/* * Copyright (c) 2023 Antmicro * * SPDX-License-Identifier: Apache-2.0 */ #include #include #include #include #include #include #include #include "ext2.h" #include "ext2_struct.h" #include "ext2_impl.h" #include "ext2_diskops.h" #include "ext2_bitmap.h" LOG_MODULE_DECLARE(ext2); /* Static declarations */ static int get_level_offsets(struct ext2_data *fs, uint32_t block, uint32_t offsets[4]); static inline uint32_t get_ngroups(struct ext2_data *fs); #define MAX_OFFSETS_SIZE 4 /* Array of zeros to be used in inode block calculation */ static const uint32_t zero_offsets[MAX_OFFSETS_SIZE]; static void fill_sblock(struct ext2_superblock *sb, struct ext2_disk_superblock *disk_sb) { sb->s_inodes_count = sys_le32_to_cpu(disk_sb->s_inodes_count); sb->s_blocks_count = sys_le32_to_cpu(disk_sb->s_blocks_count); sb->s_free_blocks_count = sys_le32_to_cpu(disk_sb->s_free_blocks_count); sb->s_free_inodes_count = sys_le32_to_cpu(disk_sb->s_free_inodes_count); sb->s_first_data_block = sys_le32_to_cpu(disk_sb->s_first_data_block); sb->s_log_block_size = sys_le32_to_cpu(disk_sb->s_log_block_size); sb->s_log_frag_size = sys_le32_to_cpu(disk_sb->s_log_frag_size); sb->s_blocks_per_group = sys_le32_to_cpu(disk_sb->s_blocks_per_group); sb->s_frags_per_group = sys_le32_to_cpu(disk_sb->s_frags_per_group); sb->s_inodes_per_group = sys_le32_to_cpu(disk_sb->s_inodes_per_group); sb->s_mnt_count = sys_le16_to_cpu(disk_sb->s_mnt_count); sb->s_max_mnt_count = sys_le16_to_cpu(disk_sb->s_max_mnt_count); sb->s_magic = sys_le16_to_cpu(disk_sb->s_magic); sb->s_state = sys_le16_to_cpu(disk_sb->s_state); sb->s_errors = sys_le16_to_cpu(disk_sb->s_errors); sb->s_creator_os = sys_le32_to_cpu(disk_sb->s_creator_os); sb->s_rev_level = sys_le32_to_cpu(disk_sb->s_rev_level); sb->s_first_ino = sys_le32_to_cpu(disk_sb->s_first_ino); sb->s_inode_size = sys_le16_to_cpu(disk_sb->s_inode_size); sb->s_block_group_nr = sys_le16_to_cpu(disk_sb->s_block_group_nr); sb->s_feature_compat = sys_le32_to_cpu(disk_sb->s_feature_compat); sb->s_feature_incompat = sys_le32_to_cpu(disk_sb->s_feature_incompat); sb->s_feature_ro_compat = sys_le32_to_cpu(disk_sb->s_feature_ro_compat); } static void fill_disk_sblock(struct ext2_disk_superblock *disk_sb, struct ext2_superblock *sb) { disk_sb->s_inodes_count = sys_cpu_to_le32(sb->s_inodes_count); disk_sb->s_blocks_count = sys_cpu_to_le32(sb->s_blocks_count); disk_sb->s_free_blocks_count = sys_cpu_to_le32(sb->s_free_blocks_count); disk_sb->s_free_inodes_count = sys_cpu_to_le32(sb->s_free_inodes_count); disk_sb->s_first_data_block = sys_cpu_to_le32(sb->s_first_data_block); disk_sb->s_log_block_size = sys_cpu_to_le32(sb->s_log_block_size); disk_sb->s_log_frag_size = sys_cpu_to_le32(sb->s_log_frag_size); disk_sb->s_blocks_per_group = sys_cpu_to_le32(sb->s_blocks_per_group); disk_sb->s_frags_per_group = sys_cpu_to_le32(sb->s_frags_per_group); disk_sb->s_inodes_per_group = sys_cpu_to_le32(sb->s_inodes_per_group); disk_sb->s_mnt_count = sys_cpu_to_le16(sb->s_mnt_count); disk_sb->s_max_mnt_count = sys_cpu_to_le16(sb->s_max_mnt_count); disk_sb->s_magic = sys_cpu_to_le16(sb->s_magic); disk_sb->s_state = sys_cpu_to_le16(sb->s_state); disk_sb->s_errors = sys_cpu_to_le16(sb->s_errors); disk_sb->s_creator_os = sys_cpu_to_le32(sb->s_creator_os); disk_sb->s_rev_level = sys_cpu_to_le32(sb->s_rev_level); disk_sb->s_first_ino = sys_cpu_to_le32(sb->s_first_ino); disk_sb->s_inode_size = sys_cpu_to_le16(sb->s_inode_size); disk_sb->s_block_group_nr = sys_cpu_to_le16(sb->s_block_group_nr); disk_sb->s_feature_compat = sys_cpu_to_le32(sb->s_feature_compat); disk_sb->s_feature_incompat = sys_cpu_to_le32(sb->s_feature_incompat); disk_sb->s_feature_ro_compat = sys_cpu_to_le32(sb->s_feature_ro_compat); } static void fill_bgroup(struct ext2_bgroup *bg, struct ext2_disk_bgroup *disk_bg) { bg->bg_block_bitmap = sys_le32_to_cpu(disk_bg->bg_block_bitmap); bg->bg_inode_bitmap = sys_le32_to_cpu(disk_bg->bg_inode_bitmap); bg->bg_inode_table = sys_le32_to_cpu(disk_bg->bg_inode_table); bg->bg_free_blocks_count = sys_le16_to_cpu(disk_bg->bg_free_blocks_count); bg->bg_free_inodes_count = sys_le16_to_cpu(disk_bg->bg_free_inodes_count); bg->bg_used_dirs_count = sys_le16_to_cpu(disk_bg->bg_used_dirs_count); } static void fill_disk_bgroup(struct ext2_disk_bgroup *disk_bg, struct ext2_bgroup *bg) { disk_bg->bg_block_bitmap = sys_cpu_to_le32(bg->bg_block_bitmap); disk_bg->bg_inode_bitmap = sys_cpu_to_le32(bg->bg_inode_bitmap); disk_bg->bg_inode_table = sys_cpu_to_le32(bg->bg_inode_table); disk_bg->bg_free_blocks_count = sys_cpu_to_le16(bg->bg_free_blocks_count); disk_bg->bg_free_inodes_count = sys_cpu_to_le16(bg->bg_free_inodes_count); disk_bg->bg_used_dirs_count = sys_cpu_to_le16(bg->bg_used_dirs_count); } static void fill_inode(struct ext2_inode *inode, struct ext2_disk_inode *dino) { inode->i_mode = sys_le16_to_cpu(dino->i_mode); inode->i_size = sys_le32_to_cpu(dino->i_size); inode->i_links_count = sys_le16_to_cpu(dino->i_links_count); inode->i_blocks = sys_le32_to_cpu(dino->i_blocks); for (int i = 0; i < EXT2_INODE_BLOCKS; i++) { inode->i_block[i] = sys_le32_to_cpu(dino->i_block[i]); } } static void fill_disk_inode(struct ext2_disk_inode *dino, struct ext2_inode *inode) { dino->i_mode = sys_cpu_to_le16(inode->i_mode); dino->i_size = sys_cpu_to_le32(inode->i_size); dino->i_links_count = sys_cpu_to_le16(inode->i_links_count); dino->i_blocks = sys_cpu_to_le32(inode->i_blocks); for (int i = 0; i < EXT2_INODE_BLOCKS; i++) { dino->i_block[i] = sys_cpu_to_le32(inode->i_block[i]); } } struct ext2_direntry *ext2_fetch_direntry(struct ext2_disk_direntry *disk_de) { if (disk_de->de_name_len > EXT2_MAX_FILE_NAME) { return NULL; } uint32_t prog_rec_len = sizeof(struct ext2_direntry) + disk_de->de_name_len; struct ext2_direntry *de = k_heap_alloc(&direntry_heap, prog_rec_len, K_FOREVER); __ASSERT(de != NULL, "allocated direntry can't be NULL"); de->de_inode = sys_le32_to_cpu(disk_de->de_inode); de->de_rec_len = sys_le16_to_cpu(disk_de->de_rec_len); de->de_name_len = disk_de->de_name_len; de->de_file_type = disk_de->de_file_type; memcpy(de->de_name, disk_de->de_name, de->de_name_len); return de; } void ext2_write_direntry(struct ext2_disk_direntry *disk_de, struct ext2_direntry *de) { disk_de->de_inode = sys_le32_to_cpu(de->de_inode); disk_de->de_rec_len = sys_le16_to_cpu(de->de_rec_len); disk_de->de_name_len = de->de_name_len; disk_de->de_file_type = de->de_file_type; memcpy(disk_de->de_name, de->de_name, de->de_name_len); } uint32_t ext2_get_disk_direntry_inode(struct ext2_disk_direntry *de) { return sys_le32_to_cpu(de->de_inode); } uint32_t ext2_get_disk_direntry_reclen(struct ext2_disk_direntry *de) { return sys_le16_to_cpu(de->de_rec_len); } uint8_t ext2_get_disk_direntry_namelen(struct ext2_disk_direntry *de) { return de->de_name_len; } uint8_t ext2_get_disk_direntry_type(struct ext2_disk_direntry *de) { return de->de_file_type; } void ext2_set_disk_direntry_inode(struct ext2_disk_direntry *de, uint32_t inode) { de->de_inode = sys_cpu_to_le32(inode); } void ext2_set_disk_direntry_reclen(struct ext2_disk_direntry *de, uint16_t reclen) { de->de_rec_len = sys_cpu_to_le16(reclen); } void ext2_set_disk_direntry_namelen(struct ext2_disk_direntry *de, uint8_t namelen) { de->de_name_len = namelen; } void ext2_set_disk_direntry_type(struct ext2_disk_direntry *de, uint8_t type) { de->de_file_type = type; } void