rp-hal-boards/boards/rp-pico/examples/pico_spi_sd_card.rs

//! # Pico SD Card Example
//!
//! Reads and writes a file from/to the SD Card that is formatted in FAT32.
//! This example uses the SPI0 device of the Raspberry Pi Pico on the
//! pins 4,5,6 and 7. If you don't use an external 3.3V power source,
//! you can connect the +3.3V output on pin 36 to the SD card.
//!
//! SD Cards up to 2TB are supported by the `embedded_sdmmc` crate.
//! I've tested this with a 64GB micro SD card.
//!
//! You need to format the card with an regular old FAT32 filesystem
//! and also make sure the first partition has the right type. This is how your
//! `fdisk` output should look like:
//!
//! ```text
//!     fdisk /dev/sdj
//!
//!     Welcome to fdisk (util-linux 2.34).
//!     Changes will remain in memory only, until you decide to write them.
//!     Be careful before using the write command.
//!
//!     Command (m for help): Disk /dev/sdj:
//!     59,49 GiB, 63864569856 bytes, 124735488 sectors
//!     Disk model: SD/MMC/MS/MSPRO
//!     Units: sectors of 1 * 512 = 512 bytes
//!     Sector size (logical/physical): 512 bytes / 512 bytes
//!     I/O size (minimum/optimal): 512 bytes / 512 bytes
//!     Disklabel type: dos
//!     Disk identifier: 0x00000000
//!
//!     Device     Boot Start       End   Sectors  Size Id Type
//!     /dev/sdj1        2048 124735487 124733440 59,5G  c W95 FAT32 (LBA)
//! ```
//!
//! The important bit here is the _Type_ with `W95 FAT32 (LBA)`, other types
//! are rejected by the `embedded_sdmmc` filesystem implementation.
//!
//! Formatting the partition can be done using `mkfs.fat`:
//!
//!     $ mkfs.fat /dev/sdj1
//!
//! In the following ASCII art the SD card is also connected to 5 strong pull up
//! resistors. I've found varying values for these, from 50kOhm, 10kOhm
//! down to 5kOhm.
//! Stronger pull up resistors will eat more amperes, but also allow faster
//! data rates.
//!
//! ```text
//!                    +3.3V
//!          Pull Ups ->||||
//!                 4x[5kOhm]
//!                     ||| \
//!  _______________    |||  \
//! |     DAT2/NC  9\---o||   \                            _|USB|_
//! | S   DAT3/CS   1|---o+----+------SS--\               |1  R 40|
//! | D   CMD/DI    2|----o----+-----MOSI-+-\             |2  P 39|
//! |     VSS1      3|-- GND   |          | |         GND-|3    38|- GND
//! | C   VDD       4|-- +3.3V |  /--SCK--+-+----SPI0 SCK-|4  P 37|
//! | A   CLK/SCK   5|---------+-/        | \----SPI0 TX--|5  I 36|- +3.3V
//! | R   VSS2      6|-- GND   |  /--MISO-+------SPI0 RX--|6  C   |
//! | D   DAT0/DO   7|---------o-/        \------SPI0 CSn-|7  O   |
//! |     DAT1/IRQ  8|-[5k]- +3.3V                        |       |
//!  """"""""""""""""                                     |       |
//!                                                       |       |
//!                                                       .........
//!                                                       |20   21|
//!                                                        """""""
//! Symbols:
//!     - (+) crossing lines, not connected
//!     - (o) connected lines
//! ```
//!
//! The example can either be used with a probe to receive debug output
//! and also the LED is used as status output. There are different blinking
//! patterns.
//!
//! For every successful stage in the example the LED will blink long once.
//! If everything is successful (9 long blink signals), the example will go
//! into a loop and either blink in a _"short long"_ or _"short short long"_ pattern.
//!
//! If there are 5 different error patterns, all with short blinking pulses:
//!
//! - **2 short blink (in a loop)**: Block device could not be aquired, either
//!   no SD card is present or some electrical problem.
//! - **3 short blink (in a loop)**: Card size could not be retrieved.
//! - **4 short blink (in a loop)**: Error getting volume/partition 0.
//! - **5 short blink (in a loop)**: Error opening root directory.
//! - **6 short blink (in a loop)**: Could not open file 'O.TST'.
//!
//! See the `Cargo.toml` file for Copyright and licence details.

