/* * This software is experimental and a work in progress. * Under no circumstances should these files be used in relation to any critical system(s). * Use of these files is at your own risk. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, * INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR * PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE * LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, * TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER * DEALINGS IN THE SOFTWARE. * * This files are free to use from http://engsta.com/stm32-flash-memory-eeprom-emulator/ by * Artur F. * * Modifications for QMK and STM32L432 by lalalademaxiya1 & lokher * * TODO: Add ECC correction interrupt handler. */ #include #include #include #include "flash_stm32.h" #include "eeprom_stm32_defs.h" #include "eeprom_stm32_l4.h" #include "print.h" /* * We emulate eeprom by writing a snapshot compacted view of eeprom contents, * followed by a write log of any change since that snapshot: * * === SIMULATED EEPROM CONTENTS === * * ┌─ Compacted─┬─ Write Log ──┐ * │............│[DWord][DWord]│ * │FFFF....FFFF│[DWord][DWord]│ * │FFFFFFFFFFFF│[DWord][DWord]│ * │....FFFFFFFF│[DWord][DWord]│ * ├────────────┼──────────────┤ * └──PAGE_BASE │ │ * PAGE_LAST─┴─WRITE_BASE │ * WRITE_LAST ──┘ * * Compacted contents are the 1's complement of the actual EEPROM contents. * e.g. An 'FFFF' represents a '0000' value. * * The size of the 'compacted' area is equal to the size of the 'emulated' eeprom. * The size of the compacted-area and write log are configurable, and the combined * size of Compacted + WriteLog is a multiple FEE_PAGE_SIZE, which is MCU dependent. * Simulated Eeprom contents are located at the end of available flash space. * * The following configuration defines can be set: * * FEE_PAGE_COUNT # Total number of pages to use for eeprom simulation (Compact + Write log) * FEE_DENSITY_BYTES # Size of simulated eeprom. (Defaults to one pages of FEE_PAGE_COUNT) * NOTE: The current implementation does not include page swapping, * and FEE_DENSITY_BYTES will consume that amount of RAM as a cached view of actual EEPROM contents. * * The maximum size of FEE_DENSITY_BYTES is currently 8192. The write log size equals * FEE_PAGE_COUNT * FEE_PAGE_SIZE - FEE_DENSITY_BYTES. * The larger the write log, the less frequently the compacted area needs to be rewritten. * * * *** General Algorithm *** * * During initialization: * The contents of the Compacted-flash area are loaded and the 1's complement value * is cached into memory (e.g. 0xFFFF in Flash represents 0x0000 in cache). * Write log entries are processed until a 0xFFFF is reached. * Each log entry updates 1/2/4 byte(s) in the cache. * * During reads: * EEPROM contents are given back directly from the cache in memory. * * During writes: * The contents of the cache is updated first. * If the Compacted-flash area corresponding to the write address is unprogrammed, the 1's complement of the value is written directly into Compacted-flash * Otherwise: * If the write log is full, erase both the Compacted-flash area and the Write log, then write cached contents to the Compacted-flash area. * Otherwise a Write log entry is constructed and appended to the next free position in the Write log. * * * *** Write Log Structure *** * * Each log entry compose of double word (2 x 32-bit) due to the minimum program size of STM32L432 flash. * * === WRITE LOG ENTRY FORMATS === * * ╔══════════ Byte-Entry ═════════╗ * ║ 