s3fs-fuse/src/fdcache.cpp
Andrew Gaul 1043e08dfa Remove uses of implicit namespace std
Fixed via:

sed -i '/using namespace std/{N;d}' src/*.cpp
sed -i 's/ string/ std::string/g' src/*.cpp
sed -i 's/(string/(std::string/g' src/*.cpp
sed -i 's/\[string/\[std::string/g' src/*.cpp
sed -i 's/^string/std::string/g' src/*.cpp
sed -i 's/ ifstream/ std::ifstream/g' src/*.cpp
sed -i 's/ istringstream/ std::istringstream/g' src/*.cpp
sed -i 's/ ostringstream/ std::ostringstream/g' src/*.cpp
sed -i 's/ max(/ std::max(/g' src/*.cpp
sed -i 's/ min(/ std::min(/g' src/*.cpp
sed -i 's/ endl/ std::endl/g' src/*.cpp
2020-09-13 11:57:20 +09:00

933 lines
31 KiB
C++

/*
* s3fs - FUSE-based file system backed by Amazon S3
*
* Copyright(C) 2007 Takeshi Nakatani <ggtakec.com>
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version 2
* of the License, or (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
*/
#include <cstdio>
#include <cstdlib>
#include <cerrno>
#include <unistd.h>
#include <sys/types.h>
#include <dirent.h>
#include "common.h"
#include "s3fs.h"
#include "fdcache.h"
#include "s3fs_util.h"
#include "string_util.h"
#include "autolock.h"
//------------------------------------------------
// Symbols
//------------------------------------------------
#define TMPFILE_FOR_CHECK_HOLE "/tmp/.s3fs_hole_check.tmp"
//
// For cache directory top path
//
#if defined(P_tmpdir)
#define TMPFILE_DIR_0PATH P_tmpdir
#else
#define TMPFILE_DIR_0PATH "/tmp"
#endif
//
// The following symbols are used by FdManager::RawCheckAllCache().
//
#define CACHEDBG_FMT_DIR_PROB "Directory: %s"
#define CACHEDBG_FMT_HEAD "------------------------------------------------------------\n" \
"Check cache file and its stats file consistency\n" \
"------------------------------------------------------------"
#define CACHEDBG_FMT_FOOT "------------------------------------------------------------\n" \
"Summary - Total files: %d\n" \
" Detected error files: %d\n" \
" Detected error directories: %d\n" \
"------------------------------------------------------------"
#define CACHEDBG_FMT_FILE_OK "File: %s%s -> [OK] no problem"
#define CACHEDBG_FMT_FILE_PROB "File: %s%s"
#define CACHEDBG_FMT_DIR_PROB "Directory: %s"
#define CACHEDBG_FMT_ERR_HEAD " -> [E] there is a mark that data exists in stats, but there is no data in the cache file."
#define CACHEDBG_FMT_WARN_HEAD " -> [W] These show no data in stats, but there is evidence of data in the cache file(no problem)."
#define CACHEDBG_FMT_WARN_OPEN "\n -> [W] This file is currently open and may not provide accurate analysis results."
#define CACHEDBG_FMT_CRIT_HEAD " -> [C] %s"
#define CACHEDBG_FMT_CRIT_HEAD2 " -> [C] "
#define CACHEDBG_FMT_PROB_BLOCK " 0x%016zx(0x%016zx bytes)"
// [NOTE]
// NOCACHE_PATH_PREFIX symbol needs for not using cache mode.
// Now s3fs I/F functions in s3fs.cpp has left the processing
// to FdManager and FdEntity class. FdManager class manages
// the list of local file stat and file descriptor in conjunction
// with the FdEntity class.
// When s3fs is not using local cache, it means FdManager must
// return new temporary file descriptor at each opening it.
// Then FdManager caches fd by key which is dummy file path
// instead of real file path.
// This process may not be complete, but it is easy way can
// be realized.
