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SDIO module completed

This commit is contained in:
pca006132 2020-06-05 11:47:06 +08:00
parent a53ed8acc8
commit 236592ae66
8 changed files with 1157 additions and 36 deletions

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@ -17,6 +17,7 @@ use libboard_zynq::{
iface::{NeighborCache, EthernetInterfaceBuilder, Routes},
time::Instant,
},
sdio::sd_card::SdCard,
time::Milliseconds,
};
use libsupport_zynq::{
@ -52,10 +53,40 @@ pub fn main_core0() {
IoPll::setup(1_000_000_000);
libboard_zynq::stdio::drop_uart();
}
#[cfg(feature = "target_cora_z7_10")]
{
IoPll::setup(1_000_000_000);
libboard_zynq::stdio::drop_uart();
}
info!("PLLs set up");
let clocks = zynq::clocks::Clocks::get();
info!("CPU Clocks: {}/{}/{}/{}", clocks.cpu_6x4x(), clocks.cpu_3x2x(), clocks.cpu_2x(), clocks.cpu_1x());
let mut sd = libboard_zynq::sdio::SDIO::sdio0(true);
// only test SD card if it is inserted
if sd.is_card_inserted() {
let result = SdCard::from_sdio(sd);
match &result {
Ok(_) => info!("OK!"),
Err(a) => info!("{:?}", a),
};
const SIZE: usize = 512 / 2;
let mut sd_card = result.unwrap();
let mut buffer: [u32; SIZE] = [0; SIZE];
for i in 0..buffer.len() {
buffer[i] = (i % 16) as u32;
}
sd_card.write_block(0x0, 2, &mut buffer).unwrap();
for i in 0..buffer.len() {
buffer[i] = 0;
}
sd_card.read_block(0x1, 2, &mut buffer).unwrap();
for i in 0..buffer.len() {
info!("buffer[{}] = {}", i, buffer[i]);
}
info!("End");
}
let mut flash = zynq::flash::Flash::new(200_000_000).linear_addressing_mode();
let flash_ram: &[u8] = unsafe { core::slice::from_raw_parts(flash.ptr(), flash.size()) };
for i in 0..=1 {

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@ -104,4 +104,18 @@ impl Clocks {
};
pll / u32::from(uart_clk_ctrl.divisor())
}
pub fn sdio_ref_clk(&self) -> u32 {
let regs = slcr::RegisterBlock::new();
let sdio_clk_ctrl = regs.sdio_clk_ctrl.read();
let pll = match sdio_clk_ctrl.srcsel() {
slcr::PllSource::ArmPll =>
self.arm,
slcr::PllSource::DdrPll =>
self.ddr,
slcr::PllSource::IoPll =>
self.io,
};
pll / u32::from(sdio_clk_ctrl.divisor())
}
}

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@ -0,0 +1,101 @@
/// ADMA library
use super::SDIO;
use libcortex_a9::cache;
use libregister::RegisterR;
#[repr(C, packed)]
#[derive(Clone, Copy)]
pub struct Adma2Desc32 {
attribute: u16,
length: u16,
address: u32,
}
// Default::default() cannot be used as it is not a constant function...
static mut ADMA2_DESCR32_TABLE: [Adma2Desc32; 32] = [Adma2Desc32 {
attribute: 0,
length: 0,
address: 0,
}; 32];
#[allow(unused)]
const DESC_MAX_LENGTH: u32 = 65536;
#[allow(unused)]
const DESC_TRANS: u16 = 0x2 << 4;
#[allow(unused)]
const DESC_INT: u16 = 0x1 << 2;
#[allow(unused)]
const DESC_END: u16 = 0x1 << 1;
#[allow(unused)]
const DESC_VALID: u16 = 0x1 << 0;
#[allow(unused)]
impl Adma2Desc32 {
pub fn set_attribute(&mut self, attribute: u16) {
unsafe {
core::ptr::write_volatile(&mut self.attribute as *mut u16, attribute);
}
}
pub fn get_attribute(&mut self) -> u16 {
unsafe { core::ptr::read_volatile(&mut self.attribute as *mut u16) }
}
pub fn set_length(&mut self, length: u16) {
unsafe {
core::ptr::write_volatile(&mut self.length as *mut u16, length);
}
}
pub fn get_length(&mut self) -> u16 {
unsafe { core::ptr::read_volatile(&mut self.length as *mut u16) }
}
pub fn set_address(&mut self, address: u32) {
unsafe {
core::ptr::write_volatile(&mut self.address as *mut u32, address);
}
}
pub fn get_address(&mut self) -> u32 {
unsafe { core::ptr::read_volatile(&mut self.address as *mut u32) }
}
}
pub fn setup_adma2_descr32(sdio: &mut SDIO, blk_cnt: u32, buffer: &mut [u32]) {
let descr_table = unsafe { &mut ADMA2_DESCR32_TABLE };
let blk_size = sdio
.regs
.block_size_block_count
.read()
.transfer_block_size() as u32;
let total_desc_lines = if blk_size * blk_cnt < DESC_MAX_LENGTH {
1
} else {
