send_csd(card.rca << 16), false)?; let csd0 = regs.respr(0).read().cardstatus() as u128; let csd1 = regs.respr(1).read().cardstatus() as u128; let csd2 = regs.respr(2).read().cardstatus() as u128; let csd3 = regs.respr(3).read().cardstatus() as u128; let csd = (csd0 << 96) | (csd1 << 64) | (csd2 << 32) | (csd3); card.csd = csd.into(); self.select_card(Some(&card))?; self.get_scr(&mut card).await?; // Set bus width let (width, acmd_arg) = match bus_width { BusWidth::Eight => unimplemented!(), BusWidth::Four if card.scr.bus_width_four() => (BusWidth::Four, 2), _ => (BusWidth::One, 0), }; Self::cmd(Cmd::app_cmd(card.rca << 16), false)?; Self::cmd(Cmd::cmd6(acmd_arg), false)?; // CPSMACT and DPSMACT must be 0 to set WIDBUS Self::wait_idle(); regs.clkcr().modify(|w| { w.set_widbus(match width { BusWidth::One => 0, BusWidth::Four => 1, BusWidth::Eight => 2, _ => panic!("Invalid Bus Width"), }) }); // Set Clock if freq.0 <= 25_000_000 { // Final clock frequency self.clkcr_set_clkdiv(freq.0, width)?; } else { // Switch to max clock for SDR12 self.clkcr_set_clkdiv(25_000_000, width)?; } self.card = Some(card); // Read status self.read_sd_status().await?; if freq.0 > 25_000_000 { // Switch to SDR25 self.signalling = self.switch_signalling_mode(Signalling::SDR25).await?; if self.signalling == Signalling::SDR25 { // Set final clock frequency self.clkcr_set_clkdiv(freq.0, width)?; if self.read_status(&card)?.state() != CurrentState::Transfer { return Err(Error::SignalingSwitchFailed); } } } // Read status after signalling change self.read_sd_status().await?; Ok(()) } #[inline(always)] pub async fn read_block(&mut self, block_idx: u32, buffer: &mut DataBlock) -> Result<(), Error> { let card_capacity = self.card()?.card_type; // NOTE(unsafe) DataBlock uses align 4 let buffer = unsafe { &mut *((&mut buffer.0) as *mut [u8; 512] as *mut [u32; 128]) }; // Always read 1 block of 512 bytes // SDSC cards are byte addressed hence the blockaddress is in multiples of 512 bytes let address = match card_capacity { CardCapacity::SDSC => block_idx * 512, _ => block_idx, }; Self::cmd(Cmd::set_block_length(512), false)?; // CMD16 let regs = T::regs(); let on_drop = OnDrop::new(|| Self::on_drop()); let transfer = self.prepare_datapath_read(buffer, 512, 9); InterruptHandler::::data_interrupts(true); Self::cmd(Cmd::read_single_block(address), true)?; let res = poll_fn(|cx| { T::state().register(cx.waker()); let status = regs.star().read(); if status.dcrcfail() { return Poll::Ready(Err(Error::Crc)); } if status.dtimeout() { return Poll::Ready(Err(Error::Timeout)); } #[cfg(sdmmc_v1)] if status.stbiterr() { return Poll::Ready(Err(Error::StBitErr)); } if status.dataend() { return Poll::Ready(Ok(())); } Poll::Pending }) .await; Self::clear_interrupt_flags(); if res.is_ok() { on_drop.defuse(); Self::stop_datapath(); drop(transfer); } res } pub async fn write_block(&mut self, block_idx: u32, buffer: &DataBlock) -> Result<(), Error> { let card = self.card.as_mut().ok_or(Error::NoCard)?; // NOTE(unsafe) DataBlock uses align 4 let buffer = unsafe { &*((&buffer.0) as *const [u8; 512] as *const [u32; 128]) }; // Always read 1 block of 512 bytes // SDSC cards are byte addressed hence the blockaddress is in multiples of 512 bytes let address = match card.card_type { CardCapacity::SDSC => block_idx * 512, _ => block_idx, }; Self::cmd(Cmd::set_block_length(512), false)?; // CMD16 let regs = T::regs(); let on_drop = OnDrop::new(|| Self::on_drop()); // sdmmc_v1 uses different cmd/dma order than v2, but only for writes #[cfg(sdmmc_v1)] Self::cmd(Cmd::write_single_block(address), true)?; let transfer = self.prepare_datapath_write(buffer, 