blob: cbdd20a7f6a0d5f397e93cf13fe9e43b6df1d6f4 [file] [log] [blame]
// Copyright 2021 The Fuchsia Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include <safemath/checked_math.h>
#include "src/storage/f2fs/f2fs.h"
namespace f2fs {
namespace {
uint32_t MaxInlineData(const Inode &inode) {
uint16_t extra_isize = 0;
uint16_t inline_xattr_isize = 0;
if (inode.i_inline & kExtraAttr) {
extra_isize = inode.i_extra_isize;
if (inode.i_inline & kInlineXattr) {
inline_xattr_isize = inode.i_inline_xattr_size;
}
} else if ((inode.i_inline & kInlineXattr) || (inode.i_inline & kInlineDentry)) {
inline_xattr_isize = kInlineXattrAddrs;
}
return sizeof(uint32_t) *
(kAddrsPerInode - extra_isize / sizeof(uint32_t) - inline_xattr_isize - 1);
}
size_t MaxInlineDentry(const Inode &inode) {
return GetBitSize(MaxInlineData(inode)) / (GetBitSize(kSizeOfDirEntry + kDentrySlotLen) + 1);
}
const uint8_t *InlineDataPtr(const Inode &inode) {
uint16_t extra_isize = (inode.i_inline & kExtraAttr) ? inode.i_extra_isize : 0;
return reinterpret_cast<const uint8_t *>(
&inode.i_addr[extra_isize / sizeof(uint32_t) + kInlineStartOffset]);
}
const uint8_t *InlineDentryBitmap(const Inode &inode) { return InlineDataPtr(inode); }
const DirEntry *InlineDentryArray(const Inode &inode) {
size_t reserved =
MaxInlineData(inode) - MaxInlineDentry(inode) * (kSizeOfDirEntry + kDentrySlotLen);
return reinterpret_cast<const DirEntry *>(InlineDentryBitmap(inode) + reserved);
}
const uint8_t (*InlineDentryNameArray(const Inode &inode))[kDentrySlotLen] {
size_t reserved = MaxInlineData(inode) - MaxInlineDentry(inode) * kDentrySlotLen;
return reinterpret_cast<const uint8_t(*)[kDentrySlotLen]>(InlineDentryBitmap(inode) + reserved);
}
static bool TestBit(const void *addr, size_t pos, size_t size) {
if (pos >= size)
return false;
const uint8_t *bitmap = static_cast<const uint8_t *>(addr);
const uint8_t mask = GetMask(uint8_t(1U), pos & kLastNodeMask);
return (bitmap[pos >> kShiftForBitSize] & mask) != 0;
}
} // namespace
template <typename T>
static inline void DisplayMember(uint32_t typesize, T value, std::string_view name) {
if (typesize == sizeof(char)) {
FX_LOGS(INFO) << "\t" << name << " [" << value << "]";
} else {
ZX_ASSERT(sizeof(T) <= typesize);
FX_LOGS(INFO) << "\t" << name << " [0x" << std::hex << value << " : " << std::dec << value
<< "]";
}
}
static int32_t operator-(CursegType &a, CursegType &&b) {
return (static_cast<int32_t>(a) - static_cast<int32_t>(b));
}
static bool operator<=(int32_t &a, CursegType &&b) { return (a <= static_cast<int32_t>(b)); }
CursegType operator+(CursegType a, uint32_t &&b) {
return static_cast<CursegType>(static_cast<uint32_t>(a) + b);
}
static inline bool IsSumNodeSeg(SummaryFooter &footer) { return footer.entry_type == kSumTypeNode; }
static inline uint64_t BlkoffFromMain(SegmentManager &manager, uint64_t block_address) {
ZX_ASSERT(block_address >= manager.GetMainAreaStartBlock());
return block_address - manager.GetMainAreaStartBlock();
}
static inline uint32_t OffsetInSegment(SuperblockInfo &sbi, SegmentManager &manager,
uint64_t block_address) {
return static_cast<uint32_t>(BlkoffFromMain(manager, block_address) %
(1 << sbi.GetLogBlocksPerSeg()));
}
static inline uint16_t AddrsPerInode(const Inode *i) {
uint16_t inline_xattr_isize = 0;
if ((i->i_inline & kExtraAttr) && (i->i_inline & kInlineXattr)) {
inline_xattr_isize = i->i_inline_xattr_size;
} else if ((i->i_inline & kInlineXattr) || (i->i_inline & kInlineDentry)) {
inline_xattr_isize = kInlineXattrAddrs;
}
return kAddrsPerInode - inline_xattr_isize;
}
zx_status_t FsckWorker::ReadBlock(void *buffer, block_t bno) { return bc_->Readblk(bno, buffer); }
zx_status_t FsckWorker::WriteBlock(void *buffer, block_t bno) { return bc_->Writeblk(bno, buffer); }
void FsckWorker::AddIntoInodeLinkMap(nid_t nid, uint32_t link_count) {
auto ret = fsck_.inode_link_map.insert({nid, {.links = link_count, .actual_links = 1}});
ZX_ASSERT(ret.second);
if (link_count > 1) {
FX_LOGS(INFO) << "\tino[0x" << std::hex << nid << "] has hard links [0x" << link_count << "]";
}
}
zx_status_t FsckWorker::FindAndIncreaseInodeLinkMap(nid_t nid) {
if (auto ret = fsck_.inode_link_map.find(nid); ret != fsck_.inode_link_map.end()) {
++ret->second.actual_links;
return ZX_OK;
}
return ZX_ERR_NOT_FOUND;
}
bool FsckWorker::IsValidSsaNodeBlock(nid_t nid, uint32_t block_address) {
auto [ret, summary_entry] = GetSummaryEntry(block_address);
if (ret == SegType::kSegTypeData || ret == SegType::kSegTypeCurData) {
FX_LOGS(ERROR) << "\tSummary footer is not a node segment summary";
return false;
} else if (ret == SegType::kSegTypeNode) {
if (LeToCpu(summary_entry.nid) != nid) {
FX_LOGS(ERROR) << "\tnid [0x" << std::hex << nid << "]";
FX_LOGS(ERROR) << "\ttarget block_address [0x" << std::hex << block_address << "]";
FX_LOGS(ERROR) << "\tsummary block_address [0x" << std::hex
<< segment_manager_->GetSumBlock(
segment_manager_->GetSegmentNumber(block_address))
<< "]";
FX_LOGS(ERROR) << "\tseg no / offset [0x" << std::hex
<< segment_manager_->GetSegmentNumber(block_address) << "/0x" << std::hex
<< OffsetInSegment(*superblock_info_, *segment_manager_, block_address) << "]";
FX_LOGS(ERROR) << "\tsummary_entry.nid [0x" << std::hex << LeToCpu(summary_entry.nid)
<< "]";
FX_LOGS(ERROR) << "\t--> node block's nid [0x" << std::hex << nid << "]";
FX_LOGS(ERROR) << "\tInvalid node seg summary\n";
return false;
}
} else if (ret == SegType::kSegTypeCurNode) {
// current node segment has no ssa
} else {
FX_LOGS(ERROR) << "\tInvalid return value of 'GetSummaryEntry'";
return false;
}
return true;
}
bool FsckWorker::IsValidSsaDataBlock(uint32_t block_address, uint32_t parent_nid,
uint16_t index_in_node, uint8_t version) {
auto [ret, summary_entry] = GetSummaryEntry(block_address);
ZX_ASSERT(ret == SegType::kSegTypeData || ret == SegType::kSegTypeCurData);
if (LeToCpu(summary_entry.nid) != parent_nid || summary_entry.version != version ||
LeToCpu(summary_entry.ofs_in_node) != index_in_node) {
FX_LOGS(ERROR) << "\tsummary_entry.nid [0x" << std::hex << LeToCpu(summary_entry.nid)
<< "]";
FX_LOGS(ERROR) << "\tsummary_entry.version [0x" << std::hex << summary_entry.version << "]";
FX_LOGS(ERROR) << "\tsummary_entry.ofs_in_node [0x" << std::hex
<< LeToCpu(summary_entry.ofs_in_node) << "]";
FX_LOGS(ERROR) << "\tparent nid [0x" << std::hex << parent_nid << "]";
FX_LOGS(ERROR) << "\tversion from nat [0x" << std::hex << version << "]";
FX_LOGS(ERROR) << "\tindex in parent node [0x" << std::hex << index_in_node << "]";
FX_LOGS(ERROR) << "\tTarget data block address [0x" << std::hex << block_address << "]";
FX_LOGS(ERROR) << "\tInvalid data seg summary\n";
return false;
}
return true;
}
bool FsckWorker::IsValidNid(nid_t nid) {
return nid <= (kNatEntryPerBlock * superblock_info_->GetSuperblock().segment_count_nat
<< (superblock_info_->GetLogBlocksPerSeg() - 1));
}
bool FsckWorker::IsValidBlockAddress(uint32_t addr) {
if (addr >= superblock_info_->GetSuperblock().block_count) {
FX_LOGS(INFO) << "\tblock[0x" << std::hex << addr << "] should be less than [0x"
<< superblock_info_->GetSuperblock().block_count << "]";
return false;
}
if (addr < segment_manager_->GetMainAreaStartBlock()) {
FX_LOGS(INFO) << "\tblock[0x" << std::hex << addr << "] should be greater than [0x"
<< segment_manager_->GetMainAreaStartBlock() << "]";
return false;
}
return true;
}
zx_status_t FsckWorker::ValidateNodeBlock(const Node &node_block, NodeInfo node_info,
FileType ftype, NodeType ntype) {
if (node_info.nid != LeToCpu(node_block.footer.nid) ||
node_info.ino != LeToCpu(node_block.footer.ino)) {
FX_LOGS(ERROR) << "\tino[0x" << std::hex << node_info.ino << "] nid[0x" << node_info.nid
<< "] blk_addr[0x" << node_info.blk_addr << "] footer.nid[0x"
<< LeToCpu(node_block.footer.nid) << "] footer.ino[0x"
<< LeToCpu(node_block.footer.ino) << "]";
return ZX_ERR_INTERNAL;
}
if (ntype == NodeType::kTypeInode) {
uint32_t i_links = LeToCpu(node_block.i.i_links);
// Orphan node. i_links should be 0.
if (ftype == FileType::kFtOrphan) {
ZX_ASSERT(i_links == 0);
} else {
ZX_ASSERT(i_links > 0);
}
}
return ZX_OK;
}
zx::result<bool> FsckWorker::UpdateContext(const Node &node_block, NodeInfo node_info,
FileType ftype, NodeType ntype) {
nid_t nid = node_info.nid;
if (ftype != FileType::kFtOrphan || fsck_.nat_area_bitmap.GetOne(ToMsbFirst(nid))) {
fsck_.nat_area_bitmap.ClearOne(ToMsbFirst(nid));
} else {
FX_LOGS(WARNING) << "\tnid duplicated [0x" << std::hex << nid << "]";
}
if (!fsck_.main_area_bitmap.GetOne(
ToMsbFirst(BlkoffFromMain(*segment_manager_, node_info.blk_addr)))) {
// Unvisited node, mark visited.
fsck_.main_area_bitmap.SetOne(
ToMsbFirst(BlkoffFromMain(*segment_manager_, node_info.blk_addr)));
if (ntype == NodeType::kTypeInode) {
uint32_t i_links = LeToCpu(node_block.i.i_links);
if (ftype != FileType::kFtDir && ftype != FileType::kFtOrphan) {
// First time visiting this inode.