#![no_std]
#![no_main]

// The macro for our start-up function
use cortex_m_rt::entry;

// info!() and error!() macros for printing information to the debug output
use defmt::*;
use defmt_rtt as _;

// Ensure we halt the program on panic (if we don't mention this crate it won't
// be linked)
use panic_halt as _;

// Pull in any important traits
use rp_pico::hal::prelude::*;

// Embed the `Hz` function/trait:
use embedded_time::rate::*;

// A shorter alias for the Peripheral Access Crate, which provides low-level
// register access
use rp_pico::hal::pac;

// Import the SPI abstraction:
use rp_pico::hal::spi;

// Import the GPIO abstraction:
use rp_pico::hal::gpio;

// A shorter alias for the Hardware Abstraction Layer, which provides
// higher-level drivers.
use rp_pico::hal;

// Link in the embedded_sdmmc crate.
// The `SdMmcSpi` is used for block level access to the card.
// And the `Controller` gives access to the FAT filesystem functions.
use embedded_sdmmc::{Controller, SdMmcSpi, TimeSource, Timestamp, VolumeIdx};

// Get the file open mode enum:
use embedded_sdmmc::filesystem::Mode;

/// A dummy timesource, which is mostly important for creating files.
#[derive(Default)]
pub struct DummyTimesource();

impl TimeSource for DummyTimesource {
    // In theory you could use the RTC of the rp2040 here, if you had
    // any external time synchronizing device.
    fn get_timestamp(&self) -> Timestamp {
        Timestamp {
            year_since_1970: 0,
            zero_indexed_month: 0,
            zero_indexed_day: 0,
            hours: 0,
            minutes: 0,
            seconds: 0,
        }
    }
}

// Setup some blinking codes:
const BLINK_OK_LONG: [u8; 1] = [8u8];
const BLINK_OK_SHORT_LONG: [u8; 4] = [1u8, 0u8, 6u8, 0u8];
const BLINK_OK_SHORT_SHORT_LONG: [u8; 6] = [1u8, 0u8, 1u8, 0u8, 6u8, 0u8];
const BLINK_ERR_2_SHORT: [u8; 4] = [1u8, 0u8, 1u8, 0u8];
const BLINK_ERR_3_SHORT: [u8; 6] = [1u8, 0u8, 1u8, 0u8, 1u8, 0u8];
const BLINK_ERR_4_SHORT: [u8; 8] = [1u8, 0u8, 1u8, 0u8, 1u8, 0u8, 1u8, 0u8];
const BLINK_ERR_5_SHORT: [u8; 10] = [1u8, 0u8, 1u8, 0u8, 1u8, 0u8, 1u8, 0u8, 1u8, 0u8];
const BLINK_ERR_6_SHORT: [u8; 12] = [1u8, 0u8, 1u8, 0u8, 1u8, 0u8, 1u8, 0u8, 1u8, 0u8, 1u8, 0u8];

fn blink_signals(
    pin: &mut dyn embedded_hal::digital::v2::OutputPin<Error = core::convert::Infallible>,
    delay: &mut cortex_m::delay::Delay,
    sig: &[u8],
) {
    for bit in sig {
        if *bit != 0 {
            pin.set_high().unwrap();
        } else {
            pin.set_low().unwrap();
        }

        let length = if *bit > 0 { *bit } else { 1 };

        for _ in 0..length {
            delay.delay_ms(100);
        }
    }

    pin.set_low().unwrap();

    delay.delay_ms(500);
}

fn blink_signals_loop(
    pin: &mut dyn embedded_hal::digital::v2::OutputPin<Error = core::convert::Infallible>,
    delay: &mut cortex_m::delay::Delay,
    sig: &[u8],
) -> ! {
    loop {
        blink_signals(pin, delay, sig);
        delay.delay_ms(1000);
    }
}