blk_size * blk_cnt / DESC_MAX_LENGTH
+ if (blk_size * blk_cnt) % DESC_MAX_LENGTH == 0 {
0
} else {
1
}
} as usize;
let ptr = buffer.as_ptr() as u32;
for desc_num in 0..total_desc_lines {
descr_table[desc_num].set_address(ptr + (desc_num as u32) * DESC_MAX_LENGTH);
descr_table[desc_num].set_attribute(DESC_TRANS | DESC_VALID);
// 0 is the max length (65536)
descr_table[desc_num].set_length(0);
}
descr_table[total_desc_lines - 1].set_attribute(DESC_TRANS | DESC_VALID | DESC_END);
descr_table[total_desc_lines - 1].set_length(
(blk_cnt * blk_size - ((total_desc_lines as u32) - 1) * DESC_MAX_LENGTH) as u16,
);
unsafe {
sdio.regs
.adma_system_address
.write(descr_table.as_ptr() as u32);
}
cache::dcci_slice(descr_table);
}

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@ -0,0 +1,133 @@
use super::regs;
const APP_CMD_PREFIX: u8 = 0x80;
#[allow(unused)]
pub mod args {
pub const CMD8_VOL_PATTERN: u32 = 0x1AA;
pub const RESPOCR_READY: u32 = 0x80000000;
pub const ACMD41_HCS: u32 = 0x40000000;
pub const ACMD41_3V3: u32 = 0x00300000;
pub const CMD1_HIGH_VOL: u32 = 0x00FF8000;
pub const OCR_S18: u32 = 1 << 24;
}
#[allow(unused)]
#[repr(u8)]
#[derive(Copy, Clone, PartialEq, Debug)]
pub enum SdCmd {
CMD0 = 0x00,
CMD1 = 0x01,
CMD2 = 0x02,
CMD3 = 0x03,
CMD4 = 0x04,
CMD5 = 0x05,
CMD6 = 0x06,
ACMD6 = APP_CMD_PREFIX + 0x06,
CMD7 = 0x07,
CMD8 = 0x08,
CMD9 = 0x09,
CMD10 = 0x0A,
CMD11 = 0x0B,
CMD12 = 0x0C,
ACMD13 = APP_CMD_PREFIX + 0x0D,
CMD16 = 0x10,
CMD17 = 0x11,
CMD18 = 0x12,
CMD19 = 0x13,
CMD21 = 0x15,
CMD23 = 0x17,
ACMD23 = APP_CMD_PREFIX + 0x17,
CMD24 = 0x18,
CMD25 = 0x19,
CMD41 = 0x29,
ACMD41 = APP_CMD_PREFIX + 0x29,
ACMD42 = APP_CMD_PREFIX + 0x2A,
ACMD51 = APP_CMD_PREFIX + 0x33,
CMD52 = 0x34,
CMD55 = 0x37,
CMD58 = 0x3A,
}
pub fn require_dat(cmd: SdCmd, is_sd_card: bool) -> bool {
use SdCmd::*;
match cmd {
CMD6 => is_sd_card,
CMD8 => !is_sd_card,
ACMD13 | CMD17 | CMD18 | CMD19 | CMD21 | CMD23 | ACMD23 | CMD24 | CMD25 | ACMD51 => true,
_ => false,
}
}
type CmdReg = regs::transfer_mode_command::Write;
fn resp_r1(w: CmdReg) -> CmdReg {
w.response_type_select(regs::ResponseTypeSelect::Length48)
.crc_check_en(true)
.index_check_en(true)
}
fn resp_r1b(w: CmdReg) -> CmdReg {
w.response_type_select(regs::ResponseTypeSelect::Legnth48Check)
.crc_check_en(true)
.index_check_en(true)
}
fn resp_r2(w: CmdReg) -> CmdReg {
w.response_type_select(regs::ResponseTypeSelect::Length136)
.crc_check_en(true)
}
fn resp_r3(w: CmdReg) -> CmdReg {
w.response_type_select(regs::ResponseTypeSelect::Length48)
}
fn resp_r6(w: CmdReg) -> CmdReg {
w.response_type_select(regs::ResponseTypeSelect::Legnth48Check)
.crc_check_en(true)
.index_check_en(true)
}
pub fn set_cmd_reg(cmd: SdCmd, is_sd_card: bool, w: CmdReg) -> CmdReg {
use SdCmd::*;
let w = w.command_index(cmd as u8 & 0x3F);
match cmd {
CMD1 => resp_r3(w),
CMD2 => resp_r2(w),
CMD3 => {
if is_sd_card {
resp_r6(w)
} else {
resp_r1(w)
}
}
CMD5 => resp_r1b(w),
CMD6 => {
if is_sd_card {
resp_r1(w).data_present_select(true)
} else {
resp_r1b(w)
}
}
ACMD6 => resp_r1(w),
CMD7 => resp_r1(w),
CMD8 => {
if is_sd_card {
resp_r1(w)
} else {
resp_r1(w).data_present_select(true)
}
}
CMD9 => resp_r2(w),
CMD10 | CMD11 | CMD12 => resp_r1(w),
ACMD13 => resp_r1(w).data_present_select(true),
CMD16 => resp_r1(w),
CMD17 | CMD18 | CMD19 | CMD21 | CMD23 | ACMD23 | CMD24 | CMD25 => {
resp_r1(w).data_present_select(true)
}
ACMD41 => resp_r3(w),
ACMD42 => resp_r1(w),
ACMD51 => resp_r1(w).data_present_select(true),
CMD52 | CMD55 => resp_r1(w),
_ => w,
}
}

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@ -1 +1,436 @@
mod regs;
pub mod sd_card;
mod adma;
mod cmd;
mod regs;
use super::clocks::Clocks;
use super::slcr;
use super::time::Milliseconds;
use embedded_hal::timer::CountDown;
use libregister::{RegisterR, RegisterRW, RegisterW};
use log::debug;
use nb;
/// Basic SDIO Struct with common low-level functions.