//
#define NOCACHE_PATH_PREFIX_FORM " __S3FS_UNEXISTED_PATH_%lx__ / " // important space words for simply
//------------------------------------------------
// FdManager class variable
//------------------------------------------------
FdManager FdManager::singleton;
pthread_mutex_t FdManager::fd_manager_lock;
pthread_mutex_t FdManager::cache_cleanup_lock;
pthread_mutex_t FdManager::reserved_diskspace_lock;
bool FdManager::is_lock_init(false);
std::string FdManager::cache_dir;
bool FdManager::check_cache_dir_exist(false);
off_t FdManager::free_disk_space = 0;
std::string FdManager::check_cache_output;
bool FdManager::checked_lseek(false);
bool FdManager::have_lseek_hole(false);
//------------------------------------------------
// FdManager class methods
//------------------------------------------------
bool FdManager::SetCacheDir(const char* dir)
{
if(!dir || '\0' == dir[0]){
cache_dir = "";
}else{
cache_dir = dir;
}
return true;
}
bool FdManager::SetCacheCheckOutput(const char* path)
{
if(!path || '\0' == path[0]){
check_cache_output.erase();
}else{
check_cache_output = path;
}
return true;
}
bool FdManager::DeleteCacheDirectory()
{
if(FdManager::cache_dir.empty()){
return true;
}
std::string cache_path;
if(!FdManager::MakeCachePath(NULL, cache_path, false)){
return false;
}
if(!delete_files_in_dir(cache_path.c_str(), true)){
return false;
}
std::string mirror_path = FdManager::cache_dir + "/." + bucket + ".mirror";
if(!delete_files_in_dir(mirror_path.c_str(), true)){
return false;
}
return true;
}
int FdManager::DeleteCacheFile(const char* path)
{
S3FS_PRN_INFO3("[path=%s]", SAFESTRPTR(path));
if(!path){
return -EIO;
}
if(FdManager::cache_dir.empty()){
return 0;
}
std::string cache_path;
if(!FdManager::MakeCachePath(path, cache_path, false)){
return 0;
}
int result = 0;
if(0 != unlink(cache_path.c_str())){
if(ENOENT == errno){
S3FS_PRN_DBG("failed to delete file(%s): errno=%d", path, errno);
}else{
S3FS_PRN_ERR("failed to delete file(%s): errno=%d", path, errno);
}
result = -errno;
}
if(!CacheFileStat::DeleteCacheFileStat(path)){
if(ENOENT == errno){
S3FS_PRN_DBG("failed to delete stat file(%s): errno=%d", path, errno);
}else{
S3FS_PRN_ERR("failed to delete stat file(%s): errno=%d", path, errno);
}
if(0 != errno){
result = -errno;
}else{
result = -EIO;
}
}
return result;
}
bool FdManager::MakeCachePath(const char* path, std::string& cache_path, bool is_create_dir, bool is_mirror_path)
{
if(FdManager::cache_dir.empty()){
cache_path = "";
return true;
}
std::string resolved_path(FdManager::cache_dir);
if(!is_mirror_path){
resolved_path += "/";
resolved_path += bucket;
}else{
resolved_path += "/.";
resolved_path += bucket;
resolved_path += ".mirror";
}
if(is_create_dir){
int result;
if(0 != (result = mkdirp(resolved_path + mydirname(path), 0777))){
S3FS_PRN_ERR("failed to create dir(%s) by errno(%d).", path, result);
return false;
}
}
if(!path || '\0' == path[0]){
cache_path = resolved_path;
}else{
cache_path = resolved_path + SAFESTRPTR(path);
}
return true;
}
bool FdManager::CheckCacheTopDir()
{
if(FdManager::cache_dir.empty()){
return true;
}
std::string toppath(FdManager::cache_dir + "/" + bucket);
return check_exist_dir_permission(toppath.c_str());
}
bool FdManager::MakeRandomTempPath(const char* path, std::string& tmppath)
{
char szBuff[64];
sprintf(szBuff, NOCACHE_PATH_PREFIX_FORM, random()); // worry for performance, but maybe don't worry.
