2 files changed, 434 insertions, 0 deletions
diff --git a/embassy-rp/src/pio_programs/mod.rs b/embassy-rp/src/pio_programs/mod.rs
index 8eac328b3..d05ba3884 100644
--- a/embassy-rp/src/pio_programs/mod.rs
+++ b/embassy-rp/src/pio_programs/mod.rs
@@ -6,6 +6,7 @@ pub mod i2s;
 pub mod onewire;
 pub mod pwm;
 pub mod rotary_encoder;
+pub mod spi;
 pub mod stepper;
 pub mod uart;
 pub mod ws2812;
diff --git a/embassy-rp/src/pio_programs/spi.rs b/embassy-rp/src/pio_programs/spi.rs
new file mode 100644
index 000000000..27d401fc9
--- /dev/null
+++ b/embassy-rp/src/pio_programs/spi.rs
@@ -0,0 +1,433 @@
+//! PIO backed SPi drivers
+use core::marker::PhantomData;
+use embassy_futures::join::join;
+use embassy_hal_internal::Peri;
+use embedded_hal_02::spi::{Phase, Polarity};
+use fixed::{traits::ToFixed, types::extra::U8};
+use crate::{
+    clocks::clk_sys_freq,
+    dma::{AnyChannel, Channel},
+    gpio::Level,
+    pio::{Common, Direction, Instance, LoadedProgram, PioPin, ShiftDirection, StateMachine},
+    spi::{Async, Blocking, Mode},
+};
+/// This struct represents a uart tx program loaded into pio instruction memory.
+pub struct PioSpiProgram<'d, PIO: crate::pio::Instance> {
+    prg: LoadedProgram<'d, PIO>,
+}
+impl<'d, PIO: crate::pio::Instance> PioSpiProgram<'d, PIO> {
+    /// Load the spi program into the given pio
+    pub fn new(common: &mut crate::pio::Common<'d, PIO>, phase: Phase) -> Self {
+        // These PIO programs are taken straight from the datasheet (3.6.1 in
+        // RP2040 datasheet, 11.6.1 in RP2350 datasheet)
+        // Pin assignments:
+        // - SCK is side-set pin 0
+        // - MOSI is OUT pin 0
+        // - MISO is IN pin 0
+        //
+        // Autopush and autopull must be enabled, and the serial frame size is set by
+        // configuring the push/pull threshold. Shift left/right is fine, but you must
+        // justify the data yourself. This is done most conveniently for frame sizes of
+        // 8 or 16 bits by using the narrow store replication and narrow load byte
+        // picking behaviour of RP2040's IO fabric.
+        let prg = match phase {
+            Phase::CaptureOnFirstTransition => {
+                let prg = pio::pio_asm!(
+                    r#"
+                        .side_set 1
+                        ; Clock phase = 0: data is captured on the leading edge of each SCK pulse, and
+                        ; transitions on the trailing edge, or some time before the first leading edge.
+                        out pins, 1 side 0 [1] ; Stall here on empty (sideset proceeds even if
+                        in pins, 1  side 1 [1] ; instruction stalls, so we stall with SCK low)
+                    "#
+                );
+                common.load_program(&prg.program)
+            }
+            Phase::CaptureOnSecondTransition => {
+                let prg = pio::pio_asm!(
+                    r#"
+                        .side_set 1
+                        ; Clock phase = 1: data transitions on the leading edge of each SCK pulse, and
+                        ; is captured on the trailing edge.
+                        out x, 1    side 0     ; Stall here on empty (keep SCK deasserted)
+                        mov pins, x side 1 [1] ; Output data, assert SCK (mov pins uses OUT mapping)
+                        in pins, 1  side 0     ; Input data, deassert SCK
+                    "#
+                );
+                common.load_program(&prg.program)
+            }
+        };
+        Self { prg }
+    }
+}
+/// PIO SPI errors.
+#[derive(Debug, Clone, Copy, PartialEq, Eq)]
+#[cfg_attr(feature = "defmt", derive(defmt::Format))]
+#[non_exhaustive]
+pub enum Error {
+    // No errors for now
+}
+/// PIO based Spi driver.
+///
+/// This driver is less flexible than the hardware backed one. Configuration can
+/// not be changed at runtime.
+pub struct Spi<'d, PIO: Instance, const SM: usize, M: Mode> {
+    sm: StateMachine<'d, PIO, SM>,
+    tx_dma: Option<Peri<'d, AnyChannel>>,
+    rx_dma: Option<Peri<'d, AnyChannel>>,
+    phantom: PhantomData<M>,
+}
+/// PIO SPI configuration.