#[entry]
fn main() -> ! {
    info!("Program start");

    // Grab our singleton objects
    let mut pac = pac::Peripherals::take().unwrap();
    let core = pac::CorePeripherals::take().unwrap();

    // Set up the watchdog driver - needed by the clock setup code
    let mut watchdog = hal::Watchdog::new(pac.WATCHDOG);

    // Configure the clocks
    //
    // The default is to generate a 125 MHz system clock
    let clocks = hal::clocks::init_clocks_and_plls(
        rp_pico::XOSC_CRYSTAL_FREQ,
        pac.XOSC,
        pac.CLOCKS,
        pac.PLL_SYS,
        pac.PLL_USB,
        &mut pac.RESETS,
        &mut watchdog,
    )
    .ok()
    .unwrap();

    // The single-cycle I/O block controls our GPIO pins
    let sio = hal::Sio::new(pac.SIO);

    // Set the pins up according to their function on this particular board
    let pins = rp_pico::Pins::new(
        pac.IO_BANK0,
        pac.PADS_BANK0,
        sio.gpio_bank0,
        &mut pac.RESETS,
    );

    // Set the LED to be an output
    let mut led_pin = pins.led.into_push_pull_output();

    // Setup a delay for the LED blink signals:
    let mut delay = cortex_m::delay::Delay::new(core.SYST, clocks.system_clock.freq().integer());

    // These are implicitly used by the spi driver if they are in the correct mode
    let _spi_sclk = pins.gpio2.into_mode::<gpio::FunctionSpi>();
    let _spi_mosi = pins.gpio3.into_mode::<gpio::FunctionSpi>();
    let _spi_miso = pins.gpio4.into_mode::<gpio::FunctionSpi>();
    let spi_cs = pins.gpio5.into_push_pull_output();

    // Create an SPI driver instance for the SPI0 device
    let spi = spi::Spi::<_, _, 8>::new(pac.SPI0);

    // Exchange the uninitialised SPI driver for an initialised one
    let spi = spi.init(
        &mut pac.RESETS,
        clocks.peripheral_clock.freq(),
        16_000_000u32.Hz(),
        &embedded_hal::spi::MODE_0,
    );

    info!("Aquire SPI SD/MMC BlockDevice...");
    let mut sdspi = SdMmcSpi::new(spi, spi_cs);

    blink_signals(&mut led_pin, &mut delay, &BLINK_OK_LONG);

    // Next we need to aquire the block device and initialize the
    // communication with the SD card.
    let block = match sdspi.acquire() {
        Ok(block) => block,
        Err(e) => {
            error!("Error retrieving card size: {}", defmt::Debug2Format(&e));
            blink_signals_loop(&mut led_pin, &mut delay, &BLINK_ERR_2_SHORT);
        }
    };

    blink_signals(&mut led_pin, &mut delay, &BLINK_OK_LONG);

    info!("Init SD card controller...");
    let mut cont = Controller::new(block, DummyTimesource::default());

    blink_signals(&mut led_pin, &mut delay, &BLINK_OK_LONG);

    info!("OK!\nCard size...");
    match cont.device().card_size_bytes() {
        Ok(size) => info!("card size is {} bytes", size),
        Err(e) => {
            error!("Error retrieving card size: {}", defmt::Debug2Format(&e));
            blink_signals_loop(&mut led_pin, &mut delay, &BLINK_ERR_3_SHORT);
        }
    }

    blink_signals(&mut led_pin, &mut delay, &BLINK_OK_LONG);

    info!("Getting Volume 0...");
    let mut volume = match cont.get_volume(VolumeIdx(0)) {
        Ok(v) => v,
        Err(e) => {
            error!("Error getting volume 0: {}", defmt::Debug2Format(&e));
            blink_signals_loop(&mut led_pin, &mut delay, &BLINK_ERR_4_SHORT);
        }
    };

    blink_signals(&mut led_pin, &mut delay, &BLINK_OK_LONG);