AddIntoInodeLinkMap(nid, i_links);
if (i_links > 1) {
++fsck_.result.multi_hard_link_files;
}
}
++fsck_.result.valid_inode_count;
}
++fsck_.result.valid_block_count;
++fsck_.result.valid_node_count;
} else {
// Once visited here, it should be an Inode.
if (ntype != NodeType::kTypeInode) {
FX_LOGS(ERROR) << std::hex << "\tDuplicated node block. nid[0x" << nid << "] blk_addr[0x"
<< node_info.blk_addr << "]";
return zx::error(ZX_ERR_INTERNAL);
}
uint32_t i_links = LeToCpu(node_block.i.i_links);
if (ftype == FileType::kFtDir) {
FX_LOGS(INFO) << "\tDuplicated inode blk. ino[0x" << std::hex << nid << "][0x" << std::hex
<< node_info.blk_addr;
return zx::error(ZX_ERR_INTERNAL);
} else {
FX_LOGS(INFO) << "\tino[0x" << std::hex << nid << "] has hard links [0x" << std::hex
<< i_links << "]";
// We don't go deeper.
if (auto status = FindAndIncreaseInodeLinkMap(nid); status != ZX_OK) {
return zx::error(status);
}
return zx::ok(false);
}
}
return zx::ok(true);
}
zx::result<NodeInfo> FsckWorker::ReadNodeBlock(nid_t nid, BlockBuffer<Node> &block) {
if (!IsValidNid(nid)) {
return zx::error(ZX_ERR_INVALID_ARGS);
}
auto result = GetNodeInfo(nid);
if (result.is_error()) {
return zx::error(ZX_ERR_NOT_FOUND);
}
NodeInfo node_info = *result;
if (node_info.blk_addr == kNewAddr) {
FX_LOGS(ERROR) << "\tnid is NEW_ADDR. [0x" << std::hex << nid << "]";
return zx::error(ZX_ERR_INTERNAL);
}
if (!IsValidBlockAddress(node_info.blk_addr) || !IsValidSsaNodeBlock(nid, node_info.blk_addr)) {
return zx::error(ZX_ERR_INTERNAL);
}
if (!sit_area_bitmap_.GetOne(ToMsbFirst(BlkoffFromMain(*segment_manager_, node_info.blk_addr)))) {
FX_LOGS(INFO) << "\tSIT bitmap is 0x0. block_address[0x" << std::hex << node_info.blk_addr
<< "]";
return zx::error(ZX_ERR_INTERNAL);
}
ZX_ASSERT(ReadBlock(&block, node_info.blk_addr) == ZX_OK);
return zx::ok(node_info);
}
zx::result<TraverseResult> FsckWorker::CheckNodeBlock(const Inode *inode, nid_t nid, FileType ftype,
NodeType ntype) {
uint64_t block_count = 0;
uint32_t link_count = 0;
auto node_block_ptr = std::make_unique<BlockBuffer<Node>>();
auto &node_block = *node_block_ptr;
// Read the node block.
auto node_info_or = ReadNodeBlock(nid, node_block);
if (node_info_or.is_error()) {
return node_info_or.take_error();
}
// Validate the node block.
auto node_info = std::move(*node_info_or);
if (auto status = ValidateNodeBlock(*node_block, node_info, ftype, ntype); status != ZX_OK) {
return zx::error(status);
}
// Update fsck context.
auto do_traverse = UpdateContext(*node_block, node_info, ftype, ntype);
if (do_traverse.is_error()) {
return do_traverse.take_error();
}
if (*do_traverse) {
// Traverse to underlying structures.
zx::result<TraverseResult> ret;
switch (ntype) {
case NodeType::kTypeInode:
inode_list_.push_back(std::make_unique<ChildInodeInfo>(nid, ftype));
ret = zx::ok(TraverseResult{0, 0});
break;
case NodeType::kTypeDirectNode:
ret = TraverseDnodeBlock(inode, *node_block, node_info, ftype);
break;
case NodeType::kTypeIndirectNode:
ret = TraverseIndirectNodeBlock(inode, *node_block, ftype);
break;
case NodeType::kTypeDoubleIndirectNode:
ret = TraverseDoubleIndirectNodeBlock(inode, *node_block, ftype);
break;
default:
ret = zx::error(ZX_ERR_INTERNAL);
break;
}
if (ret.is_error()) {
return ret.take_error();
}
block_count += ret->block_count;
link_count += ret->link_count;
}
return zx::ok(TraverseResult{block_count, link_count});
}
zx::result<TraverseResult> FsckWorker::TraverseInodeBlock(const Node &node_block,
NodeInfo node_info, FileType ftype) {
uint32_t child_count = 0, child_files = 0;
uint64_t block_count = 1;
nid_t nid = node_info.nid;
NodeType ntype;
uint64_t i_blocks = LeToCpu(node_block.i.i_blocks);
// ValidateNodeBlock ensures below.
ZX_ASSERT(node_info.nid == node_info.ino);
ZX_ASSERT(LeToCpu(node_block.footer.nid) == node_info.nid);
ZX_ASSERT(LeToCpu(node_block.footer.ino) == node_info.ino);
#if 0 // porting needed
fsck_chk_xattr_blk(sbi, nid, LeToCpu(node_block->i.i_xattr_nid), block_count);
#endif
do {
if (ftype == FileType::kFtChrdev || ftype == FileType::kFtBlkdev ||
ftype == FileType::kFtFifo || ftype == FileType::kFtSock) {
break;
}
if (node_block.i.i_inline & kInlineData) {
if (!(node_block.i.i_inline & kDataExist)) {
auto zeroes = std::make_unique<char[]>(MaxInlineData(node_block.i));
if (memcmp(zeroes.get(), InlineDataPtr(node_block.i), MaxInlineData(node_block.i))) {
FX_LOGS(WARNING) << "\tinode[" << nid << "] has junk inline data";
fsck_.data_exist_flag_set.insert(nid);
}
}
break;
}
if (node_block.i.i_inline & kInlineDentry) {
if (auto status =
CheckDentries(child_count, child_files, 1, InlineDentryBitmap(node_block.i),
InlineDentryArray(node_block.i), InlineDentryNameArray(node_block.i),
MaxInlineDentry(node_block.i));
status != ZX_OK) {
return zx::error(status);
}
} else {
uint16_t base =
(node_block.i.i_inline & kExtraAttr) ? node_block.i.i_extra_isize / sizeof(uint32_t) : 0;
// check data blocks in inode
for (uint16_t index = base; index < AddrsPerInode(&node_block.i); ++index) {
if (LeToCpu(node_block.i.i_addr[index]) != 0) {
++block_count;
if (auto status = CheckDataBlock(LeToCpu(node_block.i.i_addr[index]), child_count,
child_files, (i_blocks == block_count), ftype, nid,
index - base, node_info.version);
status != ZX_OK) {
return zx::error(status);
}
}
}
}
// check node blocks in inode: direct(2) + indirect(2) + double indirect(1)
for (int index = 0; index < 5; ++index) {
if (index == 0 || index == 1) {
ntype = NodeType::kTypeDirectNode;
} else if (index == 2 || index == 3) {
ntype = NodeType::kTypeIndirectNode;
} else if (index == 4) {
ntype = NodeType::kTypeDoubleIndirectNode;
} else {
ZX_ASSERT(0);
}
if (LeToCpu(node_block.i.i_nid[index]) != 0) {
auto ret = CheckNodeBlock(&node_block.i, LeToCpu(node_block.i.i_nid[index]), ftype, ntype);
if (ret.is_error()) {
return ret.take_error();
}
block_count += ret->block_count;
child_count += ret->link_count;
}
}
} while (false);
uint32_t i_links = LeToCpu(node_block.i.i_links);
if (i_blocks != block_count) {
FX_LOGS(WARNING) << "\tfile[0x" << std::hex << nid << "] i_blocks != block_count";
PrintNodeInfo(node_block);
return zx::error(ZX_ERR_INTERNAL);
}
if (ftype == FileType::kFtDir && i_links != child_count) {
FX_LOGS(WARNING) << "\tdir[0x" << std::hex << nid << "] i_links != link_count";
PrintNodeInfo(node_block);
return zx::error(ZX_ERR_INTERNAL);
}
return zx::ok(TraverseResult{block_count, child_count});
}
zx::result<TraverseResult> FsckWorker::TraverseDnodeBlock(const Inode *inode,
const Node &node_block,
NodeInfo node_info, FileType ftype) {
nid_t nid = node_info.nid;
uint64_t block_count = 1;
uint32_t child_count = 0, child_files = 0;
for (uint16_t index = 0; index < kAddrsPerBlock; ++index) {
if (LeToCpu(node_block.dn.addr[index]) == 0x0) {
continue;
}
++block_count;
if (auto status = CheckDataBlock(LeToCpu(node_block.dn.addr[index]), child_count, child_files,
LeToCpu(inode->i_blocks) == block_count, ftype, nid, index,
node_info.version);
status != ZX_OK) {
return zx::error(status);
}
}
return zx::ok(TraverseResult{block_count, child_count});
}
zx::result<TraverseResult> FsckWorker::TraverseIndirectNodeBlock(const Inode *inode,
const Node &node_block,
FileType ftype) {
uint64_t block_count = 1;
uint32_t child_count = 0;
for (uint32_t child_nid : node_block.in.nid) {
if (LeToCpu(child_nid) == 0x0) {
continue;
}
auto ret = CheckNodeBlock(inode, LeToCpu(child_nid), ftype, NodeType::kTypeDirectNode);
if (ret.is_error()) {
return ret;
}
block_count += ret->block_count;
child_count += ret->link_count;
}
return zx::ok(TraverseResult{block_count, child_count});
}
zx::result<TraverseResult> FsckWorker::TraverseDoubleIndirectNodeBlock(const Inode *inode,
const Node &node_block,
FileType ftype) {
uint64_t block_count = 1;
uint32_t child_count = 0;
for (uint32_t child_nid : node_block.in.nid) {
if (LeToCpu(child_nid) == 0x0) {
continue;
}
auto ret = CheckNodeBlock(inode, LeToCpu(child_nid), ftype, NodeType::kTypeIndirectNode);
if (ret.is_error()) {
return ret;
}
block_count += ret->block_count;
child_count += ret->link_count;
}
return zx::ok(TraverseResult{block_count, child_count});
}
zx_status_t FsckWorker::CheckDentries(uint32_t &child_count, uint32_t &child_files,
const int last_block, const uint8_t *dentry_bitmap,
const DirEntry *dentries, const uint8_t (*filename)[kNameLen],
const size_t max_entries) {
uint32_t hash_code;
FileType ftype;
++fsck_.dentry_depth;
for (uint32_t i = 0; i < max_entries;) {
if (!TestBit(dentry_bitmap, i, max_entries)) {
++i;
continue;
}
std::string_view name(reinterpret_cast<const char *>(filename[i]),
LeToCpu(dentries[i].name_len));
hash_code = DentryHash(name);
ftype = static_cast<FileType>(dentries[i].file_type);
// Becareful. 'dentry.file_type' is not imode
if (ftype == FileType::kFtDir) {
++child_count;
if (IsDotOrDotDot(name)) {
++i;
continue;
}
}
// Should we check '.' and '..' entries?