+#[non_exhaustive]
+#[derive(Clone)]
+pub struct Config {
+    /// Frequency (Hz).
+    pub frequency: u32,
+    /// Polarity.
+    pub polarity: Polarity,
+}
+impl Default for Config {
+    fn default() -> Self {
+        Self {
+            frequency: 1_000_000,
+            polarity: Polarity::IdleLow,
+        }
+    }
+}
+impl<'d, PIO: Instance, const SM: usize, M: Mode> Spi<'d, PIO, SM, M> {
+    #[allow(clippy::too_many_arguments)]
+    fn new_inner(
+        pio: &mut Common<'d, PIO>,
+        mut sm: StateMachine<'d, PIO, SM>,
+        clk_pin: Peri<'d, impl PioPin>,
+        mosi_pin: Peri<'d, impl PioPin>,
+        miso_pin: Peri<'d, impl PioPin>,
+        tx_dma: Option<Peri<'d, AnyChannel>>,
+        rx_dma: Option<Peri<'d, AnyChannel>>,
+        program: &PioSpiProgram<'d, PIO>,
+        config: Config,
+    ) -> Self {
+        let mut clk_pin = pio.make_pio_pin(clk_pin);
+        let mosi_pin = pio.make_pio_pin(mosi_pin);
+        let miso_pin = pio.make_pio_pin(miso_pin);
+        if let Polarity::IdleHigh = config.polarity {
+            clk_pin.set_output_inversion(true);
+        } else {
+            clk_pin.set_output_inversion(false);
+        }
+        sm.set_pins(Level::Low, &[&clk_pin, &mosi_pin]);
+        sm.set_pin_dirs(Direction::Out, &[&clk_pin, &mosi_pin]);
+        sm.set_pin_dirs(Direction::In, &[&miso_pin]);
+        let mut cfg = crate::pio::Config::default();
+        cfg.use_program(&program.prg, &[&clk_pin]);
+        cfg.set_out_pins(&[&mosi_pin]);
+        cfg.set_in_pins(&[&miso_pin]);
+        cfg.shift_in.auto_fill = true;
+        cfg.shift_in.direction = ShiftDirection::Left;
+        cfg.shift_in.threshold = 8;
+        cfg.shift_out.auto_fill = true;
+        cfg.shift_out.direction = ShiftDirection::Left;
+        cfg.shift_out.threshold = 8;
+        let sys_freq = clk_sys_freq().to_fixed::<fixed::FixedU64<U8>>();
+        let target_freq = (config.frequency * 4).to_fixed::<fixed::FixedU64<U8>>();
+        cfg.clock_divider = (sys_freq / target_freq).to_fixed();
+        sm.set_config(&cfg);
+        sm.set_enable(true);
+        Self {
+            sm,
+            tx_dma,
+            rx_dma,
+            phantom: PhantomData,
+        }
+    }
+    fn blocking_read_u8(&mut self) -> Result<u8, Error> {
+        while self.sm.rx().empty() {}
+        let value = self.sm.rx().pull() as u8;
+        Ok(value)
+    }
+    fn blocking_write_u8(&mut self, v: u8) -> Result<(), Error> {
+        let value = u32::from_be_bytes([v, 0, 0, 0]);
+        while !self.sm.tx().try_push(value) {}
+        // need to clear here for flush to work correctly
+        self.sm.tx().stalled();
+        Ok(())
+    }
+    /// Read data from SPI blocking execution until done.
+    pub fn blocking_read(&mut self, data: &mut [u8]) -> Result<(), Error> {
+        for v in data {
+            self.blocking_write_u8(0)?;
+            *v = self.blocking_read_u8()?;
+        }
+        self.flush()?;
+        Ok(())
+    }
+    /// Write data to SPI blocking execution until done.
+    pub fn blocking_write(&mut self, data: &[u8]) -> Result<(), Error> {
+        for v in data {
+            self.blocking_write_u8(*v)?;
+            let _ = self.blocking_read_u8()?;
+        }
+        self.flush()?;
+        Ok(())
+    }
+    /// Transfer data to SPI blocking execution until done.
+    pub fn blocking_transfer(&mut self, read: &mut [u8], write: &[u8]) -> Result<(), Error> {
+        let len = read.len().max(write.len());
+        for i in 0..len {
+            let wb = write.get(i).copied().unwrap_or(0);
+            self.blocking_write_u8(wb)?;
+            let rb = self.blocking_read_u8()?;
+            if let Some(r) = read.get_mut(i) {
+                *r = rb;
+            }
+        }
+        self.flush()?;
+        Ok(())
+    }
+    /// Transfer data in place to SPI blocking execution until done.
