// SPDX-License-Identifier: GPL-2.0-or-later /*************************************************************************** * Copyright (C) 2005 by Dominic Rath * * Copyright (C) 2007-2010 Øyvind Harboe * * Copyright (C) 2008 by Spencer Oliver * * Copyright (C) 2009 Zachary T Welch * * Copyright (C) 2010 by Antonio Borneo * * Copyright (C) 2017-2018 Tomas Vanek * ***************************************************************************/ #ifdef HAVE_CONFIG_H #include #endif #include #include #include #include /** * @file * Upper level of NOR flash framework. * The lower level interfaces are to drivers. These upper level ones * primarily support access from Tcl scripts or from GDB. */ static struct flash_bank *flash_banks; int flash_driver_erase(struct flash_bank *bank, unsigned int first, unsigned int last) { int retval; retval = bank->driver->erase(bank, first, last); if (retval != ERROR_OK) LOG_ERROR("failed erasing sectors %u to %u", first, last); return retval; } int flash_driver_protect(struct flash_bank *bank, int set, unsigned int first, unsigned int last) { int retval; unsigned int num_blocks; if (bank->num_prot_blocks) num_blocks = bank->num_prot_blocks; else num_blocks = bank->num_sectors; /* callers may not supply illegal parameters ... */ if (first > last || last >= num_blocks) { LOG_ERROR("illegal protection block range"); return ERROR_FAIL; } /* force "set" to 0/1 */ set = !!set; if (!bank->driver->protect) { LOG_ERROR("Flash protection is not supported."); return ERROR_FLASH_OPER_UNSUPPORTED; } /* DANGER! * * We must not use any cached information about protection state!!!! * * There are a million things that could change the protect state: * * the target could have reset, power cycled, been hot plugged, * the application could have run, etc. * * Drivers only receive valid protection block range. */ retval = bank->driver->protect(bank, set, first, last); if (retval != ERROR_OK) LOG_ERROR("failed setting protection for blocks %u to %u", first, last); return retval; } int flash_driver_write(struct flash_bank *bank, const uint8_t *buffer, uint32_t offset, uint32_t count) { int retval; retval = bank->driver->write(bank, buffer, offset, count); if (retval != ERROR_OK) { LOG_ERROR( "error writing to flash at address " TARGET_ADDR_FMT " at offset 0x%8.8" PRIx32, bank->base, offset); } return retval; } int flash_driver_read(struct flash_bank *bank, uint8_t *buffer, uint32_t offset, uint32_t count) { int retval; LOG_DEBUG("call flash_driver_read()"); retval = bank->driver->read(bank, buffer, offset, count); if (retval != ERROR_OK) { LOG_ERROR( "error reading to flash at address " TARGET_ADDR_FMT " at offset 0x%8.8" PRIx32, bank->base, offset); } return retval; } int default_flash_read(struct flash_bank *bank, uint8_t *buffer, uint32_t offset, uint32_t count) { return target_read_buffer(bank->target, offset + bank->base, count, buffer); } int flash_driver_verify(struct flash_bank *bank, const uint8_t *buffer, uint32_t offset, uint32_t count) { int retval; retval = bank->driver->verify ? bank->driver->verify(bank, buffer, offset, count) : default_flash_verify(bank, buffer, offset, count); if (retval != ERROR_OK) { LOG_ERROR("verify failed in bank at " TARGET_ADDR_FMT " starting at 0x%8.8" PRIx32, bank->base, offset); } return retval; } int default_flash_verify(struct flash_bank *bank, const uint8_t *buffer, uint32_t offset, uint32_t count) { uint32_t target_crc, image_crc; int retval; retval = image_calculate_checksum(buffer, count, &image_crc); if (retval != ERROR_OK) return retval; retval = target_checksum_memory(bank->target, offset + bank->base, count, &target_crc); if (retval != ERROR_OK) return retval; LOG_DEBUG("addr " TARGET_ADDR_FMT ", len 0x%08" PRIx32 ", crc 0x%08" PRIx32 " 0x%08" PRIx32, offset + bank->base, count, ~image_crc, ~target_crc); if (target_crc == image_crc) return ERROR_OK; else return ERROR_FAIL; } void flash_bank_add(struct flash_bank *bank) { /* put flash bank in linked list */ unsigned bank_num = 0; if (flash_banks) { /* find last flash bank */ struct flash_bank *p = flash_banks; while (p->next) { bank_num += 1; p = p->next; } p->next = bank; bank_num += 1; } else flash_banks = bank; bank->bank_number = bank_num; } struct flash_bank *flash_bank_list(void) { return flash_banks; } struct flash_bank *get_flash_bank_by_num_noprobe(unsigned int num) { struct flash_bank *p; unsigned int i = 0; for (p = flash_banks; p; p = p->next) { if (i++ == num) return p; } LOG_ERROR("flash bank %d does not exist", num); return NULL; } unsigned int flash_get_bank_count(void) { struct flash_bank *p; unsigned int i = 0; for (p = flash_banks; p; p = p->next) i++; return i; } void default_flash_free_driver_priv(struct flash_bank *bank) { free(bank->driver_priv); bank->driver_priv = NULL; } void flash_free_all_banks(void) { struct flash_bank *bank = flash_banks; while (bank) { struct flash_bank *next = bank->next; if (bank->driver->free_driver_priv) bank->driver->free_driver_priv(bank); else LOG_WARNING("Flash driver of %s does not support free_driver_priv()", bank->name); /* For 'virtual' flash driver bank->sectors and bank->prot_blocks pointers are copied from * master flash_bank structure. They point to memory locations allocated by master flash driver * so master driver is responsible for releasing them. * Avoid UB caused by double-free memory corruption if flash bank is 'virtual'. */ if (strcmp(bank->driver->name, "virtual") != 0) { free(bank->sectors); free(bank->prot_blocks); } free(bank->name); free(bank); bank = next; } flash_banks = NULL; } struct flash_bank *get_flash_bank_by_name_noprobe(const char *name) { unsigned requested = get_flash_name_index(name); unsigned found = 0; struct flash_bank *bank; for (bank = flash_banks; bank; bank = bank->next) { if (strcmp(bank->name, name) == 0) return bank; if (!flash_driver_name_matches(bank->driver->name, name)) continue; if (++found < requested) continue; return bank; } return NULL; } int get_flash_bank_by_name(const char *name, struct flash_bank **bank_result) { struct flash_bank *bank; int retval; bank = get_flash_bank_by_name_noprobe(name); if (bank) { retval = bank->driver->auto_probe(bank); if (retval != ERROR_OK) { LOG_ERROR("auto_probe failed"); return retval; } } *bank_result = bank; return ERROR_OK; } int get_flash_bank_by_num(unsigned int num, struct flash_bank **bank) { struct flash_bank *p = get_flash_bank_by_num_noprobe(num); int retval; if (!p) return ERROR_FAIL; retval = p->driver->auto_probe(p); if (retval != ERROR_OK) { LOG_ERROR("auto_probe failed"); return retval; } *bank = p; return ERROR_OK; } /* lookup flash bank by address, bank not found is success, but * result_bank is set to NULL. */ int get_flash_bank_by_addr(struct target *target, target_addr_t addr, bool check, struct flash_bank **result_bank) { struct flash_bank *c; /* cycle through bank list */ for (c = flash_banks; c; c = c->next) { if (c->target != target) continue; int retval; retval = c->driver->auto_probe(c); if (retval != ERROR_OK) { LOG_ERROR("auto_probe failed"); return retval; } /* check whether address belongs to this flash bank */ if ((addr >= c->base) && (addr <= c->base + (c->size - 1))) { *result_bank = c; return ERROR_OK; } } *result_bank = NULL; if (check) { LOG_ERROR("No flash at address " TARGET_ADDR_FMT, addr); return ERROR_FAIL; } return ERROR_OK; } static int default_flash_mem_blank_check(struct flash_bank *bank) { struct target *target = bank->target; const int buffer_size = 1024; uint32_t n_bytes; int retval = ERROR_OK; if (bank->target->state != TARGET_HALTED) { LOG_ERROR("Target not halted"); return ERROR_TARGET_NOT_HALTED; } uint8_t *buffer = malloc(buffer_size); for (unsigned int i = 0; i < bank->num_sectors; i++) { uint32_t j; bank->sectors[i].is_erased = 1; for (j = 0; j < bank->sectors[i].size; j += buffer_size) { uint32_t chunk; chunk = buffer_size; if (chunk > (bank->sectors[i].size - j)) chunk = (bank->sectors[i].size - j); retval = target_read_memory(target, bank->base + bank->sectors[i].offset + j, 4, chunk/4, buffer); if (retval != ERROR_OK) goto done; for (n_bytes = 0; n_bytes < chunk; n_bytes++) { if (buffer[n_bytes] != bank->erased_value) { bank->sectors[i].is_erased = 0; break; } } } } done: free(buffer); return retval; } int default_flash_blank_check(struct flash_bank *bank) { struct target *target = bank->target; int retval; if (bank->target->state != TARGET_HALTED) { LOG_ERROR("Target not halted"); return ERROR_TARGET_NOT_HALTED; } struct