ext2_set_disk_direntry_name(struct ext2_disk_direntry *de, const char *name, size_t len) { memcpy(de->de_name, name, len); } int ext2_fetch_superblock(struct ext2_data *fs) { struct ext2_block *b; uint32_t sblock_offset; if (fs->block_size == 1024) { sblock_offset = 0; b = ext2_get_block(fs, 1); } else { sblock_offset = 1024; b = ext2_get_block(fs, 0); } if (b == NULL) { return -ENOENT; } struct ext2_disk_superblock *disk_sb = (struct ext2_disk_superblock *)(b->data + sblock_offset); fill_sblock(&fs->sblock, disk_sb); ext2_drop_block(b); return 0; } static inline uint32_t get_ngroups(struct ext2_data *fs) { uint32_t ngroups = fs->sblock.s_blocks_count / fs->sblock.s_blocks_per_group; if (fs->sblock.s_blocks_count % fs->sblock.s_blocks_per_group != 0) { /* there is one more group if the last group is incomplete */ ngroups += 1; } return ngroups; } int ext2_fetch_block_group(struct ext2_data *fs, uint32_t group) { struct ext2_bgroup *bg = &fs->bgroup; /* Check if block group is cached */ if (group == bg->num) { return 0; } uint32_t ngroups = get_ngroups(fs); LOG_DBG("ngroups:%d", ngroups); LOG_DBG("cur_group:%d fetch_group:%d", bg->num, group); if (group > ngroups) { return -ERANGE; } uint32_t groups_per_block = fs->block_size / sizeof(struct ext2_disk_bgroup); uint32_t block = group / groups_per_block; uint32_t offset = group % groups_per_block; uint32_t global_block = fs->sblock.s_first_data_block + 1 + block; struct ext2_block *b = ext2_get_block(fs, global_block); if (b == NULL) { return -ENOENT; } struct ext2_disk_bgroup *disk_bg = ((struct ext2_disk_bgroup *)b->data) + offset; fill_bgroup(bg, disk_bg); /* Drop unused block */ ext2_drop_block(b); /* Invalidate previously fetched blocks */ ext2_drop_block(bg->inode_table); ext2_drop_block(bg->inode_bitmap); ext2_drop_block(bg->block_bitmap); bg->inode_table = bg->inode_bitmap = bg->block_bitmap = NULL; bg->fs = fs; bg->num = group; LOG_DBG("[BG:%d] itable:%d free_blk:%d free_ino:%d useddirs:%d bbitmap:%d ibitmap:%d", group, bg->bg_inode_table, bg->bg_free_blocks_count, bg->bg_free_inodes_count, bg->bg_used_dirs_count, bg->bg_block_bitmap, bg->bg_inode_bitmap); return 0; } int ext2_fetch_bg_itable(struct ext2_bgroup *bg, uint32_t block) { if (bg->inode_table && bg->inode_table_block == block) { return 0; } struct ext2_data *fs = bg->fs; uint32_t global_block = bg->bg_inode_table + block; ext2_drop_block(bg->inode_table); bg->inode_table = ext2_get_block(fs, global_block); if (bg->inode_table == NULL) { return -ENOENT; } bg->inode_table_block = block; return 0; } int ext2_fetch_bg_ibitmap(struct ext2_bgroup *bg) { if (bg->inode_bitmap) { return 0; } struct ext2_data *fs = bg->fs; uint32_t global_block = bg->bg_inode_bitmap; bg->inode_bitmap = ext2_get_block(fs, global_block); if (bg->inode_bitmap == NULL) { return -ENOENT; } return 0; } int ext2_fetch_bg_bbitmap(struct ext2_bgroup *bg) { if (bg->block_bitmap) { return 0; } struct ext2_data *fs = bg->fs; uint32_t global_block = bg->bg_block_bitmap; bg->block_bitmap = ext2_get_block(fs, global_block); if (bg->block_bitmap == NULL) { return -ENOENT; } return 0; } /** * @brief Fetch block group and inode table of given inode. * * @return Offset of inode in currently fetched inode table block. */ static int32_t get_itable_entry(struct ext2_data *fs, uint32_t ino) { int rc; uint32_t ino_group = (ino - 1) / fs->sblock.s_inodes_per_group; uint32_t ino_index = (ino - 1) % fs->sblock.s_inodes_per_group; LOG_DBG("ino_group:%d ino_index:%d", ino_group, ino_index); rc = ext2_fetch_block_group(fs, ino_group); if (rc < 0) { return rc; } uint32_t inode_size = fs->sblock.s_inode_size; uint32_t inodes_per_block = fs->block_size / inode_size; uint32_t