00 01 XX XX ║ FF FF FF YY ║ * ║ └─┬─┘ └─┬─┘ ║ └┘ ║ * ║ Len Address ║ ~Value ║ * ╚═══════════════╩═══════════════╝ * * ╔══════════ Word-Entry ═════════╗ * ║ 00 02 XX XX ║ FF FF YY YY ║ * ║ └─┬─┘ └─┬─┘ ║ └─┬─┘ ║ * ║ Len Address ║ ~Value ║ * ╚═══════════════╩═══════════════╝ * * ╔══════════ DWord-Entry ═══════╗ * ║ 00 04 XX XX ║ FF FF FF FF ║ * ║ └─┬─┘ └─┬─┘ ║ └───┬────┘ ║ * ║ Len Address ║ ~Value ║ * ╚═══════════════╩═══════════════╝ * */ #include "eeprom_stm32_defs.h" #if !defined(FEE_PAGE_SIZE) || !defined(FEE_PAGE_COUNT) || !defined(FEE_MCU_FLASH_SIZE) || !defined(FEE_PAGE_BASE_ADDRESS) # error "not implemented." #endif /* These bits indicate that the length of data which was wrote to log space */ #define FEE_BYTE_FLAG 0x00010000 #define FEE_WORD_FLAG 0x00020000 #define FEE_DWORD_FLAG 0x00040000 /* Flash byte value after erase */ #define FEE_EMPTY_BYTE ((uint8_t)0xFF) /* Flash double byte value after erase */ #define FEE_EMPTY_DBYTE ((uint16_t)0xFFFF) /* Flash word value after erase */ #define FEE_EMPTY_WORD ((uint32_t)0xFFFFFFFF) /* Flash double word value after erase */ #define FEE_EMPTY_DWORD ((uint64_t)0xFFFFFFFFFFFFFFFF) /* Size of combined compacted eeprom and write log pages */ #define FEE_DENSITY_MAX_SIZE (FEE_PAGE_COUNT * FEE_PAGE_SIZE) #ifndef FEE_MCU_FLASH_SIZE_IGNORE_CHECK /* *TODO: Get rid of this check */ # if FEE_DENSITY_MAX_SIZE > (FEE_MCU_FLASH_SIZE * 1024) # pragma message STR(FEE_DENSITY_MAX_SIZE) " > " STR(FEE_MCU_FLASH_SIZE * 1024) # error emulated eeprom: FEE_DENSITY_MAX_SIZE is greater than available flash size # endif #endif /* Size of emulated eeprom */ #ifdef FEE_DENSITY_BYTES # if (FEE_DENSITY_BYTES > FEE_DENSITY_MAX_SIZE) # pragma message STR(FEE_DENSITY_BYTES) " > " STR(FEE_DENSITY_MAX_SIZE) # error emulated eeprom: FEE_DENSITY_BYTES exceeds FEE_DENSITY_MAX_SIZE # endif # if (FEE_DENSITY_BYTES == FEE_DENSITY_MAX_SIZE) # pragma message STR(FEE_DENSITY_BYTES) " == " STR(FEE_DENSITY_MAX_SIZE) # warning emulated eeprom: FEE_DENSITY_BYTES leaves no room for a write log. This will greatly increase the flash wear rate! # endif # if FEE_DENSITY_BYTES > FEE_ADDRESS_MAX_SIZE # pragma message STR(FEE_DENSITY_BYTES) " > " STR(FEE_ADDRESS_MAX_SIZE) # error emulated eeprom: FEE_DENSITY_BYTES is greater than FEE_ADDRESS_MAX_SIZE allows # endif # if ((FEE_DENSITY_BYTES) % 8) != 0 # error emulated eeprom: FEE_DENSITY_BYTES must be a multiple of 8 # endif #else /* Default to one page of allocated space used for emulated eeprom, 3 pages for write log */ # define FEE_DENSITY_BYTES FEE_PAGE_SIZE #endif /* Size of write log */ #ifdef FEE_WRITE_LOG_BYTES # if ((FEE_DENSITY_BYTES + FEE_WRITE_LOG_BYTES) > FEE_DENSITY_MAX_SIZE) # pragma message STR(FEE_DENSITY_BYTES) " + " STR(FEE_WRITE_LOG_BYTES) " > " STR(FEE_DENSITY_MAX_SIZE) # error emulated eeprom: FEE_WRITE_LOG_BYTES exceeds remaining FEE_DENSITY_MAX_SIZE # endif # if ((FEE_WRITE_LOG_BYTES) % 8) != 0 # error emulated eeprom: FEE_WRITE_LOG_BYTES must be a multiple of 8 # endif #else /* Default to use all remaining space */ # define FEE_WRITE_LOG_BYTES (FEE_PAGE_COUNT * FEE_PAGE_SIZE - FEE_DENSITY_BYTES) #endif /* In-memory contents of emulated eeprom for faster access */ /* *TODO: Implement page swapping */ static uint64_t DWordBuf[FEE_DENSITY_BYTES / 8]; static uint8_t *DataBuf = (uint8_t *)DWordBuf; /* Pointer to the first available slot within the write log */ static uint32_t *empty_slot; /* ECC error flag, set in NMI when 2 bits ECC error is detected */ static bool