#include #if CONFIG_HAL_BOARD == HAL_BOARD_LINUX #include #include #include #include #include #include #include #include "Storage.h" using namespace Linux; /* This stores 'eeprom' data on the SD card, with a 4k size, and a in-memory buffer. This keeps the latency down. */ // name the storage file after the sketch so you can use the same board // card for ArduCopter and ArduPlane #define STORAGE_DIR "/var/run/APM" #define STORAGE_FILE STORAGE_DIR "/" SKETCHNAME ".stg" extern const AP_HAL::HAL& hal; void LinuxStorage::_storage_create(void) { mkdir(STORAGE_DIR, 0777); unlink(STORAGE_FILE); int fd = open(STORAGE_FILE, O_RDWR|O_CREAT, 0666); if (fd == -1) { hal.scheduler->panic("Failed to create " STORAGE_FILE); } for (uint16_t loc=0; locpanic("Error filling " STORAGE_FILE); } } // ensure the directory is updated with the new size fsync(fd); close(fd); } void LinuxStorage::_storage_open(void) { if (_initialised) { return; } _dirty_mask = 0; int fd = open(STORAGE_FILE, O_RDONLY); if (fd == -1) { _storage_create(); fd = open(STORAGE_FILE, O_RDONLY); if (fd == -1) { hal.scheduler->panic("Failed to open " STORAGE_FILE); } } if (read(fd, _buffer, sizeof(_buffer)) != sizeof(_buffer)) { close(fd); _storage_create(); fd = open(STORAGE_FILE, O_RDONLY); if (fd == -1) { hal.scheduler->panic("Failed to open " STORAGE_FILE); } if (read(fd, _buffer, sizeof(_buffer)) != sizeof(_buffer)) { hal.scheduler->panic("Failed to read " STORAGE_FILE); } } close(fd); _initialised = true; } /* mark some lines as dirty. Note that there is no attempt to avoid the race condition between this code and the _timer_tick() code below, which both update _dirty_mask. If we lose the race then the result is that a line is written more than once, but it won't result in a line not being written. */ void LinuxStorage::_mark_dirty(uint16_t loc, uint16_t length) { uint16_t end = loc + length; while (loc < end) { uint8_t line = (loc >> LINUX_STORAGE_LINE_SHIFT); _dirty_mask |= 1 << line; loc += LINUX_STORAGE_LINE_SIZE; } } uint8_t LinuxStorage::read_byte(uint16_t loc) { if (loc >= sizeof(_buffer)) { return 0; } _storage_open(); return _buffer[loc]; } uint16_t LinuxStorage::read_word(uint16_t loc) { uint16_t value; if (loc >= sizeof(_buffer)-(sizeof(value)-1)) { return 0; } _storage_open(); memcpy(&value, &_buffer[loc], sizeof(value)); return value; } uint32_t LinuxStorage::read_dword(uint16_t loc) { uint32_t value; if (loc >= sizeof(_buffer)-(sizeof(value)-1)) { return 0; } _storage_open(); memcpy(&value, &_buffer[loc], sizeof(value)); return value; } void LinuxStorage::read_block(void *dst, uint16_t loc, size_t n) { if (loc >= sizeof(_buffer)-(n-1)) { return; } _storage_open(); memcpy(dst, &_buffer[loc], n); } void LinuxStorage::write_byte(uint16_t loc, uint8_t value) { if (loc >= sizeof(_buffer)) { return; } if (_buffer[loc] != value) { _storage_open(); _buffer[loc] = value; _mark_dirty(loc, sizeof(value)); } } void LinuxStorage::write_word(uint16_t loc, uint16_t value) { if (loc >= sizeof(_buffer)-(sizeof(value)-1)) { return; } if (memcmp(&value, &_buffer[loc], sizeof(value)) != 0) { _storage_open(); memcpy(&_buffer[loc], &value, sizeof(value)); _mark_dirty(loc, sizeof(value)); } } void LinuxStorage::write_dword(uint16_t loc, uint32_t value) { if (loc >= sizeof(_buffer)-(sizeof(value)-1)) { return; } if (memcmp(&value, &_buffer[loc], sizeof(value)) != 0) { _storage_open(); memcpy(&_buffer[loc], &value, sizeof(value)); _mark_dirty(loc, sizeof(value)); } } void LinuxStorage::write_block(uint16_t loc, const void *src, size_t n) { if (loc >= sizeof(_buffer)-(n-1)) { return; } if (memcmp(src, &_buffer[loc], n) != 0) { _storage_open(); memcpy(&_buffer[loc], src, n); _mark_dirty(loc, n); } } void LinuxStorage::_timer_tick(void) { if (!_initialised || _dirty_mask == 0) { return; } if (_fd == -1) { _fd = open(STORAGE_FILE, O_WRONLY); if (_fd == -1) { return; } } // write out the first dirty set of lines. We don't write more // than one to keep the latency of this call to a minimum uint8_t i, n; for (i=0; i>LINUX_STORAGE_LINE_SHIFT); n++) { if (!(_dirty_mask & (1<<(n+i)))) { break; } // mark that line clean write_mask |= (1<<(n+i)); } /* write the lines. This also updates _dirty_mask. Note that because this is a SCHED_FIFO thread it will not be preempted by the main task except during blocking calls. This means we don't need a semaphore around the _dirty_mask updates. */ if (lseek(_fd, i<