tmppath = szBuff;
tmppath += path ? path : "";
return true;
}
bool FdManager::SetCheckCacheDirExist(bool is_check)
{
bool old = FdManager::check_cache_dir_exist;
FdManager::check_cache_dir_exist = is_check;
return old;
}
bool FdManager::CheckCacheDirExist()
{
if(!FdManager::check_cache_dir_exist){
return true;
}
if(FdManager::cache_dir.empty()){
return true;
}
// check the directory
struct stat st;
if(0 != stat(cache_dir.c_str(), &st)){
S3FS_PRN_ERR("could not access to cache directory(%s) by errno(%d).", cache_dir.c_str(), errno);
return false;
}
if(!S_ISDIR(st.st_mode)){
S3FS_PRN_ERR("the cache directory(%s) is not directory.", cache_dir.c_str());
return false;
}
return true;
}
off_t FdManager::GetEnsureFreeDiskSpace()
{
AutoLock auto_lock(&FdManager::reserved_diskspace_lock);
return FdManager::free_disk_space;
}
off_t FdManager::SetEnsureFreeDiskSpace(off_t size)
{
AutoLock auto_lock(&FdManager::reserved_diskspace_lock);
off_t old = FdManager::free_disk_space;
FdManager::free_disk_space = size;
return old;
}
off_t FdManager::GetFreeDiskSpace(const char* path)
{
struct statvfs vfsbuf;
std::string ctoppath;
if(!FdManager::cache_dir.empty()){
ctoppath = FdManager::cache_dir + "/";
ctoppath = get_exist_directory_path(ctoppath); // existed directory
if(ctoppath != "/"){
ctoppath += "/";
}
}else{
ctoppath = TMPFILE_DIR_0PATH "/";
}
if(path && '\0' != *path){
ctoppath += path;
}else{
ctoppath += ".";
}
if(-1 == statvfs(ctoppath.c_str(), &vfsbuf)){
S3FS_PRN_ERR("could not get vfs stat by errno(%d)", errno);
return 0;
}
return (vfsbuf.f_bavail * vfsbuf.f_frsize);
}
bool FdManager::IsSafeDiskSpace(const char* path, off_t size)
{
off_t fsize = FdManager::GetFreeDiskSpace(path);
return size + FdManager::GetEnsureFreeDiskSpace() <= fsize;
}
bool FdManager::HaveLseekHole(void)
{
if(FdManager::checked_lseek){
return FdManager::have_lseek_hole;
}
// create tempolary file
int fd;
if(-1 == (fd = open(TMPFILE_FOR_CHECK_HOLE, O_CREAT|O_RDWR, 0600))){
S3FS_PRN_ERR("failed to open tempolary file(%s) - errno(%d)", TMPFILE_FOR_CHECK_HOLE, errno);
FdManager::checked_lseek = true;
FdManager::have_lseek_hole = false;
return FdManager::have_lseek_hole;
}
// check SEEK_DATA/SEEK_HOLE options
bool result = true;
if(-1 == lseek(fd, 0, SEEK_DATA)){
if(EINVAL == errno){
S3FS_PRN_ERR("lseek does not support SEEK_DATA");
result = false;
}
}
if(result && -1 == lseek(fd, 0, SEEK_HOLE)){
if(EINVAL == errno){
S3FS_PRN_ERR("lseek does not support SEEK_HOLE");
result = false;
}
}
close(fd);
unlink(TMPFILE_FOR_CHECK_HOLE);
FdManager::checked_lseek = true;
FdManager::have_lseek_hole = result;
return FdManager::have_lseek_hole;
}
//------------------------------------------------
// FdManager methods
//------------------------------------------------
FdManager::FdManager()
{
if(this == FdManager::get()){
pthread_mutexattr_t attr;
pthread_mutexattr_init(&attr);
#if S3FS_PTHREAD_ERRORCHECK
pthread_mutexattr_settype(&attr, PTHREAD_MUTEX_ERRORCHECK);
#endif
int res;
if(0 != (res = pthread_mutex_init(&FdManager::fd_manager_lock, &attr))){
S3FS_PRN_CRIT("failed to init fd_manager_lock: %d", res);
abort();
}
if(0 != (res = pthread_mutex_init(&FdManager::cache_cleanup_lock, &attr))){
S3FS_PRN_CRIT("failed to init cache_cleanup_lock: %d", res);
abort();
}
