forked from M-Labs/zynq-rs
504 lines
14 KiB
Rust
504 lines
14 KiB
Rust
//! Quad-SPI Flash Controller
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use core::marker::PhantomData;
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use log::{error, info, warn};
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use libregister::{RegisterR, RegisterW, RegisterRW};
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use crate::{print, println};
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use super::slcr;
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use super::clocks::source::{IoPll, ClockSource};
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mod regs;
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mod bytes;
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pub use bytes::{BytesTransferExt, BytesTransfer};
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mod spi_flash_register;
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use spi_flash_register::*;
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mod transfer;
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use transfer::Transfer;
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const FLASH_BAUD_RATE: u32 = 50_000_000;
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/// 16 MB
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pub const SINGLE_CAPACITY: u32 = 0x1000000;
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pub const SECTOR_SIZE: u32 = 0x10000;
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pub const PAGE_SIZE: u32 = 0x100;
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/// Instruction: Read Identification
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const INST_RDID: u8 = 0x9F;
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/// Instruction: Read
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const INST_READ: u8 = 0x03;
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/// Instruction: Quad I/O Fast Read
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const INST_4IO_FAST_READ: u8 = 0xEB;
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/// Instruction: Write Disable
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const INST_WRDI: u8 = 0x04;
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/// Instruction: Write Enable
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const INST_WREN: u8 = 0x06;
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/// Instruction: Program page
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const INST_PP: u8 = 0x02;
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/// Instruction: Erase 4K Block
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const INST_BE_4K: u8 = 0x20;
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#[derive(Clone)]
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pub enum SpiWord {
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W8(u8),
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W16(u16),
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W24(u32),
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W32(u32),
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}
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impl From<u8> for SpiWord {
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fn from(x: u8) -> Self {
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SpiWord::W8(x)
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}
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}
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impl From<u16> for SpiWord {
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fn from(x: u16) -> Self {
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SpiWord::W16(x)
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}
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}
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impl From<u32> for SpiWord {
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fn from(x: u32) -> Self {
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SpiWord::W32(x)
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}
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}
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/// Memory-mapped mode
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pub struct LinearAddressing;
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/// Manual I/O mode
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pub struct Manual;
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/// Flash Interface Driver
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///
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/// For 2x Spansion S25FL128SAGMFIR01
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pub struct Flash<MODE> {
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regs: &'static mut regs::RegisterBlock,
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_mode: PhantomData<MODE>,
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}
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impl<MODE> Flash<MODE> {
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fn transition<TO>(self) -> Flash<TO> {
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Flash {
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regs: self.regs,
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_mode: PhantomData,
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}
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}
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fn disable_interrupts(&mut self) {
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self.regs.intr_dis.write(
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regs::IntrDis::zeroed()
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.rx_overflow(true)
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.tx_fifo_not_full(true)
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.tx_fifo_full(true)
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.rx_fifo_not_empty(true)
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.rx_fifo_full(true)
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.tx_fifo_underflow(true)
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);
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}
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fn clear_rx_fifo(&self) {
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while self.regs.intr_status.read().rx_fifo_not_empty() {
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let _ = self.regs.rx_data.read();
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}
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}
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fn clear_interrupt_status(&mut self) {
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self.regs.intr_status.write(
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regs::IntrStatus::zeroed()
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.rx_overflow(true)
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.tx_fifo_underflow(true)
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);
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}
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fn wait_tx_fifo_flush(&mut self) {
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self.regs.config.modify(|_, w| w.man_start_com(true));
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while !self.regs.intr_status.read().tx_fifo_not_full() {}
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}
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}
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impl Flash<()> {
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pub fn new(clock: u32) -> Self {
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Self::enable_clocks(clock);
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Self::setup_signals();
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Self::reset();
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let regs = regs::RegisterBlock::qspi();
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let mut flash = Flash { regs, _mode: PhantomData };
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flash.configure((FLASH_BAUD_RATE - 1 + clock) / FLASH_BAUD_RATE);
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flash
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}
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/// typical: `200_000_000` Hz
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fn enable_clocks(clock: u32) {
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let io_pll = IoPll::freq();
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let divisor = ((clock - 1 + io_pll) / clock)
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.max(1).min(63) as u8;
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slcr::RegisterBlock::unlocked(|slcr| {
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slcr.lqspi_clk_ctrl.write(
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slcr::LqspiClkCtrl::zeroed()
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.src_sel(slcr::PllSource::IoPll)
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.divisor(divisor)
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.clkact(true)
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);
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});
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}
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fn setup_signals() {
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slcr::RegisterBlock::unlocked(|slcr| {
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// 1. Configure MIO pin 1 for chip select 0 output.
