// Copyright (c) 2012 The Chromium 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 "base/files/file_util.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #if defined(OS_MACOSX) #include #include "base/mac/foundation_util.h" #elif !defined(OS_CHROMEOS) && defined(USE_GLIB) #include // for g_get_home_dir() #endif #include #include "base/basictypes.h" #include "base/files/file_enumerator.h" #include "base/files/file_path.h" #include "base/files/scoped_file.h" #include "base/logging.h" #include "base/memory/scoped_ptr.h" #include "base/memory/singleton.h" #include "base/path_service.h" #include "base/posix/eintr_wrapper.h" #include "base/stl_util.h" #include "base/strings/string_util.h" #include "base/strings/stringprintf.h" #include "base/strings/sys_string_conversions.h" #include "base/strings/utf_string_conversions.h" #include "base/sys_info.h" #include "base/threading/thread_restrictions.h" #include "base/time/time.h" #if defined(OS_ANDROID) #include "base/android/content_uri_utils.h" #include "base/os_compat_android.h" #endif #if !defined(OS_IOS) #include #endif namespace base { namespace { #if defined(OS_BSD) || defined(OS_MACOSX) || defined(OS_NACL) static int CallStat(const char *path, stat_wrapper_t *sb) { ThreadRestrictions::AssertIOAllowed(); return stat(path, sb); } static int CallLstat(const char *path, stat_wrapper_t *sb) { ThreadRestrictions::AssertIOAllowed(); return lstat(path, sb); } #else // defined(OS_BSD) || defined(OS_MACOSX) || defined(OS_NACL) static int CallStat(const char *path, stat_wrapper_t *sb) { ThreadRestrictions::AssertIOAllowed(); return stat64(path, sb); } static int CallLstat(const char *path, stat_wrapper_t *sb) { ThreadRestrictions::AssertIOAllowed(); return lstat64(path, sb); } #endif // !(defined(OS_BSD) || defined(OS_MACOSX) || defined(OS_NACL)) // Helper for NormalizeFilePath(), defined below. bool RealPath(const FilePath& path, FilePath* real_path) { ThreadRestrictions::AssertIOAllowed(); // For realpath(). FilePath::CharType buf[PATH_MAX]; if (!realpath(path.value().c_str(), buf)) return false; *real_path = FilePath(buf); return true; } // Helper for VerifyPathControlledByUser. bool VerifySpecificPathControlledByUser(const FilePath& path, uid_t owner_uid, const std::set& group_gids) { stat_wrapper_t stat_info; if (CallLstat(path.value().c_str(), &stat_info) != 0) { DPLOG(ERROR) << "Failed to get information on path " << path.value(); return false; } if (S_ISLNK(stat_info.st_mode)) { DLOG(ERROR) << "Path " << path.value() << " is a symbolic link."; return false; } if (stat_info.st_uid != owner_uid) { DLOG(ERROR) << "Path " << path.value() << " is owned by the wrong user."; return false; } if ((stat_info.st_mode & S_IWGRP) && !ContainsKey(group_gids, stat_info.st_gid)) { DLOG(ERROR) << "Path " << path.value() << " is writable by an unprivileged group."; return false; } if (stat_info.st_mode & S_IWOTH) { DLOG(ERROR) << "Path " << path.value() << " is writable by any user."; return false; } return true; } std::string TempFileName() { #if defined(OS_MACOSX) return StringPrintf(".%s.XXXXXX", base::mac::BaseBundleID()); #endif #if defined(GOOGLE_CHROME_BUILD) return std::string(".com.google.Chrome.XXXXXX"); #else return std::string(".org.chromium.Chromium.XXXXXX"); #endif } // Creates and opens a temporary file in |directory|, returning the // file descriptor. |path| is set to the temporary file path. // This function does NOT unlink() the file. int CreateAndOpenFdForTemporaryFile(FilePath directory, FilePath* path) { ThreadRestrictions::AssertIOAllowed(); // For call to mkstemp(). *path = directory.Append(base::TempFileName()); const std::string& tmpdir_string = path->value(); // this should be OK since mkstemp just replaces characters in place char* buffer = const_cast(tmpdir_string.c_str()); return HANDLE_EINTR(mkstemp(buffer)); } #if defined(OS_LINUX) // Determine if /dev/shm files can be mapped and then mprotect'd PROT_EXEC. // This depends on the mount options used for /dev/shm, which vary among // different Linux distributions and possibly local configuration. It also // depends on details of kernel--ChromeOS uses the noexec option for /dev/shm // but its kernel allows mprotect with PROT_EXEC anyway. bool DetermineDevShmExecutable() { bool result = false; FilePath path; ScopedFD fd(CreateAndOpenFdForTemporaryFile(FilePath("/dev/shm"), &path)); if (fd.is_valid()) { DeleteFile(path, false); long sysconf_result = sysconf(_SC_PAGESIZE); CHECK_GE(sysconf_result, 0); size_t pagesize = static_cast(sysconf_result); CHECK_GE(sizeof(pagesize), sizeof(sysconf_result)); void* mapping = mmap(NULL, pagesize, PROT_READ, MAP_SHARED, fd.get(), 0); if (mapping != MAP_FAILED) { if (mprotect(mapping, pagesize, PROT_READ | PROT_EXEC) == 0) result = true; munmap(mapping, pagesize); } } return result; } #endif // defined(OS_LINUX) } // namespace FilePath MakeAbsoluteFilePath(const FilePath& input) { ThreadRestrictions::AssertIOAllowed(); char full_path[PATH_MAX]; if (realpath(input.value().c_str(), full_path) == NULL) return FilePath(); return FilePath(full_path); } // TODO(erikkay): The Windows version of this accepts paths like "foo/bar/*" // which works both with and without the recursive flag. I'm not sure we need // that functionality. If not, remove from file_util_win.cc, otherwise add it // here. bool DeleteFile(const FilePath& path, bool recursive) { ThreadRestrictions::AssertIOAllowed(); const char* path_str = path.value().c_str(); stat_wrapper_t file_info; int test = CallLstat(path_str, &file_info); if (test != 0) { // The Windows version defines this condition as success. bool ret = (errno == ENOENT || errno == ENOTDIR); return ret; } if (!S_ISDIR(file_info.st_mode)) return (unlink(path_str) == 0); if (!recursive) return (rmdir(path_str) == 0); bool success = true; std::stack directories; directories.push(path.value()); FileEnumerator traversal(path, true, FileEnumerator::FILES | FileEnumerator::DIRECTORIES | FileEnumerator::SHOW_SYM_LINKS); for (FilePath current = traversal.Next(); success && !current.empty(); current = traversal.Next()) { if (traversal.GetInfo().IsDirectory()) directories.push(current.value()); else success = (unlink(current.value().c_str()) == 0); } while (success && !directories.empty()) { FilePath dir = FilePath(directories.top()); directories.pop(); success = (rmdir(dir.value().c_str()) == 0); } return success; } bool ReplaceFile(const FilePath& from_path, const FilePath& to_path, File::Error* error) { ThreadRestrictions::AssertIOAllowed(); if (rename(from_path.value().c_str(), to_path.value().c_str()) == 0) return true; if (error) *error = File::OSErrorToFileError(errno); return false; } bool CopyDirectory(const FilePath& from_path, const FilePath& to_path, bool recursive) { ThreadRestrictions::AssertIOAllowed(); // Some old callers of CopyDirectory want it to support wildcards. // After some discussion, we decided to fix those callers. // Break loudly here if anyone tries to do this. DCHECK(to_path.value().find('*') == std::string::npos); DCHECK(from_path.value().find('*') == std::string::npos); if (from_path.value().size() >= PATH_MAX) { return false; } // This function does not properly handle destinations within the source FilePath real_to_path = to_path; if (PathExists(real_to_path)) { real_to_path = MakeAbsoluteFilePath(real_to_path); if (real_to_path.empty()) return false; } else { real_to_path = MakeAbsoluteFilePath(real_to_path.DirName()); if (real_to_path.empty()) return false; } FilePath real_from_path = MakeAbsoluteFilePath(from_path); if (real_from_path.empty()) return false; if (real_to_path.value().size() >= real_from_path.value().size() && real_to_path.value().compare(0, real_from_path.value().size(), real_from_path.value()) == 0) { return