pub struct SDIO {
regs: &'static mut regs::RegisterBlock,
count_down: super::timer::global::CountDown,
input_clk_hz: u32,
card_type: CardType,
card_detect: bool,
}
#[derive(Debug)]
pub enum CmdTransferError {
CmdInhibited,
DatLineInhibited,
CmdTimeout,
Other(regs::interrupt_status::Read),
}
#[derive(PartialEq, Debug, Clone, Copy)]
pub enum CardType {
CardNone,
CardSd,
CardMmc,
}
impl SDIO {
/// Initialize SDIO0
/// card_detect means if we would use the card detect pin,
/// false to disable card detection (assume there is card inserted)
pub fn sdio0(card_detect: bool) -> Self {
// initialization according to ps7_init.c
slcr::RegisterBlock::unlocked(|slcr| {
slcr.mio_pin_40.write(
slcr::MioPin40::zeroed()
.l3_sel(0b100)
.io_type(slcr::IoBufferType::Lvcmos18)
.speed(true),
);
slcr.mio_pin_41.write(
slcr::MioPin41::zeroed()
.l3_sel(0b100)
.io_type(slcr::IoBufferType::Lvcmos18)
.speed(true),
);
slcr.mio_pin_42.write(
slcr::MioPin42::zeroed()
.l3_sel(0b100)
.io_type(slcr::IoBufferType::Lvcmos18)
.speed(true),
);
slcr.mio_pin_43.write(
slcr::MioPin43::zeroed()
.l3_sel(0b100)
.io_type(slcr::IoBufferType::Lvcmos18)
.speed(true),
);
slcr.mio_pin_44.write(
slcr::MioPin44::zeroed()
.l3_sel(0b100)
.io_type(slcr::IoBufferType::Lvcmos18)
.speed(true),
);
slcr.mio_pin_45.write(
slcr::MioPin45::zeroed()
.l3_sel(0b100)
.io_type(slcr::IoBufferType::Lvcmos18)
.speed(true),
);
// zc706 card detect pin
#[cfg(feature = "target_zc706")]
{
unsafe {
slcr.sd0_wp_cd_sel.write(0x000E000F);
}
slcr.mio_pin_14.write(
slcr::MioPin14::zeroed()
.io_type(slcr::IoBufferType::Lvcmos18)
.pullup(true)
.tri_enable(true),
);
}
// cora card detect pin
#[cfg(feature = "target_cora_z7_10")]
{
unsafe {
slcr.sd0_wp_cd_sel.write(47 << 16);
}
slcr.mio_pin_47.write(
slcr::MioPin47::zeroed()
.io_type(slcr::IoBufferType::Lvcmos18)
.speed(true),
);
}
slcr.sdio_rst_ctrl.reset_sdio0();
slcr.aper_clk_ctrl.enable_sdio0();
slcr.sdio_clk_ctrl.enable_sdio0();
});
let clocks = Clocks::get();
let mut self_ = SDIO {
regs: regs::RegisterBlock::sdio0(),
count_down: super::timer::GlobalTimer::start().countdown(),
input_clk_hz: clocks.sdio_ref_clk(),
card_type: CardType::CardNone,
card_detect,
};
self_.init();
self_
}
/// Change clock frequency to the value less than or equal to the given value.
/// From XSdPs_Change_ClkFreq in xsdps_options.c. SPEC_V3 related code is removed as
/// our board would only be V1 or V2.
fn change_clk_freq(&mut self, freq: u32) {
debug!("Change clock frequency to {}", freq);
self.regs
.clock_control
.modify(|_, w| w.sd_clk_en(false).internal_clk_en(false));
const XSDPS_CC_MAX_DIV_CNT: u32 = 256;
// calculate clock divisor
let mut div_cnt: u32 = 0x1;
let mut divisor = 0;
while div_cnt <= XSDPS_CC_MAX_DIV_CNT {
if (self.input_clk_hz / div_cnt) <= freq {
divisor = div_cnt / 2;
break;
}
div_cnt <<= 1;
}
if div_cnt > XSDPS_CC_MAX_DIV_CNT {
panic!("No valid divisor!");
}
// enable internal clock
self.regs
.clock_control
.modify(|_, w| w.sdclk_freq_divisor(divisor as u8).internal_clk_en(true));
while !self.regs.clock_control.read().internal_clk_stable() {}
// enable SD clock
self.regs.clock_control.modify(|_, w| w.sd_clk_en(true));
}
/// Initialization based on XSdPs_CfgInitialize function in xsdps.c
fn init(&mut self) {
// poweroff
self.regs
.control
.modify(|_, w| w.bus_voltage(regs::BusVoltage::V0).bus_power(false));
if self.regs.misc_reg.read().spec_ver() == regs::SpecificationVersion::V3 {
// The documentation said the field can only be V1 or V2,
// so the code is written for V1 and V2. V3 requires special handling
// which is currently not implemented.
// I hope that this would never trigger but it is safer to put a check here.
panic!("The code written is for V1 and V2");
}
// delay to poweroff card
self.delay(1);
// reset all
debug!("Reset SDIO!");
self.regs
.clock_control
.modify(|_, w| w.software_reset_all(true));
while self.regs.clock_control.read().software_reset_all() {}
// set power to 3.3V
self.regs
.control
.modify(|_, w| w.bus_voltage(regs::BusVoltage::V33).bus_power(true));
// set clock frequency
self.change_clk_freq(400_000);
// select voltage
let capabilities = self.regs.capabilities.read();
let voltage = if capabilities.voltage_3_3() {
regs::BusVoltage::V33
} else if capabilities.voltage_3_0() {
regs::BusVoltage::V30
} else if capabilities.voltage_1_8() {
regs::BusVoltage::V18
} else {
regs::BusVoltage::V0
};
self.regs.control.modify(|_, w| w.bus_voltage(voltage));
self.regs
.control
.modify(|_, w| w.dma_select(regs::DmaSelect::ADMA2_32));
// enable all interrupt status except card interrupt
self.regs.interrupt_status_en.write(
(regs::interrupt_status_en::Write { inner: 0xFFFFFFFF })
.card_interrupt_status_en(false),
);
// disable all interrupt signals
self.regs
.interrupt_signal_en
.write(regs::InterruptSignalEn::zeroed());
// set block size to 512 by default
self.regs
.block_size_block_count
.modify(|_, w| w.transfer_block_size(512));
}
/// Delay for SDIO operations, simple wrapper for nb.
pub fn delay(&mut self, ms: u64) {
self.count_down.start(Milliseconds(ms));
nb::block!(self.count_down.wait()).unwrap();
}
/// Send SD command. Basically `cmd_transfer_with_mode` with mode
/// `regs::TransferModeCommand::zeroed()`.