target_memory_check_block *block_array; block_array = malloc(bank->num_sectors * sizeof(struct target_memory_check_block)); if (!block_array) return default_flash_mem_blank_check(bank); for (unsigned int i = 0; i < bank->num_sectors; i++) { block_array[i].address = bank->base + bank->sectors[i].offset; block_array[i].size = bank->sectors[i].size; block_array[i].result = UINT32_MAX; /* erase state unknown */ } bool fast_check = true; for (unsigned int i = 0; i < bank->num_sectors; ) { retval = target_blank_check_memory(target, block_array + i, bank->num_sectors - i, bank->erased_value); if (retval < 1) { /* Run slow fallback if the first run gives no result * otherwise use possibly incomplete results */ if (i == 0) fast_check = false; break; } i += retval; /* add number of blocks done this round */ } if (fast_check) { for (unsigned int i = 0; i < bank->num_sectors; i++) bank->sectors[i].is_erased = block_array[i].result; retval = ERROR_OK; } else { if (retval == ERROR_NOT_IMPLEMENTED) LOG_USER("Running slow fallback erase check"); else LOG_USER("Running slow fallback erase check - add working memory"); retval = default_flash_mem_blank_check(bank); } free(block_array); return retval; } /* Manipulate given flash region, selecting the bank according to target * and address. Maps an address range to a set of sectors, and issues * the callback() on that set ... e.g. to erase or unprotect its members. * * Parameter iterate_protect_blocks switches iteration of protect block * instead of erase sectors. If there is no protect blocks array, sectors * are used in iteration, so compatibility for old flash drivers is retained. * * The "pad_reason" parameter is a kind of boolean: when it's NULL, the * range must fit those sectors exactly. This is clearly safe; it can't * erase data which the caller said to leave alone, for example. If it's * non-NULL, rather than failing, extra data in the first and/or last * sectors will be added to the range, and that reason string is used when * warning about those additions. */ static int flash_iterate_address_range_inner(struct target *target, char *pad_reason, target_addr_t addr, uint32_t length, bool iterate_protect_blocks, int (*callback)(struct flash_bank *bank, unsigned int first, unsigned int last)) { struct flash_bank *c; struct flash_sector *block_array; target_addr_t last_addr = addr + length - 1; /* the last address of range */ int first = -1; int last = -1; int i; int num_blocks; int retval = get_flash_bank_by_addr(target, addr, true, &c); if (retval != ERROR_OK) return retval; if (c->size == 0 || c->num_sectors == 0) { LOG_ERROR("Bank is invalid"); return ERROR_FLASH_BANK_INVALID; } if (length == 0) { /* special case, erase whole bank when length is zero */ if (addr != c->base) { LOG_ERROR("Whole bank access must start at beginning of bank."); return ERROR_FLASH_DST_BREAKS_ALIGNMENT; } return callback(c, 0, c->num_sectors - 1); } /* check whether it all fits in this bank */ if (last_addr > c->base + c->size - 1) { LOG_ERROR("Flash access does not fit into bank."); return ERROR_FLASH_DST_BREAKS_ALIGNMENT; } if (!c->prot_blocks || c->num_prot_blocks == 0) { /* flash driver does not define protect blocks, use sectors instead */ iterate_protect_blocks = false; } if (iterate_protect_blocks) { block_array = c->prot_blocks; num_blocks = c->num_prot_blocks; } else { block_array = c->sectors; num_blocks = c->num_sectors; } for (i = 0; i < num_blocks; i++) { struct flash_sector *f = &block_array[i]; target_addr_t sector_addr = c->base + f->offset; target_addr_t sector_last_addr = sector_addr + f->size - 1; /* start only on a sector boundary */ if (first < 0) { /* scanned past the first sector? */ if (addr < sector_addr) break; /* is this the first sector? */ if (addr == sector_addr) first = i; /* Does this need head-padding? If so, pad and warn; * or else force an error. * * Such padding can make trouble, since *WE* can't * ever know if that data was in use. The warning * should help users sort out messes later. */ else if (addr <= sector_last_addr && pad_reason) { /* FIXME say how many bytes (e.g. 80 KB) */ LOG_WARNING("Adding extra %s range, " TARGET_ADDR_FMT " .. " TARGET_ADDR_FMT, pad_reason, sector_addr, addr - 1); first = i; } else