#include "c_stdio.h" #include "platform.h" #include "spiffs.h" spiffs fs; #define LOG_PAGE_SIZE 256 #define LOG_BLOCK_SIZE (INTERNAL_FLASH_SECTOR_SIZE * 2) #define LOG_BLOCK_SIZE_SMALL_FS (INTERNAL_FLASH_SECTOR_SIZE) #define MIN_BLOCKS_FS 4 static u8_t spiffs_work_buf[LOG_PAGE_SIZE*2]; static u8_t spiffs_fds[32*4]; #if SPIFFS_CACHE static u8_t spiffs_cache[(LOG_PAGE_SIZE+32)*2]; #endif static s32_t my_spiffs_read(u32_t addr, u32_t size, u8_t *dst) { platform_flash_read(dst, addr, size); return SPIFFS_OK; } static s32_t my_spiffs_write(u32_t addr, u32_t size, u8_t *src) { platform_flash_write(src, addr, size); return SPIFFS_OK; } static s32_t my_spiffs_erase(u32_t addr, u32_t size) { u32_t sect_first = platform_flash_get_sector_of_address(addr); u32_t sect_last = sect_first; while( sect_first <= sect_last ) if( platform_flash_erase_sector( sect_first ++ ) == PLATFORM_ERR ) return SPIFFS_ERR_INTERNAL; return SPIFFS_OK; } void myspiffs_check_callback(spiffs_check_type type, spiffs_check_report report, u32_t arg1, u32_t arg2){ // if(SPIFFS_CHECK_PROGRESS == report) return; // NODE_ERR("type: %d, report: %d, arg1: %d, arg2: %d\n", type, report, arg1, arg2); } /******************* The W25Q32BV array is organized into 16,384 programmable pages of 256-bytes each. Up to 256 bytes can be programmed at a time.  Pages can be erased in groups of 16 (4KB sector erase), groups of 128 (32KB block erase), groups of 256 (64KB block erase) or  the entire chip (chip erase). The W25Q32BV has 1,024 erasable sectors and 64 erasable blocks respectively.  The small 4KB sectors allow for greater flexibility in applications that require data and parameter storage.  ********************/ static bool myspiffs_set_location(spiffs_config *cfg, int align, int offset, int block_size) { #ifdef SPIFFS_FIXED_LOCATION cfg->phys_addr = (SPIFFS_FIXED_LOCATION + block_size - 1) & ~(block_size-1); #else cfg->phys_addr = ( u32_t )platform_flash_get_first_free_block_address( NULL ) + offset; cfg->phys_addr = (cfg->phys_addr + align - 1) & ~(align - 1); #endif #ifdef SPIFFS_SIZE_1M_BOUNDARY cfg->phys_size = ((0x100000 - (SYS_PARAM_SEC_NUM * INTERNAL_FLASH_SECTOR_SIZE) - ( ( u32_t )cfg->phys_addr )) & ~(block_size - 1)) & 0xfffff; #else cfg->phys_size = (INTERNAL_FLASH_SIZE - ( ( u32_t )cfg->phys_addr )) & ~(block_size - 1); #endif if ((int) cfg->phys_size < 0) { return FALSE; } cfg->log_block_size = block_size; return (cfg->phys_size / block_size) >= MIN_BLOCKS_FS; } /* * Returns TRUE if FS was found * align must be a power of two */ static bool myspiffs_set_cfg(spiffs_config *cfg, int align, int offset, bool force_create) { cfg->phys_erase_block = INTERNAL_FLASH_SECTOR_SIZE; // according to datasheet cfg->log_page_size = LOG_PAGE_SIZE; // as we said cfg->hal_read_f = my_spiffs_read; cfg->hal_write_f = my_spiffs_write; cfg->hal_erase_f = my_spiffs_erase; if (!myspiffs_set_location(cfg, align, offset, LOG_BLOCK_SIZE)) { if (!myspiffs_set_location(cfg, align, offset, LOG_BLOCK_SIZE_SMALL_FS)) { return FALSE; } } NODE_DBG("fs.start:%x,max:%x\n",cfg->phys_addr,cfg->phys_size); #ifdef SPIFFS_USE_MAGIC_LENGTH if (force_create) { return TRUE; } int size = SPIFFS_probe_fs(cfg); if (size > 0 && size < cfg->phys_size) { NODE_DBG("Overriding size:%x\n",size); cfg->phys_size = size; } if (size > 0) { return TRUE; } return FALSE; #else return TRUE; #endif } static bool myspiffs_find_cfg(spiffs_config *cfg, bool force_create) { int i; if (!force_create) { #ifdef SPIFFS_FIXED_LOCATION if (myspiffs_set_cfg(cfg, 0, 0, FALSE)) { return TRUE; } #else if (INTERNAL_FLASH_SIZE >= 700000) { for (i = 0; i < 8; i++) { if (myspiffs_set_cfg(cfg, 0x10000, 0x10000 * i, FALSE)) { return TRUE; } } } for (i = 0; i < 8; i++) { if (myspiffs_set_cfg(cfg, LOG_BLOCK_SIZE, LOG_BLOCK_SIZE * i, FALSE)) { return TRUE; } } #endif } // No existing file system -- set up for a format if (INTERNAL_FLASH_SIZE >= 700000) { myspiffs_set_cfg(cfg, 0x10000, 0x10000, TRUE); #ifndef SPIFFS_MAX_FILESYSTEM_SIZE if (cfg->phys_size < 400000) { // Don't waste so much in alignment myspiffs_set_cfg(cfg, LOG_BLOCK_SIZE, LOG_BLOCK_SIZE * 4, TRUE); } #endif } else { myspiffs_set_cfg(cfg, LOG_BLOCK_SIZE, 0, TRUE); } #ifdef SPIFFS_MAX_FILESYSTEM_SIZE if (cfg->phys_size > SPIFFS_MAX_FILESYSTEM_SIZE) { cfg->phys_size = (SPIFFS_MAX_FILESYSTEM_SIZE) & ~(cfg->log_block_size - 1); } #endif return FALSE; } static bool myspiffs_mount_internal(bool force_mount) { spiffs_config cfg; if (!myspiffs_find_cfg(&cfg, force_mount) && !force_mount) { return FALSE; } fs.err_code = 0; int res = SPIFFS_mount(&fs, &cfg, spiffs_work_buf, spiffs_fds, sizeof(spiffs_fds), #if SPIFFS_CACHE spiffs_cache, sizeof(spiffs_cache), #else 0, 0, #endif // myspiffs_check_callback); 0); NODE_DBG("mount res: %d, %d\n", res, fs.err_code); return res == SPIFFS_OK; } bool myspiffs_mount() { return myspiffs_mount_internal(FALSE); } void myspiffs_unmount() { SPIFFS_unmount(&fs); } // FS formatting function // Returns 1 if OK, 0 for error int myspiffs_format( void ) { SPIFFS_unmount(&fs); myspiffs_mount_internal(TRUE); SPIFFS_unmount(&fs); NODE_DBG("Formatting: size 0x%x, addr 0x%x\n", fs.cfg.phys_size, fs.cfg.phys_addr); if (SPIFFS_format(&fs) < 0) { return 0; } return myspiffs_mount(); } #if 0 void test_spiffs() { char buf[12]; // Surely, I've mounted spiffs before entering here spiffs_file fd = SPIFFS_open(&fs, "my_file", SPIFFS_CREAT | SPIFFS_TRUNC | SPIFFS_RDWR, 0); if (SPIFFS_write(&fs, fd, (u8_t *)"Hello world", 12) < 0) NODE_DBG("errno %i\n", SPIFFS_errno(&fs)); SPIFFS_close(&fs, fd); fd = SPIFFS_open(&fs, "my_file", SPIFFS_RDWR, 0); if (SPIFFS_read(&fs, fd, (u8_t *)buf, 12) < 0) NODE_DBG("errno %i\n", SPIFFS_errno(&fs)); SPIFFS_close(&fs, fd); NODE_DBG("--> %s <--\n", buf); } #endif // *************************************************************************** // vfs API // *************************************************************************** #include #include "vfs_int.h" #define MY_LDRV_ID "FLASH" // default current drive static int is_current_drive = TRUE; // forward declarations static sint32_t myspiffs_vfs_close( const struct vfs_file *fd ); static sint32_t myspiffs_vfs_read( const struct vfs_file *fd, void *ptr, size_t len ); static sint32_t myspiffs_vfs_write( const struct vfs_file *fd, const void *ptr, size_t len ); static sint32_t myspiffs_vfs_lseek( const struct vfs_file *fd, sint32_t