ZX_ASSERT(LeToCpu(dentries[i].hash_code) == hash_code);
if (fsck_options_.verbose) {
char str[100];
std::sprintf(str, "\t[%3u] - no[0x%x] name[%s] len[0x%x] ino[0x%x] type[0x%x]",
fsck_.dentry_depth, i, name.data(), LeToCpu(dentries[i].name_len),
LeToCpu(dentries[i].ino), dentries[i].file_type);
FX_LOGS(INFO) << str;
}
auto ret = CheckNodeBlock(nullptr, LeToCpu(dentries[i].ino), ftype, NodeType::kTypeInode);
if (ret.is_error()) {
return ret.error_value();
}
i += (name.length() + kDentrySlotLen - 1) / kDentrySlotLen;
++child_files;
}
--fsck_.dentry_depth;
return ZX_OK;
}
zx_status_t FsckWorker::CheckDentryBlock(uint32_t block_address, uint32_t &child_count,
uint32_t &child_files, int last_block) {
BlockBuffer<DentryBlock> de_blk;
ZX_ASSERT(ReadBlock(&de_blk, block_address) == ZX_OK);
return CheckDentries(child_count, child_files, last_block, de_blk->dentry_bitmap, de_blk->dentry,
de_blk->filename, kNrDentryInBlock);
}
zx_status_t FsckWorker::CheckDataBlock(uint32_t block_address, uint32_t &child_count,
uint32_t &child_files, int last_block, FileType ftype,
uint32_t parent_nid, uint16_t index_in_node, uint8_t ver) {
// Is it reserved block?
if (block_address == kNewAddr) {
++fsck_.result.valid_block_count;
return ZX_OK;
}
if (!IsValidBlockAddress(block_address)) {
return ZX_ERR_INTERNAL;
}
if (!IsValidSsaDataBlock(block_address, parent_nid, index_in_node, ver)) {
return ZX_ERR_INTERNAL;
}
if (!sit_area_bitmap_.GetOne(ToMsbFirst(BlkoffFromMain(*segment_manager_, block_address)))) {
ZX_ASSERT_MSG(false, "SIT bitmap is 0x0. block_address[0x%x]\n", block_address);
}
if (fsck_.main_area_bitmap.GetOne(ToMsbFirst(BlkoffFromMain(*segment_manager_, block_address)))) {
ZX_ASSERT_MSG(false, "Duplicated data block. pnid[0x%x] index[0x%x] block_address[0x%x]\n",
parent_nid, index_in_node, block_address);
}
fsck_.main_area_bitmap.SetOne(ToMsbFirst(BlkoffFromMain(*segment_manager_, block_address)));
++fsck_.result.valid_block_count;
if (ftype == FileType::kFtDir) {
return CheckDentryBlock(block_address, child_count, child_files, last_block);
}
return ZX_OK;
}
zx_status_t FsckWorker::TraverseInode(nid_t ino, FileType ftype) {
auto status = CheckNodeBlock(nullptr, ino, ftype, NodeType::kTypeInode);
if (status.is_error()) {
return status.error_value();
}
ZX_DEBUG_ASSERT(!inode_list_.is_empty());
do {
auto inode_info = inode_list_.pop_front();
auto node_block = std::make_unique<BlockBuffer<Node>>();
auto node_info = ReadNodeBlock(inode_info->Id(), *node_block);
if (node_info.is_error()) {
return node_info.error_value();
}
if (auto ret = TraverseInodeBlock(**node_block, *node_info, inode_info->Ftype());
ret.is_error()) {
return ret.error_value();
}
} while (!inode_list_.is_empty());
return ZX_OK;
}
zx_status_t FsckWorker::CheckOrphanNodes() {
block_t start_blk, orphan_blkaddr;
if (!superblock_info_->TestCpFlags(CpFlag::kCpOrphanPresentFlag)) {
return ZX_OK;
}
start_blk =
superblock_info_->StartCpAddr() + 1 + LeToCpu(superblock_info_->GetSuperblock().cp_payload);
orphan_blkaddr = superblock_info_->StartSumAddr() - 1;
for (block_t i = 0; i < orphan_blkaddr; ++i) {
BlockBuffer<OrphanBlock> orphan_block;
ZX_ASSERT(ReadBlock(&orphan_block, start_blk + i) == ZX_OK);
for (block_t j = 0; j < LeToCpu(orphan_block->entry_count); ++j) {
nid_t ino = LeToCpu(orphan_block->ino[j]);
if (fsck_options_.verbose) {
FX_LOGS(INFO) << "\t[" << std::hex << i << "] ino [0x" << ino << "]";
}
if (zx_status_t ret = TraverseInode(ino, FileType::kFtOrphan); ret != ZX_OK) {
return ret;
}
}
}
return ZX_OK;
}
#if 0 // porting needed
int FsckWorker::FsckChkXattrBlk(uint32_t ino, uint32_t x_nid, uint32_t *block_count) {
FsckInfo *fsck = &fsck_;
NodeInfo ni;
if (x_nid == 0x0)
return 0;
if (TestValidBitmap(x_nid, fsck->nat_area_bitmap) != 0x0) {
ClearValidBitmap(x_nid, fsck->nat_area_bitmap);
} else {
ZX_ASSERT_MSG(false, "xattr_nid duplicated [0x%x]\n", x_nid);
}
*block_count = *block_count + 1;
++fsck->chk.valid_block_count;
++fsck->chk.valid_node_count;
ZX_ASSERT(GetNodeInfo(x_nid, &ni) >= 0);
if (TestValidBitmap(BlkoffFromMain(superblock_info, ni.blk_addr), fsck->main_area_bitmap) != 0) {
ZX_ASSERT_MSG(false,
"Duplicated node block for x_attr. "
"x_nid[0x%x] block addr[0x%x]\n",
x_nid, ni.blk_addr);
}
SetValidBitmap(BlkoffFromMain(superblock_info, ni.blk_addr), fsck->main_area_bitmap);
// DBG (2)
printf("ino[0x%x] x_nid[0x%x]\n", ino, x_nid);
return 0;
}
#endif
zx_status_t FsckWorker::Init() {
fsck_ = FsckInfo{};
fsck_.nr_main_blocks = segment_manager_->GetMainSegmentsCount()
<< superblock_info_->GetLogBlocksPerSeg();
fsck_.main_area_bitmap_size = CheckedDivRoundUp<uint64_t>(fsck_.nr_main_blocks, kBitsPerByte);
ZX_ASSERT(fsck_.main_area_bitmap_size == sit_area_bitmap_size_);
fsck_.main_area_bitmap.Reset(GetBitSize(fsck_.main_area_bitmap_size));
BuildNatAreaBitmap();
return ZX_OK;
}
zx_status_t FsckWorker::VerifyCursegOffset(CursegType segtype) {
CursegInfo *curseg = segment_manager_->CURSEG_I(segtype);
if (curseg->next_blkoff >= GetBitSize(kSitVBlockMapSize)) {
return ZX_ERR_INTERNAL;
}
block_t logical_curseg_offset = segment_manager_->GetMainAreaStartBlock() +
curseg->segno * superblock_info_->GetBlocksPerSeg() +
curseg->next_blkoff;
if (!IsValidBlockAddress(logical_curseg_offset)) {
return ZX_ERR_INTERNAL;
}
if (sit_area_bitmap_.GetOne(
ToMsbFirst(BlkoffFromMain(*segment_manager_, logical_curseg_offset)))) {
return ZX_ERR_INTERNAL;
}
if (curseg->alloc_type == static_cast<uint8_t>(AllocMode::kLFS)) {
for (block_t offset = curseg->next_blkoff + 1; offset < kSitVBlockMapSize; ++offset) {
block_t logical_offset = segment_manager_->GetMainAreaStartBlock() +
curseg->segno * superblock_info_->GetBlocksPerSeg() + offset;
if (sit_area_bitmap_.GetOne(ToMsbFirst(BlkoffFromMain(*segment_manager_, logical_offset)))) {
return ZX_ERR_INTERNAL;
}
}
}
return ZX_OK;
}
zx_status_t FsckWorker::Verify() {
zx_status_t status = ZX_OK;
uint32_t nr_unref_nid = 0;
std::string unreachable_nodes;
for (uint32_t i = 0; i < fsck_.nr_nat_entries; ++i) {
if (fsck_.nat_area_bitmap.GetOne(ToMsbFirst(i))) {
std::ostringstream nid;
nid << " 0x" << std::hex << i;
unreachable_nodes += nid.str();
++nr_unref_nid;
}
}
auto iter = fsck_.inode_link_map.begin();
while (iter != fsck_.inode_link_map.end()) {
if (iter->second.links == iter->second.actual_links) {
iter = fsck_.inode_link_map.erase(iter);
} else {
++iter;
}
}
for (auto const [nid, links] : fsck_.inode_link_map) {
FX_LOGS(INFO) << "\tnode[0x" << std::hex << nid << "] has inconsistent links [0x" << links.links
<< "] (actual: 0x" << links.actual_links << ")";
}
FX_LOGS(INFO) << "start checking f2fs";
std::string str = "\tunreachable nat entries\t";
if (nr_unref_nid == 0x0) {
FX_LOGS(INFO) << str << "[OK]";
} else {
FX_LOGS(INFO) << str << "[FAILED] : " << std::to_string(nr_unref_nid) << " nodes("
<< unreachable_nodes << ")";
status = ZX_ERR_INTERNAL;
}
str = "\tSIT valid block bitmap ";
if (memcmp(sit_area_bitmap_.StorageUnsafe()->GetData(),
fsck_.main_area_bitmap.StorageUnsafe()->GetData(), sit_area_bitmap_size_) == 0x0) {
FX_LOGS(INFO) << str << "[OK]";
} else {
FX_LOGS(INFO) << str << "[FAILED]";
status = ZX_ERR_INTERNAL;
}
str = "\thard link count ";
if (fsck_.inode_link_map.empty()) {
FX_LOGS(INFO) << str << "[OK] : " << fsck_.result.multi_hard_link_files;
} else {
FX_LOGS(INFO) << str << "[FAILED] : " << fsck_.result.multi_hard_link_files;
status = ZX_ERR_INTERNAL;
}
str = "\tvalid_block_count ";
if (superblock_info_->GetValidBlockCount() == fsck_.result.valid_block_count) {
FX_LOGS(INFO) << str << "[OK] : " << fsck_.result.valid_block_count;
} else {
FX_LOGS(INFO) << str << "[FAILED] : " << superblock_info_->GetValidBlockCount()
<< "(ckpt) != " << fsck_.result.valid_block_count;
status = ZX_ERR_INTERNAL;
}
str = "\tvalid_node_count[de] ";
if (superblock_info_->GetValidNodeCount() == fsck_.result.valid_node_count) {
FX_LOGS(INFO) << str << "[OK] : " << fsck_.result.valid_node_count;
} else {
FX_LOGS(INFO) << str << "[FAILED] : " << superblock_info_->GetValidNodeCount()
<< "(expected) != " << fsck_.result.valid_node_count;
status = ZX_ERR_INTERNAL;
}
str = "\tvalid_node_count[nat] ";
if (superblock_info_->GetValidNodeCount() == fsck_.result.valid_nat_entry_count) {
FX_LOGS(INFO) << str << "[OK] : " << fsck_.result.valid_nat_entry_count;
} else {
FX_LOGS(INFO) << str << "[FAILED] : " << superblock_info_->GetValidNodeCount()
<< "(expected) != " << fsck_.result.valid_nat_entry_count;
status = ZX_ERR_INTERNAL;
}
str = "\tvalid_inode_count ";
if (superblock_info_->GetValidInodeCount() == fsck_.result.valid_inode_count) {
FX_LOGS(INFO) << str << "[OK] : " << fsck_.result.valid_inode_count;
} else {
FX_LOGS(INFO) << str << "[FAILED] : " << superblock_info_->GetValidInodeCount()
<< "(ckpt) != " << fsck_.result.valid_inode_count;
status = ZX_ERR_INTERNAL;
}
str = "\tnext_blkoff in curseg ";
std::string segnums;
bool is_free = true;
for (uint32_t segtype = 0; segtype < kNrCursegType; ++segtype) {
if (VerifyCursegOffset(static_cast<CursegType>(segtype)) != ZX_OK) {
segnums += std::to_string(segtype);
segnums += " ";
is_free = false;
}
}
if (is_free) {
FX_LOGS(INFO) << str << "[OK]";
} else {
FX_LOGS(INFO) << str << "[FAILED] : " << "corrupted cursegs(" << segnums << ")";
status = ZX_ERR_INTERNAL;
}
str = "\tinline data in inodes";
if (fsck_.data_exist_flag_set.empty()) {
FX_LOGS(INFO) << str << "[OK]";
} else {
FX_LOGS(INFO) << str << "[FAILED]";
status = ZX_ERR_INTERNAL;
}
return status;
}
zx_status_t FsckWorker::RepairNat() {
CursegInfo *curseg = segment_manager_->CURSEG_I(CursegType::kCursegHotData);
BlockBuffer<SummaryBlock> &summary_block = curseg->sum_blk;
bool need_journal_update = false;
for (nid_t nid = 0; nid < fsck_.nr_nat_entries; ++nid) {
if (fsck_.nat_area_bitmap.GetOne(ToMsbFirst(nid))) {
FX_LOGS(INFO) << std::hex << "\tRemoving unreachable node [0x" << nid << "]";
// Lookup the journal first.
