/* * Copyright (c) 2018-2020, Andreas Kling * Copyright (c) 2021, sin-ack * * SPDX-License-Identifier: BSD-2-Clause */ #include #include #include #include #include namespace Kernel { ErrorOr> Ext2FS::try_create(OpenFileDescription& file_description) { return TRY(adopt_nonnull_lock_ref_or_enomem(new (nothrow) Ext2FS(file_description))); } Ext2FS::Ext2FS(OpenFileDescription& file_description) : BlockBasedFileSystem(file_description) { } Ext2FS::~Ext2FS() = default; ErrorOr Ext2FS::flush_super_block() { MutexLocker locker(m_lock); VERIFY((sizeof(ext2_super_block) % logical_block_size()) == 0); auto super_block_buffer = UserOrKernelBuffer::for_kernel_buffer((u8*)&m_super_block); return raw_write_blocks(2, (sizeof(ext2_super_block) / logical_block_size()), super_block_buffer); } ext2_group_desc const& Ext2FS::group_descriptor(GroupIndex group_index) const { // FIXME: Should this fail gracefully somehow? VERIFY(group_index <= m_block_group_count); VERIFY(group_index > 0); return block_group_descriptors()[group_index.value() - 1]; } bool Ext2FS::is_initialized_while_locked() { VERIFY(m_lock.is_locked()); return !m_root_inode.is_null(); } ErrorOr Ext2FS::initialize_while_locked() { VERIFY(m_lock.is_locked()); VERIFY(!is_initialized_while_locked()); VERIFY((sizeof(ext2_super_block) % logical_block_size()) == 0); auto super_block_buffer = UserOrKernelBuffer::for_kernel_buffer((u8*)&m_super_block); TRY(raw_read_blocks(2, (sizeof(ext2_super_block) / logical_block_size()), super_block_buffer)); auto const& super_block = this->super_block(); if constexpr (EXT2_DEBUG) { dmesgln("Ext2FS: super block magic: {:04x} (super block size: {})", super_block.s_magic, sizeof(ext2_super_block)); } if (super_block.s_magic != EXT2_SUPER_MAGIC) { dmesgln("Ext2FS: Bad super block magic"); return EINVAL; } if constexpr (EXT2_DEBUG) { dmesgln("Ext2FS: {} inodes, {} blocks", super_block.s_inodes_count, super_block.s_blocks_count); dmesgln("Ext2FS: Block size: {}", EXT2_BLOCK_SIZE(&super_block)); dmesgln("Ext2FS: First data block: {}", super_block.s_first_data_block); dmesgln("Ext2FS: Inodes per block: {}", inodes_per_block()); dmesgln("Ext2FS: Inodes per group: {}", inodes_per_group()); dmesgln("Ext2FS: Free inodes: {}", super_block.s_free_inodes_count); dmesgln("Ext2FS: Descriptors per block: {}", EXT2_DESC_PER_BLOCK(&super_block)); dmesgln("Ext2FS: Descriptor size: {}", EXT2_DESC_SIZE(&super_block)); } set_block_size(EXT2_BLOCK_SIZE(&super_block)); set_fragment_size(EXT2_FRAG_SIZE(&super_block)); // Note: This depends on the block size being available. TRY(BlockBasedFileSystem::initialize_while_locked()); VERIFY(block_size() <= (int)max_block_size); m_block_group_count = ceil_div(super_block.s_blocks_count, super_block.s_blocks_per_group); if (m_block_group_count == 0) { dmesgln("Ext2FS: no block groups :("); return EINVAL; } auto blocks_to_read = ceil_div(m_block_group_count * sizeof(ext2_group_desc), block_size()); BlockIndex first_block_of_bgdt = block_size() == 1024 ? 2 : 1; m_cached_group_descriptor_table = TRY(KBuffer::try_create_with_size("Ext2FS: Block group descriptors"sv, block_size() * blocks_to_read, Memory::Region::Access::ReadWrite)); auto buffer = UserOrKernelBuffer::for_kernel_buffer(m_cached_group_descriptor_table->data()); TRY(read_blocks(first_block_of_bgdt, blocks_to_read, buffer)); if constexpr (EXT2_DEBUG) { for (unsigned i = 1; i <= m_block_group_count; ++i) { auto const& group = group_descriptor(i); dbgln("Ext2FS: group[{}] ( block_bitmap: {}, inode_bitmap: {}, inode_table: {} )", i, group.bg_block_bitmap, group.bg_inode_bitmap, group.bg_inode_table); } } m_root_inode = TRY(build_root_inode()); return {}; } Inode& Ext2FS::root_inode() { return *m_root_inode; } bool