/* * avrdude - A Downloader/Uploader for AVR device programmers * Copyright (C) 2022 Stefan Rueger * * This program 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 2 of the License, or * (at your option) any later version. * * This program 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 . */ /* $Id$ */ #include "ac_cfg.h" #include #include #include #include #include #include #include "avrdude.h" #include "libavrdude.h" #include "avrintel.h" /* * Provides an API for cached bytewise access * * int avr_read_byte_cached(const PROGRAMMER *pgm, const AVRPART *p, const * AVRMEM *mem, unsigned long addr, unsigned char *value); * * int avr_write_byte_cached(const PROGRAMMER *pgm, const AVRPART *p, const * AVRMEM *mem, unsigned long addr, unsigned char data); * * int avr_flush_cache(const PROGRAMMER *pgm, const AVRPART *p); * * int avr_chip_erase_cached(const PROGRAMMER *pgm, const AVRPART *p); * * int avr_page_erase_cached(const PROGRAMMER *pgm, const AVRPART *p, const * AVRMEM *mem, unsigned int baseaddr); * * int avr_reset_cache(const PROGRAMMER *pgm, const AVRPART *p); * * avr_read_byte_cached() and avr_write_byte_cached() use a cache if paged * routines are available and if the device memory is EEPROM or flash, * otherwise they fall back to pgm->read_byte() and pgm->write_byte(), * respectively. Bytewise cached read always gets its data from the cache, * possibly after reading a page from the device memory. Bytewise cached * write with an address in memory range only ever modifies the cache. Any * modifications are written to the device after calling avr_flush_cache() or * when attempting to read or write from a location outside the address range * of the device memory. * * avr_flush_cache() synchronises pending writes to EEPROM and flash with the * device. With some programmer and part combinations, flash (and sometimes * EEPROM, too) looks like a NOR memory, ie, one can only write 0 bits, not 1 * bits. When this is detected, either page erase is deployed (eg, with parts * that have PDI/UPDI interfaces), or if that is not available, both EEPROM * and flash caches are fully read in, a pgm->chip_erase() command is issued * and both EEPROM and flash are written back to the device. Hence, it can * take minutes to ensure that a single previously cleared bit is set and, * therefore, this routine should be called sparingly. * * avr_chip_erase_cached() erases the chip and discards pending writes() to * flash or EEPROM. It presets the flash cache to all 0xff alleviating the * need to read from the device flash. However, if the programmer serves * bootloaders (pgm->prog_modes & PM_SPM) then the flash cache is reset * instead, necessitating flash memory be fetched from the device on first * read; the reason for this is that bootloaders emulate chip erase and they * won't overwrite themselves (some bootloaders, eg, optiboot ignore chip * erase commands) making it truly unknowable what the flash contents on * device is after a chip erase. * * For EEPROM avr_chip_erase_cached() concludes that it has been deleted if a * previously cached EEPROM page that contained cleared bits now no longer * has these clear bits on the device. Only with this evidence is the EEPROM * cache preset to all 0xff otherwise the cache discards all pending writes * to EEPROM and is left unchanged otherwise. * * The avr_page_erase_cached() function erases a page and synchronises it * with the