/// Return: Ok if success, Err(status) if failed.
fn cmd_transfer(
&mut self,
cmd: cmd::SdCmd,
arg: u32,
block_cnt: u16,
) -> Result<(), CmdTransferError> {
self.cmd_transfer_with_mode(cmd, arg, block_cnt, regs::TransferModeCommand::zeroed())
}
/// Send SD Command with additional transfer mode.
/// This function would block until response is ready.
/// Return: Ok if success, Err(status) if failed.
fn cmd_transfer_with_mode(
&mut self,
cmd: cmd::SdCmd,
arg: u32,
block_cnt: u16,
transfer_mode: regs::transfer_mode_command::Write,
) -> Result<(), CmdTransferError> {
debug!("Send Cmd {:?}", cmd);
let state = self.regs.present_state.read();
if state.command_inhibit_cmd() {
return Err(CmdTransferError::CmdInhibited);
}
self.regs
.block_size_block_count
.modify(|_, w| w.blocks_count(block_cnt));
self.regs
.clock_control
.modify(|_, w| w.timeout_counter_value(0xE));
unsafe {
self.regs.argument.write(arg);
}
self.regs
.interrupt_status_en
.write(regs::interrupt_status_en::Write { inner: 0xFFFFFFFF });
let is_sd_card = self.card_type == CardType::CardSd;
// Check DAT Line
if cmd != cmd::SdCmd::CMD21 && cmd != cmd::SdCmd::CMD19 {
if self.regs.present_state.read().command_inhibit_dat()
&& cmd::require_dat(cmd, is_sd_card)
{
return Err(CmdTransferError::DatLineInhibited);
}
}
// Set the command registers.
self.regs
.transfer_mode_command
.write(cmd::set_cmd_reg(cmd, is_sd_card, transfer_mode));
// polling for response
loop {
let status = self.regs.interrupt_status.read();
if cmd == cmd::SdCmd::CMD21 || cmd == cmd::SdCmd::CMD19 {
if status.buffer_read_ready() {
self.regs
.interrupt_status
.modify(|_, w| w.buffer_read_ready());
break;
}
}
if status.command_complete() {
break;
}
self.check_error(&status)?;
}
// wait for command complete
while !self.regs.interrupt_status.read().command_complete() {}
self.regs
.interrupt_status
.modify(|_, w| w.command_complete());
Ok(())
}
/// Check if card is inserted.
pub fn is_card_inserted(&self) -> bool {
!self.card_detect || self.regs.present_state.read().card_inserted()
}
/// Switch voltage from 3.3V to 1.8V.
fn switch_voltage(&mut self) -> Result<(), CmdTransferError> {
use cmd::SdCmd::*;
// send switch voltage command
self.cmd_transfer(CMD11, 0, 0)?;
// wait for the lines to go low
let mut state = self.regs.present_state.read();
while state.cmd_line_level()
|| state.dat0_level()
|| state.dat1_level()
|| state.dat2_level()
|| state.dat3_level()
{
state = self.regs.present_state.read();
}
// stop the clock
self.regs
.clock_control
.modify(|_, w| w.sd_clk_en(false).internal_clk_en(false));
// enabling 1.8v in controller
self.regs
.control
.modify(|_, w| w.bus_voltage(regs::BusVoltage::V18));
// wait minimum 5ms
self.delay(5);
if self.regs.control.read().bus_voltage() != regs::BusVoltage::V18 {
// I should not wrap the error of this function into another type later.
// actually this is not correct.
return Err(CmdTransferError::CmdTimeout);
}
// wait for internal clock to stabilize
self.regs
.clock_control
.modify(|_, w| w.internal_clk_en(true));
while !self.regs.clock_control.read().internal_clk_stable() {}
// enable SD clock
self.regs.clock_control.modify(|_, w| w.sd_clk_en(true));
// wait for 1ms
self.delay(1);
// wait for CMD and DATA line to go high
state = self.regs.present_state.read();
while !state.cmd_line_level()
|| !state.dat0_level()
|| !state.dat1_level()
|| !state.dat2_level()
|| !state.dat3_level()
{
state = self.regs.present_state.read();
}
Ok(())
}
/// Detect inserted card type, and set the corresponding field.
/// Return Ok(CardType) on success, Err(CmdTransferError) when failed to identify.
pub fn identify_card(&mut self) -> Result<CardType, CmdTransferError> {
use cmd::{args::*, SdCmd::*};
// actually the delay for this one is unclear in the xilinx code.
self.delay(10);
self.cmd_transfer(CMD0, 0, 0)?;
self.card_type = match self.cmd_transfer(CMD1, ACMD41_HCS | CMD1_HIGH_VOL, 0) {
Ok(()) => CardType::CardMmc,
Err(_) => CardType::CardSd,
};
// clear all status
self.regs
.interrupt_status
.write(regs::interrupt_status::Write { inner: 0xF3FFFFFF });
self.regs
.clock_control
.modify(|_, w| w.software_reset_cmd(true));
// wait for reset completion
while self.regs.clock_control.read().software_reset_cmd() {}
Ok(self.card_type)
}
/// Modify transfer block size.
fn set_block_size(&mut self, block_size: u16) -> Result<(), CmdTransferError> {
use cmd::SdCmd::*;
let state = self.regs.present_state.read();
if state.command_inhibit_cmd()
|| state.command_inhibit_dat()
|| state.write_transfer_active()
|| state.read_transfer_active()
{
return Err(CmdTransferError::CmdInhibited);
}
debug!("Set block size to {}", block_size);
// send block write command
self.cmd_transfer(CMD16, block_size as u32, 0)?;
// set block size
self.regs
.block_size_block_count
.modify(|_, w| w.transfer_block_size(block_size));
Ok(())
}
/// Check if error occured, and reset the error status.