+    pub fn blocking_transfer_in_place(&mut self, data: &mut [u8]) -> Result<(), Error> {
+        for v in data {
+            self.blocking_write_u8(*v)?;
+            *v = self.blocking_read_u8()?;
+        }
+        self.flush()?;
+        Ok(())
+    }
+    /// Block execution until SPI is done.
+    pub fn flush(&mut self) -> Result<(), Error> {
+        // Wait for all words in the FIFO to have been pulled by the SM
+        while !self.sm.tx().empty() {}
+        // Wait for last value to be written out to the wire
+        while !self.sm.tx().stalled() {}
+        Ok(())
+    }
+}
+impl<'d, PIO: Instance, const SM: usize> Spi<'d, PIO, SM, Blocking> {
+    /// Create an SPI driver in blocking mode.
+    pub fn new_blocking(
+        pio: &mut Common<'d, PIO>,
+        sm: StateMachine<'d, PIO, SM>,
+        clk: Peri<'d, impl PioPin>,
+        mosi: Peri<'d, impl PioPin>,
+        miso: Peri<'d, impl PioPin>,
+        program: &PioSpiProgram<'d, PIO>,
+        config: Config,
+    ) -> Self {
+        Self::new_inner(pio, sm, clk, mosi, miso, None, None, program, config)
+    }
+}
+impl<'d, PIO: Instance, const SM: usize> Spi<'d, PIO, SM, Async> {
+    /// Create an SPI driver in async mode supporting DMA operations.
+    #[allow(clippy::too_many_arguments)]
+    pub fn new(
+        pio: &mut Common<'d, PIO>,
+        sm: StateMachine<'d, PIO, SM>,
+        clk: Peri<'d, impl PioPin>,
+        mosi: Peri<'d, impl PioPin>,
+        miso: Peri<'d, impl PioPin>,
+        tx_dma: Peri<'d, impl Channel>,
+        rx_dma: Peri<'d, impl Channel>,
+        program: &PioSpiProgram<'d, PIO>,
+        config: Config,
+    ) -> Self {
+        Self::new_inner(
+            pio,
+            sm,
+            clk,
+            mosi,
+            miso,
+            Some(tx_dma.into()),
+            Some(rx_dma.into()),
+            program,
+            config,
+        )
+    }
+    /// Read data from SPI using DMA.
+    pub async fn read(&mut self, buffer: &mut [u8]) -> Result<(), Error> {
+        let (rx, tx) = self.sm.rx_tx();
+        let len = buffer.len();
+        let rx_ch = self.rx_dma.as_mut().unwrap().reborrow();
+        let rx_transfer = rx.dma_pull(rx_ch, buffer, false);
+        let tx_ch = self.tx_dma.as_mut().unwrap().reborrow();
+        let tx_transfer = tx.dma_push_repeated::<_, u8>(tx_ch, len);
+        join(tx_transfer, rx_transfer).await;
+        Ok(())
+    }
+    /// Write data to SPI using DMA.
+    pub async fn write(&mut self, buffer: &[u8]) -> Result<(), Error> {
+        let (rx, tx) = self.sm.rx_tx();
+        let rx_ch = self.rx_dma.as_mut().unwrap().reborrow();
+        let rx_transfer = rx.dma_pull_repeated::<_, u8>(rx_ch, buffer.len());
+        let tx_ch = self.tx_dma.as_mut().unwrap().reborrow();
+        let tx_transfer = tx.dma_push(tx_ch, buffer, false);
+        join(tx_transfer, rx_transfer).await;
+        Ok(())
+    }
+    /// Transfer data to SPI using DMA.
+    pub async fn transfer(&mut self, rx_buffer: &mut [u8], tx_buffer: &[u8]) -> Result<(), Error> {
+        self.transfer_inner(rx_buffer, tx_buffer).await
+    }
+    /// Transfer data in place to SPI using DMA.