eccd; /* Start of the emulated eeprom compacted flash area */ #define FEE_COMPACTED_BASE_ADDRESS FEE_PAGE_BASE_ADDRESS /* End of the emulated eeprom compacted flash area */ #define FEE_COMPACTED_LAST_ADDRESS (FEE_COMPACTED_BASE_ADDRESS + FEE_DENSITY_BYTES) /* Start of the emulated eeprom write log */ #define FEE_WRITE_LOG_BASE_ADDRESS FEE_COMPACTED_LAST_ADDRESS /* End of the emulated eeprom write log */ #define FEE_WRITE_LOG_LAST_ADDRESS (FEE_WRITE_LOG_BASE_ADDRESS + FEE_WRITE_LOG_BYTES) uint16_t EEPROM_Init(void) { eccd = false; /* Load emulated eeprom contents from compacted flash into memory */ uint32_t *src = (uint32_t *)FEE_COMPACTED_BASE_ADDRESS; uint32_t *dest = (uint32_t *)DataBuf; for (; src < (uint32_t *)FEE_COMPACTED_LAST_ADDRESS; ++src, ++dest) { *dest = ~*src; } /* Replay write log */ uint32_t *log_addr; for (log_addr = (uint32_t *)FEE_WRITE_LOG_BASE_ADDRESS; log_addr < (uint32_t *)FEE_WRITE_LOG_LAST_ADDRESS; log_addr += 2) { uint32_t address = *log_addr; uint32_t data = ~*(log_addr + 1); /* Break loop if ECC error is detected */ if (eccd) break; if (address == FEE_EMPTY_WORD) { break; } /* Check if value is in bytes */ else if ((address & FEE_BYTE_FLAG) == FEE_BYTE_FLAG) { uint8_t value = (uint8_t)(data & 0xFF); uint16_t addr = (uint16_t)address; DataBuf[addr] = value; } /* Check if value is in words */ else if ((address & FEE_WORD_FLAG) == FEE_WORD_FLAG) { uint16_t value = (uint16_t)(data & 0xFFFF); uint16_t addr = (uint16_t)address; *(uint16_t *)(&DataBuf[addr]) = value; } /* Check if value is in double words */ else if ((address & FEE_DWORD_FLAG) == FEE_DWORD_FLAG) { uint32_t value = data; uint16_t addr = (uint16_t)address; *(uint32_t *)(&DataBuf[addr]) = value; } } empty_slot = log_addr; /* Give more chance for NMI interrupt */ asm("nop"); /* Reset eeprom data if ECC error is detected*/ if (eccd) return 0; return FEE_DENSITY_BYTES; } /* Clear flash contents (doesn't touch in-memory DataBuf) */ static void eeprom_clear(void) { FLASH_Unlock(); for (uint16_t page_num = 0; page_num < FEE_PAGE_COUNT; ++page_num) { FLASH_ErasePage(FEE_PAGE_BASE_ADDRESS + (page_num * FEE_PAGE_SIZE)); } FLASH_Lock(); empty_slot = (uint32_t *)FEE_WRITE_LOG_BASE_ADDRESS; } /* Erase emulated eeprom */ void EEPROM_Erase(void) { /* Erase compacted pages and write log */ eeprom_clear(); /* re-initialize to reset DataBuf */ EEPROM_Init(); } /* Compact write log */ static uint8_t eeprom_compact(void) { /* Erase compacted pages and write log */ eeprom_clear(); FLASH_Unlock(); FLASH_Status final_status = FLASH_COMPLETE; /* Write emulated eeprom contents from memory to compacted flash */ uint64_t *src = (uint64_t *)DataBuf; uint32_t dest = FEE_COMPACTED_BASE_ADDRESS; uint64_t value; for (; dest < FEE_COMPACTED_LAST_ADDRESS; ++src, dest += 8) { value = *src; if (value) { FLASH_Status status = FLASH_ProgramDoubleWord(dest, ~value); if (status != FLASH_COMPLETE) final_status = status; } } FLASH_Lock(); return final_status; } static uint8_t eeprom_write_direct_entry(uint16_t Address) { /* Check if we can just write this directly to the compacted flash area */ uint32_t directAddress = FEE_COMPACTED_BASE_ADDRESS + (Address & 0xFFF8); /* Write the value directly to the compacted area without a log entry */ if (*(uint64_t *)directAddress == FEE_EMPTY_DWORD) { /* Write the value directly to the compacted area without a log entry */ uint64_t value = ~*(uint64_t *)(&DataBuf[Address & 0xFFF8]); /* Early exit if a write isn't needed */ if (value == FEE_EMPTY_DWORD) return FLASH_COMPLETE; FLASH_Unlock(); /* write to flash */ FLASH_Status status = FLASH_ProgramDoubleWord(directAddress, value); FLASH_Lock(); return status; } return 0; } static void blank_check(uint32_t Address) { /* Align address to 64 bit */ Address &= (~0x07); /* Check if target address is blank */ if (*(uint64_t *)(Address) != 0xFFFFFFFFFFFFFFFF) { if ((Address & (FEE_PAGE_SIZE - 1)) == 0) { /* Erase current page if first byte is not empty */ FLASH_Unlock(); FLASH_ErasePage(Address); FLASH_Lock(); } else { /* Compact data if we encounter non empty target address after page head */ eeprom_compact(); } } } static uint8_t eeprom_write_log_byte_entry(uint16_t Address) { /* if we can't find an empty spot, we must compact emulated eeprom */ if (empty_slot >= (uint32_t *)FEE_WRITE_LOG_LAST_ADDRESS) { /* compact the write log into the compacted flash area */ return eeprom_compact(); } blank_check((uint32_t)empty_slot); FLASH_Unlock(); /* Pack address and value into the same word */ uint64_t value = (((uint64_t)(~DataBuf[Address])) << 32) | (FEE_BYTE_FLAG) | Address; /* write to flash */ FLASH_Status status = FLASH_ProgramDoubleWord((uint32_t)empty_slot, value); empty_slot += 2; FLASH_Lock(); return status; } static uint8_t eeprom_write_log_word_entry(uint16_t Address) { /* if we can't find an empty spot, we must compact emulated eeprom */ if (empty_slot >= (uint32_t *)FEE_WRITE_LOG_LAST_ADDRESS) { /* compact the write log into the compacted flash area */ return eeprom_compact(); } blank_check((uint32_t)empty_slot); FLASH_Unlock(); /* Pack address and value into the same word */ uint64_t value = (((uint64_t)(~(*(uint16_t *)&DataBuf[Address]))) << 32) | (FEE_WORD_FLAG) | Address; /* write to flash */ FLASH_Status status = FLASH_ProgramDoubleWord((uint32_t)empty_slot, value); empty_slot += 2; FLASH_Lock(); return status; } static uint8_t eeprom_write_log_dword_entry(uint16_t Address) { /* if we can't find an empty spot, we must compact emulated eeprom */ if (empty_slot >= (uint32_t *)FEE_WRITE_LOG_LAST_ADDRESS) { /* compact the write log into the compacted flash area */ return eeprom_compact(); } blank_check((uint32_t)empty_slot); FLASH_Unlock(); /* Pack address and value into the same word */ uint64_t value = (((uint64_t)(~(*(uint32_t *)&DataBuf[Address]))) << 32) | (FEE_DWORD_FLAG) | Address; /* write to flash */ FLASH_Status status = FLASH_ProgramDoubleWord((uint32_t)empty_slot, value); empty_slot += 2; FLASH_Lock(); return status; } uint8_t EEPROM_WriteDataByte(uint16_t Address, uint8_t DataByte) { /* if the address is out-of-bounds, do nothing */ if (Address >= (FEE_DENSITY_BYTES)) { return FLASH_BAD_ADDRESS; } /* if the value is the same, don't bother writing it */ if (DataBuf[Address] == DataByte) { return 0; } /* keep DataBuf cache in sync */ DataBuf[Address] = DataByte; /* perform the write into flash memory */ /* First, attempt to write directly into the compacted flash area */ FLASH_Status status = eeprom_write_direct_entry(Address); if (!status) { status = eeprom_write_log_byte_entry(Address); } return status; } uint8_t EEPROM_WriteDataWord(uint16_t Address, uint16_t DataWord) { /* if the address is out-of-bounds, do nothing */ if (Address >= (FEE_DENSITY_BYTES - 1)) { return FLASH_BAD_ADDRESS; } /* if the value is the same, don't bother writing it */ if (*(uint16_t *)&DataBuf[Address] == DataWord) { return 0; } /* keep DataBuf cache in sync */ *(uint16_t *)(&DataBuf[Address]) = DataWord; /* perform the write into