continue; } /* is this (also?) the last sector? */ if (last_addr == sector_last_addr) { last = i; break; } /* Does this need tail-padding? If so, pad and warn; * or else force an error. */ if (last_addr < sector_last_addr && pad_reason) { /* FIXME say how many bytes (e.g. 80 KB) */ LOG_WARNING("Adding extra %s range, " TARGET_ADDR_FMT " .. " TARGET_ADDR_FMT, pad_reason, last_addr + 1, sector_last_addr); last = i; break; } /* MUST finish on a sector boundary */ if (last_addr < sector_addr) break; } /* invalid start or end address? */ if (first == -1 || last == -1) { LOG_ERROR("address range " TARGET_ADDR_FMT " .. " TARGET_ADDR_FMT " is not sector-aligned", addr, last_addr); return ERROR_FLASH_DST_BREAKS_ALIGNMENT; } /* The NOR driver may trim this range down, based on what * sectors are already erased/unprotected. GDB currently * blocks such optimizations. */ return callback(c, first, last); } /* The inner fn only handles a single bank, we could be spanning * multiple chips. */ static int flash_iterate_address_range(struct target *target, char *pad_reason, target_addr_t addr, uint32_t length, bool iterate_protect_blocks, int (*callback)(struct flash_bank *bank, unsigned int first, unsigned int last)) { struct flash_bank *c; int retval = ERROR_OK; /* Danger! zero-length iterations means entire bank! */ do { retval = get_flash_bank_by_addr(target, addr, true, &c); if (retval != ERROR_OK) return retval; uint32_t cur_length = length; /* check whether it all fits in this bank */ if (addr + length - 1 > c->base + c->size - 1) { LOG_DEBUG("iterating over more than one flash bank."); cur_length = c->base + c->size - addr; } retval = flash_iterate_address_range_inner(target, pad_reason, addr, cur_length, iterate_protect_blocks, callback); if (retval != ERROR_OK) break; length -= cur_length; addr += cur_length; } while (length > 0); return retval; } int flash_erase_address_range(struct target *target, bool pad, target_addr_t addr, uint32_t length) { return flash_iterate_address_range(target, pad ? "erase" : NULL, addr, length, false, &flash_driver_erase); } static int flash_driver_unprotect(struct flash_bank *bank, unsigned int first, unsigned int last) { return flash_driver_protect(bank, 0, first, last); } int flash_unlock_address_range(struct target *target, target_addr_t addr, uint32_t length) { /* By default, pad to sector boundaries ... the real issue here * is that our (only) caller *permanently* removes protection, * and doesn't restore it. */ return flash_iterate_address_range(target, "unprotect", addr, length, true, &flash_driver_unprotect); } static int compare_section(const void *a, const void *b) { struct imagesection *b1, *b2; b1 = *((struct imagesection **)a); b2 = *((struct imagesection **)b); if (b1->base_address == b2->base_address) return 0; else if (b1->base_address > b2->base_address) return 1; else return -1; } /** * Get aligned start address of a flash write region */ target_addr_t flash_write_align_start(struct flash_bank *bank, target_addr_t addr) { if (addr < bank->base || addr >= bank->base + bank->size || bank->write_start_alignment <= 1) return addr; if (bank->write_start_alignment == FLASH_WRITE_ALIGN_SECTOR) { uint32_t offset = addr - bank->base; uint32_t aligned = 0; for (unsigned int sect = 0; sect < bank->num_sectors; sect++) { if (bank->sectors[sect].offset > offset) break; aligned = bank->sectors[sect].offset; } return bank->base + aligned; } return addr & ~(bank->write_start_alignment - 1); } /** * Get aligned end address of a flash write region */ target_addr_t flash_write_align_end(struct flash_bank *bank, target_addr_t addr) { if (addr < bank->base || addr >= bank->base + bank->size || bank->write_end_alignment <= 1) return addr; if (bank->write_end_alignment == FLASH_WRITE_ALIGN_SECTOR) { uint32_t offset = addr - bank->base; uint32_t aligned = 0; for (unsigned int sect = 0; sect < bank->num_sectors; sect++) { aligned = bank->sectors[sect].offset + bank->sectors[sect].size - 1; if (aligned >= offset) break; } return bank->base + aligned; } return addr | (bank->write_end_alignment - 1); } /** * Check if gap between sections is bigger than minimum required to discontinue flash write */ static bool flash_write_check_gap(struct flash_bank *bank, target_addr_t addr1, target_addr_t addr2) { if (bank->minimal_write_gap == FLASH_WRITE_CONTINUOUS || addr1 < bank->base || addr1 >= bank->base + bank->size || addr2 < bank->base || addr2 >= bank->base + bank->size) return false; if (bank->minimal_write_gap == FLASH_WRITE_GAP_SECTOR) { unsigned int sect; uint32_t offset1 = addr1 - bank->base; /* find the sector following the one containing addr1 */ for (sect = 0; sect < bank->num_sectors; sect++) { if (bank->sectors[sect].offset > offset1) break; } if (sect >= bank->num_sectors) return false; uint32_t offset2 = addr2 - bank->base; return bank->sectors[sect].offset + bank->sectors[sect].size <= offset2; } target_addr_t aligned1 = flash_write_align_end(bank, addr1); target_addr_t aligned2 = flash_write_align_start(bank, addr2); return aligned1 + bank->minimal_write_gap < aligned2; } int flash_write_unlock_verify(struct target *target, struct image *image, uint32_t *written, bool erase, bool unlock, bool write, bool verify) { int retval = ERROR_OK; unsigned int section; uint32_t section_offset; struct flash_bank *c; int *padding; section = 0; section_offset = 0; if (written) *written = 0; if (erase) { /* assume all sectors need erasing - stops any problems * when flash_write is called multiple times */ flash_set_dirty(); } /* allocate padding array */ padding = calloc(image->num_sections, sizeof(*padding)); /* This fn requires all sections to be in ascending order of addresses, * whereas an image can have sections out of order. */ struct imagesection **sections = malloc(sizeof(struct imagesection *) * image->num_sections); for (unsigned int i = 0; i < image->num_sections; i++) sections[i] = &image->sections[i]; qsort(sections, image->num_sections, sizeof(struct imagesection *), compare_section); /* loop until we reach end of the image */ while (section < image->num_sections) { uint32_t buffer_idx; uint8_t *buffer; unsigned int section_last; target_addr_t run_address = sections[section]->base_address + section_offset; uint32_t run_size = sections[section]->size - section_offset; int pad_bytes = 0; if (sections[section]->size == 0) { LOG_WARNING("empty section %d", section); section++; section_offset = 0; continue; } /* find the corresponding flash bank */ retval = get_flash_bank_by_addr(target, run_address, false, &c); if (retval != ERROR_OK) goto done; if (!c) { LOG_WARNING("no flash bank found for address " TARGET_ADDR_FMT, run_address); section++; /* and skip it */ section_offset = 0; continue; } /* collect consecutive sections which fall into the same bank */ section_last = section; padding[section] = 0; while ((run_address + run_size - 1 < c->base + c->size - 1) && (section_last + 1 < image->num_sections)) { /* sections are sorted */ assert(sections[section_last + 1]->base_address >= c->base); if (sections[section_last + 1]->base_address >= (c->base + c->size)) { /* Done with this bank */ break; } /* if we have multiple sections within our image, * flash programming could fail due to alignment issues * attempt to rebuild a consecutive buffer for the flash loader */ target_addr_t run_next_addr = run_address + run_size; target_addr_t next_section_base = sections[section_last + 1]->base_address; if (next_section_base < run_next_addr) { LOG_ERROR("Section at " TARGET_ADDR_FMT " overlaps section ending at " TARGET_ADDR_FMT, next_section_base, run_next_addr); LOG_ERROR("Flash write aborted."); retval = ERROR_FAIL; goto done; } pad_bytes = next_section_base - run_next_addr; if (pad_bytes) { if (flash_write_check_gap(c, run_next_addr - 1, next_section_base)) { LOG_INFO("Flash write discontinued at " TARGET_ADDR_FMT ", next section at " TARGET_ADDR_FMT, run_next_addr, next_section_base); break; } } if (pad_bytes > 0) LOG_INFO("Padding image section %d at " TARGET_ADDR_FMT " with %d bytes", section_last, run_next_addr, pad_bytes); padding[section_last] = pad_bytes; run_size += pad_bytes; run_size += sections[++section_last]->size; } if (run_address + run_size - 1 > c->base + c->size - 1) { /* If we have more than one flash chip back to back, then we limit * the current write operation to the current chip. */ LOG_DEBUG("Truncate flash run size to the current flash chip."); run_size = c->base + c->size - run_address; assert(run_size > 0); } uint32_t padding_at_start = 0; if (c->write_start_alignment || c->write_end_alignment) { /* align write region according to bank requirements */ target_addr_t aligned_start = flash_write_align_start(c, run_address); padding_at_start = run_address - aligned_start; if (padding_at_start > 0) { LOG_WARNING("Section start address " TARGET_ADDR_FMT " breaks the required alignment of flash bank %s", run_address, c->name); LOG_WARNING("Padding %" PRIu32 " bytes from " TARGET_ADDR_FMT, padding_at_start, aligned_start); run_address -= padding_at_start; run_size += padding_at_start; } target_addr_t run_end = run_address + run_size - 1; target_addr_t aligned_end = flash_write_align_end(c, run_end); pad_bytes = aligned_end - run_end; if (pad_bytes > 0) { LOG_INFO("Padding image section %d at " TARGET_ADDR_FMT " with %d bytes (bank write end alignment)", section_last, run_end + 1, pad_bytes); padding[section_last] += pad_bytes; run_size += pad_bytes; } } else if (unlock || erase) { /* If we're applying any sector automagic, then pad this * (maybe-combined) segment to the end of its last sector. */ uint32_t offset_start = run_address - c->base; uint32_t offset_end = offset_start + run_size; uint32_t end = offset_end, delta; for (unsigned int sector = 0; sector < c->num_sectors; sector++) { end = c->sectors[sector].offset + c->sectors[sector].size; if (offset_end <= end) break; } delta = end - offset_end; padding[section_last] += delta; run_size += delta; } /* allocate buffer */ buffer = malloc(run_size); if (!buffer) { LOG_ERROR("Out of memory for flash bank buffer"); retval = ERROR_FAIL; goto done; } if (padding_at_start) memset(buffer, c->default_padded_value, padding_at_start); buffer_idx = padding_at_start; /* read sections to the buffer */ while (buffer_idx < run_size) { size_t size_read; size_read = run_size - buffer_idx; if (size_read > sections[section]->size - section_offset) size_read = sections[section]->size - section_offset; /* KLUDGE! * * #¤%#"%¤% we have to figure out the section # from the sorted * list of pointers to sections to invoke image_read_section()... */ intptr_t diff = (intptr_t)sections[section] - (intptr_t)image->sections; int t_section_num = diff / sizeof(struct imagesection); LOG_DEBUG("image_read_section: section = %d, t_section_num = %d, " "section_offset = %"PRIu32", buffer_idx = %"PRIu32", size_read = %zu", section, t_section_num, section_offset, buffer_idx, size_read); retval = image_read_section(image, t_section_num, section_offset, size_read, buffer + buffer_idx, &size_read); if (retval != ERROR_OK || size_read == 0) { free(buffer); goto done; } buffer_idx += size_read; section_offset += size_read; /* see if we need to pad the section */ if (padding[section]) { memset(buffer + buffer_idx, c->default_padded_value, padding[section]); buffer_idx += padding[section]; } if (section_offset >= sections[section]->size) { section++; section_offset = 0; } } retval = ERROR_OK; if (unlock) retval = flash_unlock_address_range(target, run_address, run_size); if (retval == ERROR_OK) { if (erase) { /* calculate and erase sectors */ retval = flash_erase_address_range(target, true, run_address, run_size); } } if (retval == ERROR_OK) { if (write) { /* write flash sectors */ retval = flash_driver_write(c, buffer, run_address - c->base, run_size); } } if (retval == ERROR_OK) { if (verify) { /* verify flash sectors */ retval = flash_driver_verify(c, buffer, run_address - c->base, run_size); } } free(buffer); if (retval != ERROR_OK) { /* abort operation */ goto done; } if (written) *written += run_size; /* add run size to total written counter */ } done: free(sections); free(padding); return retval; } int flash_write(struct target *target, struct image *image, uint32_t *written, bool erase) { return flash_write_unlock_verify(target, image, written, erase, false, true, false); } struct flash_sector *alloc_block_array(uint32_t offset, uint32_t size, unsigned int num_blocks) { struct flash_sector *array = calloc(num_blocks, sizeof(struct flash_sector)); if (!array) return NULL; for (unsigned int i = 0; i < num_blocks; i++) { array[i].offset = offset; array[i].size = size; array[i].is_erased = -1; array[i].is_protected = -1; offset += size; } return array; }