+    pub async fn transfer_in_place(&mut self, words: &mut [u8]) -> Result<(), Error> {
+        self.transfer_inner(words, words).await
+    }
+    async fn transfer_inner(&mut self, rx_buffer: *mut [u8], tx_buffer: *const [u8]) -> Result<(), Error> {
+        let (rx, tx) = self.sm.rx_tx();
+        let mut rx_ch = self.rx_dma.as_mut().unwrap().reborrow();
+        let rx_transfer = async {
+            rx.dma_pull(rx_ch.reborrow(), unsafe { &mut *rx_buffer }, false).await;
+            if tx_buffer.len() > rx_buffer.len() {
+                let read_bytes_len = tx_buffer.len() - rx_buffer.len();
+                rx.dma_pull_repeated::<_, u8>(rx_ch, read_bytes_len).await;
+            }
+        };
+        let mut tx_ch = self.tx_dma.as_mut().unwrap().reborrow();
+        let tx_transfer = async {
+            tx.dma_push(tx_ch.reborrow(), unsafe { &*tx_buffer }, false).await;
+            if rx_buffer.len() > tx_buffer.len() {
+                let write_bytes_len = rx_buffer.len() - tx_buffer.len();
+                tx.dma_push_repeated::<_, u8>(tx_ch, write_bytes_len).await;
+            }
+        };
+        join(tx_transfer, rx_transfer).await;
+        Ok(())
+    }
+}
+// ====================
+impl<'d, PIO: Instance, const SM: usize, M: Mode> embedded_hal_02::blocking::spi::Transfer<u8> for Spi<'d, PIO, SM, M> {
+    type Error = Error;
+    fn transfer<'w>(&mut self, words: &'w mut [u8]) -> Result<&'w [u8], Self::Error> {
+        self.blocking_transfer_in_place(words)?;
+        Ok(words)
+    }
+}
+impl<'d, PIO: Instance, const SM: usize, M: Mode> embedded_hal_02::blocking::spi::Write<u8> for Spi<'d, PIO, SM, M> {
+    type Error = Error;
+    fn write(&mut self, words: &[u8]) -> Result<(), Self::Error> {
+        self.blocking_write(words)
+    }
+}
+impl embedded_hal_1::spi::Error for Error {
+    fn kind(&self) -> embedded_hal_1::spi::ErrorKind {
+        match *self {}
+    }
+}
+impl<'d, PIO: Instance, const SM: usize, M: Mode> embedded_hal_1::spi::ErrorType for Spi<'d, PIO, SM, M> {
+    type Error = Error;
+}
+impl<'d, PIO: Instance, const SM: usize, M: Mode> embedded_hal_1::spi::SpiBus<u8> for Spi<'d, PIO, SM, M> {
+    fn flush(&mut self) -> Result<(), Self::Error> {
+        Ok(())
+    }
+    fn read(&mut self, words: &mut [u8]) -> Result<(), Self::Error> {
+        self.blocking_transfer(words, &[])
+    }
+    fn write(&mut self, words: &[u8]) -> Result<(), Self::Error> {
+        self.blocking_write(words)
+    }
+    fn transfer(&mut self, read: &mut [u8], write: &[u8]) -> Result<(), Self::Error> {
+        self.blocking_transfer(read, write)
+    }
+    fn transfer_in_place(&mut self, words: &mut [u8]) -> Result<(), Self::Error> {
+        self.blocking_transfer_in_place(words)
+    }
+}
+impl<'d, PIO: Instance, const SM: usize> embedded_hal_async::spi::SpiBus<u8> for Spi<'d, PIO, SM, Async> {
+    async fn flush(&mut self) -> Result<(), Self::Error> {
+        Ok(())
+    }
+    async fn write(&mut self, words: &[u8]) -> Result<(), Self::Error> {
+        self.write(words).await
+    }
+    async fn read(&mut self, words: &mut [u8]) -> Result<(), Self::Error> {
+        self.read(words).await
+    }
+    async fn transfer(&mut self, read: &mut [u8], write: &[u8]) -> Result<(), Self::Error> {
+        self.transfer(read, write).await
+    }
+    async fn transfer_in_place(&mut self, words: &mut [u8]) -> Result<(), Self::Error> {
+        self.transfer_in_place(words).await
+    }
+}

diff --git a/embassy-rp/src/pio_programs/mod.rs b/embassy-rp/src/pio_programs/mod.rs index 8eac328b3..d05ba3884 100644 --- a/embassy-rp/src/pio_programs/mod.rs +++ b/embassy-rp/src/pio_programs/mod.rs
@@ -6,6 +6,7 @@ pub mod i2s;
6	pub mod onewire;	6	pub mod onewire;
7	pub mod pwm;	7	pub mod pwm;
8	pub mod rotary_encoder;	8	pub mod rotary_encoder;
		9	pub mod spi;
9	pub mod stepper;	10	pub mod stepper;
10	pub mod uart;	11	pub mod uart;
11	pub mod ws2812;	12	pub mod ws2812;


diff --git a/embassy-rp/src/pio_programs/spi.rs b/embassy-rp/src/pio_programs/spi.rs new file mode 100644 index 000000000..27d401fc9 --- /dev/null +++ b/embassy-rp/src/pio_programs/spi.rs
@@ -0,0 +1,433 @@
		1	//! PIO backed SPi drivers
		2
		3	use core::marker::PhantomData;
		4
		5	use embassy_futures::join::join;
		6	use embassy_hal_internal::Peri;
		7	use embedded_hal_02::spi::{Phase, Polarity};
		8	use fixed::{traits::ToFixed, types::extra::U8};
		9
		10	use crate::{
		11	clocks::clk_sys_freq,
		12	dma::{AnyChannel, Channel},
		13	gpio::Level,
		14	pio::{Common, Direction, Instance, LoadedProgram, PioPin, ShiftDirection, StateMachine},
		15	spi::{Async, Blocking, Mode},
		16	};
		17
		18	/// This struct represents a uart tx program loaded into pio instruction memory.