block_index = ino_index / inodes_per_block; uint32_t block_offset = ino_index % inodes_per_block; LOG_DBG("block_index:%d block_offset:%d", block_index, block_offset); rc = ext2_fetch_bg_itable(&fs->bgroup, block_index); if (rc < 0) { return rc; } return block_offset; } int ext2_fetch_inode(struct ext2_data *fs, uint32_t ino, struct ext2_inode *inode) { int32_t itable_offset = get_itable_entry(fs, ino); LOG_DBG("fetch inode: %d", ino); if (itable_offset < 0) { return itable_offset; } struct ext2_disk_inode *dino = &BGROUP_INODE_TABLE(&fs->bgroup)[itable_offset]; fill_inode(inode, dino); /* Copy needed data into inode structure */ inode->i_fs = fs; inode->flags = 0; inode->i_id = ino; LOG_DBG("mode:%d size:%d links:%d", dino->i_mode, dino->i_size, dino->i_links_count); return 0; } /* * @param try_current -- if true then check if searched offset matches offset of currently fetched * block on that level. If they match then it is the block we are looking for. */ static int fetch_level_blocks(struct ext2_inode *inode, uint32_t offsets[4], int lvl, int max_lvl, bool try_current) { uint32_t block; bool already_fetched = try_current && (offsets[lvl] == inode->offsets[lvl]); /* all needed blocks fetched */ if (lvl > max_lvl) { return 0; } /* If already fetched block matches desired one we can use it and move to the next level. */ if (!already_fetched) { /* Fetched block on current level was wrong. * We can't use fetched blocks on this and next levels. */ try_current = false; ext2_drop_block(inode->blocks[lvl]); if (lvl == 0) { block = inode->i_block[offsets[0]]; } else { uint32_t *list = (uint32_t *)inode->blocks[lvl - 1]->data; block = sys_le32_to_cpu(list[offsets[lvl]]); } if (block == 0) { inode->blocks[lvl] = ext2_get_empty_block(inode->i_fs); } else { inode->blocks[lvl] = ext2_get_block(inode->i_fs, block); } if (inode->blocks[lvl] == NULL) { return -ENOENT; } LOG_DBG("[fetch] lvl:%d off:%d num:%d", lvl, offsets[lvl], block); } return fetch_level_blocks(inode, offsets, lvl + 1, max_lvl, try_current); } int ext2_fetch_inode_block(struct ext2_inode *inode, uint32_t block) { /* Check if correct inode block is cached. */ if (inode->flags & INODE_FETCHED_BLOCK && inode->block_num == block) { return 0; } LOG_DBG("inode:%d cur_blk:%d fetch_blk:%d", inode->i_id, inode->block_num, block); struct ext2_data *fs = inode->i_fs; int max_lvl, ret; uint32_t offsets[MAX_OFFSETS_SIZE]; bool try_current = inode->flags & INODE_FETCHED_BLOCK; max_lvl = get_level_offsets(fs, block, offsets); ret = fetch_level_blocks(inode, offsets, 0, max_lvl, try_current); if (ret < 0) { ext2_inode_drop_blocks(inode); return ret; } memcpy(inode->offsets, offsets, MAX_OFFSETS_SIZE * sizeof(uint32_t)); inode->block_lvl = max_lvl; inode->block_num = block; inode->flags |= INODE_FETCHED_BLOCK; LOG_DBG("[ino:%d fetch]\t Lvl:%d {%d, %d, %d, %d}", inode->i_id, inode->block_lvl, inode->offsets[0], inode->offsets[1], inode->offsets[2], inode->offsets[3]); return 0; } static bool all_zero(const uint32_t *offsets, int lvl) { for (int i = 0; i < lvl; ++i) { if (offsets[i] > 0) { return false; } } return true; } /** * @brief delete blocks from one described with offsets array * * NOTE: To use this function safely drop all fetched inode blocks * * @retval >=0 Number of removed blocks (only the blocks with actual inode data) * @retval <0 Error */ static int64_t delete_blocks(struct ext2_data *fs, uint32_t block_num, int lvl, const uint32_t *offsets) { __ASSERT(block_num != 0, "Can't delete zero block"); __ASSERT(lvl >= 0 && lvl < MAX_OFFSETS_SIZE, "Expected 0 <= lvl < %d (got: lvl=%d)", lvl, MAX_OFFSETS_SIZE); int ret; int64_t removed = 0, rem; uint32_t *list, start_blk; struct