if(0 != (res = pthread_mutex_init(&FdManager::reserved_diskspace_lock, &attr))){
S3FS_PRN_CRIT("failed to init reserved_diskspace_lock: %d", res);
abort();
}
FdManager::is_lock_init = true;
}else{
abort();
}
}
FdManager::~FdManager()
{
if(this == FdManager::get()){
for(fdent_map_t::iterator iter = fent.begin(); fent.end() != iter; ++iter){
FdEntity* ent = (*iter).second;
delete ent;
}
fent.clear();
if(FdManager::is_lock_init){
int res;
if(0 != (res = pthread_mutex_destroy(&FdManager::fd_manager_lock))){
S3FS_PRN_CRIT("failed to destroy fd_manager_lock: %d", res);
abort();
}
if(0 != (res = pthread_mutex_destroy(&FdManager::cache_cleanup_lock))){
S3FS_PRN_CRIT("failed to destroy cache_cleanup_lock: %d", res);
abort();
}
if(0 != (res = pthread_mutex_destroy(&FdManager::reserved_diskspace_lock))){
S3FS_PRN_CRIT("failed to destroy reserved_diskspace_lock: %d", res);
abort();
}
FdManager::is_lock_init = false;
}
}else{
abort();
}
}
FdEntity* FdManager::GetFdEntity(const char* path, int existfd)
{
S3FS_PRN_INFO3("[path=%s][fd=%d]", SAFESTRPTR(path), existfd);
if(!path || '\0' == path[0]){
return NULL;
}
AutoLock auto_lock(&FdManager::fd_manager_lock);
fdent_map_t::iterator iter = fent.find(std::string(path));
if(fent.end() != iter && (-1 == existfd || (*iter).second->GetFd() == existfd)){
iter->second->Dup();
return (*iter).second;
}
if(-1 != existfd){
for(iter = fent.begin(); iter != fent.end(); ++iter){
if((*iter).second && (*iter).second->GetFd() == existfd){
// found opened fd in map
if(0 == strcmp((*iter).second->GetPath(), path)){
iter->second->Dup();
return (*iter).second;
}
// found fd, but it is used another file(file descriptor is recycled)
// so returns NULL.
break;
}
}
}
return NULL;
}
FdEntity* FdManager::Open(const char* path, headers_t* pmeta, off_t size, time_t time, bool force_tmpfile, bool is_create, bool no_fd_lock_wait)
{
S3FS_PRN_DBG("[path=%s][size=%lld][time=%lld]", SAFESTRPTR(path), static_cast<long long>(size), static_cast<long long>(time));
if(!path || '\0' == path[0]){
return NULL;
}
bool close = false;
FdEntity* ent;
AutoLock auto_lock(&FdManager::fd_manager_lock);
// search in mapping by key(path)
fdent_map_t::iterator iter = fent.find(std::string(path));
if(fent.end() == iter && !force_tmpfile && !FdManager::IsCacheDir()){
// If the cache directory is not specified, s3fs opens a temporary file
// when the file is opened.
// Then if it could not find a entity in map for the file, s3fs should
// search a entity in all which opened the temporary file.
//
for(iter = fent.begin(); iter != fent.end(); ++iter){
if((*iter).second && (*iter).second->IsOpen() && 0 == strcmp((*iter).second->GetPath(), path)){
break; // found opened fd in mapping
}
}
}
if(fent.end() != iter){
// found
ent = (*iter).second;
ent->Dup();
if(ent->IsModified()){
// If the file is being modified, it will not be resized.
size = -1;
}
close = true;
}else if(is_create){
// not found
std::string cache_path;
if(!force_tmpfile && !FdManager::MakeCachePath(path, cache_path, true)){
S3FS_PRN_ERR("failed to make cache path for object(%s).", path);
return NULL;
}
// make new obj
ent = new FdEntity(path, cache_path.c_str());
if(!cache_path.empty()){
// using cache
fent[std::string(path)] = ent;
}else{
// not using cache, so the key of fdentity is set not really existing path.