		19	pub struct PioSpiProgram<'d, PIO: crate::pio::Instance> {
		20	prg: LoadedProgram<'d, PIO>,
		21	}
		22
		23	impl<'d, PIO: crate::pio::Instance> PioSpiProgram<'d, PIO> {
		24	/// Load the spi program into the given pio
		25	pub fn new(common: &mut crate::pio::Common<'d, PIO>, phase: Phase) -> Self {
		26	// These PIO programs are taken straight from the datasheet (3.6.1 in
		27	// RP2040 datasheet, 11.6.1 in RP2350 datasheet)
		28
		29	// Pin assignments:
		30	// - SCK is side-set pin 0
		31	// - MOSI is OUT pin 0
		32	// - MISO is IN pin 0
		33	//
		34	// Autopush and autopull must be enabled, and the serial frame size is set by
		35	// configuring the push/pull threshold. Shift left/right is fine, but you must
		36	// justify the data yourself. This is done most conveniently for frame sizes of
		37	// 8 or 16 bits by using the narrow store replication and narrow load byte
		38	// picking behaviour of RP2040's IO fabric.
		39
		40	let prg = match phase {
		41	Phase::CaptureOnFirstTransition => {
		42	let prg = pio::pio_asm!(
		43	r#"
		44	.side_set 1
		45
		46	; Clock phase = 0: data is captured on the leading edge of each SCK pulse, and
		47	; transitions on the trailing edge, or some time before the first leading edge.
		48
		49	out pins, 1 side 0 [1] ; Stall here on empty (sideset proceeds even if
		50	in pins, 1 side 1 [1] ; instruction stalls, so we stall with SCK low)
		51	"#
		52	);
		53
		54	common.load_program(&prg.program)
		55	}
		56	Phase::CaptureOnSecondTransition => {
		57	let prg = pio::pio_asm!(
		58	r#"
		59	.side_set 1
		60
		61	; Clock phase = 1: data transitions on the leading edge of each SCK pulse, and
		62	; is captured on the trailing edge.
		63
		64	out x, 1 side 0 ; Stall here on empty (keep SCK deasserted)
		65	mov pins, x side 1 [1] ; Output data, assert SCK (mov pins uses OUT mapping)
		66	in pins, 1 side 0 ; Input data, deassert SCK
		67	"#
		68	);
		69
		70	common.load_program(&prg.program)
		71	}
		72	};
		73
		74	Self { prg }
		75	}
		76	}
		77
		78	/// PIO SPI errors.
		79	#[derive(Debug, Clone, Copy, PartialEq, Eq)]
		80	#[cfg_attr(feature = "defmt", derive(defmt::Format))]
		81	#[non_exhaustive]
		82	pub enum Error {
		83	// No errors for now
		84	}
		85
		86	/// PIO based Spi driver.
		87	///
		88	/// This driver is less flexible than the hardware backed one. Configuration can
		89	/// not be changed at runtime.
		90	pub struct Spi<'d, PIO: Instance, const SM: usize, M: Mode> {
		91	sm: StateMachine<'d, PIO, SM>,
		92	tx_dma: Option<Peri<'d, AnyChannel>>,
		93	rx_dma: Option<Peri<'d, AnyChannel>>,
		94	phantom: PhantomData<M>,
		95	}
		96
		97	/// PIO SPI configuration.
		98	#[non_exhaustive]
		99	#[derive(Clone)]
		100	pub struct Config {
		101	/// Frequency (Hz).
		102	pub frequency: u32,
		103	/// Polarity.