off, int whence ); static sint32_t myspiffs_vfs_eof( const struct vfs_file *fd ); static sint32_t myspiffs_vfs_tell( const struct vfs_file *fd ); static sint32_t myspiffs_vfs_flush( const struct vfs_file *fd ); static sint32_t myspiffs_vfs_ferrno( const struct vfs_file *fd ); static sint32_t myspiffs_vfs_closedir( const struct vfs_dir *dd ); static vfs_item *myspiffs_vfs_readdir( const struct vfs_dir *dd ); static void myspiffs_vfs_iclose( const struct vfs_item *di ); static uint32_t myspiffs_vfs_isize( const struct vfs_item *di ); //static const struct tm *myspiffs_vfs_time( const struct vfs_item *di ); static const char *myspiffs_vfs_name( const struct vfs_item *di ); static vfs_vol *myspiffs_vfs_mount( const char *name, int num ); static vfs_file *myspiffs_vfs_open( const char *name, const char *mode ); static vfs_dir *myspiffs_vfs_opendir( const char *name ); static vfs_item *myspiffs_vfs_stat( const char *name ); static sint32_t myspiffs_vfs_remove( const char *name ); static sint32_t myspiffs_vfs_rename( const char *oldname, const char *newname ); static sint32_t myspiffs_vfs_fsinfo( uint32_t *total, uint32_t *used ); static sint32_t myspiffs_vfs_fscfg( uint32_t *phys_addr, uint32_t *phys_size ); static sint32_t myspiffs_vfs_format( void ); static sint32_t myspiffs_vfs_errno( void ); static void myspiffs_vfs_clearerr( void ); static sint32_t myspiffs_vfs_umount( const struct vfs_vol *vol ); // --------------------------------------------------------------------------- // function tables // static vfs_fs_fns myspiffs_fs_fns = { .mount = myspiffs_vfs_mount, .open = myspiffs_vfs_open, .opendir = myspiffs_vfs_opendir, .stat = myspiffs_vfs_stat, .remove = myspiffs_vfs_remove, .rename = myspiffs_vfs_rename, .mkdir = NULL, .fsinfo = myspiffs_vfs_fsinfo, .fscfg = myspiffs_vfs_fscfg, .format = myspiffs_vfs_format, .chdrive = NULL, .chdir = NULL, .ferrno = myspiffs_vfs_errno, .clearerr = myspiffs_vfs_clearerr }; static vfs_file_fns myspiffs_file_fns = { .close = myspiffs_vfs_close, .read = myspiffs_vfs_read, .write = myspiffs_vfs_write, .lseek = myspiffs_vfs_lseek, .eof = myspiffs_vfs_eof, .tell = myspiffs_vfs_tell, .flush = myspiffs_vfs_flush, .size = NULL, .ferrno = myspiffs_vfs_ferrno }; static vfs_item_fns myspiffs_item_fns = { .close = myspiffs_vfs_iclose, .size = myspiffs_vfs_isize, .time = NULL, .name = myspiffs_vfs_name, .is_dir = NULL, .is_rdonly = NULL, .is_hidden = NULL, .is_sys = NULL, .is_arch = NULL }; static vfs_dir_fns myspiffs_dd_fns = { .close = myspiffs_vfs_closedir, .readdir = myspiffs_vfs_readdir }; // --------------------------------------------------------------------------- // specific struct extensions // struct myvfs_file { struct vfs_file vfs_file; spiffs_file fh; }; struct myvfs_dir { struct vfs_dir vfs_dir; spiffs_DIR d; }; struct myvfs_stat { struct vfs_item vfs_item; spiffs_stat s; }; // --------------------------------------------------------------------------- // stat functions // #define GET_STAT_S(descr) \ const struct myvfs_stat *mystat = (const struct myvfs_stat *)descr; \ spiffs_stat *s = (spiffs_stat *)&(mystat->s); static void myspiffs_vfs_iclose( const struct vfs_item *di ) { // free descriptor