#include "drive.h" #include "panic.h" #include "util.h" #include "ata.h" #include "fat.h" #include "mem.h" #define MAX_FAT_DRIVES 16 #define MAX_OPEN_FILES_PER_DRIVE 32 #define PATH_SEP_CHAR '/' #define EXT_SEP_CHAR '.' enum { FA_READ_ONLY = 0x01, FA_HIDDEN = 0x02, FA_SYSTEM = 0x04, FA_LABEL = 0x08, FA_DIRECTORY = 0x10, FA_ARCHIVE = 0x20, FA_LFN = 0x0f }; struct directory_entry { uint8_t name[11]; uint8_t attrib; uint8_t name_case; uint8_t created_decimal; uint16_t created_time; uint16_t created_date; uint16_t accessed_date; uint16_t ignore; uint16_t modified_time; uint16_t modified_date; uint16_t first_cluster; uint32_t length; } __attribute__ ((packed)); struct fat_info { //3 bytes jump uint8_t oem[8]; uint16_t bytes_per_sector;//Assumed to be 512 uint8_t sectors_per_cluster;//Assumed to be 1 uint16_t reserved_sectors; uint8_t fats;//Only first is used uint16_t root_entries; uint16_t sectors;//Assumed not to be 0 uint8_t media_type; uint16_t sectors_per_fat; uint16_t sectors_per_track; uint16_t heads; uint32_t hidden_sectors; uint32_t sectors_long; uint8_t drive_number; uint8_t reserved; uint8_t ext_boot_marker; uint32_t volume_id; uint8_t label[11]; uint8_t fs_type[8]; } __attribute__ ((packed)); #define CTOS(c, fdi) ((fdi)->data_start + (c) - 2) struct open_file_info { //directory entry is the di_number'th entry in the di_sector'th sector //di_sector of 0 indicates an unused handle uint32_t di_sector; uint8_t di_number; uint16_t start_cluster; uint32_t length; }; struct fat_drive_info { const struct fat_info *fi; uint16_t *fat; uint16_t root_start; uint16_t data_start; struct open_file_info open_files[MAX_OPEN_FILES_PER_DRIVE]; }; static struct fat_drive_info infos[MAX_FAT_DRIVES]; static uint8_t next_id = 0; static uint8_t fat_driver_buffer[512]; static struct fat_info *next_fi; static void alloc_next_fi() { if (!((uint32_t)(next_fi = (struct fat_info *)((uint32_t)next_fi + 64)) & 0xfff)) if (!(next_fi = allocate_pages(1))) panic("Out of memory in FAT driver."); } static const struct drive *cur_drive; static fs_id_t cur_id; static const struct fat_drive_info *cur_fdi; static struct directory_entry *cur_dir; static uint32_t cur_sect; //loads cluster `c` static void load_cluster(uint16_t c, void *to) { if (c == 0) { *(uint8_t *)to = 0; return; } uint32_t s = CTOS(c, cur_fdi); cur_drive->read_sectors(cur_drive, s, 1, to); } static uint16_t next_cluster(uint16_t c) { panic("TODO: compute next sector (or 0 for none)"); } static const uint8_t this_dir[] = {'.', ' ', ' ', ' ', ' ', ' ', ' ', ' ', ' ', ' ', ' '}; static const uint8_t parent_dir[] = {'.', '.', ' ', ' ', ' ', ' ', ' ', ' ', ' ', ' ', ' '}; static inline bool check_fat_names(const uint8_t *a, const uint8_t *b) { return (((uint32_t *)a)[0] == ((uint32_t *)b)[0]) && (((uint32_t *)a)[1] == ((uint32_t *)b)[1]) && (((uint16_t *)a)[4] == ((uint16_t *)b)[4]) && (((uint8_t *)a)[10] == ((uint8_t *)b)[10]); } //after: cur_dir -> specified entry in root static bool try_locate_root_entry(const uint8_t *fat_name) { cur_sect = cur_fdi->root_start - 1; cur_dir = (struct directory_entry *)(fat_driver_buffer + 512); while (true) { if (cur_dir == (struct directory_entry *)(fat_driver_buffer + 512)) { cur_dir = (struct directory_entry *)fat_driver_buffer; ++cur_sect; cur_drive->read_sectors(cur_drive, cur_sect, 1, cur_dir); } if (!