		104	pub polarity: Polarity,
		105	}
		106
		107	impl Default for Config {
		108	fn default() -> Self {
		109	Self {
		110	frequency: 1_000_000,
		111	polarity: Polarity::IdleLow,
		112	}
		113	}
		114	}
		115
		116	impl<'d, PIO: Instance, const SM: usize, M: Mode> Spi<'d, PIO, SM, M> {
		117	#[allow(clippy::too_many_arguments)]
		118	fn new_inner(
		119	pio: &mut Common<'d, PIO>,
		120	mut sm: StateMachine<'d, PIO, SM>,
		121	clk_pin: Peri<'d, impl PioPin>,
		122	mosi_pin: Peri<'d, impl PioPin>,
		123	miso_pin: Peri<'d, impl PioPin>,
		124	tx_dma: Option<Peri<'d, AnyChannel>>,
		125	rx_dma: Option<Peri<'d, AnyChannel>>,
		126	program: &PioSpiProgram<'d, PIO>,
		127	config: Config,
		128	) -> Self {
		129	let mut clk_pin = pio.make_pio_pin(clk_pin);
		130	let mosi_pin = pio.make_pio_pin(mosi_pin);
		131	let miso_pin = pio.make_pio_pin(miso_pin);
		132
		133	if let Polarity::IdleHigh = config.polarity {
		134	clk_pin.set_output_inversion(true);
		135	} else {
		136	clk_pin.set_output_inversion(false);
		137	}
		138
		139	sm.set_pins(Level::Low, &[&clk_pin, &mosi_pin]);
		140	sm.set_pin_dirs(Direction::Out, &[&clk_pin, &mosi_pin]);
		141	sm.set_pin_dirs(Direction::In, &[&miso_pin]);
		142
		143	let mut cfg = crate::pio::Config::default();
		144
		145	cfg.use_program(&program.prg, &[&clk_pin]);
		146	cfg.set_out_pins(&[&mosi_pin]);
		147	cfg.set_in_pins(&[&miso_pin]);
		148
		149	cfg.shift_in.auto_fill = true;
		150	cfg.shift_in.direction = ShiftDirection::Left;
		151	cfg.shift_in.threshold = 8;
		152
		153	cfg.shift_out.auto_fill = true;
		154	cfg.shift_out.direction = ShiftDirection::Left;
		155	cfg.shift_out.threshold = 8;
		156
		157	let sys_freq = clk_sys_freq().to_fixed::<fixed::FixedU64<U8>>();
		158	let target_freq = (config.frequency * 4).to_fixed::<fixed::FixedU64<U8>>();
		159	cfg.clock_divider = (sys_freq / target_freq).to_fixed();
		160
		161	sm.set_config(&cfg);
		162	sm.set_enable(true);
		163
		164	Self {
		165	sm,
		166	tx_dma,
		167	rx_dma,
		168	phantom: PhantomData,
		169	}
		170	}
		171
		172	fn blocking_read_u8(&mut self) -> Result<u8, Error> {
		173	while self.sm.rx().empty() {}
		174	let value = self.sm.rx().pull() as u8;
		175
		176	Ok(value)
		177	}
		178
		179	fn blocking_write_u8(&mut self, v: u8) -> Result<(), Error> {
		180	let value = u32::from_be_bytes([v, 0, 0, 0]);
		181
		182	while !self.sm.tx().try_push(value) {}
		183
		184	// need to clear here for flush to work correctly
		185	self.sm.tx().stalled();
		186
		187	Ok(())
		188	}
		189
		190	/// Read data from SPI blocking execution until done.
		191	pub fn blocking_read(&mut self, data: &mut [u8]) -> Result<(), Error> {
		192	for v in data {
		193	self.blocking_write_u8(0)?;
		194	*v = self.blocking_read_u8()?;
		195	}
		196	self.flush()?;
		197	Ok(())
		198	}
		199
		200	/// Write data to SPI blocking execution until done.
		201	pub fn blocking_write(&mut self, data: &[u8]) -> Result<(), Error> {
		202	for v in data {
		203	self.blocking_write_u8(*v)?;
		204	let _ = self.blocking_read_u8()?;
		205	}
		206	self.flush()?;
		207	Ok(())
		208	}
		209
		210	/// Transfer data to SPI blocking execution until done.
		211	pub fn blocking_transfer(&mut self, read: &mut [u8], write: &[u8]) -> Result<(), Error> {
		212	let len = read.len().max(write.len());
		213	for i in 0..len {
		214	let wb = write.get(i).copied().unwrap_or(0);
		215	self.blocking_write_u8(wb)?;
		216
		217	let rb = self.blocking_read_u8()?;
		218	if let Some(r) = read.get_mut(i) {
		219	*r = rb;
		220	}
		221	}
		222	self.flush()?;
		223	Ok(())
		224	}
		225
		226	/// Transfer data in place to SPI blocking execution until done.