false; } int traverse_type = FileEnumerator::FILES | FileEnumerator::SHOW_SYM_LINKS; if (recursive) traverse_type |= FileEnumerator::DIRECTORIES; FileEnumerator traversal(from_path, recursive, traverse_type); // We have to mimic windows behavior here. |to_path| may not exist yet, // start the loop with |to_path|. struct stat from_stat; FilePath current = from_path; if (stat(from_path.value().c_str(), &from_stat) < 0) { DLOG(ERROR) << "CopyDirectory() couldn't stat source directory: " << from_path.value() << " errno = " << errno; return false; } struct stat to_path_stat; FilePath from_path_base = from_path; if (recursive && stat(to_path.value().c_str(), &to_path_stat) == 0 && S_ISDIR(to_path_stat.st_mode)) { // If the destination already exists and is a directory, then the // top level of source needs to be copied. from_path_base = from_path.DirName(); } // The Windows version of this function assumes that non-recursive calls // will always have a directory for from_path. // TODO(maruel): This is not necessary anymore. DCHECK(recursive || S_ISDIR(from_stat.st_mode)); bool success = true; while (success && !current.empty()) { // current is the source path, including from_path, so append // the suffix after from_path to to_path to create the target_path. FilePath target_path(to_path); if (from_path_base != current) { if (!from_path_base.AppendRelativePath(current, &target_path)) { success = false; break; } } if (S_ISDIR(from_stat.st_mode)) { if (mkdir(target_path.value().c_str(), from_stat.st_mode & 01777) != 0 && errno != EEXIST) { DLOG(ERROR) << "CopyDirectory() couldn't create directory: " << target_path.value() << " errno = " << errno; success = false; } } else if (S_ISREG(from_stat.st_mode)) { if (!CopyFile(current, target_path)) { DLOG(ERROR) << "CopyDirectory() couldn't create file: " << target_path.value(); success = false; } } else { DLOG(WARNING) << "CopyDirectory() skipping non-regular file: " << current.value(); } current = traversal.Next(); if (!current.empty()) from_stat = traversal.GetInfo().stat(); } return success; } bool PathExists(const FilePath& path) { ThreadRestrictions::AssertIOAllowed(); #if defined(OS_ANDROID) if (path.IsContentUri()) { return ContentUriExists(path); } #endif return access(path.value().c_str(), F_OK) == 0; } bool PathIsWritable(const FilePath& path) { ThreadRestrictions::AssertIOAllowed(); return access(path.value().c_str(), W_OK) == 0; } bool DirectoryExists(const FilePath& path) { ThreadRestrictions::AssertIOAllowed(); stat_wrapper_t file_info; if (CallStat(path.value().c_str(), &file_info) == 0) return S_ISDIR(file_info.st_mode); return false; } bool ReadFromFD(int fd, char* buffer, size_t bytes) { size_t total_read = 0; while (total_read < bytes) { ssize_t bytes_read = HANDLE_EINTR(read(fd, buffer + total_read, bytes - total_read)); if (bytes_read <= 0) break; total_read += bytes_read; } return total_read == bytes; } bool CreateSymbolicLink(const FilePath& target_path, const FilePath& symlink_path) { DCHECK(!symlink_path.empty()); DCHECK(!target_path.empty()); return ::symlink(target_path.value().c_str(), symlink_path.value().c_str()) != -1; } bool ReadSymbolicLink(const FilePath& symlink_path, FilePath* target_path) { DCHECK(!symlink_path.empty()); DCHECK(target_path); char buf[PATH_MAX]; ssize_t count = ::readlink(symlink_path.value().c_str(), buf, arraysize(buf)); if (count <= 0) { target_path->clear(); return false; } *target_path = FilePath(FilePath::StringType(buf, count)); return true; } bool GetPosixFilePermissions(const FilePath& path, int* mode) { ThreadRestrictions::AssertIOAllowed(); DCHECK(mode); stat_wrapper_t file_info; // Uses stat(), because on symbolic link, lstat() does not return valid // permission bits in st_mode if (CallStat(path.value().c_str(), &file_info) != 0) return false; *mode = file_info.st_mode & FILE_PERMISSION_MASK; return true; } bool