memory c_free( (void *)di ); } static uint32_t myspiffs_vfs_isize( const struct vfs_item *di ) { GET_STAT_S(di); return s->size; } static const char *myspiffs_vfs_name( const struct vfs_item *di ) { GET_STAT_S(di); return s->name; } // --------------------------------------------------------------------------- // volume functions // static sint32_t myspiffs_vfs_umount( const struct vfs_vol *vol ) { // not implemented return VFS_RES_ERR; } // --------------------------------------------------------------------------- // dir functions // #define GET_DIR_D(descr) \ const struct myvfs_dir *mydd = (const struct myvfs_dir *)descr; \ spiffs_DIR *d = (spiffs_DIR *)&(mydd->d); static sint32_t myspiffs_vfs_closedir( const struct vfs_dir *dd ) { GET_DIR_D(dd); sint32_t res = SPIFFS_closedir( d ); // free descriptor memory c_free( (void *)dd ); } static vfs_item *myspiffs_vfs_readdir( const struct vfs_dir *dd ) { GET_DIR_D(dd); struct myvfs_stat *stat; struct spiffs_dirent dirent; if (stat = c_malloc( sizeof( struct myvfs_stat ) )) { if (SPIFFS_readdir( d, &dirent )) { stat->vfs_item.fs_type = VFS_FS_FATFS; stat->vfs_item.fns = &myspiffs_item_fns; // copy entries to vfs' directory item stat->s.size = dirent.size; c_strncpy( stat->s.name, dirent.name, SPIFFS_OBJ_NAME_LEN ); return (vfs_item *)stat; } else { c_free( stat ); } } return NULL; } // --------------------------------------------------------------------------- // file functions // #define GET_FILE_FH(descr) \ const struct myvfs_file *myfd = (const struct myvfs_file *)descr; \ spiffs_file fh = myfd->fh; static sint32_t myspiffs_vfs_close( const struct vfs_file *fd ) { GET_FILE_FH(fd); sint32_t res = SPIFFS_close( &fs, fh ); // free descriptor memory c_free( (void *)fd ); return res; } static sint32_t myspiffs_vfs_read( const struct vfs_file *fd, void *ptr, size_t len ) { GET_FILE_FH(fd); return SPIFFS_read( &fs, fh, ptr, len ); } static sint32_t myspiffs_vfs_write( const struct vfs_file *fd, const void *ptr, size_t len ) { GET_FILE_FH(fd); return SPIFFS_write( &fs, fh, (void *)ptr, len ); } static sint32_t myspiffs_vfs_lseek( const struct vfs_file *fd, sint32_t off, int whence ) { GET_FILE_FH(fd); int spiffs_whence; switch (whence) { default: case VFS_SEEK_SET: spiffs_whence = SPIFFS_SEEK_SET; break; case VFS_SEEK_CUR: spiffs_whence = SPIFFS_SEEK_CUR; break; case VFS_SEEK_END: spiffs_whence = SPIFFS_SEEK_END; break; } return SPIFFS_lseek( &fs, fh, off, spiffs_whence ); } static sint32_t myspiffs_vfs_eof( const struct vfs_file *fd ) { GET_FILE_FH(fd); return SPIFFS_eof( &fs, fh ); } static sint32_t myspiffs_vfs_tell( const struct vfs_file *fd ) { GET_FILE_FH(fd); return SPIFFS_tell( &fs, fh ); } static sint32_t myspiffs_vfs_flush( const struct vfs_file *fd ) { GET_FILE_FH(fd); return SPIFFS_fflush( &fs, fh ) >= 0 ? VFS_RES_OK : VFS_RES_ERR; } static sint32_t myspiffs_vfs_ferrno( const struct vfs_file *fd ) { return SPIFFS_errno( &fs ); } static int fs_mode2flag(const char *mode){ if(c_strlen(mode)==1){ if(c_strcmp(mode,"w")==0) return SPIFFS_WRONLY|SPIFFS_CREAT|SPIFFS_TRUNC; else if(c_strcmp(mode, "r")==0) return SPIFFS_RDONLY; else if(c_strcmp(mode, "a")==0) return SPIFFS_WRONLY|SPIFFS_CREAT|SPIFFS_APPEND; else