bool found = false;
for (int i = 0; i < NatsInCursum(*summary_block); ++i) {
if (LeToCpu(NidInJournal(*summary_block, i)) == nid) {
// If found, bring in the last entry.
summary_block->nat_j.entries[i].nid =
summary_block->nat_j.entries[LeToCpu(summary_block->n_nats) - 1].nid;
summary_block->n_nats =
CpuToLe(static_cast<uint16_t>(LeToCpu(summary_block->n_nats) - 1));
need_journal_update = true;
found = true;
break;
}
}
if (found) {
continue;
}
// If not found, go for the NAT.
block_t block_off = nid / kNatEntryPerBlock;
uint32_t entry_off = nid % kNatEntryPerBlock;
block_t seg_off = block_off >> superblock_info_->GetLogBlocksPerSeg();
block_t block_addr = (node_manager_->GetNatAddress() +
(seg_off << superblock_info_->GetLogBlocksPerSeg() << 1) +
(block_off & ((1 << superblock_info_->GetLogBlocksPerSeg()) - 1)));
if (node_manager_->GetNatBitmap().GetOne(ToMsbFirst(block_off))) {
block_addr += superblock_info_->GetBlocksPerSeg();
}
BlockBuffer<NatBlock> nat_block;
ZX_ASSERT(ReadBlock(&nat_block, block_addr) == ZX_OK);
nat_block->entries[entry_off] = RawNatEntry{};
if (auto status = WriteBlock(&nat_block, block_addr); status != ZX_OK) {
return status;
}
}
}
if (need_journal_update) {
if (superblock_info_->TestCpFlags(CpFlag::kCpCompactSumFlag)) {
block_t summary_addr = StartSummaryBlock();
BlockBuffer fs_block;
ReadBlock(&fs_block, summary_addr);
memcpy(&fs_block, &summary_block->n_nats, kSumJournalSize);
return WriteBlock(&fs_block, summary_addr);
} else {
if (superblock_info_->TestCpFlags(CpFlag::kCpUmountFlag)) {
return WriteBlock(
&summary_block,
SummaryBlockAddress(kNrCursegType, static_cast<int>(CursegType::kCursegHotData)));
} else {
return WriteBlock(
&summary_block,
SummaryBlockAddress(kNrCursegDataType, static_cast<int>(CursegType::kCursegHotData)));
}
}
}
return ZX_OK;
}
zx_status_t FsckWorker::RepairSit() {
SitInfo &sit_i = segment_manager_->GetSitInfo();
CursegInfo *curseg = segment_manager_->CURSEG_I(CursegType::kCursegColdData);
BlockBuffer<SummaryBlock> &summary_block = curseg->sum_blk;
bool need_journal_update = false;
uint8_t *raw_sit_bitmap = static_cast<uint8_t *>(sit_area_bitmap_.StorageUnsafe()->GetData());
uint8_t *raw_main_bitmap =
static_cast<uint8_t *>(fsck_.main_area_bitmap.StorageUnsafe()->GetData());
for (uint32_t segno = 0; segno < sit_area_bitmap_size_ / kSitVBlockMapSize; ++segno) {
uint32_t sit_byte_offset = segno * kSitVBlockMapSize;
if (memcmp(raw_sit_bitmap + sit_byte_offset, raw_main_bitmap + sit_byte_offset,
std::min(kSitVBlockMapSize, sit_area_bitmap_size_ - sit_byte_offset)) == 0x0) {
continue;
}
// Lookup the journal first.
bool found = false;
for (int i = 0; i < SitsInCursum(*summary_block); ++i) {
if (LeToCpu(SegnoInJournal(*summary_block, i)) == segno) {
SitEntry &sit = summary_block->sit_j.entries[i].se;
memcpy(sit.valid_map, raw_main_bitmap + sit_byte_offset, kSitVBlockMapSize);
sit.vblocks = 0;
for (uint8_t valid_bits : sit.valid_map) {
sit.vblocks += std::bitset<8>(valid_bits).count();
}
need_journal_update = true;
found = true;
break;
}
}
if (found) {
continue;
}
// If not found in journal, go for the Sit.
std::unique_ptr<BlockBuffer<SitBlock>> sit_block = GetCurrentSitPage(segno);
uint32_t offset = SitBlockOffset(segno);
block_t sit_block_addr = sit_i.sit_base_addr + offset;
if (sit_i.sit_bitmap.GetOne(ToMsbFirst(offset))) {
sit_block_addr += sit_i.sit_blocks;
}
SitEntry &sit_entry = (*sit_block)->entries[segment_manager_->SitEntryOffset(segno)];
memcpy(sit_entry.valid_map, raw_main_bitmap + sit_byte_offset, kSitVBlockMapSize);
sit_entry.vblocks = 0;
for (uint8_t valid_bits : sit_entry.valid_map) {
sit_entry.vblocks += std::bitset<8>(valid_bits).count();
}
if (auto status = WriteBlock(sit_block->get(), sit_block_addr); status != ZX_OK) {
return status;
}
}
if (need_journal_update) {
// Write the summary.