*(uint8_t *)cur_dir) return false; if (check_fat_names(cur_dir->name, fat_name)) return true; else ++cur_dir; } } //before: cur_dir -> entry of dir to search //after: cur_dir -> specified entry in dir static bool try_locate_entry(const uint8_t *fat_name) { uint16_t cur_dir_cluster = cur_dir->first_cluster; load_cluster(cur_dir_cluster, fat_driver_buffer); cur_dir = (struct directory_entry *)fat_driver_buffer; while (true) { if (cur_dir == (struct directory_entry *)(fat_driver_buffer + 512)) { cur_dir = (struct directory_entry *)fat_driver_buffer; load_cluster(cur_dir_cluster = next_cluster(cur_dir_cluster), fat_driver_buffer); } if (!*(uint8_t *)cur_dir) return false; if (check_fat_names(cur_dir->name, fat_name)) { cur_sect = CTOS(cur_dir_cluster, cur_fdi); return true; } else ++cur_dir; } } //puts first path component's fat name into fat_name_buffer, //returns rest of path static const char *split_path(const char *path, uint8_t *fat_name_buffer) { uint8_t pi = 0, fi = 0; while (1) { if ((path[pi] == PATH_SEP_CHAR) || !path[pi]) { while (fi != 11) fat_name_buffer[fi++] = (uint8_t)' '; return path + (path[pi] ? pi + 1 : pi); } if (path[pi] == EXT_SEP_CHAR) if (fi <= 8) { while (fi != 8) fat_name_buffer[fi++] = (uint8_t)' '; ++pi; } else panic("Bad path in FAT16 driver"); else if ((fi == 8) || (fi == 11)) panic("Bad path in FAT16 driver"); else { fat_name_buffer[fi++] = (uint8_t)path[pi++]; } } } //cur_dir -> specified entry static bool try_load_from_path(const struct drive *d, const char *path) { cur_drive = d; cur_id = d->drive_id; cur_fdi = &infos[cur_id]; uint8_t fat_name[11]; path = split_path(path, fat_name); if (!try_locate_root_entry(fat_name)) return false; while (*path) { path = split_path(path, fat_name); if (!try_locate_entry(fat_name)) return false; } return true; } static drive_file_id_t fat_get_file(const struct drive *d, const char *path) { struct open_file_info *open_files = infos[d->drive_id].open_files - 1; for (drive_file_id_t n = 1; n != MAX_OPEN_FILES_PER_DRIVE + 1; ++n) if (!open_files[n].di_sector) { if (!try_load_from_path(d, path)) return 0; open_files[n].di_sector = cur_sect; open_files[n].di_number = cur_dir - (struct directory_entry *)fat_driver_buffer; open_files[n].start_cluster = cur_dir->first_cluster; open_files[n].length = cur_dir->length; return n; } panic("Maximum number of files open reached for FAT drive."); } static void fat_free_file(const struct drive *d, drive_file_id_t fid) { infos[d->drive_id].open_files[fid - 1].di_sector = 0; } static void fat_load_sector(const struct drive *d, drive_file_id_t fid, uint32_t sector, void *at) { cur_drive = d; cur_id = d->drive_id; cur_fdi = &infos[cur_id]; uint16_t c = cur_fdi->open_files[fid - 1].start_cluster; for (uint32_t i = 0; i < sector; ++i) c = next_cluster(c); load_cluster(c, at); } __attribute__ ((pure)) static uint32_t fat_get_file_length(const struct drive *d, drive_file_id_t fid) { return infos[d->drive_id].open_files[fid - 1].length; } __attribute__ ((pure)) static uint32_t fat_get_free_sectors(const struct drive *d) { uint16_t *start = infos[d->fs_id].fat + 2; uint16_t *end = start + d->n_sectors - infos[d->fs_id].data_start; uint32_t count = 0; for (uint16_t *i = start; i < end; ++i) if (!