ext2_block *list_block = NULL; bool remove_current = false; bool block_dirty = false; if (lvl == 0) { /* If we got here we will remove this block * and it is also a block with actual inode data, hence we count it. */ remove_current = true; removed++; } else { /* Current block holds a list of blocks. */ list_block = ext2_get_block(fs, block_num); if (list_block == NULL) { return -ENOENT; } list = (uint32_t *)list_block->data; if (all_zero(offsets, lvl)) { /* We remove all blocks that are referenced by current block, hence current * block isn't needed anymore. */ remove_current = true; start_blk = 0; } else if (lvl == 1) { /* We are on one before last layer of inode block table. The next layer are * single blocks, hence we will just remove them. * We can just set start_blk here and remove blocks in loop at the end of * this function. */ start_blk = offsets[0]; } else { uint32_t block_num2 = sys_le32_to_cpu(list[offsets[0]]); /* We don't remove all blocks referenced by current block. We have to use * offsets to decide which part of next block we want to remove. */ if (block_num2 == 0) { LOG_ERR("Inode block that references other blocks must be nonzero"); fs->flags |= EXT2_DATA_FLAGS_ERR; removed = -EINVAL; goto out; } /* We will start removing whole blocks from next block on this level */ start_blk = offsets[0] + 1; /* Remove desired part of lower level block. */ rem = delete_blocks(fs, block_num2, lvl - 1, &offsets[1]); if (rem < 0) { removed = rem; goto out; } removed += rem; } /* Iterate over blocks that will be entirely deleted */ for (uint32_t i = start_blk; i < fs->block_size / EXT2_BLOCK_NUM_SIZE; ++i) { uint32_t block_num2 = sys_le32_to_cpu(list[i]); if (block_num2 == 0) { continue; } rem = delete_blocks(fs, block_num2, lvl - 1, zero_offsets); if (rem < 0) { removed = rem; goto out; } removed += rem; list[i] = 0; block_dirty = true; } } if (remove_current) { LOG_DBG("free block %d (lvl %d)", block_num, lvl); /* If we remove current block, we don't have to write it's updated content. */ if (list_block) { block_dirty = false; } ret = ext2_free_block(fs, block_num); if (ret < 0) { removed = ret; } } out: if (removed >= 0 && list_block && block_dirty) { ret = ext2_write_block(fs, list_block); if (ret < 0) { removed = ret; } } ext2_drop_block(list_block); /* On error removed will contain negative error code */ return removed; } static int get_level_offsets(struct ext2_data *fs, uint32_t block, uint32_t offsets[4]) { const uint32_t B = fs->block_size / EXT2_BLOCK_NUM_SIZE; const uint32_t lvl0_blks = EXT2_INODE_BLOCK_1LVL; const uint32_t lvl1_blks = B; const uint32_t lvl2_blks = B * B; const uint32_t lvl3_blks = B * B * B; /* Level 0 */ if (block < lvl0_blks) { offsets[0] = block; return 0; } /* Level 1 */ block -= lvl0_blks; if (block < lvl1_blks) { offsets[0] = EXT2_INODE_BLOCK_1LVL; offsets[1] = block; return 1; } /* Level 2 */ block -= lvl1_blks; if (block < lvl2_blks) { offsets[0] = EXT2_INODE_BLOCK_2LVL; offsets[1] = block / B; offsets[2] = block % B; return 2; } /* Level 3 */ if (block < lvl3_blks) { block -= lvl2_blks; offsets[0] = EXT2_INODE_BLOCK_3LVL; offsets[1] = block / (B * B); offsets[2] = (block % (B * B)) / B; offsets[3] = (block % (B * B)) % B; return 3; } /* Block number is too large */ return -EINVAL; } static int block0_level(uint32_t block) { if (block >= EXT2_INODE_BLOCK_1LVL) { return block - EXT2_INODE_BLOCK_1LVL + 1; } return 0; } int64_t ext2_inode_remove_blocks(struct ext2_inode *inode, uint32_t first) { uint32_t start; int max_lvl; int64_t ret, removed = 0; uint32_t offsets[4]; struct ext2_data *fs = inode->i_fs; max_lvl = get_level_offsets(inode->i_fs, first, offsets); if (all_zero(&offsets[1], max_lvl)) { /* The first block to remove is either: * - one of the first 12 blocks in the indode * - the first referenced block in the indirect block list; * we remove also the indirect block */ start = offsets[0]; } else { /* There will be some blocks referenced from first affected block hence we can't * remove it. */ if (inode->i_block[offsets[0]] == 0) { LOG_ERR("Inode block that references other blocks must be nonzero"); fs->flags |= EXT2_DATA_FLAGS_ERR; return -EINVAL; } start = offsets[0] + 1; ret = delete_blocks(inode->i_fs, inode->i_block[offsets[0]], block0_level(offsets[0]), &offsets[1]); if (ret < 0) { return ret; } removed += ret; } for (uint32_t i = start; i < EXT2_INODE_BLOCKS; i++) { if (inode->i_block[i] == 0) { continue; } ret = delete_blocks(inode->i_fs, inode->i_block[i], block0_level(i), zero_offsets); if (ret < 0) { return ret; } removed += ret; inode->i_block[i] = 0; } return removed; } static int alloc_level_blocks(struct ext2_inode *inode) { int ret = 0; uint32_t *block; bool allocated = false; struct ext2_data *fs = inode->i_fs; for (int lvl = 0; lvl <= inode->block_lvl; ++lvl) { if (lvl == 0) { block = &inode->i_block[inode->offsets[lvl]]; } else { block = &((uint32_t *)inode->blocks[lvl - 1]->data)[inode->offsets[lvl]]; *block = sys_le32_to_cpu(*block); } if (*block == 0) { ret = ext2_assign_block_num(fs, inode->blocks[lvl]); if (ret < 0) { return ret; } /* Update block from higher level. */ *block = sys_cpu_to_le32(inode->blocks[lvl]->num); if (lvl > 0) { ret = ext2_write_block(fs, inode->blocks[lvl-1]); if (ret < 0) { return ret; } } allocated = true; /* Allocating block on that level implies that blocks on lower levels will * be allocated too hence we can set allocated here. */ LOG_DBG("Alloc lvl:%d (num: %d) %s", lvl, *block, lvl == inode->block_lvl ? "data" : "indirect"); } } if (allocated) { /* Update number of reserved blocks. * (We are always counting 512 size blocks.) */ inode->i_blocks += fs->block_size / 512; ret = ext2_commit_inode(inode); } return ret; } int ext2_commit_superblock(struct ext2_data *fs) { int ret; struct ext2_block *b; uint32_t sblock_offset; if (fs->block_size == 1024) { sblock_offset = 0; b = ext2_get_block(fs, 1); } else { sblock_offset = 1024; b = ext2_get_block(fs, 0); } if (b == NULL) { return -ENOENT; } struct ext2_disk_superblock *disk_sb = (struct ext2_disk_superblock *)(b->data + sblock_offset); fill_disk_sblock(disk_sb, &fs->sblock); ret = ext2_write_block(fs, b); if (ret < 0) { return ret; } ext2_drop_block(b); return 0; } int ext2_commit_bg(struct ext2_data *fs) { int ret; struct ext2_bgroup *bg = &fs->bgroup; uint32_t groups_per_block = fs->block_size / sizeof(struct ext2_disk_bgroup); uint32_t block = bg->num / groups_per_block; uint32_t offset = bg->num % groups_per_block; uint32_t global_block = fs->sblock.s_first_data_block + 1 + block; struct ext2_block *b = ext2_get_block(fs, global_block); if (b == NULL) { return -ENOENT; } struct ext2_disk_bgroup *disk_bg = ((struct ext2_disk_bgroup *)b->data) + offset; fill_disk_bgroup(disk_bg, bg); ret = ext2_write_block(fs, b); if (ret < 0) { return ret; } ext2_drop_block(b); return 0; } int ext2_commit_inode(struct ext2_inode *inode) { struct ext2_data *fs = inode->i_fs; int32_t itable_offset = get_itable_entry(fs, inode->i_id); if (itable_offset < 0) { return itable_offset; } /* get pointer to proper inode in fetched block */ struct ext2_disk_inode *dino = &BGROUP_INODE_TABLE(&fs->bgroup)[itable_offset]; /* fill dinode */ fill_disk_inode(dino, inode); return ext2_write_block(fs, fs->bgroup.inode_table); } int ext2_commit_inode_block(struct ext2_inode *inode) { if (!