if (superblock_info_->TestCpFlags(CpFlag::kCpCompactSumFlag)) {
block_t summary_addr = StartSummaryBlock();
BlockBuffer<uint8_t> fs_block;
ReadBlock(&fs_block, summary_addr);
memcpy(fs_block.get<uint8_t>() + kSumJournalSize, &summary_block->n_sits, kSumJournalSize);
return WriteBlock(&fs_block, summary_addr);
} else {
if (superblock_info_->TestCpFlags(CpFlag::kCpUmountFlag)) {
return WriteBlock(
&summary_block,
SummaryBlockAddress(kNrCursegType, static_cast<int>(CursegType::kCursegColdData)));
} else {
return WriteBlock(
&summary_block,
SummaryBlockAddress(kNrCursegDataType, static_cast<int>(CursegType::kCursegColdData)));
}
}
}
return ZX_OK;
}
zx_status_t FsckWorker::RepairCheckpoint() {
bool need_update_checkpoint = false;
auto &ckpt_block = superblock_info_->GetCheckpointBlock();
if (superblock_info_->GetValidBlockCount() != fsck_.result.valid_block_count) {
ckpt_block->valid_block_count = fsck_.result.valid_block_count;
need_update_checkpoint = true;
}
if (superblock_info_->GetValidNodeCount() != fsck_.result.valid_node_count) {
ckpt_block->valid_node_count = fsck_.result.valid_node_count;
need_update_checkpoint = true;
}
if (superblock_info_->GetValidInodeCount() != fsck_.result.valid_inode_count) {
ckpt_block->valid_inode_count = fsck_.result.valid_inode_count;
need_update_checkpoint = true;
}
for (uint32_t segtype = 0; segtype < kNrCursegType; ++segtype) {
CursegInfo *curseg = segment_manager_->CURSEG_I(static_cast<CursegType>(segtype));
if (VerifyCursegOffset(static_cast<CursegType>(segtype)) != ZX_OK) {
uint16_t offset;
for (offset = 0; offset < GetBitSize(kSitVBlockMapSize); ++offset) {
block_t logical_offset = segment_manager_->GetMainAreaStartBlock() +
curseg->segno * superblock_info_->GetBlocksPerSeg() + offset;
if (!sit_area_bitmap_.GetOne(
ToMsbFirst(BlkoffFromMain(*segment_manager_, logical_offset)))) {
break;
}
}
if (segtype < static_cast<uint32_t>(CursegType::kCursegHotNode)) {
ckpt_block->cur_data_blkoff[segtype] = offset;
} else {
ckpt_block->cur_node_blkoff[segtype - static_cast<uint32_t>(CursegType::kCursegHotNode)] =
offset;
}
ckpt_block->alloc_type[segtype] = static_cast<uint8_t>(AllocMode::kSSR);
need_update_checkpoint = true;
}
}
if (need_update_checkpoint) {
BlockBuffer<Checkpoint> checkpoint(ckpt_block);
uint32_t crc =
F2fsCalCrc32(kF2fsSuperMagic, checkpoint.get(), LeToCpu(checkpoint->checksum_offset));
*(reinterpret_cast<uint32_t *>(checkpoint.get<uint8_t>() +
LeToCpu(checkpoint->checksum_offset))) = crc;
if (auto status = WriteBlock(&checkpoint, superblock_info_->StartCpAddr()); status != ZX_OK) {
return status;
}
if (auto status = WriteBlock(&checkpoint, superblock_info_->StartCpAddr() +
checkpoint->cp_pack_total_block_count - 1);
status != ZX_OK) {
return status;
}
}
return ZX_OK;
}
zx_status_t FsckWorker::RepairInodeLinks() {
for (auto const [nid, links] : fsck_.inode_link_map) {
BlockBuffer<Node> node_block;
auto node_info_or = ReadNodeBlock(nid, node_block);
if (node_info_or.is_error()) {
return ZX_ERR_INTERNAL;
}
auto node_info = std::move(*node_info_or);
node_block->i.i_links = CpuToLe(links.actual_links);
if (WriteBlock(&node_block, node_info.blk_addr) != ZX_OK) {
return ZX_ERR_INTERNAL;
}
}
return ZX_OK;
}
zx_status_t FsckWorker::RepairDataExistFlag() {
for (auto const nid : fsck_.data_exist_flag_set) {
BlockBuffer<Node> node_block;
auto node_info_or = ReadNodeBlock(nid, node_block);
if (node_info_or.is_error()) {
return ZX_ERR_INTERNAL;
}
auto node_info = std::move(*node_info_or);
node_block->i.i_inline |= kDataExist;
if (WriteBlock(&node_block, node_info.blk_addr) != ZX_OK) {
return ZX_ERR_INTERNAL;
}
}
return ZX_OK;
}
zx_status_t FsckWorker::Repair() {
if (auto ret = RepairNat(); ret != ZX_OK) {
return ret;
}
if (auto ret = RepairSit(); ret != ZX_OK) {
return ret;
}
if (auto ret = RepairCheckpoint(); ret != ZX_OK) {
return ret;
}
if (auto ret = RepairInodeLinks(); ret != ZX_OK) {
return ret;
}
if (auto ret = RepairDataExistFlag(); ret != ZX_OK) {
return ret;
}
return ZX_OK;
}
void FsckWorker::PrintInodeInfo(const Inode &inode) {
uint32_t namelen = LeToCpu(inode.i_namelen);
DisplayMember(sizeof(uint32_t), inode.i_mode, "i_mode");
DisplayMember(sizeof(uint32_t), inode.i_uid, "i_uid");
DisplayMember(sizeof(uint32_t), inode.i_gid, "i_gid");
DisplayMember(sizeof(uint32_t), inode.i_links, "i_links");
DisplayMember(sizeof(uint64_t), inode.i_size, "i_size");
DisplayMember(sizeof(uint64_t), inode.i_blocks, "i_blocks");
DisplayMember(sizeof(uint64_t), inode.i_atime, "i_atime");
DisplayMember(sizeof(uint32_t), inode.i_atime_nsec, "i_atime_nsec");
DisplayMember(sizeof(uint64_t), inode.i_ctime, "i_ctime");
DisplayMember(sizeof(uint32_t), inode.i_ctime_nsec, "i_ctime_nsec");
DisplayMember(sizeof(uint64_t), inode.i_mtime, "i_mtime");
DisplayMember(sizeof(uint32_t), inode.i_mtime_nsec, "i_mtime_nsec");
DisplayMember(sizeof(uint32_t), inode.i_generation, "i_generation");
DisplayMember(sizeof(uint32_t), inode.i_current_depth, "i_current_depth");
DisplayMember(sizeof(uint32_t), inode.i_xattr_nid, "i_xattr_nid");
DisplayMember(sizeof(uint32_t), inode.i_flags, "i_flags");
DisplayMember(sizeof(uint32_t), inode.i_pino, "i_pino");
if (namelen) {
char name[kMaxNameLen];
DisplayMember(sizeof(uint32_t), inode.i_namelen, "i_namelen");
std::memcpy(name, inode.i_name, kMaxNameLen);
name[std::min(namelen, kMaxNameLen)] = '\0';
DisplayMember(sizeof(char), name, "i_name");
}
FX_LOGS(INFO) << "\ti_ext: fofs: " << std::hex << inode.i_ext.fofs
<< ", blkaddr: " << inode.i_ext.blk_addr << ", len: " << inode.i_ext.len;
DisplayMember(sizeof(uint32_t), inode.i_addr[0], "i_addr[0]"); // Pointers to data blocks
DisplayMember(sizeof(uint32_t), inode.i_addr[1], "i_addr[1]"); // Pointers to data blocks
DisplayMember(sizeof(uint32_t), inode.i_addr[2], "i_addr[2]"); // Pointers to data blocks
DisplayMember(sizeof(uint32_t), inode.i_addr[3], "i_addr[3]"); // Pointers to data blocks
for (uint32_t i = 4; i < AddrsPerInode(&inode); ++i) {
if (inode.i_addr[i] != 0x0) {
FX_LOGS(INFO) << "\ti_addr[0x" << std::hex << i << "] points data block [0x"
<< inode.i_addr[i] << "]";
break;
}
}
DisplayMember(sizeof(uint32_t), inode.i_nid[0], "i_nid[0]"); // direct
DisplayMember(sizeof(uint32_t), inode.i_nid[1], "i_nid[1]"); // direct
DisplayMember(sizeof(uint32_t), inode.i_nid[2], "i_nid[2]"); // indirect
DisplayMember(sizeof(uint32_t), inode.i_nid[3], "i_nid[3]"); // indirect
DisplayMember(sizeof(uint32_t), inode.i_nid[4], "i_nid[4]"); // double indirect
}
void FsckWorker::PrintNodeInfo(const Node &node_block) {
nid_t ino = LeToCpu(node_block.footer.ino);
nid_t nid = LeToCpu(node_block.footer.nid);
if (ino == nid) {
FX_LOGS(INFO) << "\t== node [0x" << std::hex << nid << ":" << nid << "] is inode ==";
PrintInodeInfo(node_block.i);
} else {
uint32_t *dump_blk = (uint32_t *)&node_block;
FX_LOGS(INFO) << "\t== node [0x" << std::hex << nid << ":" << nid
<< "] is direct or indirect ==";
for (int i = 0; i <= 10; ++i) { // MSG (0)
FX_LOGS(INFO) << "\t[" << i << "]\t\t\t[0x" << dump_blk[i] << " : " << dump_blk[i] << "]";
}
}
}
void FsckWorker::PrintRawSuperblockInfo() {
const Superblock &sb = superblock_info_->GetSuperblock();
FX_LOGS(INFO) << "==== f2fs superblock ====";
DisplayMember(sizeof(uint32_t), sb.magic, "magic");
DisplayMember(sizeof(uint32_t), sb.major_ver, "major_ver");
DisplayMember(sizeof(uint32_t), sb.minor_ver, "minor_ver");
DisplayMember(sizeof(uint32_t), sb.log_sectorsize, "log_sectorsize");
DisplayMember(sizeof(uint32_t), sb.log_sectors_per_block, "log_sectors_per_block");
DisplayMember(sizeof(uint32_t), sb.log_blocksize, "log_blocksize");
DisplayMember(sizeof(uint32_t), sb.log_blocks_per_seg, "log_blocks_per_seg");
DisplayMember(sizeof(uint32_t), sb.segs_per_sec, "segs_per_sec");
DisplayMember(sizeof(uint32_t), sb.secs_per_zone, "secs_per_zone");
DisplayMember(sizeof(uint32_t), sb.checksum_offset, "checksum_offset");
DisplayMember(sizeof(uint64_t), sb.block_count, "block_count");
DisplayMember(sizeof(uint32_t), sb.section_count, "section_count");
DisplayMember(sizeof(uint32_t), sb.segment_count, "segment_count");
DisplayMember(sizeof(uint32_t), sb.segment_count_ckpt, "segment_count_ckpt");
DisplayMember(sizeof(uint32_t), sb.segment_count_sit, "segment_count_sit");
DisplayMember(sizeof(uint32_t), sb.segment_count_nat, "segment_count_nat");
DisplayMember(sizeof(uint32_t), sb.segment_count_ssa, "segment_count_ssa");
DisplayMember(sizeof(uint32_t), sb.segment_count_main, "segment_count_main");
DisplayMember(sizeof(uint32_t), sb.segment0_blkaddr, "segment0_blkaddr");
DisplayMember(sizeof(uint32_t), sb.cp_blkaddr, "cp_blkaddr");
DisplayMember(sizeof(uint32_t), sb.sit_blkaddr, "sit_blkaddr");
DisplayMember(sizeof(uint32_t), sb.nat_blkaddr, "nat_blkaddr");
DisplayMember(sizeof(uint32_t), sb.ssa_blkaddr, "ssa_blkaddr");