		227	pub fn blocking_transfer_in_place(&mut self, data: &mut [u8]) -> Result<(), Error> {
		228	for v in data {
		229	self.blocking_write_u8(*v)?;
		230	*v = self.blocking_read_u8()?;
		231	}
		232	self.flush()?;
		233	Ok(())
		234	}
		235
		236	/// Block execution until SPI is done.
		237	pub fn flush(&mut self) -> Result<(), Error> {
		238	// Wait for all words in the FIFO to have been pulled by the SM
		239	while !self.sm.tx().empty() {}
		240
		241	// Wait for last value to be written out to the wire
		242	while !self.sm.tx().stalled() {}
		243
		244	Ok(())
		245	}
		246	}
		247
		248	impl<'d, PIO: Instance, const SM: usize> Spi<'d, PIO, SM, Blocking> {
		249	/// Create an SPI driver in blocking mode.
		250	pub fn new_blocking(
		251	pio: &mut Common<'d, PIO>,
		252	sm: StateMachine<'d, PIO, SM>,
		253	clk: Peri<'d, impl PioPin>,
		254	mosi: Peri<'d, impl PioPin>,
		255	miso: Peri<'d, impl PioPin>,
		256	program: &PioSpiProgram<'d, PIO>,
		257	config: Config,
		258	) -> Self {
		259	Self::new_inner(pio, sm, clk, mosi, miso, None, None, program, config)
		260	}
		261	}
		262
		263	impl<'d, PIO: Instance, const SM: usize> Spi<'d, PIO, SM, Async> {
		264	/// Create an SPI driver in async mode supporting DMA operations.
		265	#[allow(clippy::too_many_arguments)]
		266	pub fn new(
		267	pio: &mut Common<'d, PIO>,
		268	sm: StateMachine<'d, PIO, SM>,
		269	clk: Peri<'d, impl PioPin>,
		270	mosi: Peri<'d, impl PioPin>,
		271	miso: Peri<'d, impl PioPin>,
		272	tx_dma: Peri<'d, impl Channel>,
		273	rx_dma: Peri<'d, impl Channel>,
		274	program: &PioSpiProgram<'d, PIO>,
		275	config: Config,
		276	) -> Self {
		277	Self::new_inner(
		278	pio,
		279	sm,
		280	clk,
		281	mosi,
		282	miso,
		283	Some(tx_dma.into()),
		284	Some(rx_dma.into()),
		285	program,
		286	config,
		287	)
		288	}
		289
		290	/// Read data from SPI using DMA.
		291	pub async fn read(&mut self, buffer: &mut [u8]) -> Result<(), Error> {
		292	let (rx, tx) = self.sm.rx_tx();
		293
		294	let len = buffer.len();
		295
		296	let rx_ch = self.rx_dma.as_mut().unwrap().reborrow();
		297	let rx_transfer = rx.dma_pull(rx_ch, buffer, false);
		298
		299	let tx_ch = self.tx_dma.as_mut().unwrap().reborrow();
		300	let tx_transfer = tx.dma_push_repeated::<_, u8>(tx_ch, len);
		301
		302	join(tx_transfer, rx_transfer).await;
		303
		304	Ok(())
		305	}
		306
		307	/// Write data to SPI using DMA.
		308	pub async fn write(&mut self, buffer: &[u8]) -> Result<(), Error> {
		309	let (rx, tx) = self.sm.rx_tx();
		310
		311	let rx_ch = self.rx_dma.as_mut().unwrap().reborrow();
		312	let rx_transfer = rx.dma_pull_repeated::<_, u8>(rx_ch, buffer.len());
		313
		314	let tx_ch = self.tx_dma.as_mut().unwrap().reborrow();
		315	let tx_transfer = tx.dma_push(tx_ch, buffer, false);
		316
		317	join(tx_transfer, rx_transfer).await;
		318
		319	Ok(())
		320	}
		321
		322	/// Transfer data to SPI using DMA.
		323	pub async fn transfer(&mut self, rx_buffer: &mut [u8], tx_buffer: &[u8]) -> Result<(), Error> {
		324	self.transfer_inner(rx_buffer, tx_buffer).await
		325	}
		326
		327	/// Transfer data in place to SPI using DMA.