/// Return Err(CmdTransferError) if error occured, Ok(()) otherwise.
fn check_error(
&mut self,
status: &regs::interrupt_status::Read,
) -> Result<(), CmdTransferError> {
if status.error_interrupt() {
let err_status = if status.inner & 0xFFFE0000 == 0 {
CmdTransferError::CmdTimeout
} else {
CmdTransferError::Other(regs::interrupt_status::Read {
inner: status.inner,
})
};
// reset all error status
self.regs
.interrupt_status
.write(regs::interrupt_status::Write { inner: 0xF3FF0000 });
return Err(err_status);
}
Ok(())
}
}

View File

@ -1,7 +1,8 @@
use volatile_register::{RO, RW, WO};
use core::fmt;
use libregister::{register, register_at, register_bit, register_bits, register_bits_typed};
use volatile_register::{RO, RW};
#[allow(unused)]
#[repr(C)]
pub struct RegisterBlock {
pub sdma_system_address: RW<u32>,
@ -14,19 +15,24 @@ pub struct RegisterBlock {
/// Host. power, block gap, wakeup control
pub control: Control,
/// Clock and timeout control, and software reset register.
pub timing_control: TimingControl,
pub clock_control: ClockControl,
pub interrupt_status: InterruptStatus,
pub interrupt_status_en: InterruptStatusEn,
pub interrupt_signal_en: InterruptSignalEn,
pub auto_cmd12_error_status: AutoCmd12ErrorStatus,
pub capabilities: Capabilities,
pub unused0: RO<u32>,
pub max_current_capabilities: MaxCurrentCapabilities,
pub unused1: RO<u32>,
pub force_event: ForceEvent,
pub adma_error_status: AdmaErrorStatus,
pub adma_system_address: RW<u32>,
pub unused2: RO<u32>,
pub boot_data_timeout_counter: RW<u32>,
pub debug_selection: DebugSelection,
pub unused3: [RO<u32>; 34],
pub spi_interrupt_support: SpiInterruptSupport,
pub unused4: [RO<u32>; 2],
pub misc_reg: MiscReg,
}
@ -50,6 +56,7 @@ pub enum ResponseTypeSelect {
#[allow(unused)]
#[repr(u8)]
#[derive(PartialEq, Debug)]
pub enum BusVoltage {
/// 3.3V
V33 = 0b111,
@ -57,6 +64,8 @@ pub enum BusVoltage {
V30 = 0b110,
/// 1.8V, typ.
V18 = 0b101,
/// No power,
V0 = 0b000,
}
#[allow(unused)]
@ -64,23 +73,8 @@ pub enum BusVoltage {
pub enum DmaSelect {
SDMA = 0b00,
ADMA1 = 0b01,
ADMA2 = 0b10,
ADMA3 = 0b11,
}
#[allow(unused)]
#[repr(u8)]
/// SDCLK Frequency divisor, d(number) means baseclock divided by (number).
pub enum SdclkFreqDivisor {
D256 = 0x80,
D128 = 0x40,
D64 = 0x20,
D32 = 0x10,
D16 = 0x08,
D8 = 0x04,
D4 = 0x02,
D2 = 0x01,
D1 = 0x00,
ADMA2_32 = 0b10,
ADMA2_64 = 0b11,
}
#[allow(unused)]
@ -93,13 +87,15 @@ pub enum AdmaErrorState {
#[allow(unused)]
#[repr(u8)]
#[derive(PartialEq)]
pub enum SpecificationVersion {
V1 = 0,
V2 = 1,
V3 = 2,
}
register_at!(RegisterBlock, 0xE0100000, sd0);
register_at!(RegisterBlock, 0xE0101000, sd1);
register_at!(RegisterBlock, 0xE0100000, sdio0);
register_at!(RegisterBlock, 0xE0101000, sdio1);
register!(block_size_block_count, BlockSizeBlockCount, RW, u32);
register_bits!(
@ -328,27 +324,27 @@ register_bit!(
0
);
register!(timing_control, TimingControl, RW, u32);
register!(clock_control, ClockControl, RW, u32);
register_bit!(
timing_control,
clock_control,
/// Software reset for DAT line.
software_reset_dat,
26
);
register_bit!(
timing_control,
clock_control,
/// Software reset for CMD line.
software_reset_cmd,
25
);
register_bit!(
timing_control,
clock_control,
/// Software reset for ALL.
software_reset_all,
24
);
register_bits!(
timing_control,
clock_control,
/// Determines the interval by which DAT line time-outs are detected.
/// Interval = TMCLK * 2^(13 + val)
/// Note: 0b1111 is reserved.
@ -357,27 +353,26 @@ register_bits!(
16,
19
);
register_bits_typed!(
timing_control,
register_bits!(
clock_control,
/// Selects the frequency divisor, thus the clock frequency for SDCLK.