512, 9); InterruptHandler::::data_interrupts(true); #[cfg(sdmmc_v2)] Self::cmd(Cmd::write_single_block(address), true)?; let res = poll_fn(|cx| { T::state().register(cx.waker()); let status = regs.star().read(); if status.dcrcfail() { return Poll::Ready(Err(Error::Crc)); } if status.dtimeout() { return Poll::Ready(Err(Error::Timeout)); } #[cfg(sdmmc_v1)] if status.stbiterr() { return Poll::Ready(Err(Error::StBitErr)); } if status.dataend() { return Poll::Ready(Ok(())); } Poll::Pending }) .await; Self::clear_interrupt_flags(); match res { Ok(_) => { on_drop.defuse(); Self::stop_datapath(); drop(transfer); // TODO: Make this configurable let mut timeout: u32 = 0x00FF_FFFF; // Try to read card status (ACMD13) while timeout > 0 { match self.read_sd_status().await { Ok(_) => return Ok(()), Err(Error::Timeout) => (), // Try again Err(e) => return Err(e), } timeout -= 1; } Err(Error::SoftwareTimeout) } Err(e) => Err(e), } } /// Get a reference to the initialized card /// /// # Errors /// /// Returns Error::NoCard if [`init_card`](#method.init_card) /// has not previously succeeded #[inline(always)] pub fn card(&self) -> Result<&Card, Error> { self.card.as_ref().ok_or(Error::NoCard) } /// Get the current SDMMC bus clock pub fn clock(&self) -> Hertz { self.clock } } impl<'d, T: Instance, Dma: SdmmcDma + 'd> Drop for Sdmmc<'d, T, Dma> { fn drop(&mut self) { T::Interrupt::disable(); Self::on_drop(); critical_section::with(|_| { self.clk.set_as_disconnected(); self.cmd.set_as_disconnected(); self.d0.set_as_disconnected(); if let Some(x) = &mut self.d1 { x.set_as_disconnected(); } if let Some(x) = &mut self.d2 { x.set_as_disconnected(); } if let Some(x) = &mut self.d3 { x.set_as_disconnected(); } }); } } /// SD card Commands impl Cmd { const fn new(cmd: u8, arg: u32, resp: Response) -> Cmd { Cmd { cmd, arg, resp } } /// CMD0: Idle const fn idle() -> Cmd { Cmd::new(0, 0, Response::None) } /// CMD2: Send CID const fn all_send_cid() -> Cmd { Cmd::new(2, 0, Response::Long) } /// CMD3: Send Relative Address const fn send_rel_addr() -> Cmd { Cmd::new(3, 0, Response::Short) } /// CMD6: Switch Function Command /// ACMD6: Bus Width const fn cmd6(arg: u32) -> Cmd { Cmd::new(6, arg, Response::Short) } /// CMD7: Select one card and put it into the _Tranfer State_ const fn sel_desel_card(rca: u32) -> Cmd { Cmd::new(7, rca, Response::Short) } /// CMD8: const fn hs_send_ext_csd(arg: u32) -> Cmd { Cmd::new(8, arg, Response::Short) } /// CMD9: const fn send_csd(rca: u32) -> Cmd { Cmd::new(9, rca, Response::Long) } /// CMD12: //const fn stop_transmission() -> Cmd { // Cmd::new(12, 0, Response::Short) //} /// CMD13: Ask card to send status register /// ACMD13: SD Status const fn card_status(rca: u32) -> Cmd { Cmd::new(13, rca, Response::Short) } /// CMD16: const fn set_block_length(blocklen: u32) -> Cmd { Cmd::new(16, blocklen, Response::Short) } /// CMD17: Block Read const fn read_single_block(addr: u32) -> Cmd { Cmd::new(17, addr, Response::Short) } /// CMD18: Multiple Block Read //const fn read_multiple_blocks(addr: u32) -> Cmd { // Cmd::new(18, addr, Response::Short) //} /// CMD24: Block Write const fn write_single_block(addr: u32) -> Cmd { Cmd::new(24, addr, Response::Short) } const fn app_op_cmd(arg: u32) -> Cmd { Cmd::new(41, arg, Response::Short) } const fn cmd51() -> Cmd { Cmd::new(51, 0, Response::Short) } /// App Command. Indicates that next command will be a app command const fn app_cmd(rca: u32) -> Cmd { Cmd::new(55, rca, Response::Short) } } ////////////////////////////////////////////////////// pub(crate) mod sealed { use super::*; pub trait Instance { type Interrupt: interrupt::typelevel::Interrupt; fn regs() -> RegBlock; fn state() -> &'static AtomicWaker; fn kernel_clk() -> Hertz; } pub trait Pins {} } pub trait Instance: sealed::Instance + RccPeripheral + 'static {} pin_trait!