    // After we have the volume (partition) of the drive we got to open the
    // root directory:
    let dir = match cont.open_root_dir(&volume) {
        Ok(dir) => dir,
        Err(e) => {
            error!("Error opening root dir: {}", defmt::Debug2Format(&e));
            blink_signals_loop(&mut led_pin, &mut delay, &BLINK_ERR_5_SHORT);
        }
    };

    info!("Root directory opened!");
    blink_signals(&mut led_pin, &mut delay, &BLINK_OK_LONG);

    // This shows how to iterate through the directory and how
    // to get the file names (and print them in hope they are UTF-8 compatible):
    cont.iterate_dir(&volume, &dir, |ent| {
        info!(
            "/{}.{}",
            core::str::from_utf8(ent.name.base_name()).unwrap(),
            core::str::from_utf8(ent.name.extension()).unwrap()
        );
    })
    .unwrap();

    blink_signals(&mut led_pin, &mut delay, &BLINK_OK_LONG);

    let mut successful_read = false;

    // Next we going to read a file from the SD card:
    if let Ok(mut file) = cont.open_file_in_dir(&mut volume, &dir, "O.TST", Mode::ReadOnly) {
        let mut buf = [0u8; 32];
        let read_count = cont.read(&volume, &mut file, &mut buf).unwrap();
        cont.close_file(&volume, file).unwrap();

        if read_count >= 2 {
            info!("READ {} bytes: {}", read_count, buf);

            // If we read what we wrote before the last reset,
            // we set a flag so that the success blinking at the end
            // changes it's pattern.
            if buf[0] == 0x42 && buf[1] == 0x1E {
                successful_read = true;
            }
        }
    }

    blink_signals(&mut led_pin, &mut delay, &BLINK_OK_LONG);

    match cont.open_file_in_dir(&mut volume, &dir, "O.TST", Mode::ReadWriteCreateOrTruncate) {
        Ok(mut file) => {
            cont.write(&mut volume, &mut file, b"\x42\x1E").unwrap();
            cont.close_file(&volume, file).unwrap();
        }
        Err(e) => {
            error!("Error opening file 'O.TST': {}", defmt::Debug2Format(&e));
            blink_signals_loop(&mut led_pin, &mut delay, &BLINK_ERR_6_SHORT);
        }
    }

    cont.free();

    blink_signals(&mut led_pin, &mut delay, &BLINK_OK_LONG);

    if successful_read {
        info!("Successfully read previously written file 'O.TST'");
    } else {
        info!("Could not read file, which is ok for the first run.");
        info!("Reboot the pico!");
    }

    loop {
        if successful_read {
            blink_signals(&mut led_pin, &mut delay, &BLINK_OK_SHORT_SHORT_LONG);
        } else {
            blink_signals(&mut led_pin, &mut delay, &BLINK_OK_SHORT_LONG);
        }