SetPosixFilePermissions(const FilePath& path, int mode) { ThreadRestrictions::AssertIOAllowed(); DCHECK((mode & ~FILE_PERMISSION_MASK) == 0); // Calls stat() so that we can preserve the higher bits like S_ISGID. stat_wrapper_t stat_buf; if (CallStat(path.value().c_str(), &stat_buf) != 0) return false; // Clears the existing permission bits, and adds the new ones. mode_t updated_mode_bits = stat_buf.st_mode & ~FILE_PERMISSION_MASK; updated_mode_bits |= mode & FILE_PERMISSION_MASK; if (HANDLE_EINTR(chmod(path.value().c_str(), updated_mode_bits)) != 0) return false; return true; } #if !defined(OS_MACOSX) // This is implemented in file_util_mac.mm for Mac. bool GetTempDir(FilePath* path) { const char* tmp = getenv("TMPDIR"); if (tmp) { *path = FilePath(tmp); } else { #if defined(OS_ANDROID) return PathService::Get(base::DIR_CACHE, path); #else *path = FilePath("/tmp"); #endif } return true; } #endif // !defined(OS_MACOSX) #if !defined(OS_MACOSX) // Mac implementation is in file_util_mac.mm. FilePath GetHomeDir() { #if defined(OS_CHROMEOS) if (SysInfo::IsRunningOnChromeOS()) { // On Chrome OS chrome::DIR_USER_DATA is overridden with a primary user // homedir once it becomes available. Return / as the safe option. return FilePath("/"); } #endif const char* home_dir = getenv("HOME"); if (home_dir && home_dir[0]) return FilePath(home_dir); #if defined(OS_ANDROID) DLOG(WARNING) << "OS_ANDROID: Home directory lookup not yet implemented."; #elif defined(USE_GLIB) && !defined(OS_CHROMEOS) // g_get_home_dir calls getpwent, which can fall through to LDAP calls so // this may do I/O. However, it should be rare that $HOME is not defined and // this is typically called from the path service which has no threading // restrictions. The path service will cache the result which limits the // badness of blocking on I/O. As a result, we don't have a thread // restriction here. home_dir = g_get_home_dir(); if (home_dir && home_dir[0]) return FilePath(home_dir); #endif FilePath rv; if (GetTempDir(&rv)) return rv; // Last resort. return FilePath("/tmp"); } #endif // !defined(OS_MACOSX) bool CreateTemporaryFile(FilePath* path) { ThreadRestrictions::AssertIOAllowed(); // For call to close(). FilePath directory; if (!GetTempDir(&directory)) return false; int fd = CreateAndOpenFdForTemporaryFile(directory, path); if (fd < 0) return false; close(fd); return true; } FILE* CreateAndOpenTemporaryFileInDir(const FilePath& dir, FilePath* path) { int fd = CreateAndOpenFdForTemporaryFile(dir, path); if (fd < 0) return NULL; FILE* file = fdopen(fd, "a+"); if (!file) close(fd); return file; } bool CreateTemporaryFileInDir(const FilePath& dir, FilePath* temp_file) { ThreadRestrictions::AssertIOAllowed(); // For call to close(). int fd = CreateAndOpenFdForTemporaryFile(dir, temp_file); return ((fd >= 0) && !IGNORE_EINTR(close(fd))); } static bool CreateTemporaryDirInDirImpl(const FilePath& base_dir, const FilePath::StringType& name_tmpl, FilePath* new_dir) { ThreadRestrictions::AssertIOAllowed(); // For call to mkdtemp(). DCHECK(name_tmpl.find("XXXXXX") != FilePath::StringType::npos) << "Directory name template must contain \"XXXXXX\"."; FilePath sub_dir = base_dir.Append(name_tmpl); std::string sub_dir_string = sub_dir.value(); // this should be OK since mkdtemp just replaces characters in place char* buffer = const_cast(sub_dir_string.c_str()); char* dtemp = mkdtemp(buffer); if (!dtemp) { DPLOG(ERROR) << "mkdtemp"; return false; } *new_dir = FilePath(dtemp); return true; } bool CreateTemporaryDirInDir(const FilePath& base_dir, const FilePath::StringType& prefix, FilePath* new_dir) { FilePath::StringType mkdtemp_template = prefix; mkdtemp_template.append(FILE_PATH_LITERAL("XXXXXX")); return CreateTemporaryDirInDirImpl(base_dir, mkdtemp_template, new_dir); } bool CreateNewTempDirectory(const FilePath::StringType& prefix, FilePath* new_temp_path) { FilePath