/// Choose the smallest possible divisor which results in a clock frequency
/// that is less than or equal to the target frequency.
sdclk_freq_divisor,
u8,
SdclkFreqDivisor,
8,
15
);
register_bit!(timing_control, sd_clk_en, 2);
register_bit!(clock_control, sd_clk_en, 2);
register_bit!(
timing_control,
clock_control,
/// 1 when SD clock is stable.
/// Note that this field is read-only.
internal_clk_stable,
1,
RO
);
register_bit!(timing_control, internal_clk_en, 0);
register_bit!(clock_control, internal_clk_en, 0);
register!(interrupt_status, InterruptStatus, RW, u32, 1 << 15 | 1 << 8);
register_bit!(interrupt_status, ceata_error, 29, WTC);
@ -545,3 +540,9 @@ register_bits!(
0,
7
);
impl fmt::Debug for interrupt_status::Read {
fn fmt(&self, fmt: &mut fmt::Formatter) -> fmt::Result {
fmt.write_fmt(format_args!("status: {:0X}", self.inner))
}
}

View File

@ -0,0 +1,350 @@
use super::{adma::setup_adma2_descr32, cmd, CardType, CmdTransferError, SDIO};
use libcortex_a9::cache;
use libregister::{RegisterR, RegisterRW, RegisterW};
use log::debug;
#[derive(Debug)]
pub enum CardInitializationError {
AlreadyInitialized,
NoCardInserted,
InitializationFailedOther,
InitializationFailedCmd(CmdTransferError),
}
impl From<CmdTransferError> for CardInitializationError {
fn from(error: CmdTransferError) -> Self {
CardInitializationError::InitializationFailedCmd(error)
}
}
#[derive(Debug)]
enum CardVersion {
SdVer1,
SdVer2,
}
pub struct SdCard {
sdio: SDIO,
card_version: CardVersion,
hcs: bool,
card_id: [u32; 4],
rel_card_addr: u32,
sector_cnt: u32,
switch_1v8: bool,
width_4_bit: bool,
}
const BLK_SIZE_MASK: u16 = 0x00000FFF;
impl core::fmt::Display for SdCard {
fn fmt(&self, f: &mut core::fmt::Formatter) -> core::fmt::Result {
write!(f, "SdCard: \n card version: {:?}\n hcs: {}\n card id: {:?}\n rel card addr: {}\n sector count: {}",
self.card_version, self.hcs, self.card_id, self.rel_card_addr, self.sector_cnt)
}
}
impl SdCard {
fn sd_card_initialize(&mut self) -> Result<(), CardInitializationError> {
use cmd::{args::*, SdCmd::*};
if !self.sdio.is_card_inserted() {
return Err(CardInitializationError::NoCardInserted);
}
// CMD0
self.sdio.cmd_transfer(CMD0, 0, 0)?;
match self.sdio.cmd_transfer(CMD8, CMD8_VOL_PATTERN, 0) {
Err(CmdTransferError::CmdTimeout) => {
// reset
self.sdio
.regs
.clock_control
.modify(|_, w| w.software_reset_cmd(true));
// wait until reset is completed
while self.sdio.regs.clock_control.read().software_reset_cmd() {}
}
// for other error, return initialization failed
Err(e) => return Err(CardInitializationError::from(e)),
_ => (),
}
self.card_version = if self.sdio.regs.responses[0].read() != CMD8_VOL_PATTERN {
CardVersion::SdVer1
} else {
CardVersion::SdVer2
};
// send ACMD41 while card is still busy with power up
loop {
self.sdio.cmd_transfer(CMD55, 0, 0)?;
self.sdio
.cmd_transfer(ACMD41, ACMD41_HCS | ACMD41_3V3 | (0x1FF << 15), 0)?;
if (self.sdio.regs.responses[0].read() & RESPOCR_READY) != 0 {
break;
}
}
let response = self.sdio.regs.responses[0].read();
// update HCS support flag
self.hcs = (response & ACMD41_HCS) != 0;
if (response & OCR_S18) != 0 {
self.switch_1v8 = true;
self.sdio.switch_voltage()?;
}
self.sdio.cmd_transfer(CMD2, 0, 0)?;
for i in 0..=3 {
self.card_id[i] = self.sdio.regs.responses[i].read();
}
self.rel_card_addr = 0;
while self.rel_card_addr == 0 {
self.sdio.cmd_transfer(CMD3, 0, 0)?;
self.rel_card_addr = self.sdio.regs.responses[0].read() & 0xFFFF0000;
}
self.sdio.cmd_transfer(CMD9, self.rel_card_addr, 0)?;
self.sdio
.regs
.interrupt_status
.modify(|_, w| w.transfer_complete());
let mut csd: [u32; 4] = [0, 0, 0, 0];
for i in 0..=3 {
csd[i] = self.sdio.regs.responses[i].read();
debug!("CSD[{}] = {:0X}", i, csd[i]);
}
const CSD_STRUCT_MSK: u32 = 0x00C00000;
const C_SIZE_MULT_MASK: u32 = 0x00000380;
const C_SIZE_LOWER_MASK: u32 = 0xFFC00000;
const C_SIZE_UPPER_MASK: u32 = 0x00000003;
const READ_BLK_LEN_MASK: u32 = 0x00000F00;
const CSD_V2_C_SIZE_MASK: u32 = 0x3FFFFF00;
const XSDPS_BLK_SIZE_512_MASK: u32 = 0x200;
if ((csd[3] & CSD_STRUCT_MSK) >> 22) == 0 {
let blk_len = 1 << ((csd[2] & READ_BLK_LEN_MASK) >> 8);
let mult = 1 << (((csd[1] & C_SIZE_MULT_MASK) >> 7) + 2);
let mut device_size = (csd[1] & C_SIZE_LOWER_MASK) >> 22;
device_size |= (csd[2] & C_SIZE_UPPER_MASK) << 10;
device_size = (device_size + 1) * mult;
device_size = device_size * blk_len;
self.sector_cnt = device_size / XSDPS_BLK_SIZE_512_MASK;
} else if ((csd[3] & CSD_STRUCT_MSK) >> 22) == 1 {
self.sector_cnt = (((csd[1] & CSD_V2_C_SIZE_MASK) >> 8) + 1) * 1024;
} else {
return Err(CardInitializationError::InitializationFailedOther);
}
self.sdio.change_clk_freq(25_000_000);
// CMD7: select card
self.sdio.cmd_transfer(CMD7, self.rel_card_addr, 0)?;
// pull up
self.sdio.cmd_transfer(CMD55, self.rel_card_addr, 0)?;
self.sdio.cmd_transfer(ACMD42, 0, 0)?;
let mut scr: [u32; 8] = [0; 8];
self.get_bus_width(&mut scr)?;
debug!("{:?}", scr);
if scr[1] & 0x4 != 0 {
// 4bit support
debug!("4 bit support");
self.change_bus_width()?;
}
self.sdio.set_block_size(512)?;
Ok(())
}
/// Convert SDIO into SdCard struct, error if no card inserted or it is not an SD card.