        delay.delay_ms(1000);
    }
}
Add an example for accessing an SD/MMC card via SPI (#258) 2022-01-10 00:16:35 +11:00			`//! # Pico SD Card Example`
			`//!`
			`//! Reads and writes a file from/to the SD Card that is formatted in FAT32.`
			`//! This example uses the SPI0 device of the Raspberry Pi Pico on the`
			`//! pins 4,5,6 and 7. If you don't use an external 3.3V power source,`
			`//! you can connect the +3.3V output on pin 36 to the SD card.`
			`//!`
			//! SD Cards up to 2TB are supported by the `embedded_sdmmc` crate.
			`//! I've tested this with a 64GB micro SD card.`
			`//!`
			`//! You need to format the card with an regular old FAT32 filesystem`
			`//! and also make sure the first partition has the right type. This is how your`
			//! `fdisk` output should look like:
			`//!`
			//! ```text
			`//! fdisk /dev/sdj`
			`//!`
			`//! Welcome to fdisk (util-linux 2.34).`
			`//! Changes will remain in memory only, until you decide to write them.`
			`//! Be careful before using the write command.`
			`//!`
			`//! Command (m for help): Disk /dev/sdj:`
			`//! 59,49 GiB, 63864569856 bytes, 124735488 sectors`
			`//! Disk model: SD/MMC/MS/MSPRO`
			`//! Units: sectors of 1 * 512 = 512 bytes`
			`//! Sector size (logical/physical): 512 bytes / 512 bytes`
			`//! I/O size (minimum/optimal): 512 bytes / 512 bytes`
			`//! Disklabel type: dos`
			`//! Disk identifier: 0x00000000`
			`//!`
			`//! Device Boot Start End Sectors Size Id Type`
			`//! /dev/sdj1 2048 124735487 124733440 59,5G c W95 FAT32 (LBA)`
			//! ```
			`//!`
			//! The important bit here is the _Type_ with `W95 FAT32 (LBA)`, other types
			//! are rejected by the `embedded_sdmmc` filesystem implementation.
			`//!`
			//! Formatting the partition can be done using `mkfs.fat`:
			`//!`
			`//! $ mkfs.fat /dev/sdj1`
			`//!`
			`//! In the following ASCII art the SD card is also connected to 5 strong pull up`
			`//! resistors. I've found varying values for these, from 50kOhm, 10kOhm`
			`//! down to 5kOhm.`
			`//! Stronger pull up resistors will eat more amperes, but also allow faster`
			`//! data rates.`
			`//!`
			//! ```text
			`//! +3.3V`
			`//! Pull Ups ->\|\|\|\|`
			`//! 4x[5kOhm]`
			`//! \|\|\| \`
			`//! _______________ \|\|\| \`
			`//! \| DAT2/NC 9\---o\|\| \ _\|USB\|_`
			`//! \| S DAT3/CS 1\|---o+----+------SS--\ \|1 R 40\|`
			`//! \| D CMD/DI 2\|----o----+-----MOSI-+-\ \|2 P 39\|`
			`//! \| VSS1 3\|-- GND \| \| \| GND-\|3 38\|- GND`
			`//! \| C VDD 4\|-- +3.3V \| /--SCK--+-+----SPI0 SCK-\|4 P 37\|`
			`//! \| A CLK/SCK 5\|---------+-/ \| \----SPI0 TX--\|5 I 36\|- +3.3V`
			`//! \| R VSS2 6\|-- GND \| /--MISO-+------SPI0 RX--\|6 C \|`
			`//! \| D DAT0/DO 7\|---------o-/ \------SPI0 CSn-\|7 O \|`
			`//! \| DAT1/IRQ 8\|-[5k]- +3.3V \| \|`
			`//! """""""""""""""" \| \|`
			`//! \| \|`
			`//! .........`
			`//! \|20 21\|`
			`//! """""""`
			`//! Symbols:`
			`//! - (+) crossing lines, not connected`
			`//! - (o) connected lines`
			//! ```
			`//!`
			`//! The example can either be used with a probe to receive debug output`
			`//! and also the LED is used as status output. There are different blinking`
			`//! patterns.`
			`//!`
			`//! For every successful stage in the example the LED will blink long once.`
			`//! If everything is successful (9 long blink signals), the example will go`
			`//! into a loop and either blink in a _"short long"_ or _"short short long"_ pattern.`
			`//!`
			`//! If there are 5 different error patterns, all with short blinking pulses:`
			`//!`
			`//! - 2 short blink (in a loop): Block device could not be aquired, either`
			`//! no SD card is present or some electrical problem.`
			`//! - 3 short blink (in a loop): Card size could not be retrieved.`
			`//! - 4 short blink (in a loop): Error getting volume/partition 0.`
			`//! - 5 short blink (in a loop): Error opening root directory.`
			`//! - 6 short blink (in a loop): Could not open file 'O.TST'.`
			`//!`
			//! See the `Cargo.toml` file for Copyright and licence details.