		328	pub async fn transfer_in_place(&mut self, words: &mut [u8]) -> Result<(), Error> {
		329	self.transfer_inner(words, words).await
		330	}
		331
		332	async fn transfer_inner(&mut self, rx_buffer: mut [u8], tx_buffer: const [u8]) -> Result<(), Error> {
		333	let (rx, tx) = self.sm.rx_tx();
		334
		335	let mut rx_ch = self.rx_dma.as_mut().unwrap().reborrow();
		336	let rx_transfer = async {
		337	rx.dma_pull(rx_ch.reborrow(), unsafe { &mut *rx_buffer }, false).await;
		338
		339	if tx_buffer.len() > rx_buffer.len() {
		340	let read_bytes_len = tx_buffer.len() - rx_buffer.len();
		341
		342	rx.dma_pull_repeated::<_, u8>(rx_ch, read_bytes_len).await;
		343	}
		344	};
		345
		346	let mut tx_ch = self.tx_dma.as_mut().unwrap().reborrow();
		347	let tx_transfer = async {
		348	tx.dma_push(tx_ch.reborrow(), unsafe { &*tx_buffer }, false).await;
		349
		350	if rx_buffer.len() > tx_buffer.len() {
		351	let write_bytes_len = rx_buffer.len() - tx_buffer.len();
		352
		353	tx.dma_push_repeated::<_, u8>(tx_ch, write_bytes_len).await;
		354	}
		355	};
		356
		357	join(tx_transfer, rx_transfer).await;
		358
		359	Ok(())
		360	}
		361	}
		362
		363	// ====================
		364
		365	impl<'d, PIO: Instance, const SM: usize, M: Mode> embedded_hal_02::blocking::spi::Transfer<u8> for Spi<'d, PIO, SM, M> {
		366	type Error = Error;
		367	fn transfer<'w>(&mut self, words: &'w mut [u8]) -> Result<&'w [u8], Self::Error> {
		368	self.blocking_transfer_in_place(words)?;
		369	Ok(words)
		370	}
		371	}
		372
		373	impl<'d, PIO: Instance, const SM: usize, M: Mode> embedded_hal_02::blocking::spi::Write<u8> for Spi<'d, PIO, SM, M> {
		374	type Error = Error;
		375
		376	fn write(&mut self, words: &[u8]) -> Result<(), Self::Error> {
		377	self.blocking_write(words)
		378	}
		379	}
		380
		381	impl embedded_hal_1::spi::Error for Error {
		382	fn kind(&self) -> embedded_hal_1::spi::ErrorKind {
		383	match *self {}
		384	}
		385	}
		386
		387	impl<'d, PIO: Instance, const SM: usize, M: Mode> embedded_hal_1::spi::ErrorType for Spi<'d, PIO, SM, M> {
		388	type Error = Error;
		389	}
		390
		391	impl<'d, PIO: Instance, const SM: usize, M: Mode> embedded_hal_1::spi::SpiBus<u8> for Spi<'d, PIO, SM, M> {
		392	fn flush(&mut self) -> Result<(), Self::Error> {
		393	Ok(())
		394	}
		395
		396	fn read(&mut self, words: &mut [u8]) -> Result<(), Self::Error> {
		397	self.blocking_transfer(words, &[])
		398	}
		399
		400	fn write(&mut self, words: &[u8]) -> Result<(), Self::Error> {
		401	self.blocking_write(words)
		402	}
		403
		404	fn transfer(&mut self, read: &mut [u8], write: &[u8]) -> Result<(), Self::Error> {
		405	self.blocking_transfer(read, write)
		406	}
		407
		408	fn transfer_in_place(&mut self, words: &mut [u8]) -> Result<(), Self::Error> {
		409	self.blocking_transfer_in_place(words)
		410	}
		411	}
		412
		413	impl<'d, PIO: Instance, const SM: usize> embedded_hal_async::spi::SpiBus<u8> for Spi<'d, PIO, SM, Async> {
		414	async fn flush(&mut self) -> Result<(), Self::Error> {
		415	Ok(())
		416	}
		417
		418	async fn write(&mut self, words: &[u8]) -> Result<(), Self::Error> {
		419	self.write(words).await
		420	}
		421
		422	async fn read(&mut self, words: &mut [u8]) -> Result<(), Self::Error> {
		423	self.read(words).await
		424	}
		425
		426	async fn transfer(&mut self, read: &mut [u8], write: &[u8]) -> Result<(), Self::Error> {
		427	self.transfer(read, write).await
		428	}
		429
		430	async fn transfer_in_place(&mut self, words: &mut [u8]) -> Result<(), Self::Error> {
		431	self.transfer_in_place(words).await
		432	}
		433	}