/************************************************************************************ * Copyright (C) 2011 Uros Platise. All rights reserved. * Author: Uros Platise * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in * the documentation and/or other materials provided with the * distribution. * 3. Neither the name NuttX nor the names of its contributors may be * used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE * COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS * OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN * ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGE. * ************************************************************************************/ /* * This file is free software: you can redistribute it and/or modify it * under the terms of the GNU General Public License as published by the * Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This file is distributed in the hope that it will be useful, but * WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. * See the GNU General Public License for more details. * * You should have received a copy of the GNU General Public License along * with this program. If not, see . * * Modified for use in AP_HAL by Andrew Tridgell and Siddharth Bharat Purohit */ #include "flash.h" #include "hal.h" #include #include "stm32_util.h" #include "hrt.h" #include // #pragma GCC optimize("O0") /* this driver has been tested with STM32F427 and STM32F412 */ #ifndef HAL_NO_FLASH_SUPPORT #ifndef BOARD_FLASH_SIZE #error "You must define BOARD_FLASH_SIZE in kbyte" #endif #define KB(x) ((x*1024)) // Refer Flash memory map in the User Manual to fill the following fields per microcontroller #define STM32_FLASH_BASE 0x08000000 #define STM32_FLASH_SIZE KB(BOARD_FLASH_SIZE) // optionally disable interrupts during flash writes #ifndef STM32_FLASH_DISABLE_ISR #define STM32_FLASH_DISABLE_ISR 0 #endif // the 2nd bank of flash needs to be handled differently #define STM32_FLASH_BANK2_START (STM32_FLASH_BASE+0x00080000) #if defined(STM32F4) #if BOARD_FLASH_SIZE == 512 #define STM32_FLASH_NPAGES 8 static const uint32_t flash_memmap[STM32_FLASH_NPAGES] = { KB(16), KB(16), KB(16), KB(16), KB(64), KB(128), KB(128), KB(128) }; #elif BOARD_FLASH_SIZE == 1024 #define STM32_FLASH_NPAGES 12 static const uint32_t flash_memmap[STM32_FLASH_NPAGES] = { KB(16), KB(16), KB(16), KB(16), KB(64), KB(128), KB(128), KB(128), KB(128), KB(128), KB(128), KB(128) }; #elif BOARD_FLASH_SIZE == 2048 #define STM32_FLASH_NPAGES 24 static const uint32_t flash_memmap[STM32_FLASH_NPAGES] = { KB(16), KB(16), KB(16), KB(16), KB(64), KB(128), KB(128), KB(128), KB(128), KB(128), KB(128), KB(128), KB(16), KB(16), KB(16), KB(16), KB(64), KB(128), KB(128), KB(128), KB(128), KB(128), KB(128), KB(128)}; #else #error "BOARD_FLASH_SIZE invalid" #endif #elif defined(STM32F7) #if BOARD_FLASH_SIZE == 512 #define STM32_FLASH_NPAGES 8 static const uint32_t