(CkPin, Instance); pin_trait!(CmdPin, Instance); pin_trait!(D0Pin, Instance); pin_trait!(D1Pin, Instance); pin_trait!(D2Pin, Instance); pin_trait!(D3Pin, Instance); pin_trait!(D4Pin, Instance); pin_trait!(D5Pin, Instance); pin_trait!(D6Pin, Instance); pin_trait!(D7Pin, Instance); #[cfg(sdmmc_v1)] dma_trait!(SdmmcDma, Instance); // SDMMCv2 uses internal DMA #[cfg(sdmmc_v2)] pub trait SdmmcDma {} #[cfg(sdmmc_v2)] impl SdmmcDma for NoDma {} cfg_if::cfg_if! { // TODO, these could not be implemented, because required clocks are not exposed in RCC: // - H7 uses pll1_q_ck or pll2_r_ck depending on SDMMCSEL // - L1 uses pll48 // - L4 uses clk48(pll48) // - L4+, L5, U5 uses clk48(pll48) or PLLSAI3CLK(PLLP) depending on SDMMCSEL if #[cfg(stm32f1)] { // F1 uses AHB1(HCLK), which is correct in PAC macro_rules! kernel_clk { ($inst:ident) => { ::frequency() } } } else if #[cfg(any(stm32f2, stm32f4))] { // F2, F4 always use pll48 macro_rules! kernel_clk { ($inst:ident) => { critical_section::with(|_| unsafe { crate::rcc::get_freqs().pll48 }).expect("PLL48 is required for SDIO") } } } else if #[cfg(stm32f7)] { macro_rules! kernel_clk { (SDMMC1) => { critical_section::with(|_| unsafe { let sdmmcsel = crate::pac::RCC.dckcfgr2().read().sdmmc1sel(); if sdmmcsel == crate::pac::rcc::vals::Sdmmcsel::SYSCLK { crate::rcc::get_freqs().sys } else { crate::rcc::get_freqs().pll48.expect("PLL48 is required for SDMMC") } }) }; (SDMMC2) => { critical_section::with(|_| unsafe { let sdmmcsel = crate::pac::RCC.dckcfgr2().read().sdmmc2sel(); if sdmmcsel == crate::pac::rcc::vals::Sdmmcsel::SYSCLK { crate::rcc::get_freqs().sys } else { crate::rcc::get_freqs().pll48.expect("PLL48 is required for SDMMC") } }) }; } } else { // Use default peripheral clock and hope it works macro_rules! kernel_clk { ($inst:ident) => { ::frequency() } } } } foreach_peripheral!( (sdmmc, $inst:ident) => { impl sealed::Instance for peripherals::$inst { type Interrupt = crate::interrupt::typelevel::$inst; fn regs() -> RegBlock { crate::pac::$inst } fn state() -> &'static ::embassy_sync::waitqueue::AtomicWaker { static WAKER: ::embassy_sync::waitqueue::AtomicWaker = ::embassy_sync::waitqueue::AtomicWaker::new(); &WAKER } fn kernel_clk() -> Hertz { kernel_clk!($inst) } } impl Instance for peripherals::$inst {} }; ); #[cfg(feature = "embedded-sdmmc")] mod sdmmc_rs { use embedded_sdmmc::{Block, BlockCount, BlockDevice, BlockIdx}; use super::*; impl<'d, T: Instance, Dma: SdmmcDma> BlockDevice for Sdmmc<'d, T, Dma> { type Error = Error; async fn read( &mut self, blocks: &mut [Block], start_block_idx: BlockIdx, _reason: &str, ) -> Result<(), Self::Error> { let mut address = start_block_idx.0; for block in blocks.iter_mut() { let block: &mut [u8; 512] = &mut block.contents; // NOTE(unsafe) Block uses align(4) let block = unsafe { &mut *(block as *mut _ as *mut DataBlock) }; self.read_block(address, block).await?; address += 1; } Ok(()) } async fn write(&mut self, blocks: &[Block], start_block_idx: BlockIdx) -> Result<(), Self::Error> { let mut address = start_block_idx.0; for block in blocks.iter() { let block: &[u8; 512] = &block.contents; // NOTE(unsafe) DataBlock uses align 4 let block = unsafe { &*(block as *const _ as *const DataBlock) }; self.write_block(address, block).await?; address += 1; } Ok(()) } fn num_blocks(&self) -> Result { let card = self.card()?; let count = card.csd.block_count(); Ok(BlockCount(count)) } } }