flash memory */ /* First, attempt to write directly into the compacted flash area */ FLASH_Status status = eeprom_write_direct_entry(Address); if (!status) { status = eeprom_write_log_word_entry(Address); } return status; } uint8_t EEPROM_WriteDataDWord(uint16_t Address, uint32_t DataDWord) { /* if the address is out-of-bounds, do nothing */ if (Address >= (FEE_DENSITY_BYTES - 3)) { return FLASH_BAD_ADDRESS; } /* if the value is the same, don't bother writing it */ if (*(uint32_t *)&DataBuf[Address] == DataDWord) { return 0; } /* keep DataBuf cache in sync */ *(uint32_t *)&DataBuf[Address] = DataDWord; /* perform the write into flash memory */ /* First, attempt to write directly into the compacted flash area */ FLASH_Status status = eeprom_write_direct_entry(Address); if (!status) { status = eeprom_write_log_dword_entry(Address); } return status; } uint8_t EEPROM_ReadDataByte(uint16_t Address) { uint8_t DataByte = 0xFF; if (Address < FEE_DENSITY_BYTES) { DataByte = DataBuf[Address]; } return DataByte; } uint16_t EEPROM_ReadDataWord(uint16_t Address) { uint16_t DataWord = 0xFFFF; if (Address < FEE_DENSITY_BYTES - 1) { /* Check word alignment */ if (Address % 2) { DataWord = DataBuf[Address] | (DataBuf[Address + 1] << 8); } else { DataWord = *(uint16_t *)(&DataBuf[Address]); } } return DataWord; } /***************************************************************************** * Bind to eeprom_driver.c *******************************************************************************/ uint16_t eeprom_driver_init(void) { return EEPROM_Init(); } void eeprom_driver_erase(void) { EEPROM_Erase(); } void eeprom_read_block(void *buf, const void *addr, size_t len) { const uint8_t *src = (const uint8_t *)addr; uint8_t * dest = (uint8_t *)buf; /* Check word alignment */ if (len && (uint32_t)src % 2) { /* Read the unaligned first byte */ *dest++ = EEPROM_ReadDataByte((const uintptr_t)((uint16_t *)src++)); --len; } uint16_t value; bool aligned = ((uint32_t)dest % 2 == 0); while (len > 1) { value = EEPROM_ReadDataWord((const uintptr_t)((uint16_t *)src)); if (aligned) { *(uint16_t *)dest = value; dest += 2; } else { *dest++ = value; *dest++ = value >> 8; } src += 2; len -= 2; } if (len) { *dest = EEPROM_ReadDataByte((const uintptr_t)src); } } void eeprom_write_block(const void *buf, void *addr, size_t len) { uint8_t * dest = (uint8_t *)addr; const uint8_t *src = (const uint8_t *)buf; uint8_t write_len; while (len > 0) { /* Check and try to write double word fisrt */ if ((uintptr_t)dest % 4 == 0 && len >= 4) { uint32_t dwvalue; bool dwaligned = ((uint32_t)src % 4 == 0); if (dwaligned) { dwvalue = *(uint32_t *)src; } else { dwvalue = *(uint8_t *)src | (*(uint8_t *)(src + 1) << 8) | (*(uint8_t *)(src + 2) << 16) | (*(uint8_t *)(src + 3) << 24); } EEPROM_WriteDataDWord((uintptr_t)((uint16_t *)dest), dwvalue); write_len = 4; } /* Check and try to write word */ else if ((uintptr_t)dest % 2 == 0 && len >= 2) { uint16_t wvalue; bool waligned = ((uintptr_t)src % 2 == 0); if (waligned) { wvalue = *(uint16_t *)src; } else { wvalue = *(uint8_t *)src | (*(uint8_t *)(src + 1) << 8); } EEPROM_WriteDataWord((uintptr_t)((uint16_t *)dest), wvalue); write_len = 2; } else { /* Write the unaligned or single byte */ EEPROM_WriteDataByte((uintptr_t)dest, *src); write_len = 1; } dest += write_len; src += write_len; len -= write_len; } } void NMI_Handler(void) { if (FLASH->ECCR & FLASH_ECCR_ECCD) { /* Clear ECCD error NMI */ FLASH->ECCR = FLASH_ECCR_ECCD; eccd = true; } }