pub fn from_sdio(mut sdio: SDIO) -> Result<Self, CardInitializationError> {
match sdio.identify_card()? {
CardType::CardSd => (),
_ => return Err(CardInitializationError::NoCardInserted),
};
let mut _self = SdCard {
sdio,
card_version: CardVersion::SdVer1,
hcs: false,
card_id: [0, 0, 0, 0],
rel_card_addr: 0,
sector_cnt: 0,
switch_1v8: false,
width_4_bit: false,
};
_self.sd_card_initialize()?;
Ok(_self)
}
/// Convert SdCard struct back to SDIO struct.
pub fn to_sdio(self) -> SDIO {
self.sdio
}
/// read blocks starting from an address. Each block has length 512 byte.
/// Note that the address is block address, i.e. 0 for 0~512, 1 for 512~1024, etc.
pub fn read_block(
&mut self,
address: u32,
block_cnt: u16,
buffer: &mut [u32],
) -> Result<(), CmdTransferError> {
assert!(buffer.len() >= (block_cnt as usize) * (512 / 4));
// set block size if not set already
if self
.sdio
.regs
.block_size_block_count
.read()
.transfer_block_size()
!= 512
{
self.sdio.set_block_size(512)?;
}
setup_adma2_descr32(&mut self.sdio, block_cnt as u32, buffer);
// invalidate D cache, required for ZC706, not sure for Cora Z7 10
cache::dcci_slice(buffer);
let cmd = if block_cnt == 1 {
cmd::SdCmd::CMD17
} else {
cmd::SdCmd::CMD18
};
let mode = if block_cnt == 1 {
super::regs::TransferModeCommand::zeroed()
.block_count_en(true)
.direction_select(true)
.dma_en(true)
} else {
super::regs::TransferModeCommand::zeroed()
.auto_cmd12_en(true)
.block_count_en(true)
.direction_select(true)
.multi_block_en(true)
.dma_en(true)
};
self.sdio
.cmd_transfer_with_mode(cmd, address, block_cnt, mode)?;
self.wait_transfer_complete()?;
cache::dcci_slice(buffer);
Ok(())
}
/// write blocks starting from an address. Each block has length 512 byte.
/// Note that the address is block address, i.e. 0 for 0~512, 1 for 512~1024, etc.
pub fn write_block(
&mut self,
address: u32,
block_cnt: u16,
buffer: &mut [u32],
) -> Result<(), CmdTransferError> {
assert!(buffer.len() >= (block_cnt as usize) * (512 / 4));
// set block size if not set already
if self
.sdio
.regs
.block_size_block_count
.read()
.transfer_block_size()
!= 512
{
self.sdio.set_block_size(512)?;
}
setup_adma2_descr32(&mut self.sdio, block_cnt as u32, buffer);
// invalidate D cache, required for ZC706, not sure for Cora Z7 10
cache::dcci_slice(buffer);
let cmd = if block_cnt == 1 {
cmd::SdCmd::CMD24
} else {
cmd::SdCmd::CMD25
};
let mode = if block_cnt == 1 {
super::regs::TransferModeCommand::zeroed()
.block_count_en(true)
.dma_en(true)
} else {
super::regs::TransferModeCommand::zeroed()
.auto_cmd12_en(true)
.block_count_en(true)
.multi_block_en(true)
.dma_en(true)
};
self.sdio
.cmd_transfer_with_mode(cmd, address, block_cnt, mode)?;
// wait for transfer complete interrupt
self.wait_transfer_complete()?;
cache::dcci_slice(buffer);
Ok(())
}
fn get_bus_width(&mut self, buf: &mut [u32]) -> Result<(), CmdTransferError> {
use cmd::SdCmd::*;
debug!("Getting bus width");
for i in 0..8 {
buf[i] = 0;
}
// send block write command
self.sdio.cmd_transfer(CMD55, self.rel_card_addr, 0)?;
let blk_cnt: u16 = 1;
let blk_size: u16 = 8 & BLK_SIZE_MASK;
self.sdio
.regs
.block_size_block_count
.modify(|_, w| w.transfer_block_size(blk_size));
setup_adma2_descr32(&mut self.sdio, blk_cnt as u32, buf);
cache::dcci_slice(buf);
self.sdio.cmd_transfer_with_mode(
ACMD51,
0,
blk_cnt,
super::regs::TransferModeCommand::zeroed()
.dma_en(true)
.direction_select(true),
)?;
self.wait_transfer_complete()?;
cache::dcci_slice(buf);
Ok(())
}
fn change_bus_width(&mut self) -> Result<(), CmdTransferError> {