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slcr.mio_pin_01.write(
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slcr::MioPin01::zeroed()
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.l0_sel(true)
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.io_type(slcr::IoBufferType::Lvcmos18)
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.pullup(true)
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);
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// Configure MIO pins 2 through 5 for I/O.
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slcr.mio_pin_02.write(
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slcr::MioPin02::zeroed()
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.l0_sel(true)
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.io_type(slcr::IoBufferType::Lvcmos18)
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);
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slcr.mio_pin_03.write(
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slcr::MioPin03::zeroed()
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.l0_sel(true)
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.io_type(slcr::IoBufferType::Lvcmos18)
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);
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slcr.mio_pin_04.write(
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slcr::MioPin04::zeroed()
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.l0_sel(true)
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.io_type(slcr::IoBufferType::Lvcmos18)
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);
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slcr.mio_pin_05.write(
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slcr::MioPin05::zeroed()
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.l0_sel(true)
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.io_type(slcr::IoBufferType::Lvcmos18)
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);
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// 3. Configure MIO pin 6 for serial clock 0 output.
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slcr.mio_pin_06.write(
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slcr::MioPin06::zeroed()
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.l0_sel(true)
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.io_type(slcr::IoBufferType::Lvcmos18)
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);
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// Option: Add Second Device Chip Select
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// 4. Configure MIO pin 0 for chip select 1 output.
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slcr.mio_pin_00.write(
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slcr::MioPin00::zeroed()
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.l0_sel(true)
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.io_type(slcr::IoBufferType::Lvcmos18)
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);
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// Option: Add Second Serial Clock
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// 5. Configure MIO pin 9 for serial clock 1 output.
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slcr.mio_pin_09.write(
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slcr::MioPin09::zeroed()
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.l0_sel(true)
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.io_type(slcr::IoBufferType::Lvcmos18)
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.pullup(true)
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);
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// Option: Add 4-bit Data
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// 6. Configure MIO pins 10 through 13 for I/O.
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slcr.mio_pin_10.write(
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slcr::MioPin10::zeroed()
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.l0_sel(true)
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.io_type(slcr::IoBufferType::Lvcmos18)
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.pullup(true)
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);
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slcr.mio_pin_11.write(
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slcr::MioPin11::zeroed()
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.l0_sel(true)
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.io_type(slcr::IoBufferType::Lvcmos18)
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.pullup(true)
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);
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slcr.mio_pin_12.write(
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slcr::MioPin12::zeroed()
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.l0_sel(true)
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.io_type(slcr::IoBufferType::Lvcmos18)
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.pullup(true)
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);
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slcr.mio_pin_13.write(
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slcr::MioPin13::zeroed()
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.l0_sel(true)
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.io_type(slcr::IoBufferType::Lvcmos18)
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.pullup(true)
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);
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// Option: Add Feedback Output Clock
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// 7. Configure MIO pin 8 for feedback clock.