cache. * * Finally, avr_reset_cache() resets the cache without synchronising pending * writes() to the device. * * This file also holds the following utility functions * * // Does the programmer/memory combo have paged memory access? * int avr_has_paged_access(const PROGRAMMER *pgm, const AVRMEM *mem); * * // Read the page containing addr from the device into buf * int avr_read_page_default(const PROGRAMMER *pgm, const AVRPART *p, const AVRMEM *mem, int addr, unsigned char *buf); * * // Write the data page to the device into the page containing addr * int avr_write_page_default(const PROGRAMMER *pgm, const AVRPART *p, const AVRMEM *mem, int addr, unsigned char *data); * * // Could memory region s1 be the result of a NOR-memory copy of s3 onto s2? * int avr_is_and(const unsigned char *s1, const unsigned char *s2, const unsigned char *s3, size_t n); * */ /* * Paged access? * - Programmer must have paged routines * - Memory has positive page size, which is a power of two * - Memory has positive size, which is a multiple of the page size * - Memory is flash type or eeprom type * * Note that in this definition the page size can be 1 */ int avr_has_paged_access(const PROGRAMMER *pgm, const AVRMEM *mem) { return pgm->paged_load && pgm->paged_write && mem->page_size > 0 && (mem->page_size & (mem->page_size-1)) == 0 && mem->size > 0 && mem->size % mem->page_size == 0 && (avr_mem_is_flash_type(mem) || avr_mem_is_eeprom_type(mem)); } #define fallback_read_byte (pgm->read_byte != avr_read_byte_cached? pgm->read_byte: avr_read_byte_default) #define fallback_write_byte (pgm->write_byte != avr_write_byte_cached? pgm->write_byte: avr_write_byte_default) /* * Read the page containing addr from the device into buf * - Caller to ensure buf has mem->page_size bytes * - Part memory buffer mem is unaffected by this (though temporarily changed) * - Uses read_byte() if memory page size is one, otherwise paged_load() * - Fall back to bytewise read if paged_load() returned an error * - On failure returns a negative value, on success a non-negative value, which is either * + The number of bytes read by pgm->paged_load() if that succeeded * + LIBAVRDUDE_SUCCESS (0) if the fallback of bytewise read succeeded */ int avr_read_page_default(const PROGRAMMER *pgm, const AVRPART *p, const AVRMEM *mem, int addr, unsigned char *buf) { if(!avr_has_paged_access(pgm, mem) || addr < 0 || addr >= mem->size) return LIBAVRDUDE_GENERAL_FAILURE; int rc, pgsize = mem->page_size, base = addr & ~(pgsize-1); unsigned char *pagecopy = cfg_malloc("avr_read_page_default()", pgsize); if(pgsize == 1) return fallback_read_byte(pgm, p, mem, addr, buf); memcpy(pagecopy, mem->buf + base, pgsize); if((rc = pgm->paged_load(pgm, p, mem, pgsize, base, pgsize)) >= 0) memcpy(buf, mem->buf + base, pgsize); memcpy(mem->buf + base, pagecopy, pgsize); if(rc < 0 && pgm->read_byte != avr_read_byte_cached) { rc = LIBAVRDUDE_SUCCESS; for(int i=0; iread_byte(pgm, p, mem, base+i, pagecopy+i) < 0) { rc = LIBAVRDUDE_GENERAL_FAILURE; break; } } if(rc == LIBAVRDUDE_SUCCESS) memcpy(buf, pagecopy, pgsize); } free(pagecopy); return rc; } /* * Write the data page to the device into the page containing addr * - Caller to provide all mem->page_size bytes incl padding if any * - Part memory buffer mem is unaffected by this (though temporarily changed) * - Uses write_byte() if memory page size is one, otherwise paged_write() */ int avr_write_page_default(const PROGRAMMER *pgm, const