// (but not strictly unexisting path.)
//
// [NOTE]
// The reason why this process here, please look at the definition of the
// comments of NOCACHE_PATH_PREFIX_FORM symbol.
//
std::string tmppath;
FdManager::MakeRandomTempPath(path, tmppath);
fent[tmppath] = ent;
}
}else{
return NULL;
}
// open
if(0 != ent->Open(pmeta, size, time, no_fd_lock_wait)){
if(close){
ent->Close();
}
return NULL;
}
if(close){
ent->Close();
}
return ent;
}
FdEntity* FdManager::ExistOpen(const char* path, int existfd, bool ignore_existfd)
{
S3FS_PRN_DBG("[path=%s][fd=%d][ignore_existfd=%s]", SAFESTRPTR(path), existfd, ignore_existfd ? "true" : "false");
// search by real path
FdEntity* ent = Open(path, NULL, -1, -1, false, false);
if(!ent && (ignore_existfd || (-1 != existfd))){
// search from all fdentity because of not using cache.
AutoLock auto_lock(&FdManager::fd_manager_lock);
for(fdent_map_t::iterator iter = fent.begin(); iter != fent.end(); ++iter){
if((*iter).second && (*iter).second->IsOpen() && (ignore_existfd || ((*iter).second->GetFd() == existfd))){
// found opened fd in map
if(0 == strcmp((*iter).second->GetPath(), path)){
ent = (*iter).second;
ent->Dup();
}else{
// found fd, but it is used another file(file descriptor is recycled)
// so returns NULL.
}
break;
}
}
}
return ent;
}
void FdManager::Rename(const std::string &from, const std::string &to)
{
AutoLock auto_lock(&FdManager::fd_manager_lock);
fdent_map_t::iterator iter = fent.find(from);
if(fent.end() == iter && !FdManager::IsCacheDir()){
// If the cache directory is not specified, s3fs opens a temporary file
// when the file is opened.
// Then if it could not find a entity in map for the file, s3fs should
// search a entity in all which opened the temporary file.
//
for(iter = fent.begin(); iter != fent.end(); ++iter){
if((*iter).second && (*iter).second->IsOpen() && 0 == strcmp((*iter).second->GetPath(), from.c_str())){
break; // found opened fd in mapping
}
}
}
if(fent.end() != iter){
// found
S3FS_PRN_DBG("[from=%s][to=%s]", from.c_str(), to.c_str());
FdEntity* ent = (*iter).second;
// retrieve old fd entity from map
fent.erase(iter);
// rename path and caches in fd entity
std::string fentmapkey;
if(!ent->RenamePath(to, fentmapkey)){
S3FS_PRN_ERR("Failed to rename FdEntity object for %s to %s", from.c_str(), to.c_str());
return;
}
// set new fd entity to map
fent[fentmapkey] = ent;
}
}
bool FdManager::Close(FdEntity* ent)
{
S3FS_PRN_DBG("[ent->file=%s][ent->fd=%d]", ent ? ent->GetPath() : "", ent ? ent->GetFd() : -1);
if(!ent){
return true; // returns success
}
AutoLock auto_lock(&FdManager::fd_manager_lock);
for(fdent_map_t::iterator iter = fent.begin(); iter != fent.end(); ++iter){
if((*iter).second == ent){
ent->Close();
if(!ent->IsOpen()){
// remove found entity from map.