			`#![no_std]`
			`#![no_main]`

			`// The macro for our start-up function`
			`use cortex_m_rt::entry;`

			`// info!() and error!() macros for printing information to the debug output`
			`use defmt::*;`
			`use defmt_rtt as _;`

			`// Ensure we halt the program on panic (if we don't mention this crate it won't`
			`// be linked)`
			`use panic_halt as _;`

			`// Pull in any important traits`
			`use rp_pico::hal::prelude::*;`

			// Embed the `Hz` function/trait:
			`use embedded_time::rate::*;`

			`// A shorter alias for the Peripheral Access Crate, which provides low-level`
			`// register access`
			`use rp_pico::hal::pac;`

			`// Import the SPI abstraction:`
			`use rp_pico::hal::spi;`

			`// Import the GPIO abstraction:`
			`use rp_pico::hal::gpio;`

			`// A shorter alias for the Hardware Abstraction Layer, which provides`
			`// higher-level drivers.`
			`use rp_pico::hal;`

			`// Link in the embedded_sdmmc crate.`
			// The `SdMmcSpi` is used for block level access to the card.
			// And the `Controller` gives access to the FAT filesystem functions.
			`use embedded_sdmmc::{Controller, SdMmcSpi, TimeSource, Timestamp, VolumeIdx};`

			`// Get the file open mode enum:`
			`use embedded_sdmmc::filesystem::Mode;`

			`/// A dummy timesource, which is mostly important for creating files.`
			`#[derive(Default)]`
			`pub struct DummyTimesource();`

			`impl TimeSource for DummyTimesource {`
			`// In theory you could use the RTC of the rp2040 here, if you had`
			`// any external time synchronizing device.`
			`fn get_timestamp(&self) -> Timestamp {`
			`Timestamp {`
			`year_since_1970: 0,`
			`zero_indexed_month: 0,`
			`zero_indexed_day: 0,`
			`hours: 0,`
			`minutes: 0,`
			`seconds: 0,`
			`}`
			`}`
			`}`

			`// Setup some blinking codes:`
			`const BLINK_OK_LONG: [u8; 1] = [8u8];`
			`const BLINK_OK_SHORT_LONG: [u8; 4] = [1u8, 0u8, 6u8, 0u8];`
			`const BLINK_OK_SHORT_SHORT_LONG: [u8; 6] = [1u8, 0u8, 1u8, 0u8, 6u8, 0u8];`
			`const BLINK_ERR_2_SHORT: [u8; 4] = [1u8, 0u8, 1u8, 0u8];`
			`const BLINK_ERR_3_SHORT: [u8; 6] = [1u8, 0u8, 1u8, 0u8, 1u8, 0u8];`
			`const BLINK_ERR_4_SHORT: [u8; 8] = [1u8, 0u8, 1u8, 0u8, 1u8, 0u8, 1u8, 0u8];`
			`const BLINK_ERR_5_SHORT: [u8; 10] = [1u8, 0u8, 1u8, 0u8, 1u8, 0u8, 1u8, 0u8, 1u8, 0u8];`
			`const BLINK_ERR_6_SHORT: [u8; 12] = [1u8, 0u8, 1u8, 0u8, 1u8, 0u8, 1u8, 0u8, 1u8, 0u8, 1u8, 0u8];`

			`fn blink_signals(`
			`pin: &mut dyn embedded_hal::digital::v2::OutputPin<Error = core::convert::Infallible>,`
			`delay: &mut cortex_m::delay::Delay,`
			`sig: &[u8],`
			`) {`
			`for bit in sig {`
			`if *bit != 0 {`
			`pin.set_high().unwrap();`
			`} else {`
			`pin.set_low().unwrap();`
			`}`