(inode->flags & INODE_FETCHED_BLOCK)) { return -EINVAL; } int ret; LOG_DBG("inode:%d current_blk:%d", inode->i_id, inode->block_num); ret = alloc_level_blocks(inode); if (ret < 0) { return ret; } ret = ext2_write_block(inode->i_fs, inode_current_block(inode)); return ret; } int ext2_clear_inode(struct ext2_data *fs, uint32_t ino) { int ret; int32_t itable_offset = get_itable_entry(fs, ino); if (itable_offset < 0) { return itable_offset; } memset(&BGROUP_INODE_TABLE(&fs->bgroup)[itable_offset], 0, sizeof(struct ext2_disk_inode)); ret = ext2_write_block(fs, fs->bgroup.inode_table); return ret; } int64_t ext2_alloc_block(struct ext2_data *fs) { int rc, bitmap_slot; uint32_t group = 0, set; int32_t total; rc = ext2_fetch_block_group(fs, group); if (rc < 0) { return rc; } LOG_DBG("Free blocks: %d", fs->bgroup.bg_free_blocks_count); while ((rc >= 0) && (fs->bgroup.bg_free_blocks_count == 0)) { group++; rc = ext2_fetch_block_group(fs, group); if (rc == -ERANGE) { /* reached last group */ return -ENOSPC; } } if (rc < 0) { return rc; } rc = ext2_fetch_bg_bbitmap(&fs->bgroup); if (rc < 0) { return rc; } bitmap_slot = ext2_bitmap_find_free(BGROUP_BLOCK_BITMAP(&fs->bgroup), fs->block_size); if (bitmap_slot < 0) { LOG_WRN("Cannot find free block in group %d (rc: %d)", group, bitmap_slot); return bitmap_slot; } /* In bitmap blocks are counted from s_first_data_block hence we have to add this offset. */ total = group * fs->sblock.s_blocks_per_group + bitmap_slot + fs->sblock.s_first_data_block; LOG_DBG("Found free block %d in group %d (total: %d)", bitmap_slot, group, total); rc = ext2_bitmap_set(BGROUP_BLOCK_BITMAP(&fs->bgroup), bitmap_slot, fs->block_size); if (rc < 0) { return rc; } fs->bgroup.bg_free_blocks_count -= 1; fs->sblock.s_free_blocks_count -= 1; set = ext2_bitmap_count_set(BGROUP_BLOCK_BITMAP(&fs->bgroup), fs->sblock.s_blocks_count); if (set != (fs->sblock.s_blocks_count - fs->sblock.s_free_blocks_count)) { error_behavior(fs, "Wrong number of used blocks in superblock and bitmap"); return -EINVAL; } rc = ext2_commit_superblock(fs); if (rc < 0) { LOG_DBG("super block write returned: %d", rc); return -EIO; } rc = ext2_commit_bg(fs); if (rc < 0) { LOG_DBG("block group write returned: %d", rc); return -EIO; } rc = ext2_write_block(fs, fs->bgroup.block_bitmap); if (rc < 0) { LOG_DBG("block bitmap write returned: %d", rc); return -EIO; } return total; } static int check_zero_inode(struct ext2_data *fs, uint32_t ino) { int32_t itable_offset = get_itable_entry(fs, ino); if (itable_offset < 0) { return itable_offset; } uint8_t *bytes = (uint8_t *)&BGROUP_INODE_TABLE(&fs->bgroup)[itable_offset]; for (int i = 0; i < sizeof(struct ext2_disk_inode); ++i) { if (bytes[i] != 0) { return -EINVAL; } } return 0; } int32_t ext2_alloc_inode(struct ext2_data *fs) { int rc, r; uint32_t group = 0, set; int32_t global_idx; rc = ext2_fetch_block_group(fs, group); while (fs->bgroup.bg_free_inodes_count == 0 && rc >= 0) { group++; rc = ext2_fetch_block_group(fs, group); if (rc == -ERANGE) { /* reached last group */ return -ENOSPC; } } if (rc < 0) { return rc; } LOG_DBG("Free inodes (bg): %d", fs->bgroup.bg_free_inodes_count); LOG_DBG("Free inodes (sb): %d", fs->sblock.s_free_inodes_count); rc = ext2_fetch_bg_ibitmap(&fs->bgroup); if (rc < 0) { return rc; } r = ext2_bitmap_find_free(BGROUP_INODE_BITMAP(&fs->bgroup), fs->block_size); if (r < 0) { LOG_DBG("Cannot find free inode in group %d (rc: %d)", group, r); return r; } /* Add 1 because inodes are counted from 1 not 0. */ global_idx = group * fs->sblock.s_inodes_per_group + r + 1; /* Inode table entry for found inode must be cleared. */ if (check_zero_inode(fs, global_idx) != 0) { error_behavior(fs, "Inode is not cleared in