fent.erase(iter++);
// check another key name for entity value to be on the safe side
for(; iter != fent.end(); ){
if((*iter).second == ent){
fent.erase(iter++);
}else{
++iter;
}
}
delete ent;
}
return true;
}
}
return false;
}
bool FdManager::ChangeEntityToTempPath(FdEntity* ent, const char* path)
{
AutoLock auto_lock(&FdManager::fd_manager_lock);
for(fdent_map_t::iterator iter = fent.begin(); iter != fent.end(); ){
if((*iter).second == ent){
fent.erase(iter++);
std::string tmppath;
FdManager::MakeRandomTempPath(path, tmppath);
fent[tmppath] = ent;
}else{
++iter;
}
}
return false;
}
void FdManager::CleanupCacheDir()
{
//S3FS_PRN_DBG("cache cleanup requested");
if(!FdManager::IsCacheDir()){
return;
}
AutoLock auto_lock_no_wait(&FdManager::cache_cleanup_lock, AutoLock::NO_WAIT);
if(auto_lock_no_wait.isLockAcquired()){
//S3FS_PRN_DBG("cache cleanup started");
CleanupCacheDirInternal("");
//S3FS_PRN_DBG("cache cleanup ended");
}else{
// wait for other thread to finish cache cleanup
AutoLock auto_lock(&FdManager::cache_cleanup_lock);
}
}
void FdManager::CleanupCacheDirInternal(const std::string &path)
{
DIR* dp;
struct dirent* dent;
std::string abs_path = cache_dir + "/" + bucket + path;
if(NULL == (dp = opendir(abs_path.c_str()))){
S3FS_PRN_ERR("could not open cache dir(%s) - errno(%d)", abs_path.c_str(), errno);
return;
}
for(dent = readdir(dp); dent; dent = readdir(dp)){
if(0 == strcmp(dent->d_name, "..") || 0 == strcmp(dent->d_name, ".")){
continue;
}
std::string fullpath = abs_path;
fullpath += "/";
fullpath += dent->d_name;
struct stat st;
if(0 != lstat(fullpath.c_str(), &st)){
S3FS_PRN_ERR("could not get stats of file(%s) - errno(%d)", fullpath.c_str(), errno);
closedir(dp);
return;
}
std::string next_path = path + "/" + dent->d_name;
if(S_ISDIR(st.st_mode)){
CleanupCacheDirInternal(next_path);
}else{
AutoLock auto_lock(&FdManager::fd_manager_lock, AutoLock::NO_WAIT);
if (!auto_lock.isLockAcquired()) {
S3FS_PRN_ERR("could not get fd_manager_lock when clean up file(%s)", next_path.c_str());
continue;
}
fdent_map_t::iterator iter = fent.find(next_path);
if(fent.end() == iter) {
S3FS_PRN_DBG("cleaned up: %s", next_path.c_str());
FdManager::DeleteCacheFile(next_path.c_str());
}
}
}
closedir(dp);
}
bool FdManager::ReserveDiskSpace(off_t size)
{
if(IsSafeDiskSpace(NULL, size)){
AutoLock auto_lock(&FdManager::reserved_diskspace_lock);
free_disk_space += size;
return true;
}
return false;
}
void FdManager::FreeReservedDiskSpace(off_t size)
{
AutoLock auto_lock(&FdManager::reserved_diskspace_lock);
free_disk_space -= size;
}
//
// Inspect all files for stats file for cache file
//
// [NOTE]
// The minimum sub_path parameter is "/".
// The sub_path is a directory path starting from "/" and ending with "/".
//
// This method produces the following output.
//
// * Header
// ------------------------------------------------------------
// Check cache file and its stats file consistency
// ------------------------------------------------------------
// * When the cache file and its stats information match
// File path: <file path> -> [OK] no problem
//
// * If there is a problem with the cache file and its stats information
// File path: <file path>
// -> [P] <If the problem is that parsing is not possible in the first place, the message is output here with this prefix.>
// -> [E] there is a mark that data exists in stats, but there is no data in the cache file.
// <offset address>(bytes)
// ...
// ...
// -> [W] These show no data in stats, but there is evidence of data in the cache file.(no problem.)
// <offset address>(bytes)
// ...
// ...