*i) ++count; return count; } static void fat_name_to_path(const uint8_t *fat_name, char *path) { uint8_t last_visible = -1; for (uint8_t i = 0; i < 8; ++i) { if (fat_name[i] != (uint8_t)' ') last_visible = i; path[i] = (char)fat_name[i]; } if (fat_name[8] || fat_name[9] || fat_name[10]) { path[last_visible + 1] = EXT_SEP_CHAR; for (uint8_t fi = 8, ti = last_visible + 2; fi < 11; ++fi, ++ti) { if (fat_name[fi] != (uint8_t)' ') last_visible = ti; path[ti] = (char)fat_name[fi]; } } path[last_visible + 1] = '\0'; } static uint32_t enumerate_root(const struct drive *d, struct directory_content_info *info, uint32_t max) { uint32_t sect = infos[d->drive_id].root_start - 1; struct directory_entry *entry = (struct directory_entry *)(fat_driver_buffer + 512); struct directory_content_info *fill = info; while (true) { if (entry == (struct directory_entry *)(fat_driver_buffer + 512)) { entry = (struct directory_entry *)fat_driver_buffer; ++sect; d->read_sectors(d, sect, 1, entry); } if (!*(uint8_t *)entry || (info == fill + max)) return fill - info; if (entry-> attrib & FA_LABEL) { ++entry; continue; } fill->is_dir = entry->attrib & FA_DIRECTORY; fill->size = entry->length; fat_name_to_path(entry->name, fill->name); ++entry; ++fill; } } static uint32_t fat_enumerate_dir(const struct drive *d, const char *path, struct directory_content_info *info, uint32_t max) { if (!*path) return enumerate_root(d, info, max); if (!try_load_from_path(d, path)) return 0; uint16_t cluster = cur_dir->first_cluster; load_cluster(cluster, fat_driver_buffer); struct directory_entry *entry = (struct directory_entry *)fat_driver_buffer; struct directory_content_info *fill = info; while (true) { if (entry == (struct directory_entry *)(fat_driver_buffer + 512)) { entry = (struct directory_entry *)fat_driver_buffer; load_cluster(cluster = next_cluster(cluster), fat_driver_buffer); } if (!*(uint8_t *)entry || (fill == info + max)) return fill - info; if (check_fat_names(entry->name, this_dir) || check_fat_names(entry->name, parent_dir)) { ++entry; continue; } fill->is_dir = entry->attrib & FA_DIRECTORY; fill->size = entry->length; fat_name_to_path(entry->name, fill->name); ++entry; ++fill; } } void init_fat() { next_fi = allocate_pages(1); } bool try_fat_init_drive(struct drive *d) { if (next_id >= MAX_FAT_DRIVES) panic("Maximum number of FAT drives reached."); if (!d->read_sectors(d, 0, 1, fat_driver_buffer)) return false; memcpy(next_fi, fat_driver_buffer + 3, sizeof(struct fat_info)); uint32_t *fs_type_32 = (uint32_t *)next_fi->fs_type; if ((fs_type_32[0] != ('F' + 'A' * 256 + 'T' * 65536 + '1' * 16777216)) || (fs_type_32[1] != ('6' + ' ' * 256 + ' ' * 65536 + ' ' * 16777216))) return false; d->fs_type = "FAT16"; d->get_file = &fat_get_file; d->free_file = &fat_free_file; d->load_sector = &fat_load_sector; d->get_file_length = &fat_get_file_length; d->enumerate_dir = &fat_enumerate_dir; d->get_free_sectors = &fat_get_free_sectors; d->fs_id = next_id; infos[next_id].fi = next_fi; infos[next_id].fat = allocate_pages(((next_fi->sectors_per_fat - 1) >> 3) + 1); infos[next_id].root_start = next_fi->reserved_sectors + next_fi->sectors_per_fat * next_fi->fats; infos[next_id].data_start = infos[next_id].root_start + ((next_fi->root_entries - 1) >> 4) + 1; d->read_sectors(d, next_fi->reserved_sectors, next_fi->sectors_per_fat, infos[next_id].fat); struct open_file_info *open_files = infos[next_id].open_files - 1; for (drive_file_id_t i = 0; i < MAX_OPEN_FILES_PER_DRIVE; ++i) open_files[i].di_sector = 0; alloc_next_fi(); ++next_id; return true; }