use cmd::SdCmd::*;
debug!("Changing bus speed");
self.sdio.cmd_transfer(CMD55, self.rel_card_addr, 0)?;
self.width_4_bit = true;
self.sdio.cmd_transfer(ACMD6, 0x2, 0)?;
self.sdio.delay(1);
self.sdio
.regs
.control
.modify(|_, w| w.data_width_select(true));
Ok(())
}
fn wait_transfer_complete(&mut self) -> Result<(), CmdTransferError> {
debug!("Wait for transfer complete");
let mut status = self.sdio.regs.interrupt_status.read();
while !status.transfer_complete() {
self.sdio.check_error(&status)?;
status = self.sdio.regs.interrupt_status.read();
}
debug!("Clearing transfer complete");
self.sdio
.regs
.interrupt_status
.modify(|_, w| w.transfer_complete());
Ok(())
}
}

View File

@ -94,7 +94,7 @@ pub struct RegisterBlock {
pub gem1_clk_ctrl: GemClkCtrl,
pub smc_clk_ctrl: RW<u32>,
pub lqspi_clk_ctrl: LqspiClkCtrl,
pub sdio_clk_ctrl: RW<u32>,
pub sdio_clk_ctrl: SdioClkCtrl,
pub uart_clk_ctrl: UartClkCtrl,
pub spi_clk_ctrl: RW<u32>,
pub can_clk_ctrl: RW<u32>,
@ -127,7 +127,7 @@ pub struct RegisterBlock {
pub dmac_rst_ctrl: RW<u32>,
pub usb_rst_ctrl: RW<u32>,
pub gem_rst_ctrl: RW<u32>,
pub sdio_rst_ctrl: RW<u32>,
pub sdio_rst_ctrl: SdioRstCtrl,
pub spi_rst_ctrl: RW<u32>,
pub can_rst_ctrl: RW<u32>,
pub i2c_rst_ctrl: RW<u32>,
@ -391,6 +391,8 @@ register_bit!(clk_621_true, clk_621_true, 0);
register!(aper_clk_ctrl, AperClkCtrl, RW, u32);
register_bit!(aper_clk_ctrl, uart1_cpu_1xclkact, 21);
register_bit!(aper_clk_ctrl, uart0_cpu_1xclkact, 20);
register_bit!(aper_clk_ctrl, sdio1_cpu_1xclkact, 11);
register_bit!(aper_clk_ctrl, sdio0_cpu_1xclkact, 10);
impl AperClkCtrl {
pub fn enable_uart0(&mut self) {
self.modify(|_, w| w.uart0_cpu_1xclkact(true));
@ -399,6 +401,14 @@ impl AperClkCtrl {
pub fn enable_uart1(&mut self) {
self.modify(|_, w| w.uart1_cpu_1xclkact(true));
}
pub fn enable_sdio0(&mut self) {
self.modify(|_, w| w.sdio0_cpu_1xclkact(true));
}
pub fn enable_sdio1(&mut self) {
self.modify(|_, w| w.sdio1_cpu_1xclkact(true));
}
}
register!(rclk_ctrl, RclkCtrl, RW, u32);
@ -423,6 +433,24 @@ register_bit!(gem_clk_ctrl,
/// SMC reference clock control
clkact, 0);
register!(sdio_clk_ctrl, SdioClkCtrl, RW, u32);
register_bit!(sdio_clk_ctrl, clkact0, 0);
register_bit!(sdio_clk_ctrl, clkact1, 1);
register_bits!(sdio_clk_ctrl, divisor, u8, 8, 13);
register_bits_typed!(sdio_clk_ctrl, srcsel, u8, PllSource, 4, 5);
impl SdioClkCtrl {
pub fn enable_sdio0(&mut self) {
self.modify(|_, w| {
w.divisor(0x14).srcsel(PllSource::IoPll).clkact0(true)
})
}
pub fn enable_sdio1(&mut self) {
self.modify(|_, w| {
w.divisor(0x14).srcsel(PllSource::IoPll).clkact1(true)
})
}
}
register!(uart_clk_ctrl, UartClkCtrl, RW, u32);
register_bit!(uart_clk_ctrl, clkact0, 0);
register_bit!(uart_clk_ctrl, clkact1, 1);
@ -453,6 +481,34 @@ impl UartClkCtrl {
}
}
register!(sdio_rst_ctrl, SdioRstCtrl, RW, u32);
register_bit!(sdio_rst_ctrl, sdio1_ref_rst, 5);
register_bit!(sdio_rst_ctrl, sdio0_ref_rst, 4);
register_bit!(sdio_rst_ctrl, sdio1_cpu1x_rst, 1);
register_bit!(sdio_rst_ctrl, sdio0_cpu1x_rst, 0);
impl SdioRstCtrl {
pub fn reset_sdio0(&mut self) {
self.modify(|_, w|
w.sdio0_ref_rst(true)
.sdio0_cpu1x_rst(true)
);
self.modify(|_, w|
w.sdio0_ref_rst(false)
.sdio0_cpu1x_rst(false)
);
}
pub fn reset_sdio1(&mut self) {
self.modify(|_, w|
w.sdio1_ref_rst(true)
.sdio1_cpu1x_rst(true)
);
self.modify(|_, w|
w.sdio1_ref_rst(false)
.sdio1_cpu1x_rst(false)
);
}
}
register!(uart_rst_ctrl, UartRstCtrl, RW, u32);
register_bit!(uart_rst_ctrl, uart0_ref_rst, 3);
register_bit!(uart_rst_ctrl, uart1_ref_rst, 2);