return SPIFFS_RDONLY; } else if (c_strlen(mode)==2){ if(c_strcmp(mode,"r+")==0) return SPIFFS_RDWR; else if(c_strcmp(mode, "w+")==0) return SPIFFS_RDWR|SPIFFS_CREAT|SPIFFS_TRUNC; else if(c_strcmp(mode, "a+")==0) return SPIFFS_RDWR|SPIFFS_CREAT|SPIFFS_APPEND; else return SPIFFS_RDONLY; } else { return SPIFFS_RDONLY; } } // --------------------------------------------------------------------------- // filesystem functions // static vfs_file *myspiffs_vfs_open( const char *name, const char *mode ) { struct myvfs_file *fd; int flags = fs_mode2flag( mode ); if (fd = (struct myvfs_file *)c_malloc( sizeof( struct myvfs_file ) )) { if (0 < (fd->fh = SPIFFS_open( &fs, name, flags, 0 ))) { fd->vfs_file.fs_type = VFS_FS_SPIFFS; fd->vfs_file.fns = &myspiffs_file_fns; return (vfs_file *)fd; } else { c_free( fd ); } } return NULL; } static vfs_dir *myspiffs_vfs_opendir( const char *name ){ struct myvfs_dir *dd; if (dd = (struct myvfs_dir *)c_malloc( sizeof( struct myvfs_dir ) )) { if (SPIFFS_opendir( &fs, name, &(dd->d) )) { dd->vfs_dir.fs_type = VFS_FS_SPIFFS; dd->vfs_dir.fns = &myspiffs_dd_fns; return (vfs_dir *)dd; } else { c_free( dd ); } } return NULL; } static vfs_item *myspiffs_vfs_stat( const char *name ) { struct myvfs_stat *s; if (s = (struct myvfs_stat *)c_malloc( sizeof( struct myvfs_stat ) )) { if (0 <= SPIFFS_stat( &fs, name, &(s->s) )) { s->vfs_item.fs_type = VFS_FS_SPIFFS; s->vfs_item.fns = &myspiffs_item_fns; return (vfs_item *)s; } else { c_free( s ); } } return NULL; } static sint32_t myspiffs_vfs_remove( const char *name ) { return SPIFFS_remove( &fs, name ); } static sint32_t myspiffs_vfs_rename( const char *oldname, const char *newname ) { return SPIFFS_rename( &fs, oldname, newname ); } static sint32_t myspiffs_vfs_fsinfo( uint32_t *total, uint32_t *used ) { return SPIFFS_info( &fs, total, used ); } static sint32_t myspiffs_vfs_fscfg( uint32_t *phys_addr, uint32_t *phys_size ) { *phys_addr = fs.cfg.phys_addr; *phys_size = fs.cfg.phys_size; return VFS_RES_OK; } static vfs_vol *myspiffs_vfs_mount( const char *name, int num ) { // volume descriptor not supported, just return TRUE / FALSE return myspiffs_mount() ? (vfs_vol *)1 : NULL; } static sint32_t myspiffs_vfs_format( void ) { return myspiffs_format(); } static sint32_t myspiffs_vfs_errno( void ) { return SPIFFS_errno( &fs ); } static void myspiffs_vfs_clearerr( void ) { SPIFFS_clearerr( &fs ); } // --------------------------------------------------------------------------- // VFS interface functions // vfs_fs_fns *myspiffs_realm( const char *inname, char **outname, int set_current_drive ) { if (inname[0] == '/') { size_t idstr_len = c_strlen( MY_LDRV_ID ); // logical drive is specified, check if it's our id if (0 == c_strncmp( &(inname[1]), MY_LDRV_ID, idstr_len )) { *outname = (char *)&(inname[1 + idstr_len]); if (*outname[0] == '/') { // skip leading / (*outname)++; } if (set_current_drive) is_current_drive = TRUE; return &myspiffs_fs_fns; } } else { // no logical drive in patchspec, are we current drive? if (is_current_drive) { *outname = (char *)inname; return &myspiffs_fs_fns; } } if (set_current_drive) is_current_drive = FALSE; return NULL; }