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slcr.mio_pin_08.write(
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slcr::MioPin08::zeroed()
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.l0_sel(true)
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.io_type(slcr::IoBufferType::Lvcmos18)
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.pullup(true)
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);
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});
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}
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fn reset() {
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slcr::RegisterBlock::unlocked(|slcr| {
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slcr.lqspi_rst_ctrl.write(
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slcr::LqspiRstCtrl::zeroed()
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.ref_rst(true)
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.cpu1x_rst(true)
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);
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slcr.lqspi_rst_ctrl.write(
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slcr::LqspiRstCtrl::zeroed()
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);
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});
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}
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fn configure(&mut self, divider: u32) {
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// Disable
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self.regs.enable.write(
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regs::Enable::zeroed()
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);
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self.disable_interrupts();
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self.regs.lqspi_cfg.write(
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regs::LqspiCfg::zeroed()
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);
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self.clear_rx_fifo();
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self.clear_interrupt_status();
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// for a baud_rate_div=1 LPBK_DLY_ADJ would be required
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let mut baud_rate_div = 2u32;
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while baud_rate_div < 7 && 2u32.pow(1 + baud_rate_div) < divider {
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baud_rate_div += 1;
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}
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self.regs.config.write(regs::Config::zeroed()
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.baud_rate_div(baud_rate_div as u8)
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.mode_sel(true)
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.leg_flsh(true)
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.holdb_dr(true)
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// 32 bits TX FIFO width
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.fifo_width(0b11)
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);
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// Initialize RX/TX pipes thresholds
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unsafe {
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self.regs.rx_thres.write(1);
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self.regs.tx_thres.write(1);
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}
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}
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pub fn linear_addressing_mode(self) -> Flash<LinearAddressing> {
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// Set manual start enable to auto mode.
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// Assert the chip select.
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self.regs.config.modify(|_, w| w
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.man_start_en(false)
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.pcs(false)
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.manual_cs(false)
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);
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self.regs.lqspi_cfg.write(regs::LqspiCfg::zeroed()
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// Quad I/O Fast Read
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.inst_code(INST_4IO_FAST_READ)
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.dummy_mask(0x2)
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.mode_en(false)
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.mode_bits(0xFF)
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// 2 devices
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.two_mem(true)
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.u_page(false)
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// Quad SPI mode
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.lq_mode(true)
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);
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self.regs.enable.write(
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regs::Enable::zeroed()
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.spi_en(true)
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);
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self.transition()
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}
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pub fn manual_mode(self, chip_index: usize) -> Flash<Manual> {
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self.regs.config.modify(|_, w| w
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.man_start_en(true)
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.manual_cs(true)
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.endian(true)
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);
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self.regs.lqspi_cfg.write(regs::LqspiCfg::zeroed()
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// Quad I/O Fast Read
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.inst_code(INST_READ)
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.dummy_mask(0x2)
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.mode_en(false)
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.mode_bits(0xFF)
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// 2 devices
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.two_mem(true)
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.u_page(chip_index != 0)
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// Quad SPI mode
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.lq_mode(false)
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);
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self.transition()
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}
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}
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impl Flash<LinearAddressing> {
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/// Stop linear addressing mode
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pub fn stop(self) -> Flash<()> {
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self.regs.enable.modify(|_, w| w.spi_en(false));
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// De-assert chip select.
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self.regs.config.modify(|_, w| w.pcs(true));
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self.transition()
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}
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pub fn ptr<T>(&mut self) -> *mut T {
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0xFC00_0000 as *mut _
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}
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pub fn size(&self) -> usize {
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2 * (SINGLE_CAPACITY as usize)
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}
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}
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impl Flash<Manual> {
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pub fn stop(self) -> Flash<()> {
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self.transition()
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}
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pub fn read_reg<R: SpiFlashRegister>(&mut self) -> R {
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let args = Some(R::inst_code());
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let transfer = self.transfer(args.into_iter(), 2)
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.bytes_transfer();
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R::new(transfer.skip(1).next().unwrap())
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}
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pub fn read_reg_until<R, F, A>(&mut self, f: F) -> A
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where
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R: SpiFlashRegister,
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F: Fn(R) -> Option<A>,
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{
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let mut result = None;
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while result.is_none() {
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let args = Some(R::inst_code());
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for b in self.transfer(args.into_iter(), 32)
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.bytes_transfer().skip(1) {
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result = f(R::new(b));
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if result.is_none() {
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break;
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}
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}
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}
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result.unwrap()
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}
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/// Status Register-1 remains `0x00` immediately after invoking a command.