inode table!"); return -EINVAL; } LOG_DBG("Found free inode %d in group %d (global_idx: %d)", r, group, global_idx); rc = ext2_bitmap_set(BGROUP_INODE_BITMAP(&fs->bgroup), r, fs->block_size); if (rc < 0) { return rc; } fs->bgroup.bg_free_inodes_count -= 1; fs->sblock.s_free_inodes_count -= 1; set = ext2_bitmap_count_set(BGROUP_INODE_BITMAP(&fs->bgroup), fs->sblock.s_inodes_count); if (set != fs->sblock.s_inodes_count - fs->sblock.s_free_inodes_count) { error_behavior(fs, "Wrong number of used inodes in superblock and bitmap"); return -EINVAL; } rc = ext2_commit_superblock(fs); if (rc < 0) { LOG_DBG("super block write returned: %d", rc); return -EIO; } rc = ext2_commit_bg(fs); if (rc < 0) { LOG_DBG("block group write returned: %d", rc); return -EIO; } rc = ext2_write_block(fs, fs->bgroup.inode_bitmap); if (rc < 0) { LOG_DBG("block bitmap write returned: %d", rc); return -EIO; } LOG_DBG("Free inodes (bg): %d", fs->bgroup.bg_free_inodes_count); LOG_DBG("Free inodes (sb): %d", fs->sblock.s_free_inodes_count); return global_idx; } int ext2_free_block(struct ext2_data *fs, uint32_t block) { LOG_DBG("Free block %d", block); /* Block bitmaps tracks blocks starting from s_first_data_block. */ block -= fs->sblock.s_first_data_block; int rc; uint32_t group = block / fs->sblock.s_blocks_per_group; uint32_t off = block % fs->sblock.s_blocks_per_group; uint32_t set; rc = ext2_fetch_block_group(fs, group); if (rc < 0) { return rc; } rc = ext2_fetch_bg_bbitmap(&fs->bgroup); if (rc < 0) { return rc; } rc = ext2_bitmap_unset(BGROUP_BLOCK_BITMAP(&fs->bgroup), off, fs->block_size); if (rc < 0) { return rc; } fs->bgroup.bg_free_blocks_count += 1; fs->sblock.s_free_blocks_count += 1; set = ext2_bitmap_count_set(BGROUP_BLOCK_BITMAP(&fs->bgroup), fs->sblock.s_blocks_count); if (set != fs->sblock.s_blocks_count - fs->sblock.s_free_blocks_count) { error_behavior(fs, "Wrong number of used blocks in superblock and bitmap"); return -EINVAL; } rc = ext2_commit_superblock(fs); if (rc < 0) { LOG_DBG("super block write returned: %d", rc); return -EIO; } rc = ext2_commit_bg(fs); if (rc < 0) { LOG_DBG("block group write returned: %d", rc); return -EIO; } rc = ext2_write_block(fs, fs->bgroup.block_bitmap); if (rc < 0) { LOG_DBG("block bitmap write returned: %d", rc); return -EIO; } return 0; } int ext2_free_inode(struct ext2_data *fs, uint32_t ino, bool directory) { LOG_DBG("Free inode %d", ino); int rc; uint32_t group = (ino - 1) / fs->sblock.s_inodes_per_group; uint32_t bitmap_off = (ino - 1) % fs->sblock.s_inodes_per_group; uint32_t set; rc = ext2_fetch_block_group(fs, group); if (rc < 0) { return rc; } rc = ext2_fetch_bg_ibitmap(&fs->bgroup); if (rc < 0) { return rc; } rc = ext2_bitmap_unset(BGROUP_INODE_BITMAP(&fs->bgroup), bitmap_off, fs->block_size); if (rc < 0) { return rc; } rc = ext2_clear_inode(fs, ino); if (rc < 0) { return rc; } fs->bgroup.bg_free_inodes_count += 1; fs->sblock.s_free_inodes_count += 1; if (directory) { fs->bgroup.bg_used_dirs_count -= 1; } set = ext2_bitmap_count_set(BGROUP_INODE_BITMAP(&fs->bgroup), fs->sblock.s_inodes_count); if (set != fs->sblock.s_inodes_count - fs->sblock.s_free_inodes_count) { error_behavior(fs, "Wrong number of used inodes in superblock and bitmap"); return -EINVAL; } LOG_INF("Inode %d is free", ino); rc = ext2_commit_superblock(fs); if (rc < 0) { LOG_DBG("super block write returned: %d", rc); return -EIO; } rc = ext2_commit_bg(fs); if (rc < 0) { LOG_DBG("block group write returned: %d", rc); return -EIO; } rc = ext2_write_block(fs, fs->bgroup.inode_bitmap); if (rc < 0) { LOG_DBG("block bitmap write returned: %d", rc); return -EIO; } rc = fs->backend_ops->sync(fs); if (rc < 0) { return -EIO; } return 0; }