DisplayMember(sizeof(uint32_t), sb.main_blkaddr, "main_blkaddr");
DisplayMember(sizeof(uint32_t), sb.root_ino, "root_ino");
DisplayMember(sizeof(uint32_t), sb.node_ino, "node_ino");
DisplayMember(sizeof(uint32_t), sb.meta_ino, "meta_ino");
DisplayMember(sizeof(uint32_t), sb.cp_payload, "cp_payload");
}
void FsckWorker::PrintCheckpointInfo() {
const Checkpoint &cp = superblock_info_->GetCheckpoint();
uint32_t alloc_type;
FX_LOGS(INFO) << "==== f2fs checkpoint pack ====";
DisplayMember(sizeof(uint64_t), cp.checkpoint_ver, "checkpoint_ver");
DisplayMember(sizeof(uint64_t), cp.user_block_count, "user_block_count");
DisplayMember(sizeof(uint64_t), cp.valid_block_count, "valid_block_count");
DisplayMember(sizeof(uint32_t), cp.rsvd_segment_count, "rsvd_segment_count");
DisplayMember(sizeof(uint32_t), cp.overprov_segment_count, "overprov_segment_count");
DisplayMember(sizeof(uint32_t), cp.free_segment_count, "free_segment_count");
alloc_type = cp.alloc_type[static_cast<int>(CursegType::kCursegHotNode)];
DisplayMember(sizeof(uint32_t), alloc_type, "alloc_type[CursegType::kCursegHotNode]");
alloc_type = cp.alloc_type[static_cast<int>(CursegType::kCursegWarmNode)];
DisplayMember(sizeof(uint32_t), alloc_type, "alloc_type[CursegType::kCursegWarmNode]");
alloc_type = cp.alloc_type[static_cast<int>(CursegType::kCursegColdNode)];
DisplayMember(sizeof(uint32_t), alloc_type, "alloc_type[CursegType::kCursegColdNode]");
alloc_type = cp.alloc_type[static_cast<int>(CursegType::kCursegHotNode)];
DisplayMember(sizeof(uint32_t), cp.cur_node_segno[0], "cur_node_segno[0]");
DisplayMember(sizeof(uint32_t), cp.cur_node_segno[1], "cur_node_segno[1]");
DisplayMember(sizeof(uint32_t), cp.cur_node_segno[2], "cur_node_segno[2]");
DisplayMember(sizeof(uint32_t), cp.cur_node_blkoff[0], "cur_node_blkoff[0]");
DisplayMember(sizeof(uint32_t), cp.cur_node_blkoff[1], "cur_node_blkoff[1]");
DisplayMember(sizeof(uint32_t), cp.cur_node_blkoff[2], "cur_node_blkoff[2]");
alloc_type = cp.alloc_type[static_cast<int>(CursegType::kCursegHotData)];
DisplayMember(sizeof(uint32_t), alloc_type, "alloc_type[CursegType::kCursegHotData]");
alloc_type = cp.alloc_type[static_cast<int>(CursegType::kCursegWarmData)];
DisplayMember(sizeof(uint32_t), alloc_type, "alloc_type[CursegType::kCursegWarmData]");
alloc_type = cp.alloc_type[static_cast<int>(CursegType::kCursegColdData)];
DisplayMember(sizeof(uint32_t), alloc_type, "alloc_type[CursegType::kCursegColdData]");
DisplayMember(sizeof(uint32_t), cp.cur_data_segno[0], "cur_data_segno[0]");
DisplayMember(sizeof(uint32_t), cp.cur_data_segno[1], "cur_data_segno[1]");
DisplayMember(sizeof(uint32_t), cp.cur_data_segno[2], "cur_data_segno[2]");
DisplayMember(sizeof(uint32_t), cp.cur_data_blkoff[0], "cur_data_blkoff[0]");
DisplayMember(sizeof(uint32_t), cp.cur_data_blkoff[1], "cur_data_blkoff[1]");
DisplayMember(sizeof(uint32_t), cp.cur_data_blkoff[2], "cur_data_blkoff[2]");
DisplayMember(sizeof(uint32_t), cp.ckpt_flags, "ckpt_flags");
DisplayMember(sizeof(uint32_t), cp.cp_pack_total_block_count, "cp_pack_total_block_count");
DisplayMember(sizeof(uint32_t), cp.cp_pack_start_sum, "cp_pack_start_sum");
DisplayMember(sizeof(uint32_t), cp.valid_node_count, "valid_node_count");
DisplayMember(sizeof(uint32_t), cp.valid_inode_count, "valid_inode_count");
DisplayMember(sizeof(uint32_t), cp.next_free_nid, "next_free_nid");
DisplayMember(sizeof(uint32_t), cp.sit_ver_bitmap_bytesize, "sit_ver_bitmap_bytesize");
DisplayMember(sizeof(uint32_t), cp.nat_ver_bitmap_bytesize, "nat_ver_bitmap_bytesize");
DisplayMember(sizeof(uint32_t), cp.checksum_offset, "checksum_offset");
DisplayMember(sizeof(uint64_t), cp.elapsed_time, "elapsed_time");
}
zx_status_t FsckWorker::GetValidSuperblock() {
if (auto sb_or = LoadSuperblock(*bc_); sb_or.is_error()) {
return ZX_ERR_NOT_FOUND;
} else {
MountOptions options;
options.SetValue(MountOption::kActiveLogs, kNrCursegType);
superblock_info_ = std::make_unique<SuperblockInfo>(std::move(*sb_or));
}
return ZX_OK;
}
zx::result<std::pair<std::unique_ptr<BlockBuffer<Checkpoint>>, uint64_t>>
FsckWorker::ValidateCheckpoint(block_t cp_addr) {
block_t blk_size = superblock_info_->GetBlocksize();
uint64_t cur_version = 0, pre_version = 0;
uint32_t crc = 0;
uint32_t crc_offset;
auto cp_block_ptr = std::make_unique<BlockBuffer<Checkpoint>>();
auto &cp_block = *cp_block_ptr;
// Read the 1st cp block in this CP pack
if (ReadBlock(&cp_block, cp_addr) != ZX_OK) {
return zx::error(ZX_ERR_INTERNAL);
}
crc_offset = LeToCpu(cp_block->checksum_offset);
if (crc_offset >= blk_size) {
return zx::error(ZX_ERR_INTERNAL);
}
crc = *reinterpret_cast<uint32_t *>(cp_block.get<uint8_t>() + crc_offset);
if (!F2fsCrcValid(crc, cp_block.get(), crc_offset)) {
return zx::error(ZX_ERR_INTERNAL);
}
pre_version = LeToCpu(cp_block->checkpoint_ver);
// Read the 2nd cp block in this CP pack
cp_addr += LeToCpu(cp_block->cp_pack_total_block_count) - 1;
if (ReadBlock(&cp_block, cp_addr) != ZX_OK) {
return zx::error(ZX_ERR_INTERNAL);
}
crc_offset = LeToCpu(cp_block->checksum_offset);
if (crc_offset >= blk_size) {
return zx::error(ZX_ERR_INTERNAL);
}
crc = *reinterpret_cast<uint32_t *>(cp_block.get<uint8_t>() + crc_offset);
if (!F2fsCrcValid(crc, cp_block.get(), crc_offset)) {
return zx::error(ZX_ERR_INTERNAL);
}
cur_version = LeToCpu(cp_block->checkpoint_ver);
if (cur_version == pre_version) {
return zx::ok(std::pair<std::unique_ptr<BlockBuffer<Checkpoint>>, uint64_t>{
std::move(cp_block_ptr), cur_version});
}
return zx::error(ZX_ERR_INTERNAL);
}
zx_status_t FsckWorker::GetValidCheckpoint() {
const Superblock &raw_sb = superblock_info_->GetSuperblock();
zx::result<std::pair<std::unique_ptr<BlockBuffer<Checkpoint>>, uint64_t>> current =
zx::error(ZX_ERR_NOT_FOUND);
block_t cp_start_blk_no = 0;
for (auto checkpoint_start :
{LeToCpu(raw_sb.cp_blkaddr),
LeToCpu(raw_sb.cp_blkaddr) + (1 << LeToCpu(raw_sb.log_blocks_per_seg))}) {
auto checkpoint_or = ValidateCheckpoint(checkpoint_start);
if (checkpoint_or.is_error()) {
continue;
}
if (current.is_error() || VerAfter(checkpoint_or->second, current->second)) {
current = std::move(checkpoint_or);
cp_start_blk_no = checkpoint_start;
}
}
if (current.is_error()) {
return current.error_value();
}
superblock_info_->SetCheckpoint(*current->first.get());
if (raw_sb.cp_payload) {
superblock_info_->SetExtraSitBitmap(raw_sb.cp_payload * kBlockSize);
for (uint32_t i = 0; i < raw_sb.cp_payload; ++i) {
BlockBuffer blk;
ReadBlock(&blk, cp_start_blk_no + 1 + i);
CloneBits(superblock_info_->GetExtraSitBitmap(), &blk, GetBitSize(i * kBlockSize),
GetBitSize(kBlockSize));
}
}
return ZX_OK;
}
zx_status_t FsckWorker::InitNodeManager() {
const Superblock &sb_raw = superblock_info_->GetSuperblock();
uint32_t nat_segs, nat_blocks;
node_manager_->SetNatAddress(LeToCpu(sb_raw.nat_blkaddr));
// segment_count_nat includes pair segment so divide to 2.
nat_segs = LeToCpu(sb_raw.segment_count_nat) >> 1;
nat_blocks = nat_segs << LeToCpu(sb_raw.log_blocks_per_seg);
node_manager_->SetMaxNid(kNatEntryPerBlock * nat_blocks);
node_manager_->SetNextScanNid(LeToCpu(superblock_info_->GetCheckpoint().next_free_nid));
if (zx_status_t status = node_manager_->AllocNatBitmap(superblock_info_->GetNatBitmapSize());
status != ZX_OK) {
return ZX_ERR_NO_MEMORY;
}
// copy version bitmap
node_manager_->SetNatBitmap(superblock_info_->GetNatBitmap());
return ZX_OK;
}
zx_status_t FsckWorker::BuildNodeManager() {
if (node_manager_ = std::make_unique<NodeManager>(superblock_info_.get());
node_manager_ == nullptr) {
return ZX_ERR_NO_MEMORY;
}
if (zx_status_t err = InitNodeManager(); err != ZX_OK) {
return err;
}
return ZX_OK;
}
zx_status_t FsckWorker::BuildSitInfo() {
const Superblock &raw_sb = superblock_info_->GetSuperblock();
const Checkpoint &ckpt = superblock_info_->GetCheckpoint();
std::unique_ptr<SitInfo> sit_i;
uint32_t sit_segs;
uint32_t bitmap_size;
if (sit_i = std::make_unique<SitInfo>(); sit_i == nullptr) {
return ZX_ERR_NO_MEMORY;
}
sit_i->sentries = std::make_unique<SegmentEntry[]>(segment_manager_->TotalSegs());
for (uint32_t start = 0; start < segment_manager_->TotalSegs(); ++start) {
sit_i->sentries[start].cur_valid_map.Reset(GetBitSize(kSitVBlockMapSize));
sit_i->sentries[start].ckpt_valid_map.Reset(GetBitSize(kSitVBlockMapSize));
}
sit_segs = LeToCpu(raw_sb.segment_count_sit) >> 1;
bitmap_size = superblock_info_->GetSitBitmapSize();
sit_i->sit_bitmap.Reset(GetBitSize(bitmap_size));
CloneBits(sit_i->sit_bitmap, superblock_info_->GetSitBitmap(), 0, GetBitSize(bitmap_size));
sit_i->sit_base_addr = LeToCpu(raw_sb.sit_blkaddr);
sit_i->sit_blocks = sit_segs << superblock_info_->GetLogBlocksPerSeg();
sit_i->written_valid_blocks = LeToCpu(safemath::checked_cast<uint32_t>(ckpt.valid_block_count));
