use core::convert::TryInto; use core::ptr::write_volatile; use atomic_polyfill::{fence, Ordering}; use super::{FlashRegion, FlashSector, FLASH_REGIONS, WRITE_SIZE}; use crate::flash::Error; use crate::pac; pub const fn get_flash_regions() -> &'static [&'static FlashRegion] { &FLASH_REGIONS } pub(crate) unsafe fn lock() { pac::FLASH.cr().modify(|w| w.set_lock(true)); } pub(crate) unsafe fn unlock() { pac::FLASH.keyr().write(|w| w.set_fkeyr(0x4567_0123)); pac::FLASH.keyr().write(|w| w.set_fkeyr(0xCDEF_89AB)); } pub(crate) unsafe fn begin_write() { assert_eq!(0, WRITE_SIZE % 2); pac::FLASH.cr().write(|w| w.set_pg(true)); } pub(crate) unsafe fn end_write() { 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 chunk in buf.chunks(2) { write_volatile(address as *mut u16, u16::from_le_bytes(chunk.try_into().unwrap())); address += chunk.len() as u32; // prevents parallelism errors fence(Ordering::SeqCst); } blocking_wait_ready() } pub(crate) unsafe fn blocking_erase_sector(sector: &FlashSector) -> Result<(), Error> { pac::FLASH.cr().modify(|w| { w.set_per(true); }); pac::FLASH.ar().write(|w| w.set_far(sector.start)); pac::FLASH.cr().modify(|w| { w.set_strt(true); }); let mut ret: Result<(), Error> = blocking_wait_ready(); if !pac::FLASH.sr().read().eop() { trace!("FLASH: EOP not set"); ret = Err(Error::Prog); } else { pac::FLASH.sr().write(|w| w.set_eop(true)); } pac::FLASH.cr().modify(|w| w.set_per(false)); clear_all_err(); if ret.is_err() { return ret; } Ok(()) } pub(crate) unsafe fn clear_all_err() { pac::FLASH.sr().modify(|w| { if w.pgerr() { w.set_pgerr(true); } if w.wrprterr() { w.set_wrprterr(true); } if w.eop() { w.set_eop(true); } }); } unsafe fn blocking_wait_ready() -> Result<(), Error> { loop { let sr = pac::FLASH.sr().read(); if !sr.bsy() { if sr.wrprterr() { return Err(Error::Protected); } if sr.pgerr() { return Err(Error::Seq); } return Ok(()); } } }