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fn wait_while_sr1_zeroed(&mut self) -> SR1 {
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self.read_reg_until::<SR1, _, SR1>(|sr1|
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if sr1.is_zeroed() {
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None
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} else {
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Some(sr1)
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}
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)
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}
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/// Read Identification
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pub fn rdid(&mut self) -> core::iter::Skip<BytesTransfer<Transfer<core::option::IntoIter<u32>, u32>>> {
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let args = Some((INST_RDID as u32) << 24);
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self.transfer(args.into_iter(), 0x44)
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.bytes_transfer().skip(1)
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}
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/// Read flash data
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pub fn read(&mut self, offset: u32, len: usize
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) -> core::iter::Take<core::iter::Skip<BytesTransfer<Transfer<core::option::IntoIter<u32>, u32>>>>
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{
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let args = Some(((INST_READ as u32) << 24) | (offset as u32));
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self.transfer(args.into_iter(), len + 6)
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.bytes_transfer().skip(6).take(len)
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}
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pub fn erase(&mut self, offset: u32) {
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let args = Some(((INST_BE_4K as u32) << 24) | (offset as u32));
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self.transfer(args.into_iter(), 4);
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let sr1 = self.wait_while_sr1_zeroed();
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if sr1.e_err() {
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error!("E_ERR");
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} else if sr1.p_err() {
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error!("P_ERR");
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} else if sr1.wip() {
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info!("Erase in progress");
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while self.read_reg::<SR1>().wip() {
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print!(".");
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}
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println!("");
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} else {
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warn!("erased? sr1={:02X}", sr1.inner);
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}
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}
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pub fn program<I: Iterator<Item=u32>>(&mut self, offset: u32, data: I) {
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{
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let len = 4 + 4 * data.size_hint().0;
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let args = Some(SpiWord::W32(((INST_PP as u32) << 24) | (offset as u32))).into_iter()
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.chain(data.map(SpiWord::W32));
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self.transfer(args, len);
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}
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// let sr1 = self.wait_while_sr1_zeroed();
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let sr1 = self.read_reg::<SR1>();
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if sr1.e_err() {
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error!("E_ERR");
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} else if sr1.p_err() {
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error!("P_ERR");
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} else if sr1.wip() {
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info!("Program in progress");
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while self.read_reg::<SR1>().wip() {
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print!(".");
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}
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println!("");
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} else {
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warn!("programmed? sr1={:02X}", sr1.inner);
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}
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}
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pub fn write_enabled<F: Fn(&mut Self) -> R, R>(&mut self, f: F) -> R {
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// Write Enable
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let args = Some(INST_WREN);
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self.transfer(args.into_iter(), 1);
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self.regs.gpio.modify(|_, w| w.wp_n(true));
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let sr1 = self.wait_while_sr1_zeroed();
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if !sr1.wel() {
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panic!("Cannot write-enable flash");
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}
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let result = f(self);
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// Write Disable
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let args = Some(INST_WRDI);
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self.transfer(args.into_iter(), 1);
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self.regs.gpio.modify(|_, w| w.wp_n(false));
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result
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}
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pub fn transfer<'s: 't, 't, Args, W>(&'s mut self, args: Args, len: usize) -> Transfer<'t, Args, W>
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where
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Args: Iterator<Item = W>,
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W: Into<SpiWord>,
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{
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Transfer::new(self, args, len)
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}
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pub fn dump(&mut self, label: &'_ str, inst_code: u8) {
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print!("{}:", label);
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let args = Some(u32::from(inst_code) << 24);
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for b in self.transfer(args.into_iter(), 32).bytes_transfer() {
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print!(" {:02X}", b);
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}
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println!("");
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}
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}
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