embassy/embassy-stm32/src/flash/l.rs

use core::ptr::write_volatile;

use atomic_polyfill::{fence, Ordering};

use super::{FlashRegion, WRITE_SIZE};
use crate::flash::Error;
use crate::pac;

const ERASE_SIZE: usize = super::BANK1::ERASE_SIZE;

pub(crate) unsafe fn lock() {
    #[cfg(any(flash_wl, flash_wb, flash_l4))]
    pac::FLASH.cr().modify(|w| w.set_lock(true));

    #[cfg(any(flash_l0))]
    pac::FLASH.pecr().modify(|w| {
        w.set_optlock(true);
        w.set_prglock(true);
        w.set_pelock(true);
    });
}

pub(crate) unsafe fn unlock() {
    #[cfg(any(flash_wl, flash_wb, flash_l4))]
    {
        pac::FLASH.keyr().write(|w| w.set_keyr(0x4567_0123));
        pac::FLASH.keyr().write(|w| w.set_keyr(0xCDEF_89AB));
    }

    #[cfg(any(flash_l0, flash_l1))]
    {
        pac::FLASH.pekeyr().write(|w| w.set_pekeyr(0x89ABCDEF));
        pac::FLASH.pekeyr().write(|w| w.set_pekeyr(0x02030405));

        pac::FLASH.prgkeyr().write(|w| w.set_prgkeyr(0x8C9DAEBF));
        pac::FLASH.prgkeyr().write(|w| w.set_prgkeyr(0x13141516));
    }
}

pub(crate) unsafe fn begin_write() {
    assert_eq!(0, WRITE_SIZE % 4);

    #[cfg(any(flash_wl, flash_wb, flash_l4))]
    pac::FLASH.cr().write(|w| w.set_pg(true));
}

pub(crate) unsafe fn end_write() {
    #[cfg(any(flash_wl, flash_wb, flash_l4))]
    pac::FLASH.cr().write(|w| w.set_pg(false));
}

pub(crate) unsafe fn blocking_write(start_address: u32, buf: &[u8; WRITE_SIZE]) -> Result<(), Error> {
    let mut address = start_address;
    for val in buf.chunks(4) {
        write_volatile(address as *mut u32, u32::from_le_bytes(val.try_into().unwrap()));
        address += val.len() as u32;

        // prevents parallelism errors
        fence(Ordering::SeqCst);
    }

    blocking_wait_ready()
}

pub(crate) fn is_eraseable_range(start_address: u32, end_address: u32) -> bool {
    start_address % ERASE_SIZE as u32 == 0 && end_address % ERASE_SIZE as u32 == 0
}

pub(crate) unsafe fn blocking_erase(start_address: u32, end_address: u32) -> Result<(), Error> {
    for page in (start_address..end_address).step_by(ERASE_SIZE) {
        #[cfg(any(flash_l0, flash_l1))]
        {
            pac::FLASH.pecr().modify(|w| {
                w.set_erase(true);
                w.set_prog(true);
            });

            write_volatile(page as *mut u32, 0xFFFFFFFF);
        }

        #[cfg(any(flash_wl, flash_wb, flash_l4))]
        {
            let idx = (page - super::FLASH_BASE as u32) / ERASE_SIZE as u32;

            #[cfg(flash_l4)]
            let (idx, bank) = if idx > 255 { (idx - 256, true) } else { (idx, false) };

            pac::FLASH.cr().modify(|w| {
                w.set_per(true);
                w.set_pnb(idx as u8);
                #[cfg(any(flash_wl, flash_wb))]
                w.set_strt(true);
                #[cfg(any(flash_l4))]
                w.set_start(true);
                #[cfg(any(flash_l4))]
                w.set_bker(bank);
            });
        }

        let ret: Result<(), Error> = blocking_wait_ready();

        #[cfg(any(flash_wl, flash_wb, flash_l4))]
        pac::FLASH.cr().modify(|w| w.set_per(false));

        #[cfg(any(flash_l0, flash_l1))]
        pac::FLASH.pecr().modify(|w| {
            w.set_erase(false);
            w.set_prog(false);
        });

        clear_all_err();
        if ret.is_err() {
            return ret;
        }
    }

    Ok(())
}

pub(crate) unsafe fn clear_all_err() {
    pac::FLASH.sr().modify(|w| {
        #[cfg(any(flash_wl, flash_wb, flash_l4, flash_l0))]
        if w.rderr() {
            w.set_rderr(true);
        }
        #[cfg(any(flash_wl, flash_wb, flash_l4))]
        if w.fasterr() {
            w.set_fasterr(true);
        }
        #[cfg(any(flash_wl, flash_wb, flash_l4))]
        if w.miserr() {
            w.set_miserr(true);
        }
        #[cfg(any(flash_wl, flash_wb, flash_l4))]
        if w.pgserr() {
            w.set_pgserr(true);
        }
        if w.sizerr() {
            w.set_sizerr(true);
        }
        if w.pgaerr() {
            w.set_pgaerr(true);
        }
        if w.wrperr() {
            w.set_wrperr(true);
        }
        #[cfg(any(flash_wl, flash_wb, flash_l4))]
        if w.progerr() {
            w.set_progerr(true);
        }
        #[cfg(any(flash_wl, flash_wb, flash_l4))]
        if w.operr() {
            w.set_operr(true);
        }
    });
}