sit_i->bitmap_size = bitmap_size;
sit_i->dirty_sentries = 0;
sit_i->elapsed_time = LeToCpu(ckpt.elapsed_time);
segment_manager_->SetSitInfo(std::move(sit_i));
return ZX_OK;
}
void FsckWorker::ResetCurseg(CursegType type, int modified) {
CursegInfo *curseg = segment_manager_->CURSEG_I(type);
curseg->segno = curseg->next_segno;
curseg->zone = segment_manager_->GetZoneNoFromSegNo(curseg->segno);
curseg->next_blkoff = 0;
curseg->next_segno = kNullSegNo;
}
zx_status_t FsckWorker::ReadCompactedSummaries() {
const Checkpoint &ckpt = superblock_info_->GetCheckpoint();
block_t start;
BlockBuffer<> fs_block;
uint32_t offset;
CursegInfo *curseg;
start = StartSummaryBlock();
ReadBlock(&fs_block, start++);
curseg = segment_manager_->CURSEG_I(CursegType::kCursegHotData);
memcpy(&curseg->sum_blk->n_nats, fs_block.get<uint8_t>(), kSumJournalSize);
curseg = segment_manager_->CURSEG_I(CursegType::kCursegColdData);
memcpy(&curseg->sum_blk->n_sits, fs_block.get<uint8_t>() + kSumJournalSize, kSumJournalSize);
offset = 2 * kSumJournalSize;
for (int32_t i = static_cast<int32_t>(CursegType::kCursegHotData);
i <= CursegType::kCursegColdData; ++i) {
unsigned short blk_off;
uint32_t segno;
curseg = segment_manager_->CURSEG_I(static_cast<CursegType>(i));
segno = LeToCpu(ckpt.cur_data_segno[i]);
blk_off = LeToCpu(ckpt.cur_data_blkoff[i]);
curseg->next_segno = segno;
ResetCurseg(static_cast<CursegType>(i), 0);
curseg->alloc_type = ckpt.alloc_type[i];
curseg->next_blkoff = blk_off;
if (curseg->alloc_type == static_cast<uint8_t>(AllocMode::kSSR)) {
blk_off = safemath::checked_cast<unsigned short>(superblock_info_->GetBlocksPerSeg());
}
for (uint32_t j = 0; j < blk_off; ++j) {
memcpy(&curseg->sum_blk->entries[j], &fs_block.get<uint8_t>()[offset], kSummarySize);
offset += kSummarySize;
if (offset + kSummarySize <= kPageSize - kSumFooterSize) {
continue;
}
memset(&fs_block, 0, kPageSize);
ReadBlock(&fs_block, start++);
offset = 0;
}
}
return ZX_OK;
}
zx_status_t FsckWorker::RestoreNodeSummary(uint32_t segno, SummaryBlock &summary_block) {
BlockBuffer<Node> node_block;
block_t addr = segment_manager_->StartBlock(segno);
// scan the node segment
for (uint32_t i = 0; i < superblock_info_->GetBlocksPerSeg(); ++i, ++addr) {
if (ReadBlock(&node_block, addr)) {
break;
}
summary_block.entries[i].nid = node_block->footer.nid;
}
return ZX_OK;
}
zx_status_t FsckWorker::ReadNormalSummaries(CursegType type) {
const Checkpoint &ckpt = superblock_info_->GetCheckpoint();
unsigned short blk_off;
uint32_t segno = 0;
block_t block_address = 0;
if (IsDataSeg(type)) {
segno = LeToCpu(ckpt.cur_data_segno[static_cast<int>(type)]);
blk_off = LeToCpu(ckpt.cur_data_blkoff[type - CursegType::kCursegHotData]);
if (superblock_info_->TestCpFlags(CpFlag::kCpUmountFlag)) {
block_address = SummaryBlockAddress(kNrCursegType, static_cast<int>(type));
} else {
block_address = SummaryBlockAddress(kNrCursegDataType, static_cast<int>(type));
}
} else {
segno = LeToCpu(ckpt.cur_node_segno[type - CursegType::kCursegHotNode]);
blk_off = LeToCpu(ckpt.cur_node_blkoff[type - CursegType::kCursegHotNode]);
if (superblock_info_->TestCpFlags(CpFlag::kCpUmountFlag)) {
block_address = SummaryBlockAddress(kNrCursegNodeType, type - CursegType::kCursegHotNode);
} else {
block_address = segment_manager_->GetSumBlock(segno);
}
}
BlockBuffer<SummaryBlock> summary_block;
ReadBlock(&summary_block, block_address);
if (IsNodeSeg(type)) {
if (superblock_info_->TestCpFlags(CpFlag::kCpUmountFlag)) {
#if 0 // do not change original value
Summary *sum_entry = &sum_blk->entries[0];
for (uint64_t i = 0; i < superblock_info->GetBlocksPerSeg(); ++i, ++sum_entry) {
sum_entry->version = 0;
sum_entry->ofs_in_node = 0;
}
#endif
} else {
if (zx_status_t ret = RestoreNodeSummary(segno, *summary_block); ret != ZX_OK) {
return ret;
}
}
}
CursegInfo *curseg = segment_manager_->CURSEG_I(type);
memcpy(curseg->sum_blk.get(), summary_block.get(), kPageSize);
curseg->next_segno = segno;
ResetCurseg(type, 0);
curseg->alloc_type = ckpt.alloc_type[static_cast<int>(type)];
curseg->next_blkoff = blk_off;
return ZX_OK;
}
zx_status_t FsckWorker::RestoreCursegSummaries() {
int32_t type = static_cast<int32_t>(CursegType::kCursegHotData);
if (superblock_info_->TestCpFlags(CpFlag::kCpCompactSumFlag)) {
if (zx_status_t ret = ReadCompactedSummaries(); ret != ZX_OK) {
return ret;
}
type = static_cast<int32_t>(CursegType::kCursegHotNode);
}
for (; type <= CursegType::kCursegColdNode; ++type) {
if (zx_status_t ret = ReadNormalSummaries(static_cast<CursegType>(type)); ret != ZX_OK) {
return ret;
}
}
return ZX_OK;
}
zx_status_t FsckWorker::BuildCurseg() {
for (int i = 0; i < kNrCursegType; ++i) {
CursegInfo *curseg = segment_manager_->CURSEG_I(static_cast<CursegType>(i));
memset(curseg->sum_blk.get(), 0, kBlockSize);
curseg->segno = kNullSegNo;
curseg->next_blkoff = 0;
}
return RestoreCursegSummaries();
}
inline void FsckWorker::CheckSegmentRange(uint32_t segno) {
uint32_t end_segno = segment_manager_->GetSegmentsCount() - 1;
ZX_ASSERT(segno <= end_segno);
}
std::unique_ptr<BlockBuffer<SitBlock>> FsckWorker::GetCurrentSitPage(uint32_t segno) {
SitInfo &sit_i = segment_manager_->GetSitInfo();
uint32_t offset = SitBlockOffset(segno);
block_t block_address = sit_i.sit_base_addr + offset;
auto sit_block_ptr = std::make_unique<BlockBuffer<SitBlock>>();
CheckSegmentRange(segno);
// calculate sit block address
if (sit_i.sit_bitmap.GetOne(ToMsbFirst(offset))) {
block_address += sit_i.sit_blocks;
}
ReadBlock(sit_block_ptr->get(), block_address);
return sit_block_ptr;
}
void FsckWorker::CheckBlockCount(uint32_t segno, const SitEntry &raw_sit) {
uint32_t end_segno = segment_manager_->GetSegmentsCount() - 1;
int valid_blocks = 0;
// check segment usage
ZX_ASSERT(GetSitVblocks(raw_sit) <= superblock_info_->GetBlocksPerSeg());
// check boundary of a given segment number
ZX_ASSERT(segno <= end_segno);
// check bitmap with valid block count
for (uint64_t i = 0; i < superblock_info_->GetBlocksPerSeg(); ++i) {
if (TestBit(raw_sit.valid_map, ToMsbFirst(i), kSitVBlockMapSizeInBit)) {
++valid_blocks;
}
}
ZX_ASSERT(GetSitVblocks(raw_sit) == valid_blocks);
}
void FsckWorker::SegmentInfoFromRawSit(SegmentEntry &segment_entry, const SitEntry &raw_sit) {
segment_entry.valid_blocks = GetSitVblocks(raw_sit);
segment_entry.ckpt_valid_blocks = GetSitVblocks(raw_sit);
CloneBits<RawBitmapHeap>(segment_entry.cur_valid_map, raw_sit.valid_map, 0,
GetBitSize(kSitVBlockMapSize));
CloneBits<RawBitmapHeap>(segment_entry.ckpt_valid_map, raw_sit.valid_map, 0,
GetBitSize(kSitVBlockMapSize));
segment_entry.type = GetSitType(raw_sit);
segment_entry.mtime = LeToCpu(raw_sit.mtime);
}
SegmentEntry &FsckWorker::GetSegmentEntry(uint32_t segno) {
SitInfo &sit_i = segment_manager_->GetSitInfo();
return sit_i.sentries[segno];
}
SegType FsckWorker::GetSumBlockInfo(uint32_t segno, BlockBuffer<SummaryBlock> &summary_block) {
const Checkpoint &ckpt = superblock_info_->GetCheckpoint();
CursegInfo *curseg;
block_t ssa_blk;
ssa_blk = segment_manager_->GetSumBlock(segno);
for (int type = 0; type < kNrCursegNodeType; ++type) {
if (segno == ckpt.cur_node_segno[type]) {
curseg = segment_manager_->CURSEG_I(CursegType::kCursegHotNode + type);
memcpy(summary_block.get(), curseg->sum_blk.get(), kBlockSize);
return SegType::kSegTypeCurNode; // current node seg was not stored
}
}
for (int type = 0; type < kNrCursegDataType; ++type) {
if (segno == ckpt.cur_data_segno[type]) {
curseg = segment_manager_->CURSEG_I(CursegType::kCursegHotData + type);
memcpy(summary_block.get(), curseg->sum_blk.get(), kBlockSize);
ZX_ASSERT(!IsSumNodeSeg(summary_block->footer));
if (fsck_options_.verbose) {
FX_LOGS(INFO) << "\tsegno [0x" << std::hex << segno << "] is current data seg[0x" << type
<< "]";
}
return SegType::kSegTypeCurData; // current data seg was not stored
}
}
ZX_ASSERT(ReadBlock(&summary_block, ssa_blk) == ZX_OK);
if (IsSumNodeSeg(summary_block->footer)) {
return SegType::kSegTypeNode;
}
return SegType::kSegTypeData;
}
uint32_t FsckWorker::GetSegmentNumber(uint32_t block_address) {
return static_cast<uint32_t>(BlkoffFromMain(*segment_manager_, block_address) >>
superblock_info_->GetLogBlocksPerSeg());
}
std::pair<SegType, Summary> FsckWorker::GetSummaryEntry(uint32_t block_address) {
uint32_t segno, offset;
Summary summary_entry;
segno = GetSegmentNumber(block_address);
offset = OffsetInSegment(*superblock_info_, *segment_manager_, block_address);
BlockBuffer<SummaryBlock> summary_block;
auto type = GetSumBlockInfo(segno, summary_block);
memcpy(&summary_entry, &summary_block->entries[offset], sizeof(Summary));
return {type, summary_entry};
}
zx::result<RawNatEntry> FsckWorker::GetNatEntry(nid_t nid) {
block_t block_off;
block_t block_addr;
block_t seg_off;
block_t entry_off;