Ext2FS::find_block_containing_inode(InodeIndex inode, BlockIndex& block_index, unsigned& offset) const { auto const& super_block = this->super_block(); if (inode != EXT2_ROOT_INO && inode < EXT2_FIRST_INO(&super_block)) return false; if (inode > super_block.s_inodes_count) return false; auto const& bgd = group_descriptor(group_index_from_inode(inode)); u64 full_offset = ((inode.value() - 1) % inodes_per_group()) * inode_size(); block_index = bgd.bg_inode_table + (full_offset >> EXT2_BLOCK_SIZE_BITS(&super_block)); offset = full_offset & (block_size() - 1); return true; } Ext2FS::BlockListShape Ext2FS::compute_block_list_shape(unsigned blocks) const { BlockListShape shape; unsigned const entries_per_block = EXT2_ADDR_PER_BLOCK(&super_block()); unsigned blocks_remaining = blocks; shape.direct_blocks = min((unsigned)EXT2_NDIR_BLOCKS, blocks_remaining); blocks_remaining -= shape.direct_blocks; if (!blocks_remaining) return shape; shape.indirect_blocks = min(blocks_remaining, entries_per_block); shape.meta_blocks += 1; blocks_remaining -= shape.indirect_blocks; if (!blocks_remaining) return shape; shape.doubly_indirect_blocks = min(blocks_remaining, entries_per_block * entries_per_block); shape.meta_blocks += 1; shape.meta_blocks += ceil_div(shape.doubly_indirect_blocks, entries_per_block); blocks_remaining -= shape.doubly_indirect_blocks; if (!blocks_remaining) return shape; shape.triply_indirect_blocks = min(blocks_remaining, entries_per_block * entries_per_block * entries_per_block); shape.meta_blocks += 1; shape.meta_blocks += ceil_div(shape.triply_indirect_blocks, entries_per_block * entries_per_block); shape.meta_blocks += ceil_div(shape.triply_indirect_blocks, entries_per_block); blocks_remaining -= shape.triply_indirect_blocks; VERIFY(blocks_remaining == 0); return shape; } u8 Ext2FS::internal_file_type_to_directory_entry_type(DirectoryEntryView const& entry) const { switch (entry.file_type) { case EXT2_FT_REG_FILE: return DT_REG; case EXT2_FT_DIR: return DT_DIR; case EXT2_FT_CHRDEV: return DT_CHR; case EXT2_FT_BLKDEV: return DT_BLK; case EXT2_FT_FIFO: return DT_FIFO; case EXT2_FT_SOCK: return DT_SOCK; case EXT2_FT_SYMLINK: return DT_LNK; default: return DT_UNKNOWN; } } Ext2FS::FeaturesReadOnly Ext2FS::get_features_readonly() const { if (m_super_block.s_rev_level > 0) return static_cast(m_super_block.s_feature_ro_compat); return Ext2FS::FeaturesReadOnly::None; } u64 Ext2FS::inodes_per_block() const { return EXT2_INODES_PER_BLOCK(&super_block()); } u64 Ext2FS::inodes_per_group() const { return EXT2_INODES_PER_GROUP(&super_block()); } u64 Ext2FS::inode_size() const { return EXT2_INODE_SIZE(&super_block()); } u64 Ext2FS::blocks_per_group() const { return EXT2_BLOCKS_PER_GROUP(&super_block()); } ErrorOr Ext2FS::write_ext2_inode(InodeIndex inode, ext2_inode const& e2inode) { BlockIndex block_index; unsigned offset; if (!find_block_containing_inode(inode, block_index, offset)) return EINVAL; auto buffer = UserOrKernelBuffer::for_kernel_buffer(const_cast((u8 const*)&e2inode)); return write_block(block_index, buffer, inode_size(), offset); } auto Ext2FS::allocate_blocks(GroupIndex preferred_group_index, size_t count) -> ErrorOr> { dbgln_if(EXT2_DEBUG, "Ext2FS: allocate_blocks(preferred group: {}, count {})", preferred_group_index, count); if (count == 0) return Vector {}; Vector blocks; TRY(blocks.try_ensure_capacity(count)); MutexLocker locker(m_lock); auto group_index = preferred_group_index; if (!group_descriptor(preferred_group_index).bg_free_blocks_count) { group_index = 1; } while (blocks.size() < count) { bool found_a_group = false; if (group_descriptor(group_index).bg_free_blocks_count) { found_a_group = true; } else { if (group_index == preferred_group_index) group_index = 