//
bool FdManager::RawCheckAllCache(FILE* fp, const char* cache_stat_top_dir, const char* sub_path, int& total_file_cnt, int& err_file_cnt, int& err_dir_cnt)
{
if(!cache_stat_top_dir || '\0' == cache_stat_top_dir[0] || !sub_path || '\0' == sub_path[0]){
S3FS_PRN_ERR("Parameter cache_stat_top_dir is empty.");
return false;
}
// open directory of cache file's stats
DIR* statsdir;
std::string target_dir = cache_stat_top_dir;
target_dir += sub_path;
if(NULL == (statsdir = opendir(target_dir.c_str()))){
S3FS_PRN_ERR("Could not open directory(%s) by errno(%d)", target_dir.c_str(), errno);
return false;
}
// loop in directory of cache file's stats
struct dirent* pdirent = NULL;
while(NULL != (pdirent = readdir(statsdir))){
if(DT_DIR == pdirent->d_type){
// found directory
if(0 == strcmp(pdirent->d_name, ".") || 0 == strcmp(pdirent->d_name, "..")){
continue;
}
// reentrant for sub directory
std::string subdir_path = sub_path;
subdir_path += pdirent->d_name;
subdir_path += '/';
if(!RawCheckAllCache(fp, cache_stat_top_dir, subdir_path.c_str(), total_file_cnt, err_file_cnt, err_dir_cnt)){
// put error message for this dir.
++err_dir_cnt;
S3FS_PRN_CACHE(fp, CACHEDBG_FMT_DIR_PROB, subdir_path.c_str());
S3FS_PRN_CACHE(fp, CACHEDBG_FMT_CRIT_HEAD, "Something error is occurred in checking this directory");
}
}else{
++total_file_cnt;
// make cache file path
std::string strOpenedWarn;
std::string cache_path;
std::string object_file_path = sub_path;
object_file_path += pdirent->d_name;
if(!FdManager::MakeCachePath(object_file_path.c_str(), cache_path, false, false) || cache_path.empty()){
++err_file_cnt;
S3FS_PRN_CACHE(fp, CACHEDBG_FMT_FILE_PROB, object_file_path.c_str(), strOpenedWarn.c_str());
S3FS_PRN_CACHE(fp, CACHEDBG_FMT_CRIT_HEAD, "Could not make cache file path");
continue;
}
// check if the target file is currently in operation.
{
AutoLock auto_lock(&FdManager::fd_manager_lock);
fdent_map_t::iterator iter = fent.find(object_file_path);
if(fent.end() != iter){
// This file is opened now, then we need to put warning message.
strOpenedWarn = CACHEDBG_FMT_WARN_OPEN;
}
}
// open cache file
int cache_file_fd;
if(-1 == (cache_file_fd = open(cache_path.c_str(), O_RDONLY))){
++err_file_cnt;
S3FS_PRN_CACHE(fp, CACHEDBG_FMT_FILE_PROB, object_file_path.c_str(), strOpenedWarn.c_str());
S3FS_PRN_CACHE(fp, CACHEDBG_FMT_CRIT_HEAD, "Could not open cache file");
continue;
}
// get inode number for cache file
struct stat st;
if(0 != fstat(cache_file_fd, &st)){
++err_file_cnt;
S3FS_PRN_CACHE(fp, CACHEDBG_FMT_FILE_PROB, object_file_path.c_str(), strOpenedWarn.c_str());
S3FS_PRN_CACHE(fp, CACHEDBG_FMT_CRIT_HEAD, "Could not get file inode number for cache file");
close(cache_file_fd);
continue;
}
ino_t cache_file_inode = st.st_ino;
// open cache stat file and load page info.