flash_memmap[STM32_FLASH_NPAGES] = { KB(16), KB(16), KB(16), KB(16), KB(64), KB(128), KB(128), KB(128) }; #elif BOARD_FLASH_SIZE == 1024 #define STM32_FLASH_NPAGES 8 static const uint32_t flash_memmap[STM32_FLASH_NPAGES] = { KB(32), KB(32), KB(32), KB(32), KB(128), KB(256), KB(256), KB(256) }; #elif BOARD_FLASH_SIZE == 2048 #define STM32_FLASH_NPAGES 12 static const uint32_t flash_memmap[STM32_FLASH_NPAGES] = { KB(32), KB(32), KB(32), KB(32), KB(128), KB(256), KB(256), KB(256), KB(256), KB(256), KB(256), KB(256) }; #else #error "BOARD_FLASH_SIZE invalid" #endif #elif defined(STM32H7) #define STM32_FLASH_NPAGES (BOARD_FLASH_SIZE / 128) #define STM32_FLASH_FIXED_PAGE_SIZE 128 #elif defined(STM32F100_MCUCONF) || defined(STM32F103_MCUCONF) #define STM32_FLASH_NPAGES BOARD_FLASH_SIZE #define STM32_FLASH_FIXED_PAGE_SIZE 1 #elif defined(STM32F105_MCUCONF) #define STM32_FLASH_NPAGES (BOARD_FLASH_SIZE/2) #define STM32_FLASH_FIXED_PAGE_SIZE 2 #elif defined(STM32F303_MCUCONF) #define STM32_FLASH_NPAGES (BOARD_FLASH_SIZE/2) #define STM32_FLASH_FIXED_PAGE_SIZE 2 #elif defined(STM32G4) #define STM32_FLASH_NPAGES (BOARD_FLASH_SIZE/2) #define STM32_FLASH_FIXED_PAGE_SIZE 2 #elif defined(STM32L4) #define STM32_FLASH_NPAGES (BOARD_FLASH_SIZE/2) #define STM32_FLASH_FIXED_PAGE_SIZE 2 #else #error "Unsupported processor for flash.c" #endif #if defined(__GNUC__) && __GNUC__ >= 6 #ifdef STORAGE_FLASH_PAGE static_assert(STORAGE_FLASH_PAGE < STM32_FLASH_NPAGES, "STORAGE_FLASH_PAGE out of range"); #endif #endif // keep a cache of the page addresses #ifndef STM32_FLASH_FIXED_PAGE_SIZE static uint32_t flash_pageaddr[STM32_FLASH_NPAGES]; static bool flash_pageaddr_initialised; #endif static bool flash_keep_unlocked; #ifndef FLASH_KEY1 #define FLASH_KEY1 0x45670123 #endif #ifndef FLASH_KEY2 #define FLASH_KEY2 0xCDEF89AB #endif #ifndef FLASH_OPTKEY1 #define FLASH_OPTKEY1 0x08192A3B #endif #ifndef FLASH_OPTKEY2 #define FLASH_OPTKEY2 0x4C5D6E7F #endif /* Some compiler options will convert short loads and stores into byte loads * and stores. We don't want this to happen for IO reads and writes! */ /* # define getreg16(a) (*(volatile uint16_t *)(a)) */ static inline uint16_t getreg16(unsigned int addr) { uint16_t retval; __asm__ __volatile__("\tldrh %0, [%1]\n\t" : "=r"(retval) : "r"(addr)); return retval; } /* define putreg16(v,a) (*(volatile uint16_t *)(a) = (v)) */ static inline void putreg16(uint16_t val, unsigned int addr) { __asm__ __volatile__("\tstrh %0, [%1]\n\t": : "r"(val), "r"(addr)); } /* # define getreg32(a) (*(volatile uint32_t *)(a)) */ static inline uint32_t getreg32(unsigned int addr) { uint32_t retval; __asm__ __volatile__("\tldr %0, [%1]\n\t" : "=r"(retval) : "r"(addr)); return retval; } /* define putreg32(v,a) */ static inline void putreg32(uint32_t val, unsigned int addr) { *(volatile uint32_t *)(addr) = val; } static void stm32_flash_wait_idle(void) { __DSB(); #if defined(STM32H7) while ((FLASH->SR1 & (FLASH_SR_BSY|FLASH_SR_QW|FLASH_SR_WBNE)) || (FLASH->SR2 & (FLASH_SR_BSY|FLASH_SR_QW|FLASH_SR_WBNE))) { // nop } #else while (FLASH->SR & FLASH_SR_BSY) { // nop } #endif } static void stm32_flash_clear_errors(void) { #if defined(STM32H7) FLASH->CCR1 = ~0; FLASH->CCR2 = ~0; #else FLASH->SR = 0xF3; #endif } static void stm32_flash_unlock(void) { if (flash_keep_unlocked) { return; } stm32_flash_wait_idle(); #if defined(STM32H7) if (FLASH->CR1 & FLASH_CR_LOCK) { /* Unlock sequence */ FLASH->KEYR1 = FLASH_KEY1; FLASH->KEYR1 = FLASH_KEY2; } if (FLASH->CR2 & FLASH_CR_LOCK) { /* Unlock sequence */ FLASH->KEYR2 = FLASH_KEY1; FLASH->KEYR2 = FLASH_KEY2; } #else if (FLASH->CR & FLASH_CR_LOCK) { /* Unlock sequence */ FLASH->KEYR = FLASH_KEY1; FLASH->KEYR = FLASH_KEY2; } #endif #ifdef FLASH_ACR_DCEN // disable the data cache - see stm32 errata 2.1.11 FLASH->ACR &= ~FLASH_ACR_DCEN; #endif } void stm32_flash_lock(void) { if (flash_keep_unlocked) { return; } #if defined(STM32H7) if (FLASH->SR1 & FLASH_SR_QW) { FLASH->CR1 |= FLASH_CR_FW; } if (FLASH->SR2 & FLASH_SR_QW) { FLASH->CR2 |= FLASH_CR_FW; } stm32_flash_wait_idle(); FLASH->CR1 |= FLASH_CR_LOCK; FLASH->CR2 |= FLASH_CR_LOCK; #else stm32_flash_wait_idle(); FLASH->CR |= FLASH_CR_LOCK; #endif #ifdef FLASH_ACR_DCEN // reset and re-enable the data cache - see stm32 errata 2.1.11 FLASH->ACR |= FLASH_ACR_DCRST; FLASH->ACR &= ~FLASH_ACR_DCRST; FLASH->ACR |= FLASH_ACR_DCEN; #endif } #if defined(STM32H7) && defined(HAL_FLASH_PROTECTION) static void stm32_flash_wait_opt_idle(void) { __DSB(); while (FLASH->OPTSR_CUR & FLASH_OPTSR_OPT_BUSY) { // nop } } static void stm32_flash_opt_clear_errors(void) { FLASH->OPTCCR = FLASH_OPTCCR_CLR_OPTCHANGEERR; } static bool stm32_flash_unlock_options(void) { stm32_flash_wait_opt_idle(); if (FLASH->OPTCR & FLASH_OPTCR_OPTLOCK) { /* Unlock sequence */ FLASH->OPTKEYR = FLASH_OPTKEY1; FLASH->OPTKEYR = FLASH_OPTKEY2; } if (FLASH->OPTSR_CUR & FLASH_OPTSR_OPTCHANGEERR) { return false; } return true; } static bool stm32_flash_lock_options(void) { stm32_flash_wait_opt_idle(); FLASH->OPTCR |= FLASH_OPTCR_OPTLOCK; if (FLASH->OPTSR_CUR & FLASH_OPTSR_OPTCHANGEERR) { return false; } return true; } #endif /* get the memory address of a page */ uint32_t stm32_flash_getpageaddr(uint32_t page) { if (page >= STM32_FLASH_NPAGES) { return 0; } #if defined(STM32_FLASH_FIXED_PAGE_SIZE) return STM32_FLASH_BASE + page * STM32_FLASH_FIXED_PAGE_SIZE * 1024; #else if (!flash_pageaddr_initialised) { uint32_t address = STM32_FLASH_BASE; uint8_t i; for (i = 0; i < STM32_FLASH_NPAGES; i++) { flash_pageaddr[i] = address; address += stm32_flash_getpagesize(i); } flash_pageaddr_initialised = true; } return flash_pageaddr[page]; #endif } /* get size in bytes of a page */ uint32_t stm32_flash_getpagesize(uint32_t page) { #if defined(STM32_FLASH_FIXED_PAGE_SIZE) (void)page; return STM32_FLASH_FIXED_PAGE_SIZE * 1024; #else return flash_memmap[page]; #endif } /* return total number of pages */ uint32_t stm32_flash_getnumpages() { return STM32_FLASH_NPAGES; } bool stm32_flash_ispageerased(uint32_t page) { uint32_t addr; uint32_t count; if (page >= STM32_FLASH_NPAGES) { return false; } for (addr = stm32_flash_getpageaddr(page), count = stm32_flash_getpagesize(page); count; count -= 4, addr += 4) { uint32_t v = getreg32(addr); if (v != 0xffffffff) { return false; } } return true; } #ifndef HAL_BOOTLOADER_BUILD static uint32_t last_erase_ms; #endif /* erase a page */ bool stm32_flash_erasepage(uint32_t page) { if (page >= STM32_FLASH_NPAGES) { return false; } #ifndef HAL_BOOTLOADER_BUILD last_erase_ms = hrt_millis32(); #endif #if STM32_FLASH_DISABLE_ISR syssts_t sts = chSysGetStatusAndLockX(); #endif stm32_flash_wait_idle(); stm32_flash_unlock(); // clear any previous errors stm32_flash_clear_errors(); #if defined(STM32H7) if (page < 8) { // first bank FLASH->SR1 = ~0; stm32_flash_wait_idle(); uint32_t snb = page << 8; // use 32 bit operations FLASH->CR1 = FLASH_CR_PSIZE_1 | snb | FLASH_CR_SER; FLASH->CR1 |= FLASH_CR_START; while (FLASH->SR1 & FLASH_SR_QW) ; } else { // second bank FLASH->SR2 = ~0; stm32_flash_wait_idle(); uint32_t snb = (page-8) << 8; // use 32 bit operations FLASH->CR2 = FLASH_CR_PSIZE_1 | snb | FLASH_CR_SER; FLASH->CR2 |= FLASH_CR_START; while (FLASH->SR2 & FLASH_SR_QW) ; } #elif defined(STM32F1) || defined(STM32F3) FLASH->CR = FLASH_CR_PER; FLASH->AR = stm32_flash_getpageaddr(page); FLASH->CR |= FLASH_CR_STRT; #elif defined(STM32F4) || defined(STM32F7) // the snb mask is not contiguous, calculate the mask for the page uint8_t snb = (((page % 12) << 3) | ((page / 12) << 7)); // use 32 bit operations FLASH->CR = FLASH_CR_PSIZE_1 | snb | FLASH_CR_SER; FLASH->CR |= FLASH_CR_STRT; #elif defined(STM32G4) FLASH->CR = FLASH_CR_PER; // rather oddly, PNB is a 7 bit field that the ref manual says can // contain 8 bits we assume that for 512k single bank devices // there is an 8th bit FLASH->CR |= page<CR |= FLASH_CR_STRT; #elif defined(STM32L4) FLASH->CR = FLASH_CR_PER; FLASH->CR |= page<CR |= FLASH_CR_STRT; #else #error "Unsupported MCU" #endif stm32_flash_wait_idle(); stm32_cacheBufferInvalidate((void*)stm32_flash_getpageaddr(page), stm32_flash_getpagesize(page)); stm32_flash_lock(); #if STM32_FLASH_DISABLE_ISR chSysRestoreStatusX(sts); #endif #ifndef HAL_BOOTLOADER_BUILD last_erase_ms = hrt_millis32(); #endif return stm32_flash_ispageerased(page); } #if defined(STM32H7) // Check that the flash line is erased as writing to an un-erased line causes flash corruption static bool stm32h7_check_all_ones(uint32_t addr, uint32_t words) { for (uint32_t i = 0; i < words; i++) { // check that the byte was erased if (getreg32(addr) != 0xFFFFFFFF) { return false; } addr += 4; } return true; } /* the H7 needs special handling, and only writes 32 bytes at a time */ static bool stm32h7_flash_write32(uint32_t addr, const void *buf) { volatile