1; for (; group_index <= m_block_group_count; group_index = GroupIndex { group_index.value() + 1 }) { if (group_descriptor(group_index).bg_free_blocks_count) { found_a_group = true; break; } } } VERIFY(found_a_group); auto const& bgd = group_descriptor(group_index); auto* cached_bitmap = TRY(get_bitmap_block(bgd.bg_block_bitmap)); int blocks_in_group = min(blocks_per_group(), super_block().s_blocks_count); auto block_bitmap = cached_bitmap->bitmap(blocks_in_group); BlockIndex first_block_in_group = (group_index.value() - 1) * blocks_per_group() + first_block_index().value(); size_t free_region_size = 0; auto first_unset_bit_index = block_bitmap.find_longest_range_of_unset_bits(count - blocks.size(), free_region_size); VERIFY(first_unset_bit_index.has_value()); dbgln_if(EXT2_DEBUG, "Ext2FS: allocating free region of size: {} [{}]", free_region_size, group_index); for (size_t i = 0; i < free_region_size; ++i) { BlockIndex block_index = (first_unset_bit_index.value() + i) + first_block_in_group.value(); TRY(set_block_allocation_state(block_index, true)); blocks.unchecked_append(block_index); dbgln_if(EXT2_DEBUG, " allocated > {}", block_index); } } VERIFY(blocks.size() == count); return blocks; } ErrorOr Ext2FS::allocate_inode(GroupIndex preferred_group) { dbgln_if(EXT2_DEBUG, "Ext2FS: allocate_inode(preferred_group: {})", preferred_group); MutexLocker locker(m_lock); // FIXME: We shouldn't refuse to allocate an inode if there is no group that can house the whole thing. // In those cases we should just spread it across multiple groups. auto is_suitable_group = [this](auto group_index) { auto& bgd = group_descriptor(group_index); return bgd.bg_free_inodes_count && bgd.bg_free_blocks_count >= 1; }; GroupIndex group_index; if (preferred_group.value() && is_suitable_group(preferred_group)) { group_index = preferred_group; } else { for (unsigned i = 1; i <= m_block_group_count; ++i) { if (is_suitable_group(i)) { group_index = i; break; } } } if (!group_index) { dmesgln("Ext2FS: allocate_inode: no suitable group found for new inode"); return ENOSPC; } dbgln_if(EXT2_DEBUG, "Ext2FS: allocate_inode: found suitable group [{}] for new inode :^)", group_index); auto const& bgd = group_descriptor(group_index); unsigned inodes_in_group = min(inodes_per_group(), super_block().s_inodes_count); InodeIndex first_inode_in_group = (group_index.value() - 1) * inodes_per_group() + 1; auto* cached_bitmap = TRY(get_bitmap_block(bgd.bg_inode_bitmap)); auto inode_bitmap = cached_bitmap->bitmap(inodes_in_group); for (size_t i = 0; i < inode_bitmap.size(); ++i) { if (inode_bitmap.get(i)) continue; inode_bitmap.set(i, true); auto inode_index = InodeIndex(first_inode_in_group.value() + i); cached_bitmap->dirty = true; m_super_block.s_free_inodes_count--; m_super_block_dirty = true; const_cast(bgd).bg_free_inodes_count--; m_block_group_descriptors_dirty = true; // In case the inode cache had this cached as "non-existent", uncache that info. m_inode_cache.remove(inode_index.value()); return inode_index; } dmesgln("Ext2FS: allocate_inode found no available inode, despite bgd claiming there are inodes :("); return EIO; } Ext2FS::GroupIndex Ext2FS::group_index_from_block_index(BlockIndex block_index) const { if (!block_index) return 0; return (block_index.value() - 1) / blocks_per_group() + 1; } auto Ext2FS::group_index_from_inode(InodeIndex inode) const -> GroupIndex { if (!inode) return 0; return (inode.value() - 1) / inodes_per_group() + 1; } ErrorOr Ext2FS::get_inode_allocation_state(InodeIndex index) const { MutexLocker locker(m_lock); if (index == 0) return EINVAL; auto group_index = group_index_from_inode(index); auto const& bgd = group_descriptor(group_index); unsigned index_in_group = index.value() - ((group_index.value() - 1) * inodes_per_group()); unsigned bit_index = (index_in_group - 1) % inodes_per_group(); auto* cached_bitmap = TRY(const_cast(*this).get_bitmap_block(bgd.bg_inode_bitmap)); return cached_bitmap->bitmap(inodes_per_group()).get(bit_index); } ErrorOr Ext2FS::update_bitmap_block(BlockIndex bitmap_block, size_t bit_index, bool new_state, u32& super_block_counter, u16& group_descriptor_counter) { auto* cached_bitmap = TRY(get_bitmap_block(bitmap_block)); bool current_state = cached_bitmap->bitmap(blocks_per_group()).get(bit_index); if (current_state == new_state) { dbgln("Ext2FS: Bit {} in bitmap block {} had unexpected state {}", bit_index, bitmap_block, current_state); return EIO; } cached_bitmap->bitmap(blocks_per_group()).set(bit_index, new_state); cached_bitmap->dirty = true; if (new_state) { --super_block_counter; --group_descriptor_counter; } else { ++super_block_counter; ++group_descriptor_counter; } m_super_block_dirty = true; m_block_group_descriptors_dirty = true; return {}; } ErrorOr Ext2FS::set_inode_allocation_state(InodeIndex inode_index, bool new_state) { MutexLocker locker(m_lock); auto group_index = group_index_from_inode(inode_index); unsigned index_in_group = inode_index.value() - ((group_index.value() - 1) * inodes_per_group()); unsigned bit_index = (index_in_group - 1) % inodes_per_group(); dbgln_if(EXT2_DEBUG, "Ext2FS: set_inode_allocation_state: Inode {} -> {}", inode_index, new_state); auto& bgd = const_cast(group_descriptor(group_index)); return update_bitmap_block(bgd.bg_inode_bitmap, bit_index, new_state, m_super_block.s_free_inodes_count, bgd.bg_free_inodes_count); } Ext2FS::BlockIndex Ext2FS::first_block_index() const { return block_size() == 1024 ? 1 : 0; } ErrorOr Ext2FS::get_bitmap_block(BlockIndex bitmap_block_index) { for (auto& cached_bitmap : m_cached_bitmaps) { if (cached_bitmap->bitmap_block_index == bitmap_block_index) return cached_bitmap.ptr(); } auto block = TRY(KBuffer::try_create_with_size("Ext2FS: Cached bitmap block"sv, block_size(), Memory::Region::Access::ReadWrite)); auto buffer = UserOrKernelBuffer::for_kernel_buffer(block->data()); TRY(read_block(bitmap_block_index, &buffer, block_size())); auto new_bitmap = TRY(adopt_nonnull_own_or_enomem(new (nothrow) CachedBitmap(bitmap_block_index, move(block)))); TRY(m_cached_bitmaps.try_append(move(new_bitmap))); return m_cached_bitmaps.last().ptr(); } ErrorOr Ext2FS::set_block_allocation_state(BlockIndex block_index, bool new_state) { VERIFY(block_index != 0); MutexLocker locker(m_lock); auto group_index = group_index_from_block_index(block_index); unsigned index_in_group = (block_index.value() - first_block_index().value()) - ((group_index.value() - 1) * blocks_per_group()); unsigned bit_index = index_in_group % blocks_per_group(); auto& bgd = const_cast(group_descriptor(group_index)); dbgln_if(EXT2_DEBUG, "Ext2FS: Block {} state -> {} (in bitmap block {})", block_index, new_state, bgd.bg_block_bitmap); return update_bitmap_block(bgd.bg_block_bitmap, bit_index, new_state, m_super_block.s_free_blocks_count, bgd.bg_free_blocks_count); } ErrorOr> Ext2FS::create_directory(Ext2FSInode& parent_inode, StringView name, mode_t mode, UserID uid, GroupID gid) { MutexLocker locker(m_lock); VERIFY(is_directory(mode)); auto inode = TRY(create_inode(parent_inode, name, mode, 0, uid, gid)); dbgln_if(EXT2_DEBUG, "Ext2FS: create_directory: created new directory named '{} with inode {}", name, inode->index()); Vector entries; auto current_directory_name = TRY(KString::try_create("."sv)); TRY(entries.try_empend(move(current_directory_name), inode->index(), static_cast(EXT2_FT_DIR))); auto parent_directory_name = TRY(KString::try_create(".."sv)); TRY(entries.try_empend(move(parent_directory_name), parent_inode.index(), static_cast(EXT2_FT_DIR))); TRY(static_cast(*inode).write_directory(entries)); TRY(parent_inode.increment_link_count()); auto& bgd = const_cast(group_descriptor(group_index_from_inode(inode->identifier().index()))); ++bgd.bg_used_dirs_count; m_block_group_descriptors_dirty = true; return inode; } ErrorOr> Ext2FS::create_inode(Ext2FSInode& parent_inode, StringView name, mode_t mode, dev_t dev, UserID uid, GroupID gid) { if (name.length() > EXT2_NAME_LEN) return ENAMETOOLONG; if (parent_inode.m_raw_inode.i_links_count == 0) return ENOENT; ext2_inode e2inode {}; auto now = kgettimeofday().to_truncated_seconds(); e2inode.i_mode = mode; e2inode.i_uid = uid.value(); e2inode.i_gid = gid.value(); e2inode.i_size = 0; e2inode.i_atime = now; e2inode.i_ctime = now; e2inode.i_mtime = now; e2inode.i_dtime = 0; e2inode.i_flags = 0; // For directories, add +1 link count for the "." entry in self. e2inode.i_links_count = is_directory(mode); if (is_character_device(mode)) e2inode.i_block[0] = dev; else if (is_block_device(mode)) e2inode.i_block[1] = dev; auto inode_id = TRY(allocate_inode()); dbgln_if(EXT2_DEBUG, "Ext2FS: writing initial metadata for inode {}", inode_id.value()); TRY(write_ext2_inode(inode_id, e2inode)); auto new_inode = TRY(get_inode({ fsid(), inode_id })); dbgln_if(EXT2_DEBUG, "Ext2FS: Adding inode '{}' (mode {:o}) to parent directory {}", name, mode, parent_inode.index()); TRY(parent_inode.add_child(*new_inode, name, mode)); return new_inode; } void Ext2FS::uncache_inode(InodeIndex index) { MutexLocker locker(m_lock); m_inode_cache.remove(index); } unsigned Ext2FS::total_block_count() const { MutexLocker locker(m_lock); return super_block().s_blocks_count; } unsigned Ext2FS::free_block_count() const { MutexLocker locker(m_lock); return super_block().s_free_blocks_count; } unsigned Ext2FS::total_inode_count() const { MutexLocker locker(m_lock); return super_block().s_inodes_count; } unsigned Ext2FS::free_inode_count() const { MutexLocker locker(m_lock); return super_block().s_free_inodes_count; } ErrorOr Ext2FS::prepare_to_clear_last_mount() { MutexLocker locker(m_lock); for (auto& it : m_inode_cache) { if (it.value->ref_count() > 1) return EBUSY; } BlockBasedFileSystem::remove_disk_cache_before_last_unmount(); m_inode_cache.clear(); m_root_inode = nullptr; return {}; } ErrorOr Ext2FS::free_inode(Ext2FSInode& inode) { MutexLocker locker(m_lock); VERIFY(inode.m_raw_inode.i_links_count == 0); dbgln_if(EXT2_DEBUG, "Ext2FS[{}]::free_inode(): Inode {} has no more links, time to delete!", fsid(), inode.index()); // Mark all blocks used by this inode as free. { auto blocks = TRY(inode.compute_block_list_with_meta_blocks()); for (auto block_index : blocks) { VERIFY(block_index <= super_block().s_blocks_count); if (block_index.value()) TRY(set_block_allocation_state(block_index, false)); } } // If the inode being freed is a directory, update block group directory counter. if (inode.is_directory()) { auto& bgd = const_cast(group_descriptor(group_index_from_inode(inode.index()))); --bgd.bg_used_dirs_count; dbgln_if(EXT2_DEBUG, "Ext2FS[{}]::free_inode(): Decremented bg_used_dirs_count to {} for inode {}", fsid(), bgd.bg_used_dirs_count, inode.index()); m_block_group_descriptors_dirty = true; } // NOTE: After this point, the inode metadata is wiped. memset(&inode.m_raw_inode, 0, sizeof(ext2_inode)); inode.m_raw_inode.i_dtime = kgettimeofday().to_truncated_seconds(); TRY(write_ext2_inode(inode.index(), inode.m_raw_inode)); // Mark the inode as free. TRY(set_inode_allocation_state(inode.index(), false)); return {}; } void Ext2FS::flush_block_group_descriptor_table() { MutexLocker locker(m_lock); auto blocks_to_write = ceil_div(m_block_group_count * sizeof(ext2_group_desc), block_size()); auto first_block_of_bgdt = block_size() == 1024 ? 