PageList pagelist;
CacheFileStat cfstat(object_file_path.c_str());
if(!cfstat.ReadOnlyOpen() || !pagelist.Serialize(cfstat, false, cache_file_inode)){
++err_file_cnt;
S3FS_PRN_CACHE(fp, CACHEDBG_FMT_FILE_PROB, object_file_path.c_str(), strOpenedWarn.c_str());
S3FS_PRN_CACHE(fp, CACHEDBG_FMT_CRIT_HEAD, "Could not load cache file stats information");
close(cache_file_fd);
continue;
}
cfstat.Release();
// compare cache file size and stats information
if(st.st_size != pagelist.Size()){
++err_file_cnt;
S3FS_PRN_CACHE(fp, CACHEDBG_FMT_FILE_PROB, object_file_path.c_str(), strOpenedWarn.c_str());
S3FS_PRN_CACHE(fp, CACHEDBG_FMT_CRIT_HEAD2 "The cache file size(%lld) and the value(%lld) from cache file stats are different", static_cast<long long int>(st.st_size), static_cast<long long int>(pagelist.Size()));
close(cache_file_fd);
continue;
}
// compare cache file stats and cache file blocks
fdpage_list_t err_area_list;
fdpage_list_t warn_area_list;
if(!pagelist.CompareSparseFile(cache_file_fd, st.st_size, err_area_list, warn_area_list)){
// Found some error or warning
S3FS_PRN_CACHE(fp, CACHEDBG_FMT_FILE_PROB, object_file_path.c_str(), strOpenedWarn.c_str());
if(!warn_area_list.empty()){
S3FS_PRN_CACHE(fp, CACHEDBG_FMT_WARN_HEAD);
for(fdpage_list_t::const_iterator witer = warn_area_list.begin(); witer != warn_area_list.end(); ++witer){
S3FS_PRN_CACHE(fp, CACHEDBG_FMT_PROB_BLOCK, static_cast<size_t>(witer->offset), static_cast<size_t>(witer->bytes));
}
}
if(!err_area_list.empty()){
++err_file_cnt;
S3FS_PRN_CACHE(fp, CACHEDBG_FMT_ERR_HEAD);
for(fdpage_list_t::const_iterator eiter = err_area_list.begin(); eiter != err_area_list.end(); ++eiter){
S3FS_PRN_CACHE(fp, CACHEDBG_FMT_PROB_BLOCK, static_cast<size_t>(eiter->offset), static_cast<size_t>(eiter->bytes));
}
}
}else{
// There is no problem!
if(!strOpenedWarn.empty()){
strOpenedWarn += "\n ";
}
S3FS_PRN_CACHE(fp, CACHEDBG_FMT_FILE_OK, object_file_path.c_str(), strOpenedWarn.c_str());
}
err_area_list.clear();
warn_area_list.clear();
close(cache_file_fd);
}
}
closedir(statsdir);
return true;
}
bool FdManager::CheckAllCache()
{
if(!FdManager::HaveLseekHole()){
S3FS_PRN_ERR("lseek does not support SEEK_DATA/SEEK_HOLE, then could not check cache.");
return false;
}
FILE* fp;
if(FdManager::check_cache_output.empty()){
fp = stdout;
}else{
if(NULL == (fp = fopen(FdManager::check_cache_output.c_str(), "a+"))){
S3FS_PRN_ERR("Could not open(create) output file(%s) for checking all cache by errno(%d)", FdManager::check_cache_output.c_str(), errno);
return false;
}
}
// print head message
S3FS_PRN_CACHE(fp, CACHEDBG_FMT_HEAD);
// Loop in directory of cache file's stats
std::string top_path = CacheFileStat::GetCacheFileStatTopDir();
int total_file_cnt = 0;
int err_file_cnt = 0;
int err_dir_cnt = 0;
bool result = RawCheckAllCache(fp, top_path.c_str(), "/", total_file_cnt, err_file_cnt, err_dir_cnt);
if(!result){
S3FS_PRN_ERR("Processing failed due to some problem.");
}
// print foot message
S3FS_PRN_CACHE(fp, CACHEDBG_FMT_FOOT, total_file_cnt, err_file_cnt, err_dir_cnt);
if(stdout != fp){
fclose(fp);
}
return result;
}
/*
* Local variables:
* tab-width: 4
* c-basic-offset: 4
* End:
* vim600: expandtab sw=4 ts=4 fdm=marker
* vim<600: expandtab sw=4 ts=4
*/