			`let length = if bit > 0 { bit } else { 1 };`

			`for _ in 0..length {`
			`delay.delay_ms(100);`
			`}`
			`}`

			`pin.set_low().unwrap();`

			`delay.delay_ms(500);`
			`}`

			`fn blink_signals_loop(`
			`pin: &mut dyn embedded_hal::digital::v2::OutputPin<Error = core::convert::Infallible>,`
			`delay: &mut cortex_m::delay::Delay,`
			`sig: &[u8],`
			`) -> ! {`
			`loop {`
			`blink_signals(pin, delay, sig);`
			`delay.delay_ms(1000);`
			`}`
			`}`

			`#[entry]`
			`fn main() -> ! {`
			`info!("Program start");`

			`// Grab our singleton objects`
			`let mut pac = pac::Peripherals::take().unwrap();`
			`let core = pac::CorePeripherals::take().unwrap();`

			`// Set up the watchdog driver - needed by the clock setup code`
			`let mut watchdog = hal::Watchdog::new(pac.WATCHDOG);`

			`// Configure the clocks`
			`//`
			`// The default is to generate a 125 MHz system clock`
			`let clocks = hal::clocks::init_clocks_and_plls(`
			`rp_pico::XOSC_CRYSTAL_FREQ,`
			`pac.XOSC,`
			`pac.CLOCKS,`
			`pac.PLL_SYS,`
			`pac.PLL_USB,`
			`&mut pac.RESETS,`
			`&mut watchdog,`
			`)`
			`.ok()`
			`.unwrap();`

			`// The single-cycle I/O block controls our GPIO pins`
			`let sio = hal::Sio::new(pac.SIO);`

			`// Set the pins up according to their function on this particular board`
			`let pins = rp_pico::Pins::new(`
			`pac.IO_BANK0,`
			`pac.PADS_BANK0,`
			`sio.gpio_bank0,`
			`&mut pac.RESETS,`
			`);`

			`// Set the LED to be an output`
			`let mut led_pin = pins.led.into_push_pull_output();`

			`// Setup a delay for the LED blink signals:`
			`let mut delay = cortex_m::delay::Delay::new(core.SYST, clocks.system_clock.freq().integer());`

			`// These are implicitly used by the spi driver if they are in the correct mode`
			`let _spi_sclk = pins.gpio2.into_mode::<gpio::FunctionSpi>();`
			`let _spi_mosi = pins.gpio3.into_mode::<gpio::FunctionSpi>();`
			`let _spi_miso = pins.gpio4.into_mode::<gpio::FunctionSpi>();`
			`let spi_cs = pins.gpio5.into_push_pull_output();`

			`// Create an SPI driver instance for the SPI0 device`
			`let spi = spi::Spi::<_, _, 8>::new(pac.SPI0);`

			`// Exchange the uninitialised SPI driver for an initialised one`
			`let spi = spi.init(`
			`&mut pac.RESETS,`
			`clocks.peripheral_clock.freq(),`
			`16_000_000u32.Hz(),`
			`&embedded_hal::spi::MODE_0,`
			`);`

			`info!("Aquire SPI SD/MMC BlockDevice...");`
			`let mut sdspi = SdMmcSpi::new(spi, spi_cs);`

			`blink_signals(&mut led_pin, &mut delay, &BLINK_OK_LONG);`

			`// Next we need to aquire the block device and initialize the`
			`// communication with the SD card.`
			`let block = match sdspi.acquire() {`
			`Ok(block) => block,`
			`Err(e) => {`
			`error!("Error retrieving card size: {}", defmt::Debug2Format(&e));`
			`blink_signals_loop(&mut led_pin, &mut delay, &BLINK_ERR_2_SHORT);`
			`}`
			`};`

			`blink_signals(&mut led_pin, &mut delay, &BLINK_OK_LONG);`

			`info!("Init SD card controller...");`
			`let mut cont = Controller::new(block, DummyTimesource::default());`

			`blink_signals(&mut led_pin, &mut delay, &BLINK_OK_LONG);`

			`info!("OK!\nCard size...");`
			`match cont.device().card_size_bytes() {`
			`Ok(size) => info!("card size is {} bytes", size),`
			`Err(e) => {`
			`error!("Error retrieving card size: {}", defmt::Debug2Format(&e));`
			`blink_signals_loop(&mut led_pin, &mut delay, &BLINK_ERR_3_SHORT);`
			`}`
			`}`