unsafe fn blocking_wait_ready() -> Result<(), Error> {
    loop {
        let sr = pac::FLASH.sr().read();

        if !sr.bsy() {
            #[cfg(any(flash_wl, flash_wb, flash_l4))]
            if sr.progerr() {
                return Err(Error::Prog);
            }

            if sr.wrperr() {
                return Err(Error::Protected);
            }

            if sr.pgaerr() {
                return Err(Error::Unaligned);
            }

            if sr.sizerr() {
                return Err(Error::Size);
            }

            #[cfg(any(flash_wl, flash_wb, flash_l4))]
            if sr.miserr() {
                return Err(Error::Miss);
            }

            #[cfg(any(flash_wl, flash_wb, flash_l4))]
            if sr.pgserr() {
                return Err(Error::Seq);
            }

            return Ok(());
        }
    }
}
Refactor flash handling to different modules for different families 2022-05-02 15:36:02 +02:00			`use core::ptr::write_volatile;`

Add is_eraseable_range and split write into consecutive parts 2023-03-25 16:04:45 +01:00			`use atomic_polyfill::{fence, Ordering};`

			`use super::{FlashRegion, WRITE_SIZE};`
Refactor flash handling to different modules for different families 2022-05-02 15:36:02 +02:00			`use crate::flash::Error;`
			`use crate::pac;`

Align L family 2023-03-25 13:30:24 +01:00			`const ERASE_SIZE: usize = super::BANK1::ERASE_SIZE;`

Refactor flash handling to different modules for different families 2022-05-02 15:36:02 +02:00			`pub(crate) unsafe fn lock() {`
			`#[cfg(any(flash_wl, flash_wb, flash_l4))]`
			`pac::FLASH.cr().modify(\|w\| w.set_lock(true));`

			`#[cfg(any(flash_l0))]`
			`pac::FLASH.pecr().modify(\|w\| {`
			`w.set_optlock(true);`
			`w.set_prglock(true);`
			`w.set_pelock(true);`
			`});`
			`}`

			`pub(crate) unsafe fn unlock() {`
			`#[cfg(any(flash_wl, flash_wb, flash_l4))]`
			`{`
			`pac::FLASH.keyr().write(\|w\| w.set_keyr(0x4567_0123));`
			`pac::FLASH.keyr().write(\|w\| w.set_keyr(0xCDEF_89AB));`
			`}`

			`#[cfg(any(flash_l0, flash_l1))]`
			`{`
			`pac::FLASH.pekeyr().write(\|w\| w.set_pekeyr(0x89ABCDEF));`
			`pac::FLASH.pekeyr().write(\|w\| w.set_pekeyr(0x02030405));`

			`pac::FLASH.prgkeyr().write(\|w\| w.set_prgkeyr(0x8C9DAEBF));`
			`pac::FLASH.prgkeyr().write(\|w\| w.set_prgkeyr(0x13141516));`
			`}`
			`}`

Add is_eraseable_range and split write into consecutive parts 2023-03-25 16:04:45 +01:00			`pub(crate) unsafe fn begin_write() {`
			`assert_eq!(0, WRITE_SIZE % 4);`

Refactor flash handling to different modules for different families 2022-05-02 15:36:02 +02:00			`#[cfg(any(flash_wl, flash_wb, flash_l4))]`
			`pac::FLASH.cr().write(\|w\| w.set_pg(true));`
Add is_eraseable_range and split write into consecutive parts 2023-03-25 16:04:45 +01:00			`}`
Refactor flash handling to different modules for different families 2022-05-02 15:36:02 +02:00
Add is_eraseable_range and split write into consecutive parts 2023-03-25 16:04:45 +01:00			`pub(crate) unsafe fn end_write() {`
Refactor flash handling to different modules for different families 2022-05-02 15:36:02 +02:00			`#[cfg(any(flash_wl, flash_wb, flash_l4))]`
			`pac::FLASH.cr().write(\|w\| w.set_pg(false));`
Add is_eraseable_range and split write into consecutive parts 2023-03-25 16:04:45 +01:00			`}`

			`pub(crate) unsafe fn blocking_write(start_address: u32, buf: &[u8; WRITE_SIZE]) -> Result<(), Error> {`
			`let mut address = start_address;`
			`for val in buf.chunks(4) {`
			`write_volatile(address as *mut u32, u32::from_le_bytes(val.try_into().unwrap()));`
			`address += val.len() as u32;`

			`// prevents parallelism errors`
			`fence(Ordering::SeqCst);`
			`}`

			`blocking_wait_ready()`
			`}`
Refactor flash handling to different modules for different families 2022-05-02 15:36:02 +02:00
Add is_eraseable_range and split write into consecutive parts 2023-03-25 16:04:45 +01:00			`pub(crate) fn is_eraseable_range(start_address: u32, end_address: u32) -> bool {`
			`start_address % ERASE_SIZE as u32 == 0 && end_address % ERASE_SIZE as u32 == 0`
Refactor flash handling to different modules for different families 2022-05-02 15:36:02 +02:00			`}`

