use core::convert::TryInto;
use core::ptr::write_volatile;
use core::sync::atomic::{fence, Ordering};
use super::{FlashRegion, FlashSector, BANK1_REGION, FLASH_REGIONS, WRITE_SIZE};
use crate::flash::Error;
use crate::pac;
pub const fn is_default_layout() -> bool {
true
}
const fn is_dual_bank() -> bool {
FLASH_REGIONS.len() == 2
}
pub fn get_flash_regions() -> &'static [&'static FlashRegion] {
&FLASH_REGIONS
}
pub(crate) unsafe fn lock() {
pac::FLASH.bank(0).cr().modify(|w| w.set_lock(true));
if is_dual_bank() {
pac::FLASH.bank(1).cr().modify(|w| w.set_lock(true));
}
}
pub(crate) unsafe fn unlock() {
pac::FLASH.bank(0).keyr().write(|w| w.set_keyr(0x4567_0123));
pac::FLASH.bank(0).keyr().write(|w| w.set_keyr(0xCDEF_89AB));
if is_dual_bank() {
pac::FLASH.bank(1).keyr().write(|w| w.set_keyr(0x4567_0123));
pac::FLASH.bank(1).keyr().write(|w| w.set_keyr(0xCDEF_89AB));
}
}
pub(crate) unsafe fn enable_blocking_write() {
assert_eq!(0, WRITE_SIZE % 4);
}
pub(crate) unsafe fn disable_blocking_write() {}
pub(crate) unsafe fn blocking_write(start_address: u32, buf: &[u8; WRITE_SIZE]) -> Result<(), Error> {
// We cannot have the write setup sequence in begin_write as it depends on the address
let bank = if start_address < BANK1_REGION.end() {
pac::FLASH.bank(0)
} else {
pac::FLASH.bank(1)
};
bank.cr().write(|w| {
w.set_pg(true);
w.set_psize(2); // 32 bits at once
});
cortex_m::asm::isb();
cortex_m::asm::dsb();
fence(Ordering::SeqCst);
let mut res = None;
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;
res = Some(blocking_wait_ready(bank));
bank.sr().modify(|w| {
if w.eop() {
w.set_eop(true);
}
});
if res.unwrap().is_err() {
break;
}
}
bank.cr().write(|w| w.set_pg(false));
cortex_m::asm::isb();
cortex_m::asm::dsb();
fence(Ordering::SeqCst);
res.unwrap()
}
pub(crate) unsafe fn blocking_erase_sector(sector: &FlashSector) -> Result<(), Error> {
let bank = pac::FLASH.bank(sector.bank as usize);
bank.cr().modify(|w| {
w.set_ser(true);
w.set_snb(sector.index_in_bank)
});
bank.cr().modify(|w| {
w.set_start(true);
});
let ret: Result<(), Error> = blocking_wait_ready(bank);
bank.cr().modify(|w| w.set_ser(false));
bank_clear_all_err(bank);
ret
}
pub(crate) unsafe fn clear_all_err() {
bank_clear_all_err(pac::FLASH.bank(0));
bank_clear_all_err(pac::FLASH.bank(1));
}
unsafe fn bank_clear_all_err(bank: pac::flash::Bank) {
bank.sr().modify(|w| {
if w.wrperr() {
w.set_wrperr(true);
}
if w.pgserr() {
w.set_pgserr(true);
}
if w.strberr() {
// single address was written multiple times, can be ignored
w.set_strberr(true);
}
if w.incerr() {
// writing to a different address when programming 256 bit word was not finished
w.set_incerr(true);
}
if w.operr() {
w.set_operr(true);
}
if w.sneccerr1() {
// single ECC error
w.set_sneccerr1(true);
}
if w.dbeccerr() {
// double ECC error
w.set_dbeccerr(true);
}
if w.rdperr() {
w.set_rdperr(true);
}
if w.rdserr() {
w.set_rdserr(true);
}
});
}
unsafe fn blocking_wait_ready(bank: pac::flash::Bank) -> Result<(), Error> {
loop {
let sr = bank.sr().read();
if !sr.bsy() && !sr.qw() {
if sr.wrperr() {
return Err(Error::Protected);
}
if sr.pgserr() {
error!("pgserr");
return Err(Error::Seq);
}
if sr.incerr() {
// writing to a different address when programming 256 bit word was not finished
error!("incerr");
return Err(Error::Seq);
}
if sr.operr() {
return Err(Error::Prog);
}
if sr.sneccerr1() {
// single ECC error
return Err(Error::Prog);
}
if sr.dbeccerr() {
// double ECC error
return Err(Error::Prog);
}
if sr.rdperr() {
return Err(Error::Protected);
}
if sr.rdserr() {
return Err(Error::Protected);
}
return Ok(());
}
}
}