			`blink_signals(&mut led_pin, &mut delay, &BLINK_OK_LONG);`

			`info!("Getting Volume 0...");`
			`let mut volume = match cont.get_volume(VolumeIdx(0)) {`
			`Ok(v) => v,`
			`Err(e) => {`
			`error!("Error getting volume 0: {}", defmt::Debug2Format(&e));`
			`blink_signals_loop(&mut led_pin, &mut delay, &BLINK_ERR_4_SHORT);`
			`}`
			`};`

			`blink_signals(&mut led_pin, &mut delay, &BLINK_OK_LONG);`

			`// After we have the volume (partition) of the drive we got to open the`
			`// root directory:`
			`let dir = match cont.open_root_dir(&volume) {`
			`Ok(dir) => dir,`
			`Err(e) => {`
			`error!("Error opening root dir: {}", defmt::Debug2Format(&e));`
			`blink_signals_loop(&mut led_pin, &mut delay, &BLINK_ERR_5_SHORT);`
			`}`
			`};`

			`info!("Root directory opened!");`
			`blink_signals(&mut led_pin, &mut delay, &BLINK_OK_LONG);`

			`// This shows how to iterate through the directory and how`
			`// to get the file names (and print them in hope they are UTF-8 compatible):`
			`cont.iterate_dir(&volume, &dir, \|ent\| {`
			`info!(`
			`"/{}.{}",`
			`core::str::from_utf8(ent.name.base_name()).unwrap(),`
			`core::str::from_utf8(ent.name.extension()).unwrap()`
			`);`
			`})`
			`.unwrap();`

			`blink_signals(&mut led_pin, &mut delay, &BLINK_OK_LONG);`

			`let mut successful_read = false;`

			`// Next we going to read a file from the SD card:`
			`if let Ok(mut file) = cont.open_file_in_dir(&mut volume, &dir, "O.TST", Mode::ReadOnly) {`
			`let mut buf = [0u8; 32];`
			`let read_count = cont.read(&volume, &mut file, &mut buf).unwrap();`
			`cont.close_file(&volume, file).unwrap();`

			`if read_count >= 2 {`
			`info!("READ {} bytes: {}", read_count, buf);`

			`// If we read what we wrote before the last reset,`
			`// we set a flag so that the success blinking at the end`
			`// changes it's pattern.`
			`if buf[0] == 0x42 && buf[1] == 0x1E {`
			`successful_read = true;`
			`}`
			`}`
			`}`

			`blink_signals(&mut led_pin, &mut delay, &BLINK_OK_LONG);`

			`match cont.open_file_in_dir(&mut volume, &dir, "O.TST", Mode::ReadWriteCreateOrTruncate) {`
			`Ok(mut file) => {`
			`cont.write(&mut volume, &mut file, b"\x42\x1E").unwrap();`
			`cont.close_file(&volume, file).unwrap();`
			`}`
			`Err(e) => {`
			`error!("Error opening file 'O.TST': {}", defmt::Debug2Format(&e));`
			`blink_signals_loop(&mut led_pin, &mut delay, &BLINK_ERR_6_SHORT);`
			`}`
			`}`

			`cont.free();`

			`blink_signals(&mut led_pin, &mut delay, &BLINK_OK_LONG);`

			`if successful_read {`
			`info!("Successfully read previously written file 'O.TST'");`
			`} else {`
			`info!("Could not read file, which is ok for the first run.");`
			`info!("Reboot the pico!");`
			`}`

			`loop {`
			`if successful_read {`
			`blink_signals(&mut led_pin, &mut delay, &BLINK_OK_SHORT_SHORT_LONG);`
			`} else {`
			`blink_signals(&mut led_pin, &mut delay, &BLINK_OK_SHORT_LONG);`
			`}`

			`delay.delay_ms(1000);`
			`}`
			`}`