/* Please contribute your ideas! See http://dev.ardupilot.org for details 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 3 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 . */ /* a class to allow for FLASH to be used as a memory backed storage backend for any HAL. The basic methodology is to use a log based storage system over two flash sectors. Key design elements: - erase of sectors only called on init, as erase will lock the flash and prevent code execution - write using log based system - read requires scan of all log elements. This is expected to be called rarely - assumes flash that erases to 0xFF and where writing can only clear bits, not set them - assumes flash sectors are much bigger than storage size. If they aren't then caller can aggregate multiple sectors. Designed for 128k flash sectors with 16k storage size. - assumes two flash sectors are available */ #pragma once #include #if defined(STM32F1) /* the STM32F1 can't change individual bits from 1 to 0 unless all bits in the 16 bit word are 1 */ #define AP_FLASHSTORAGE_MULTI_WRITE 0 #else #define AP_FLASHSTORAGE_MULTI_WRITE 1 #endif /* The StorageManager holds the layout of non-volatile storeage */ class AP_FlashStorage { private: static const uint8_t block_size = 8; static const uint16_t num_blocks = HAL_STORAGE_SIZE / block_size; static const uint8_t max_write = 64; public: // caller provided function to write to a flash sector FUNCTOR_TYPEDEF(FlashWrite, bool, uint8_t , uint32_t , const uint8_t *, uint16_t ); // caller provided function to read from a flash sector. Only called on init() FUNCTOR_TYPEDEF(FlashRead, bool, uint8_t , uint32_t , uint8_t *, uint16_t ); // caller provided function to erase a flash sector. Only called from init() FUNCTOR_TYPEDEF(FlashErase, bool, uint8_t ); // caller provided function to indicate if erasing is allowed FUNCTOR_TYPEDEF(FlashEraseOK, bool); // constructor. AP_FlashStorage(uint8_t *mem_buffer, // buffer of storage_size bytes uint32_t flash_sector_size, // size of each flash sector in bytes FlashWrite flash_write, // function to write to flash FlashRead flash_read, // function to read from flash FlashErase flash_erase, // function to erase flash FlashEraseOK flash_erase_ok); // function to check if erasing allowed // initialise storage, filling mem_buffer with current contents bool init(void); // re-initialise storage, using current mem_buffer bool re_initialise(void); // switch full sector - should only be called when safe to have CPU // offline for considerable periods as an erase will be needed bool switch_full_sector(void); // write some data to storage from mem_buffer bool write(uint16_t offset, uint16_t length); // fixed storage size static const uint16_t storage_size = block_size * num_blocks; private: uint8_t *mem_buffer; const uint32_t flash_sector_size; FlashWrite flash_write; FlashRead flash_read; FlashErase flash_erase; FlashEraseOK flash_erase_ok; uint8_t current_sector; uint32_t write_offset; uint32_t reserved_space; bool write_error; // 24 bit signature #if AP_FLASHSTORAGE_MULTI_WRITE static const uint32_t signature = 0x51685B; #else static const uint32_t signature = 0x51; #endif // 8 bit sector states enum SectorState { #if AP_FLASHSTORAGE_MULTI_WRITE SECTOR_STATE_AVAILABLE = 0xFF, SECTOR_STATE_IN_USE = 0xFE, SECTOR_STATE_FULL = 0xFC #else SECTOR_STATE_AVAILABLE = 0xFFFFFFFF, SECTOR_STATE_IN_USE = 0xFFFFFFF1, SECTOR_STATE_FULL = 0xFFF2FFF1, #endif }; // header in first word of each sector struct sector_header { #if AP_FLASHSTORAGE_MULTI_WRITE uint32_t state:8; uint32_t signature:24; #else uint32_t state:32; uint32_t signature:16; #endif }; enum BlockState { BLOCK_STATE_AVAILABLE = 0x3, BLOCK_STATE_WRITING = 0x1, BLOCK_STATE_VALID = 0x0 }; // header of each block of data struct block_header { uint16_t state:2; uint16_t block_num:11; uint16_t num_blocks_minus_one:3; }; // amount of space needed to write full storage static const uint32_t reserve_size = (storage_size / max_write) * (sizeof(block_header) + max_write) + max_write; // load data from a sector bool load_sector(uint8_t sector); // erase a sector and write header bool erase_sector(uint8_t sector, bool mark_available); // erase all sectors and reset bool erase_all(); // write all of mem_buffer to current sector bool write_all(); // return true if all bytes are zero bool all_zero(uint16_t ofs, uint16_t size); // switch to next sector for writing bool switch_sectors(void); };