AVRPART *p, const AVRMEM *mem, int addr, unsigned char *data) { if(!avr_has_paged_access(pgm, mem) || addr < 0 || addr >= mem->size) return LIBAVRDUDE_GENERAL_FAILURE; int rc, pgsize = mem->page_size, base = addr & ~(pgsize-1); unsigned char *pagecopy = cfg_malloc("avr_write_page_default()", pgsize); if(pgsize == 1) return fallback_write_byte(pgm, p, mem, addr, *data); memcpy(pagecopy, mem->buf + base, pgsize); memcpy(mem->buf + base, data, pgsize); rc = pgm->paged_write(pgm, p, mem, pgsize, base, pgsize); memcpy(mem->buf + base, pagecopy, pgsize); free(pagecopy); return rc; } // Could memory region s1 be the result of a NOR-memory copy of s3 onto s2? int avr_is_and(const unsigned char *s1, const unsigned char *s2, const unsigned char *s3, size_t n) { while(n--) if(*s1++ != (*s2++ & *s3++)) return 0; return 1; } static int cacheAddress(int addr, const AVR_Cache *cp, const AVRMEM *mem) { int cacheaddr = addr + (int) (mem->offset - cp->offset); if(cacheaddr < 0 || cacheaddr >= cp->size) { // Should never happen (unless offsets wrong in avrdude.conf) pmsg_error("%s cache address 0x%04x out of range [0, 0x%04x]\n", mem->desc, cacheaddr, cp->size-1); return LIBAVRDUDE_GENERAL_FAILURE; } if(mem->page_size != cp->page_size) { // Should never happen (unless incompatible page sizes in avrdude.conf) pmsg_error("%s page size %d incompatible with cache page size %d\n", mem->desc, mem->page_size, cp->page_size); return LIBAVRDUDE_GENERAL_FAILURE; } return cacheaddr; } static int loadCachePage(AVR_Cache *cp, const PROGRAMMER *pgm, const AVRPART *p, const AVRMEM *mem, int addr, int cacheaddr, int nlOnErr) { int pgno = cacheaddr/cp->page_size; if(!cp->iscached[pgno]) { // Read cached section from device int cachebase = cacheaddr & ~(cp->page_size-1); if(avr_read_page_default(pgm, p, mem, addr & ~(cp->page_size-1), cp->cont + cachebase) < 0) { report_progress(1, -1, NULL); if(nlOnErr && quell_progress) msg_info("\n"); pmsg_error("unable to read %s page at addr 0x%04x\n", mem->desc, addr); return LIBAVRDUDE_GENERAL_FAILURE; } // Copy last read device page, so we can later check for changes memcpy(cp->copy + cachebase, cp->cont + cachebase, cp->page_size); cp->iscached[pgno] = 1; } return LIBAVRDUDE_SUCCESS; } static int initCache(AVR_Cache *cp, const PROGRAMMER *pgm, const AVRPART *p) { AVRMEM *basemem = avr_locate_mem(p, cp == pgm->cp_flash? "flash": "eeprom"); if(!basemem || !avr_has_paged_access(pgm, basemem)) return LIBAVRDUDE_GENERAL_FAILURE; cp->size = basemem->size; cp->page_size = basemem->page_size; cp->offset = basemem->offset; cp->cont = cfg_malloc("initCache()", cp->size); cp->copy = cfg_malloc("initCache()", cp->size); cp->iscached = cfg_malloc("initCache()", cp->size/cp->page_size); if((pgm->prog_modes & PM_SPM) && avr_mem_is_flash_type(basemem)) { // Could be vector bootloader // Caching the vector page gives control to the progammer that then can patch the reset vector if(loadCachePage(cp, pgm, p, basemem, 0, 0, 0) < 0) return LIBAVRDUDE_GENERAL_FAILURE; } return LIBAVRDUDE_SUCCESS; } static int writeCachePage(AVR_Cache *cp, const PROGRAMMER *pgm, const AVRPART *p, const AVRMEM *mem, int base, int nlOnErr) { // Write modified page cont to device; if unsuccessful try bytewise access if(avr_write_page_default(pgm, p, mem, base, cp->cont + base) < 0) { if(pgm->read_byte != avr_read_byte_cached && pgm->write_byte != avr_write_byte_cached) { for(int i=0; i < cp->page_size; i++) if(cp->cont[base+i] != cp->copy[base+i]) if(pgm->write_byte(pgm, p, mem, base+i, cp->cont[base+i]) < 0 || pgm->read_byte(pgm, p, mem, base+i, cp->copy+base+i) < 0) { report_progress(1, -1, NULL); if(nlOnErr && quell_progress) msg_info("\n"); pmsg_error("%s access error at addr 0x%04x\n", mem->desc, base+i); return LIBAVRDUDE_GENERAL_FAILURE; } return LIBAVRDUDE_SUCCESS; // Bytewise writes & reads successful } report_progress(1, -1, NULL); if(nlOnErr && quell_progress) msg_info("\n"); pmsg_error("write %s page error at addr 0x%04x\n", mem->desc, base); return LIBAVRDUDE_GENERAL_FAILURE; } // Read page back from device and update copy to what is on device if(avr_read_page_default(pgm, p, mem, base, cp->copy + base) < 0) { report_progress(1, -1, NULL); if(nlOnErr && quell_progress) msg_info("\n"); pmsg_error("unable to read %s page at addr 0x%04x\n", mem->desc, base); return LIBAVRDUDE_GENERAL_FAILURE; } return LIBAVRDUDE_SUCCESS; } // Does the memory region only haxe 0xff? static int _is_all_0xff(const void *p, size_t n) { const unsigned char *q = (const unsigned char *) p; return n <= 0 || (*q == 0xff && memcmp(q, q+1, n-1) == 0); } // A coarse guess where any bootloader might start (prob underestimates the start) static int guessBootStart(const PROGRAMMER *pgm, const AVRPART *p) { int bootstart = 0; const AVR_Cache *cp = pgm->cp_flash; if(p->prog_modes & PM_UPDI) // Modern AVRs put the bootloader at 0 return 0; if(p->n_boot_sections > 0 && p->boot_section_size > 0) bootstart = cp->size - (p->boot_section_size<<(p->n_boot_sections-1)); if(bootstart <= cp->size/2 || bootstart >= cp->size) bootstart = cp->size > 32768? cp->size - 16384: cp->size*3/4; return bootstart & ~(cp->page_size-1); } // Page erase but without error messages if it does not work static int silent_page_erase(const PROGRAMMER *pgm, const AVRPART *p, const AVRMEM *m, unsigned int a) { int bakverb = verbose; verbose = -123; int ret = pgm->page_erase? pgm->page_erase(pgm, p, m, a): -1; verbose = bakverb; return ret; } typedef struct { AVRMEM *mem; AVR_Cache *cp; int isflash, zopaddr, pgerase; } CacheDesc_t; // Write both EEPROM and flash caches to device and free them int avr_flush_cache(const PROGRAMMER *pgm, const AVRPART *p) { CacheDesc_t mems[2] = { { avr_locate_mem(p, "flash"), pgm->cp_flash, 1, -1, 0 }, { avr_locate_mem(p, "eeprom"), pgm->cp_eeprom, 0, -1, 0 }, }; int chpages = 0; bool chiperase = 0; // Count page changes and find a page that needs a clear bit set for(size_t i = 0; i < sizeof mems/sizeof*mems; i++) { AVRMEM *mem = mems[i].mem; AVR_Cache *cp = mems[i].cp; if(!mem || !cp->cont) continue; for(int pgno = 0, n = 0; n < cp->size; pgno++, n += cp->page_size) { if(cp->iscached[pgno]) if(memcmp(cp->copy + n, cp->cont + n, cp->page_size)) { chpages++; if(mems[i].zopaddr == -1 && !avr_is_and(cp->cont + n, cp->copy + n, cp->cont + n, cp->page_size)) mems[i].zopaddr = n; } } } if(!chpages) return LIBAVRDUDE_SUCCESS; pmsg_info("synching cache to device ... "); fflush(stderr); // Check whether page erase needed and working and whether chip erase needed for(size_t i = 0; i < sizeof mems/sizeof*mems; i++) { AVRMEM *mem = mems[i].mem; AVR_Cache *cp = mems[i].cp; if(!mem) continue; if(!cp->cont) // Ensure cache is initialised from now on if(initCache(cp, pgm, p) < 0) { if(quell_progress) msg_info("\n"); pmsg_error("unable to initialise the cache\n"); return LIBAVRDUDE_GENERAL_FAILURE; } if(chiperase || mems[i].zopaddr < 0) continue; int n=mems[i].zopaddr; if(writeCachePage(cp, pgm, p, mem, n, 1) < 0) return LIBAVRDUDE_GENERAL_FAILURE; // Same? OK, can set cleared bit to one, "normal" memory if(!memcmp(cp->copy + n, cp->cont + n, cp->page_size)) { chpages--; continue; } // Probably NOR memory, check out page erase if(silent_page_erase(pgm, p, mem, n) >= 0) { if(writeCachePage(cp, pgm, p, mem, n, 1) < 0) return LIBAVRDUDE_GENERAL_FAILURE; // Worked OK? Can use page erase on this memory if(!memcmp(cp->copy + n, cp->cont + n, cp->page_size)) { mems[i].pgerase = 1; chpages--; continue; } } chiperase = 1; } if(!chpages) { msg_info("done\n"); return LIBAVRDUDE_SUCCESS; } if(chiperase) { if(quell_progress) { msg_info("reading/chip erase/writing cycle needed ... "); fflush(stderr); } int nrd = 0; // Count read operations needed for(size_t i = 0; i < sizeof mems/sizeof*mems; i++) { AVRMEM *mem = mems[i].mem; AVR_Cache *cp = mems[i].cp; if(!mem) continue; for(int pgno = 0, n = 0; n < cp->size; pgno++, n += cp->page_size) if(!cp->iscached[pgno]) nrd++; } report_progress(0, 1, "Reading"); if(nrd) { // Read full flash and EEPROM for(size_t i = 0; i < sizeof mems/sizeof*mems; i++) { AVRMEM *mem = mems[i].mem; AVR_Cache *cp = mems[i].cp; if(!mem) continue; for(int ird = 0, pgno = 0, n = 0; n < cp->size; pgno++, n += cp->page_size) { if(!cp->iscached[pgno]) { report_progress(ird++, nrd, NULL); if(loadCachePage(cp, pgm, p, mem, n, n, 1) < 0) return LIBAVRDUDE_GENERAL_FAILURE; } } } } report_progress(1, 0, NULL); report_progress(0, 1, "Erasing"); if(avr_chip_erase(pgm, p) < 0) { report_progress(1, -1, NULL); if(quell_progress) msg_info("\n"); pmsg_error("chip erase failed\n"); return LIBAVRDUDE_GENERAL_FAILURE; } // Update cache copies after chip erase so that writing back is efficient for(size_t i = 0; i < sizeof mems/sizeof*mems; i++) { AVRMEM *mem = mems[i].mem; AVR_Cache *cp = mems[i].cp; if(!mem) continue; if(mems[i].isflash) { // flash memset(cp->copy, 0xff, cp->size); // record device memory as erased if(pgm->prog_modes & PM_SPM) { // Bootloaders will not overwrite themselves // Read back generously estimated bootloader section to avoid verification errors int bootstart = guessBootStart(pgm, p); int nbo = (cp->size - bootstart)/cp->page_size; for(int ibo = 0, n = bootstart; n < cp->size; n += cp->page_size) { report_progress(1+ibo++, nbo+2, NULL); if(avr_read_page_default(pgm, p, mem, n, cp->copy + n) < 0) { report_progress(1, -1, NULL); if(quell_progress) msg_info("\n"); pmsg_error("flash read failed at addr 0x%04x\n", n); return LIBAVRDUDE_GENERAL_FAILURE; } } } } else { // EEPROM // Don't know whether chip erase has zapped EEPROM for(int n = 0; n < cp->size; n += cp->page_size) { if(!_is_all_0xff(cp->copy + n, cp->page_size)) { // First page that had EEPROM data if(avr_read_page_default(pgm, p, mem, n, cp->copy + n) < 0) { report_progress(1, -1, NULL); if(quell_progress) msg_info("\n"); pmsg_error("EEPROM read failed at addr 0x%04x\n", n); return LIBAVRDUDE_GENERAL_FAILURE; } // EEPROM zapped by chip erase? Set all copy to 0xff if(_is_all_0xff(cp->copy + n, cp->page_size)) memset(cp->copy, 0xff, cp->size); break; } } } } report_progress(1, 0, NULL); } int nwr = 0; // Count number of writes for(size_t i = 0; i < sizeof mems/sizeof*mems; i++) { AVRMEM *mem = mems[i].mem; AVR_Cache *cp = mems[i].cp; if(!mem) continue; for(int pgno = 0, n = 0; n < cp->size; pgno++, n += cp->page_size) if(cp->iscached[pgno] && memcmp(cp->copy + n, cp->cont + n, cp->page_size)) nwr++; } report_progress(0, 1, "Writing"); if(nwr) { // Write all modified pages to the device for(size_t i = 0; i < sizeof mems/sizeof*mems; i++) { AVRMEM *mem = mems[i].mem; AVR_Cache *cp = mems[i].cp; if(!mem || !cp->cont) continue; for(int iwr = 0, pgno = 0, n = 0; n < cp->size; pgno++, n += cp->page_size) { if(cp->iscached[pgno] && memcmp(cp->copy + n, cp->cont + n, cp->page_size)) { if(!chiperase && mems[i].pgerase) pgm->page_erase(pgm, p, mem, n); if(writeCachePage(cp, pgm, p, mem, n, 1) < 0) return LIBAVRDUDE_GENERAL_FAILURE; if(memcmp(cp->copy + n, cp->cont + n, cp->page_size)) { report_progress(1, -1, NULL); if(quell_progress) msg_info("\n"); pmsg_error("verification mismatch at %s page addr 0x%04x\n", mem->desc, n); return LIBAVRDUDE_GENERAL_FAILURE; } report_progress(iwr++, nwr, NULL); } } } } report_progress(1, 0, NULL); msg_info(quell_progress? "done\n": "\n"); return LIBAVRDUDE_SUCCESS; } /* * Read byte via a read/write cache * - Used if paged routines available and if memory is EEPROM or flash * - Otherwise fall back to pgm->read_byte() * - Out of memory addr: synchronise cache and, if successful, pretend reading a zero * - Cache is automagically created and initialised if needed */ int avr_read_byte_cached(const PROGRAMMER *pgm, const AVRPART *p, const AVRMEM *mem, unsigned long addr, unsigned char *value) { // Use pgm->read_byte() if not EEPROM/flash or no paged access if(!avr_has_paged_access(pgm, mem)) return fallback_read_byte(pgm, p, mem, addr, value); // If address is out of range synchronise cache and, if successful, pretend reading a zero if(addr >= (unsigned long) mem->size) { if(avr_flush_cache(pgm, p) < 0) return LIBAVRDUDE_GENERAL_FAILURE; *value = 0; return LIBAVRDUDE_SUCCESS; } AVR_Cache *cp = avr_mem_is_eeprom_type(mem)? pgm->cp_eeprom: pgm->cp_flash; if(!cp->cont) // Init cache if needed if(initCache(cp, pgm, p) < 0) return LIBAVRDUDE_GENERAL_FAILURE; int cacheaddr = cacheAddress((int) addr, cp, mem); if(cacheaddr < 0) return LIBAVRDUDE_GENERAL_FAILURE; // Ensure cache page is there if(loadCachePage(cp, pgm, p, mem, addr, cacheaddr, 0) < 0) return LIBAVRDUDE_GENERAL_FAILURE; *value = cp->cont[cacheaddr]; return LIBAVRDUDE_SUCCESS; } /* * Write byte via a read/write cache * - Used if paged routines available and if memory is EEPROM or flash * - Otherwise fall back to pgm->write_byte() * - Out of memory addr: synchronise cache with device and return whether successful * - If programmer indicates a readonly spot, return LIBAVRDUDE_SOFTFAIL * - Cache is automagically created and initialised if needed */ int avr_write_byte_cached(const PROGRAMMER *pgm, const AVRPART *p, const AVRMEM *mem, unsigned long addr, unsigned char data) { if(pgm->readonly && pgm->readonly(pgm, p, mem, addr)) return LIBAVRDUDE_SOFTFAIL; // Use pgm->write_byte() if not EEPROM/flash or no paged access if(!avr_has_paged_access(pgm, mem)) return fallback_write_byte(pgm, p, mem, addr, data); // If address is out of range synchronise caches with device and return whether successful if(addr >= (unsigned long) mem->size) return avr_flush_cache(pgm, p); AVR_Cache *cp = avr_mem_is_eeprom_type(mem)? pgm->cp_eeprom: pgm->cp_flash; if(!cp->cont) // Init cache if needed if(initCache(cp, pgm, p) < 0) return LIBAVRDUDE_GENERAL_FAILURE; int cacheaddr = cacheAddress((int) addr, cp, mem); if(cacheaddr < 0) return LIBAVRDUDE_GENERAL_FAILURE; // Ensure