if ((nid / kNatEntryPerBlock) > fsck_.nr_nat_entries) {
FX_LOGS(WARNING) << "\tnid is over max nid";
return zx::error(ZX_ERR_INVALID_ARGS);
}
if (auto result = LookupNatInJournal(nid); result.is_ok()) {
return result;
}
block_off = nid / kNatEntryPerBlock;
entry_off = nid % kNatEntryPerBlock;
seg_off = block_off >> superblock_info_->GetLogBlocksPerSeg();
block_addr =
(node_manager_->GetNatAddress() + (seg_off << superblock_info_->GetLogBlocksPerSeg() << 1) +
(block_off & ((1 << superblock_info_->GetLogBlocksPerSeg()) - 1)));
if (node_manager_->GetNatBitmap().GetOne(ToMsbFirst(block_off))) {
block_addr += superblock_info_->GetBlocksPerSeg();
}
BlockBuffer<NatBlock> nat_block;
ZX_ASSERT(ReadBlock(&nat_block, block_addr) == ZX_OK);
return zx::ok(nat_block->entries[entry_off]);
}
zx::result<NodeInfo> FsckWorker::GetNodeInfo(nid_t nid) {
NodeInfo node_info;
auto result = GetNatEntry(nid);
if (result.is_error()) {
return result.take_error();
}
RawNatEntry raw_nat = *result;
node_info.nid = nid;
NodeInfoFromRawNat(node_info, raw_nat);
return zx::ok(node_info);
}
void FsckWorker::BuildSitEntries() {
SitInfo &sit_i = segment_manager_->GetSitInfo();
CursegInfo *curseg = segment_manager_->CURSEG_I(CursegType::kCursegColdData);
SummaryBlock *sum = &curseg->sum_blk;
for (uint32_t segno = 0; segno < segment_manager_->TotalSegs(); ++segno) {
SegmentEntry &segment_entry = sit_i.sentries[segno];
SitEntry sit;
bool found = false;
for (int i = 0; i < SitsInCursum(*sum); ++i) {
if (LeToCpu(SegnoInJournal(*sum, i)) == segno) {
sit = sum->sit_j.entries[i].se;
found = true;
break;
}
}
if (!found) {
std::unique_ptr<BlockBuffer<SitBlock>> sit_block = GetCurrentSitPage(segno);
sit = (*sit_block)->entries[segment_manager_->SitEntryOffset(segno)];
}
CheckBlockCount(segno, sit);
SegmentInfoFromRawSit(segment_entry, sit);
}
}
zx_status_t FsckWorker::BuildSegmentManager() {
const Superblock &raw_super = superblock_info_->GetSuperblock();
const Checkpoint &ckpt = superblock_info_->GetCheckpoint();
if (segment_manager_ = std::make_unique<SegmentManager>(*superblock_info_);
segment_manager_ == nullptr) {
return ZX_ERR_NO_MEMORY;
}
// init sm info
segment_manager_->SetSegment0StartBlock(LeToCpu(raw_super.segment0_blkaddr));
segment_manager_->SetMainAreaStartBlock(LeToCpu(raw_super.main_blkaddr));
segment_manager_->SetSegmentsCount(LeToCpu(raw_super.segment_count));
segment_manager_->SetReservedSegmentsCount(LeToCpu(ckpt.rsvd_segment_count));
segment_manager_->SetOPSegmentsCount(LeToCpu(ckpt.overprov_segment_count));
segment_manager_->SetMainSegmentsCount(LeToCpu(raw_super.segment_count_main));
segment_manager_->SetSSAreaStartBlock(LeToCpu(raw_super.ssa_blkaddr));
if (auto status = BuildSitInfo(); status != ZX_OK) {
return status;
}
if (auto status = segment_manager_->BuildFreeSegmap(); status != ZX_OK) {
return status;
}
if (auto status = BuildCurseg(); status != ZX_OK) {
return status;
}
BuildSitEntries();
return ZX_OK;
}
void FsckWorker::BuildSitAreaBitmap() {
uint32_t vblocks = 0;
sit_area_bitmap_size_ = segment_manager_->GetMainSegmentsCount() * kSitVBlockMapSize;
sit_area_bitmap_.Reset(GetBitSize(sit_area_bitmap_size_));
uint8_t *raw_bitmap = static_cast<uint8_t *>(sit_area_bitmap_.StorageUnsafe()->GetData());
for (uint32_t segno = 0; segno < segment_manager_->GetMainSegmentsCount(); ++segno) {
SegmentEntry &segment_entry = GetSegmentEntry(segno);
CloneBits<RawBitmapHeap>(raw_bitmap, segment_entry.cur_valid_map, 0,
GetBitSize(kSitVBlockMapSize));
vblocks = 0;
for (uint64_t j = 0; j < kSitVBlockMapSize; ++j) {
vblocks += std::bitset<8>(*raw_bitmap++).count();
}
ZX_ASSERT(vblocks == segment_entry.valid_blocks);
if (segment_entry.valid_blocks == 0x0) {
if (superblock_info_->GetCheckpoint().cur_node_segno[0] == segno ||
superblock_info_->GetCheckpoint().cur_data_segno[0] == segno ||
superblock_info_->GetCheckpoint().cur_node_segno[1] == segno ||
superblock_info_->GetCheckpoint().cur_data_segno[1] == segno ||
superblock_info_->GetCheckpoint().cur_node_segno[2] == segno ||
superblock_info_->GetCheckpoint().cur_data_segno[2] == segno) {
continue;
}
} else {
ZX_ASSERT(segment_entry.valid_blocks <= 512);
}
}
}
zx::result<RawNatEntry> FsckWorker::LookupNatInJournal(nid_t nid) {
RawNatEntry raw_nat;
CursegInfo *curseg = segment_manager_->CURSEG_I(CursegType::kCursegHotData);
SummaryBlock *sum = &curseg->sum_blk;
for (int i = 0; i < NatsInCursum(*sum); ++i) {
if (LeToCpu(NidInJournal(*sum, i)) == nid) {
RawNatEntry ret = NatInJournal(*sum, i);
if (fsck_options_.verbose) {
FX_LOGS(INFO) << "\tnid [0x" << nid << "] in nat cache";
}
memcpy(&raw_nat, &ret, sizeof(RawNatEntry));
return zx::ok(raw_nat);
}
}
return zx::error(ZX_ERR_NOT_FOUND);
}
void FsckWorker::BuildNatAreaBitmap() {
const Superblock &raw_sb = superblock_info_->GetSuperblock();
nid_t nid, nr_nat_blks;
block_t block_off;
block_t block_addr;
block_t seg_off;
// Alloc & build nat entry bitmap
nr_nat_blks = (LeToCpu(raw_sb.segment_count_nat) / 2) << superblock_info_->GetLogBlocksPerSeg();
fsck_.nr_nat_entries = nr_nat_blks * kNatEntryPerBlock;
fsck_.nat_area_bitmap_size = CheckedDivRoundUp(fsck_.nr_nat_entries, kBitsPerByte);
fsck_.nat_area_bitmap.Reset(GetBitSize(fsck_.nat_area_bitmap_size));
for (block_off = 0; block_off < nr_nat_blks; ++block_off) {
seg_off = block_off >> superblock_info_->GetLogBlocksPerSeg();
block_addr = node_manager_->GetNatAddress() +
(seg_off << superblock_info_->GetLogBlocksPerSeg() << 1) +
(block_off & ((1 << superblock_info_->GetLogBlocksPerSeg()) - 1));
if (node_manager_->GetNatBitmap().GetOne(ToMsbFirst(block_off))) {
block_addr += superblock_info_->GetBlocksPerSeg();
}
BlockBuffer<NatBlock> nat_block;
ZX_ASSERT(ReadBlock(&nat_block, block_addr) == ZX_OK);
nid = block_off * kNatEntryPerBlock;
for (uint32_t i = 0; i < kNatEntryPerBlock; ++i) {
NodeInfo node_info;
node_info.nid = nid + i;
if ((nid + i) == superblock_info_->GetNodeIno() ||
(nid + i) == superblock_info_->GetMetaIno()) {
ZX_ASSERT(nat_block->entries[i].block_addr != 0x0);
continue;
}
if (auto result = LookupNatInJournal(nid + i); result.is_ok()) {
RawNatEntry raw_nat = *result;
NodeInfoFromRawNat(node_info, raw_nat);
if (node_info.blk_addr != kNullAddr) {
fsck_.nat_area_bitmap.SetOne(ToMsbFirst(nid + i));
++fsck_.result.valid_nat_entry_count;
}
} else {
NodeInfoFromRawNat(node_info, nat_block->entries[i]);
if (node_info.blk_addr != kNullAddr) {
ZX_ASSERT(nid + i != 0x0);
if (fsck_options_.verbose) {
FX_LOGS(INFO) << "\tnid[0x" << std::hex << nid + i << "] in nat entry [0x"
<< node_info.blk_addr << "] [0x" << node_info.ino << "]";
}
fsck_.nat_area_bitmap.SetOne(ToMsbFirst(nid + i));
++fsck_.result.valid_nat_entry_count;
}
}
}
}
if (fsck_options_.verbose) {
FX_LOGS(INFO) << "\tvalid nat entries (block_addr != 0x0) [0x" << std::hex
<< fsck_.result.valid_nat_entry_count << " : "
<< fsck_.result.valid_nat_entry_count << "]";
}
}
zx_status_t FsckWorker::DoMount() {
if (mounted_) {
DoUmount();
}
if (auto status = GetValidSuperblock(); status != ZX_OK) {
FX_LOGS(ERROR) << "\tCan't find a valid F2FS superblock: " << status;
return status;
}
if (auto status = GetValidCheckpoint(); status != ZX_OK) {
FX_LOGS(ERROR) << "\tCan't find valid checkpoint: " << status;
return status;
}
if (auto status = BuildSegmentManager(); status != ZX_OK) {
FX_LOGS(ERROR) << "\tbuild_segment_manager failed: " << status;
return status;
}
if (auto status = BuildNodeManager(); status != ZX_OK) {
FX_LOGS(ERROR) << "\tbuild_segment_manager failed: " << status;
return status;
}
BuildSitAreaBitmap();
mounted_ = true;
return ZX_OK;
}
void FsckWorker::DoUmount() {
if (!mounted_) {
return;
}
node_manager_.reset();
segment_manager_.reset();
mounted_ = false;
}
zx_status_t FsckWorker::DoFsck() {
if (auto status = Init(); status != ZX_OK) {
return status;
}
if (auto status = CheckOrphanNodes(); status != ZX_OK) {
return status;
}
// Traverse all inodes from root inode
if (zx_status_t ret = TraverseInode(superblock_info_->GetRootIno(), FileType::kFtDir);
ret != ZX_OK) {
return ret;
}
if (auto status = Verify(); status != ZX_OK) {
if (fsck_options_.repair) {
status = Repair();
FX_LOGS(INFO) << "repairing f2fs " << (status == ZX_OK ? "[OK]" : "[FAILED]");
}
return status;
}
return ZX_OK;
}
zx_status_t FsckWorker::Run() {
zx_status_t status = ZX_OK;
if (status = DoMount(); status != ZX_OK) {
return status;
}
status = DoFsck();
if (status != ZX_OK) {
FX_LOGS(INFO) << "f2fs corruption detected";
PrintRawSuperblockInfo();
PrintCheckpointInfo();
}
return status;
}
zx_status_t Fsck(std::unique_ptr<BcacheMapper> bc, const FsckOptions &options,
std::unique_ptr<BcacheMapper> *out) {
zx_status_t status;
FsckWorker fsck(std::move(bc), options);
status = fsck.Run();
if (out != nullptr) {
*out = fsck.Destroy();
}
return status;
}
} // namespace f2fs