Add is_eraseable_range and split write into consecutive parts 2023-03-25 16:04:45 +01:00			`pub(crate) unsafe fn blocking_erase(start_address: u32, end_address: u32) -> Result<(), Error> {`
			`for page in (start_address..end_address).step_by(ERASE_SIZE) {`
Refactor flash handling to different modules for different families 2022-05-02 15:36:02 +02:00			`#[cfg(any(flash_l0, flash_l1))]`
			`{`
			`pac::FLASH.pecr().modify(\|w\| {`
			`w.set_erase(true);`
			`w.set_prog(true);`
			`});`

			`write_volatile(page as *mut u32, 0xFFFFFFFF);`
			`}`

			`#[cfg(any(flash_wl, flash_wb, flash_l4))]`
			`{`
Align L family 2023-03-25 13:30:24 +01:00			`let idx = (page - super::FLASH_BASE as u32) / ERASE_SIZE as u32;`
Use correct index and bank 2022-06-07 15:59:22 +02:00
			`#[cfg(flash_l4)]`
Run rustfmt. 2022-06-12 22:15:44 +02:00			`let (idx, bank) = if idx > 255 { (idx - 256, true) } else { (idx, false) };`
Refactor flash handling to different modules for different families 2022-05-02 15:36:02 +02:00
			`pac::FLASH.cr().modify(\|w\| {`
			`w.set_per(true);`
			`w.set_pnb(idx as u8);`
			`#[cfg(any(flash_wl, flash_wb))]`
			`w.set_strt(true);`
			`#[cfg(any(flash_l4))]`
			`w.set_start(true);`
Use correct index and bank 2022-06-07 15:59:22 +02:00			`#[cfg(any(flash_l4))]`
			`w.set_bker(bank);`
Refactor flash handling to different modules for different families 2022-05-02 15:36:02 +02:00			`});`
			`}`

			`let ret: Result<(), Error> = blocking_wait_ready();`

			`#[cfg(any(flash_wl, flash_wb, flash_l4))]`
			`pac::FLASH.cr().modify(\|w\| w.set_per(false));`

			`#[cfg(any(flash_l0, flash_l1))]`
			`pac::FLASH.pecr().modify(\|w\| {`
			`w.set_erase(false);`
			`w.set_prog(false);`
			`});`

			`clear_all_err();`
			`if ret.is_err() {`
			`return ret;`
			`}`
			`}`

			`Ok(())`
			`}`

			`pub(crate) unsafe fn clear_all_err() {`
			`pac::FLASH.sr().modify(\|w\| {`
			`#[cfg(any(flash_wl, flash_wb, flash_l4, flash_l0))]`
			`if w.rderr() {`
			`w.set_rderr(true);`
			`}`
			`#[cfg(any(flash_wl, flash_wb, flash_l4))]`
			`if w.fasterr() {`
			`w.set_fasterr(true);`
			`}`
			`#[cfg(any(flash_wl, flash_wb, flash_l4))]`
			`if w.miserr() {`
			`w.set_miserr(true);`
			`}`
			`#[cfg(any(flash_wl, flash_wb, flash_l4))]`
			`if w.pgserr() {`
			`w.set_pgserr(true);`
			`}`
			`if w.sizerr() {`
			`w.set_sizerr(true);`
			`}`
			`if w.pgaerr() {`
			`w.set_pgaerr(true);`
			`}`
			`if w.wrperr() {`
			`w.set_wrperr(true);`
			`}`
			`#[cfg(any(flash_wl, flash_wb, flash_l4))]`
			`if w.progerr() {`
			`w.set_progerr(true);`
			`}`
			`#[cfg(any(flash_wl, flash_wb, flash_l4))]`
			`if w.operr() {`
			`w.set_operr(true);`
			`}`
			`});`
			`}`

Add is_eraseable_range and split write into consecutive parts 2023-03-25 16:04:45 +01:00			`unsafe fn blocking_wait_ready() -> Result<(), Error> {`
Refactor flash handling to different modules for different families 2022-05-02 15:36:02 +02:00			`loop {`
			`let sr = pac::FLASH.sr().read();`

			`if !sr.bsy() {`
			`#[cfg(any(flash_wl, flash_wb, flash_l4))]`
			`if sr.progerr() {`
			`return Err(Error::Prog);`
			`}`

			`if sr.wrperr() {`
			`return Err(Error::Protected);`
			`}`

			`if sr.pgaerr() {`
			`return Err(Error::Unaligned);`
			`}`

			`if sr.sizerr() {`
			`return Err(Error::Size);`
			`}`

			`#[cfg(any(flash_wl, flash_wb, flash_l4))]`
			`if sr.miserr() {`
			`return Err(Error::Miss);`
			`}`

			`#[cfg(any(flash_wl, flash_wb, flash_l4))]`
			`if sr.pgserr() {`
			`return Err(Error::Seq);`
			`}`

			`return Ok(());`
			`}`
			`}`
			`}`