cache page is there if(loadCachePage(cp, pgm, p, mem, addr, cacheaddr, 0) < 0) return LIBAVRDUDE_GENERAL_FAILURE; cp->cont[cacheaddr] = data; return LIBAVRDUDE_SUCCESS; } // Erase the chip and set the cache accordingly int avr_chip_erase_cached(const PROGRAMMER *pgm, const AVRPART *p) { CacheDesc_t mems[2] = { { avr_locate_mem(p, "flash"), pgm->cp_flash, 1, -1, 0 }, { avr_locate_mem(p, "eeprom"), pgm->cp_eeprom, 0, -1, 0 }, }; int rc; if((rc = pgm->chip_erase(pgm, p)) < 0) return rc; for(size_t i = 0; i < sizeof mems/sizeof*mems; i++) { AVRMEM *mem = mems[i].mem; AVR_Cache *cp = mems[i].cp; if(!mem || !avr_has_paged_access(pgm, mem)) continue; if(!cp->cont) // Init cache if needed if(initCache(cp, pgm, p) < 0) return LIBAVRDUDE_GENERAL_FAILURE; if(mems[i].isflash) { // flash if(pgm->prog_modes & PM_SPM) { // reset cache to unknown memset(cp->iscached, 0, cp->size/cp->page_size); } else { // preset all pages as erased memset(cp->copy, 0xff, cp->size); memset(cp->cont, 0xff, cp->size); memset(cp->iscached, 1, cp->size/cp->page_size); } } else { // EEPROM: test whether cached pages were zapped bool erasedee = 0; for(int pgno = 0, n = 0; n < cp->size; pgno++, n += cp->page_size) { if(cp->iscached[pgno]) { if(!_is_all_0xff(cp->copy + n, cp->page_size)) { // Page has EEPROM data? if(avr_read_page_default(pgm, p, mem, n, cp->copy + n) < 0) return LIBAVRDUDE_GENERAL_FAILURE; erasedee = _is_all_0xff(cp->copy + n, cp->page_size); break; } } } if(erasedee) { // EEPROM was erased, set cache correspondingly memset(cp->copy, 0xff, cp->size); memset(cp->cont, 0xff, cp->size); memset(cp->iscached, 1, cp->size/cp->page_size); } else { // discard previous writes, but leave cache for(int pgno = 0, n = 0; n < cp->size; pgno++, n += cp->page_size) if(cp->iscached[pgno]) memcpy(cp->cont + n, cp->copy + n, cp->page_size); } } } return LIBAVRDUDE_SUCCESS; } // Erase a page and synchronise it with the cache int avr_page_erase_cached(const PROGRAMMER *pgm, const AVRPART *p, const AVRMEM *mem, unsigned int uaddr) { int addr = uaddr; if(!avr_has_paged_access(pgm, mem) || addr < 0 || addr >= mem->size) return LIBAVRDUDE_GENERAL_FAILURE; if(mem->page_size == 1) { if(fallback_write_byte(pgm, p, mem, uaddr, 0xff) < 0) return LIBAVRDUDE_GENERAL_FAILURE; } else { if(silent_page_erase(pgm, p, mem, uaddr) < 0) return LIBAVRDUDE_GENERAL_FAILURE; } AVR_Cache *cp = avr_mem_is_eeprom_type(mem)? pgm->cp_eeprom: pgm->cp_flash; if(!cp->cont) // Init cache if needed if(initCache(cp, pgm, p) < 0) return LIBAVRDUDE_GENERAL_FAILURE; int cacheaddr = cacheAddress(addr, cp, mem); if(cacheaddr < 0) return LIBAVRDUDE_GENERAL_FAILURE; // Invalidate this cache page and read back, ie, we don't trust the page_erase() routine cp->iscached[cacheaddr/cp->page_size] = 0; // Reload cache page if(loadCachePage(cp, pgm, p, mem, (int) addr, cacheaddr, 0) < 0) return LIBAVRDUDE_GENERAL_FAILURE; if(!_is_all_0xff(cp->cont + (cacheaddr & ~(cp->page_size-1)), cp->page_size)) return LIBAVRDUDE_GENERAL_FAILURE; return LIBAVRDUDE_SUCCESS; } // Free cache(s) discarding any pending writes int avr_reset_cache(const PROGRAMMER *pgm, const AVRPART *p_unused) { AVR_Cache *mems[2] = { pgm->cp_flash, pgm->cp_eeprom, }; for(size_t i = 0; i < sizeof mems/sizeof*mems; i++) { AVR_Cache *cp = mems[i]; if(cp->cont) free(cp->cont); if(cp->copy) free(cp->copy); if(cp->iscached) free(cp->iscached); memset(cp, 0, sizeof*cp); } return LIBAVRDUDE_SUCCESS; }