2 : 1; auto buffer = UserOrKernelBuffer::for_kernel_buffer((u8*)block_group_descriptors()); if (auto result = write_blocks(first_block_of_bgdt, blocks_to_write, buffer); result.is_error()) dbgln("Ext2FS[{}]::flush_block_group_descriptor_table(): Failed to write blocks: {}", fsid(), result.error()); } void Ext2FS::flush_writes() { { MutexLocker locker(m_lock); if (m_super_block_dirty) { auto result = flush_super_block(); if (result.is_error()) { dbgln("Ext2FS[{}]::flush_writes(): Failed to write superblock: {}", fsid(), result.error()); // FIXME: We should handle this error. VERIFY_NOT_REACHED(); } m_super_block_dirty = false; } if (m_block_group_descriptors_dirty) { flush_block_group_descriptor_table(); m_block_group_descriptors_dirty = false; } for (auto& cached_bitmap : m_cached_bitmaps) { if (cached_bitmap->dirty) { auto buffer = UserOrKernelBuffer::for_kernel_buffer(cached_bitmap->buffer->data()); if (auto result = write_block(cached_bitmap->bitmap_block_index, buffer, block_size()); result.is_error()) { dbgln("Ext2FS[{}]::flush_writes(): Failed to write blocks: {}", fsid(), result.error()); } cached_bitmap->dirty = false; dbgln_if(EXT2_DEBUG, "Ext2FS[{}]::flush_writes(): Flushed bitmap block {}", fsid(), cached_bitmap->bitmap_block_index); } } // Uncache Inodes that are only kept alive by the index-to-inode lookup cache. // We don't uncache Inodes that are being watched by at least one InodeWatcher. // FIXME: It would be better to keep a capped number of Inodes around. // The problem is that they are quite heavy objects, and use a lot of heap memory // for their (child name lookup) and (block list) caches. m_inode_cache.remove_all_matching([](InodeIndex, LockRefPtr const& cached_inode) { // NOTE: If we're asked to look up an inode by number (via get_inode) and it turns out // to not exist, we remember the fact that it doesn't exist by caching a nullptr. // This seems like a reasonable time to uncache ideas about unknown inodes, so do that. if (cached_inode == nullptr) return true; return cached_inode->ref_count() == 1 && !cached_inode->has_watchers(); }); } BlockBasedFileSystem::flush_writes(); } ErrorOr> Ext2FS::build_root_inode() const { MutexLocker locker(m_lock); BlockIndex block_index; unsigned offset; if (!find_block_containing_inode(EXT2_ROOT_INO, block_index, offset)) return EINVAL; auto inode = TRY(adopt_nonnull_lock_ref_or_enomem(new (nothrow) Ext2FSInode(const_cast(*this), EXT2_ROOT_INO))); auto buffer = UserOrKernelBuffer::for_kernel_buffer(reinterpret_cast(&inode->m_raw_inode)); TRY(read_block(block_index, &buffer, sizeof(ext2_inode), offset)); return inode; } ErrorOr> Ext2FS::get_inode(InodeIdentifier inode) const { MutexLocker locker(m_lock); VERIFY(inode.fsid() == fsid()); VERIFY(m_root_inode); if (inode.index() == EXT2_ROOT_INO) return *m_root_inode; { auto it = m_inode_cache.find(inode.index()); if (it != m_inode_cache.end()) { if (!it->value) return ENOENT; return NonnullLockRefPtr { *it->value }; } } auto inode_allocation_state = TRY(get_inode_allocation_state(inode.index())); if (!inode_allocation_state) { TRY(m_inode_cache.try_set(inode.index(), nullptr)); return ENOENT; } BlockIndex block_index; unsigned offset; if (!find_block_containing_inode(inode.index(), block_index, offset)) return EINVAL; auto new_inode = TRY(adopt_nonnull_lock_ref_or_enomem(new (nothrow) Ext2FSInode(const_cast(*this), inode.index()))); auto buffer = UserOrKernelBuffer::for_kernel_buffer(reinterpret_cast(&new_inode->m_raw_inode)); TRY(read_block(block_index, &buffer, sizeof(ext2_inode), offset)); TRY(m_inode_cache.try_set(inode.index(), new_inode)); return new_inode; } }