uint32_t *CR, *CCR, *SR; if (addr - STM32_FLASH_BASE < 8 * STM32_FLASH_FIXED_PAGE_SIZE * 1024) { CR = &FLASH->CR1; CCR = &FLASH->CCR1; SR = &FLASH->SR1; } else { CR = &FLASH->CR2; CCR = &FLASH->CCR2; SR = &FLASH->SR2; } stm32_flash_wait_idle(); *CCR = ~0; *CR |= FLASH_CR_PG; const uint32_t *v = (const uint32_t *)buf; for (uint8_t i=0; i<8; i++) { while (*SR & (FLASH_SR_BSY|FLASH_SR_QW)) ; putreg32(*v, addr); v++; addr += 4; } __DSB(); stm32_flash_wait_idle(); *CCR = ~0; *CR &= ~FLASH_CR_PG; return true; } static bool stm32_flash_write_h7(uint32_t addr, const void *buf, uint32_t count) { uint8_t *b = (uint8_t *)buf; if ((count & 0x1F) || (addr & 0x1F)) { // only allow 256 bit aligned writes return false; } // check for erasure if (!stm32h7_check_all_ones(addr, count >> 2)) { return false; } #if STM32_FLASH_DISABLE_ISR syssts_t sts = chSysGetStatusAndLockX(); #endif stm32_flash_unlock(); bool success = true; while (count >= 32) { if (!stm32h7_flash_write32(addr, b)) { success = false; goto failed; } // check contents if (memcmp((void*)addr, b, 32) != 0) { success = false; goto failed; } addr += 32; count -= 32; b += 32; } failed: stm32_flash_lock(); #if STM32_FLASH_DISABLE_ISR chSysRestoreStatusX(sts); #endif return success; } #endif // STM32H7 #if defined(STM32F4) || defined(STM32F7) static bool stm32_flash_write_f4f7(uint32_t addr, const void *buf, uint32_t count) { uint8_t *b = (uint8_t *)buf; /* STM32 requires half-word access */ if (count & 1) { return false; } if ((addr+count) > STM32_FLASH_BASE+STM32_FLASH_SIZE) { return false; } /* Get flash ready and begin flashing */ if (!(RCC->CR & RCC_CR_HSION)) { return false; } #if STM32_FLASH_DISABLE_ISR syssts_t sts = chSysGetStatusAndLockX(); #endif stm32_flash_unlock(); // clear previous errors stm32_flash_clear_errors(); stm32_flash_wait_idle(); // do as much as possible with 32 bit writes while (count >= 4 && (addr & 3) == 0) { FLASH->CR &= ~(FLASH_CR_PSIZE); FLASH->CR |= FLASH_CR_PSIZE_1 | FLASH_CR_PG; const uint32_t v1 = *(uint32_t *)b; putreg32(v1, addr); // ensure write ordering with cache __DSB(); stm32_flash_wait_idle(); const uint32_t v2 = getreg32(addr); if (v2 != v1) { FLASH->CR &= ~(FLASH_CR_PG); goto failed; } count -= 4; b += 4; addr += 4; } // the rest as 16 bit while (count >= 2) { FLASH->CR &= ~(FLASH_CR_PSIZE); FLASH->CR |= FLASH_CR_PSIZE_0 | FLASH_CR_PG; putreg16(*(uint16_t *)b, addr); // ensure write ordering with cache __DSB(); stm32_flash_wait_idle(); if (getreg16(addr) != *(uint16_t *)b) { FLASH->CR &= ~(FLASH_CR_PG); goto failed; } count -= 2; b += 2; addr += 2; } FLASH->CR &= ~(FLASH_CR_PG); stm32_flash_lock(); #if STM32_FLASH_DISABLE_ISR chSysRestoreStatusX(sts); #endif return true; failed: stm32_flash_lock(); #if STM32_FLASH_DISABLE_ISR chSysRestoreStatusX(sts); #endif return false; } #endif // STM32F4 || STM32F7 uint32_t _flash_fail_line; uint32_t _flash_fail_addr; uint32_t _flash_fail_count; uint8_t *_flash_fail_buf; #if defined(STM32F1) || defined(STM32F3) static bool stm32_flash_write_f1(uint32_t addr, const void *buf, uint32_t count) { uint8_t *b = (uint8_t *)buf; /* STM32 requires half-word access */ if (count & 1) { _flash_fail_line = __LINE__; return false; } if ((addr+count) > STM32_FLASH_BASE+STM32_FLASH_SIZE) { _flash_fail_line = __LINE__; return false; } #if STM32_FLASH_DISABLE_ISR syssts_t sts = chSysGetStatusAndLockX(); #endif stm32_flash_unlock(); stm32_flash_wait_idle(); // program in 16 bit steps while (count >= 2) { FLASH->CR = FLASH_CR_PG; putreg16(*(uint16_t *)b, addr); stm32_flash_wait_idle(); FLASH->CR = 0; if (getreg16(addr) != *(uint16_t *)b) { _flash_fail_line = __LINE__; _flash_fail_addr = addr; _flash_fail_count = count; _flash_fail_buf = b; goto failed; } count -= 2; b += 2; addr += 2; } stm32_flash_lock(); #if STM32_FLASH_DISABLE_ISR chSysRestoreStatusX(sts); #endif return true; failed: stm32_flash_lock(); #if STM32_FLASH_DISABLE_ISR chSysRestoreStatusX(sts); #endif return false; } #endif // STM32F1 or STM32F3 #if defined(STM32G4) || defined(STM32L4) static bool stm32_flash_write_g4(uint32_t addr, const void *buf, uint32_t count) { uint32_t *b = (uint32_t *)buf; /* STM32G4 requires double-word access */ if ((count & 7) || (addr & 7)) { _flash_fail_line = __LINE__; return false; } if ((addr+count) > STM32_FLASH_BASE+STM32_FLASH_SIZE) { _flash_fail_line = __LINE__; return false; } // skip already programmed word pairs while (count >= 8 && getreg32(addr+0) == b[0] && getreg32(addr+4) == b[1]) { count -= 8; addr += 8; b += 2; } if (count == 0) { return true; } #if STM32_FLASH_DISABLE_ISR syssts_t sts = chSysGetStatusAndLockX(); #endif stm32_flash_unlock(); stm32_flash_wait_idle(); // program in 16 bit steps while (count >= 2) { FLASH->CR = FLASH_CR_PG; putreg32(b[0], addr+0); putreg32(b[1], addr+4); stm32_flash_wait_idle(); FLASH->CR = 0; if (getreg32(addr+0) != b[0] || getreg32(addr+4) != b[1]) { _flash_fail_line = __LINE__; _flash_fail_addr = addr; _flash_fail_count = count; _flash_fail_buf = (uint8_t *)b; goto failed; } count -= 8; b += 2; addr += 8; } stm32_flash_lock(); #if STM32_FLASH_DISABLE_ISR chSysRestoreStatusX(sts); #endif return true; failed: stm32_flash_lock(); #if STM32_FLASH_DISABLE_ISR chSysRestoreStatusX(sts); #endif return false; } #endif // STM32G4 bool stm32_flash_write(uint32_t addr, const void *buf, uint32_t count) { #if defined(STM32F1) || defined(STM32F3) return stm32_flash_write_f1(addr, buf, count); #elif defined(STM32F4) || defined(STM32F7) return stm32_flash_write_f4f7(addr, buf, count); #elif defined(STM32H7) return stm32_flash_write_h7(addr, buf, count); #elif defined(STM32G4) || defined(STM32L4) return stm32_flash_write_g4(addr, buf, count); #else #error "Unsupported MCU" #endif } void stm32_flash_keep_unlocked(bool set) { if (set && !flash_keep_unlocked) { stm32_flash_unlock(); flash_keep_unlocked = true; } else if (!set && flash_keep_unlocked) { flash_keep_unlocked = false; stm32_flash_lock(); } } /** * @brief write protect the main flash or bootloader sectors */ void stm32_flash_protect_flash(bool bootloader, bool protect) { (void)bootloader; (void)protect; #if defined(STM32H7) && !defined(HAL_BOOTLOADER_BUILD) && defined(HAL_FLASH_PROTECTION) uint32_t prg1 = FLASH->WPSN_CUR1; uint32_t prg2 = FLASH->WPSN_CUR2; #ifndef STORAGE_FLASH_PAGE const uint32_t storage_page = 0xFF; #else const uint32_t storage_page = STORAGE_FLASH_PAGE; #endif const uint32_t reserve_page = (FLASH_LOAD_ADDRESS - 0x08000000) / (1024 * 128); if (bootloader) { // only lock the reserved section for (uint32_t i = 0; i < reserve_page; i++) { if (protect) { prg1 &= ~(1U<WPSN_CUR1 && prg2 == FLASH->WPSN_CUR2) { return; } stm32_flash_opt_clear_errors(); stm32_flash_clear_errors(); if (stm32_flash_unlock_options()) { FLASH->WPSN_PRG1 = prg1; FLASH->WPSN_PRG2 = prg2; FLASH->OPTCR |= FLASH_OPTCR_OPTSTART; stm32_flash_wait_opt_idle(); stm32_flash_lock_options(); } #endif } /* * remove all protections from flash banks * this is a destructive operation requiring bank erasure * see H743 reference manual 4.3.10 - flash bank erase with protection removal */ void stm32_flash_unprotect_flash() { #if defined(STM32H7) && defined(HAL_FLASH_PROTECTION) stm32_flash_opt_clear_errors(); stm32_flash_clear_errors(); if ((FLASH->PRAR_CUR2 & 0xFFF) <= ((FLASH->PRAR_CUR2 >> 16) & 0xFFF) || (FLASH->SCAR_CUR2 & 0xFFF) <= ((FLASH->SCAR_CUR2 >> 16) & 0xFFF)) { if (stm32_flash_unlock_options()) { const uint32_t start_addr = 0x00; const uint32_t end_addr = 0xFF; const uint32_t prg = (1 << 31) | ((start_addr << 16) | end_addr); FLASH->PRAR_PRG2 = prg; FLASH->SCAR_PRG2 = prg; FLASH->WPSN_PRG2 = 0xFF; stm32_flash_unlock(); FLASH->CR2 |= FLASH_CR_BER; // bank 2 erase FLASH->CR2 |= FLASH_CR_START; stm32_flash_wait_idle(); stm32_flash_lock(); } } if ((FLASH->PRAR_CUR1 & 0xFFF) <= ((FLASH->PRAR_CUR1 >> 16) & 0xFFF) || (FLASH->SCAR_CUR1 & 0xFFF) <= ((FLASH->SCAR_CUR1 >> 16) & 0xFFF)) { if (stm32_flash_unlock_options()) { const uint32_t start_addr = 0x00; const uint32_t end_addr = 0xFF; const uint32_t prg = (1 << 31) | ((start_addr << 16) | end_addr); FLASH->PRAR_PRG1 = prg; FLASH->SCAR_PRG1 = prg; FLASH->WPSN_PRG1 = 0xFF; stm32_flash_unlock(); FLASH->CR1 |= FLASH_CR_BER; // bank 1 erase FLASH->CR1 |= FLASH_CR_START; stm32_flash_wait_idle(); stm32_flash_lock(); } } // remove write protection from banks 1&2 if ((FLASH->WPSN_CUR2 & 0xFF) != 0xFF || (FLASH->WPSN_CUR1 & 0xFF) != 0xFF) { if (stm32_flash_unlock_options()) { FLASH->WPSN_PRG1 = 0xFF; FLASH->WPSN_PRG2 = 0xFF; FLASH->OPTCR |= FLASH_OPTCR_OPTSTART; stm32_flash_wait_opt_idle(); stm32_flash_lock_options(); } } #endif } #ifndef HAL_BOOTLOADER_BUILD /* return true if we had a recent erase */ bool stm32_flash_recent_erase(void) { return hrt_millis32() - last_erase_ms < 3000U; } #endif #endif // HAL_NO_FLASH_SUPPORT