tmpdir; if (!GetTempDir(&tmpdir)) return false; return CreateTemporaryDirInDirImpl(tmpdir, TempFileName(), new_temp_path); } bool CreateDirectoryAndGetError(const FilePath& full_path, File::Error* error) { ThreadRestrictions::AssertIOAllowed(); // For call to mkdir(). std::vector subpaths; // Collect a list of all parent directories. FilePath last_path = full_path; subpaths.push_back(full_path); for (FilePath path = full_path.DirName(); path.value() != last_path.value(); path = path.DirName()) { subpaths.push_back(path); last_path = path; } // Iterate through the parents and create the missing ones. for (std::vector::reverse_iterator i = subpaths.rbegin(); i != subpaths.rend(); ++i) { if (DirectoryExists(*i)) continue; if (mkdir(i->value().c_str(), 0700) == 0) continue; // Mkdir failed, but it might have failed with EEXIST, or some other error // due to the the directory appearing out of thin air. This can occur if // two processes are trying to create the same file system tree at the same // time. Check to see if it exists and make sure it is a directory. int saved_errno = errno; if (!DirectoryExists(*i)) { if (error) *error = File::OSErrorToFileError(saved_errno); return false; } } return true; } bool NormalizeFilePath(const FilePath& path, FilePath* normalized_path) { FilePath real_path_result; if (!RealPath(path, &real_path_result)) return false; // To be consistant with windows, fail if |real_path_result| is a // directory. stat_wrapper_t file_info; if (CallStat(real_path_result.value().c_str(), &file_info) != 0 || S_ISDIR(file_info.st_mode)) return false; *normalized_path = real_path_result; return true; } // TODO(rkc): Refactor GetFileInfo and FileEnumerator to handle symlinks // correctly. http://code.google.com/p/chromium-os/issues/detail?id=15948 bool IsLink(const FilePath& file_path) { stat_wrapper_t st; // If we can't lstat the file, it's safe to assume that the file won't at // least be a 'followable' link. if (CallLstat(file_path.value().c_str(), &st) != 0) return false; if (S_ISLNK(st.st_mode)) return true; else return false; } bool GetFileInfo(const FilePath& file_path, File::Info* results) { stat_wrapper_t file_info; #if defined(OS_ANDROID) if (file_path.IsContentUri()) { File file = OpenContentUriForRead(file_path); if (!file.IsValid()) return false; return file.GetInfo(results); } else { #endif // defined(OS_ANDROID) if (CallStat(file_path.value().c_str(), &file_info) != 0) return false; #if defined(OS_ANDROID) } #endif // defined(OS_ANDROID) results->FromStat(file_info); return true; } FILE* OpenFile(const FilePath& filename, const char* mode) { ThreadRestrictions::AssertIOAllowed(); FILE* result = NULL; do { result = fopen(filename.value().c_str(), mode); } while (!result && errno == EINTR); return result; } // NaCl doesn't implement system calls to open files directly. #if !defined(OS_NACL) FILE* FileToFILE(File file, const char* mode) { FILE* stream = fdopen(file.GetPlatformFile(), mode); if (stream) file.TakePlatformFile(); return stream; } #endif // !defined(OS_NACL) int ReadFile(const FilePath& filename, char* data, int max_size) { ThreadRestrictions::AssertIOAllowed(); int fd = HANDLE_EINTR(open(filename.value().c_str(), O_RDONLY)); if (fd < 0) return -1; ssize_t bytes_read = HANDLE_EINTR(read(fd, data, max_size)); if (IGNORE_EINTR(close(fd)) < 0) return -1; return bytes_read; } int WriteFile(const FilePath& filename, const char* data, int size) { ThreadRestrictions::AssertIOAllowed(); int fd = HANDLE_EINTR(creat(filename.value().c_str(), 0640)); if (fd < 0) return -1; int bytes_written = WriteFileDescriptor(fd, data, size); if (IGNORE_EINTR(close(fd)) < 0) return -1; return bytes_written; } int WriteFileDescriptor(const int fd, const char* data, int size) { // Allow for partial writes. ssize_t bytes_written_total = 0; for (ssize_t bytes_written_partial = 0; bytes_written_total < size; bytes_written_total += bytes_written_partial) { bytes_written_partial = HANDLE_EINTR(write(fd, data + bytes_written_total, size - bytes_written_total)); if (bytes_written_partial < 0) return -1; } return bytes_written_total; } int AppendToFile(const FilePath& filename, const char* data, int size) { ThreadRestrictions::AssertIOAllowed(); int fd = HANDLE_EINTR(open(filename.value().c_str(), O_WRONLY | O_APPEND)); if (fd < 0) return -1; int bytes_written = WriteFileDescriptor(fd, data, size); if (IGNORE_EINTR(close(fd)) < 0) return -1; return bytes_written; } // Gets the current working directory for the process. bool GetCurrentDirectory(FilePath* dir) { // getcwd can return ENOENT, which implies it checks against the disk. ThreadRestrictions::AssertIOAllowed(); char system_buffer[PATH_MAX] = ""; if (!getcwd(system_buffer, sizeof(system_buffer))) { NOTREACHED(); return false; } *dir = FilePath(system_buffer); return true; } // Sets the current working directory for the process. bool SetCurrentDirectory(const FilePath& path) { ThreadRestrictions::AssertIOAllowed(); int ret = chdir(path.value().c_str()); return !ret; } bool VerifyPathControlledByUser(const FilePath& base, const FilePath& path, uid_t owner_uid, const std::set& group_gids) { if (base != path && !base.IsParent(path)) { DLOG(ERROR) << "|base| must be a subdirectory of |path|. base = \"" << base.value() << "\", path = \"" << path.value() << "\""; return false; } std::vector base_components; std::vector path_components; base.GetComponents(&base_components); path.GetComponents(&path_components); std::vector::const_iterator ib, ip; for (ib = base_components.begin(), ip = path_components.begin(); ib != base_components.end(); ++ib, ++ip) { // |base| must be a subpath of |path|, so all components should match. // If these CHECKs fail, look at the test that base is a parent of // path at the top of this function. DCHECK(ip != path_components.end()); DCHECK(*ip == *ib); } FilePath current_path = base; if (!VerifySpecificPathControlledByUser(current_path, owner_uid, group_gids)) return false; for (; ip != path_components.end(); ++ip) { current_path = current_path.Append(*ip); if (!VerifySpecificPathControlledByUser( current_path, owner_uid, group_gids)) return false; } return true; } #if defined(OS_MACOSX) && !defined(OS_IOS) bool VerifyPathControlledByAdmin(const FilePath& path) { const unsigned kRootUid = 0; const FilePath kFileSystemRoot("/"); // The name of the administrator group on mac os. const char* const kAdminGroupNames[] = { "admin", "wheel" }; // Reading the groups database may touch the file system. ThreadRestrictions::AssertIOAllowed(); std::set allowed_group_ids; for (int i = 0, ie = arraysize(kAdminGroupNames); i < ie; ++i) { struct group *group_record = getgrnam(kAdminGroupNames[i]); if (!group_record) { DPLOG(ERROR) << "Could not get the group ID of group \"" << kAdminGroupNames[i] << "\"."; continue; } allowed_group_ids.insert(group_record->gr_gid); } return VerifyPathControlledByUser( kFileSystemRoot, path, kRootUid, allowed_group_ids); } #endif // defined(OS_MACOSX) && !defined(OS_IOS) int GetMaximumPathComponentLength(const FilePath& path) { ThreadRestrictions::AssertIOAllowed(); return pathconf(path.value().c_str(), _PC_NAME_MAX); } #if !defined(OS_ANDROID) // This is implemented in file_util_android.cc for that platform. bool GetShmemTempDir(bool executable, FilePath* path) { #if defined(OS_LINUX) bool use_dev_shm = true; if (executable) { static const bool s_dev_shm_executable = DetermineDevShmExecutable(); use_dev_shm = s_dev_shm_executable; } if (use_dev_shm) { *path = FilePath("/dev/shm"); return true; } #endif return GetTempDir(path); } #endif // !defined(OS_ANDROID) // ----------------------------------------------------------------------------- namespace internal { bool MoveUnsafe(const FilePath& from_path, const FilePath& to_path) { ThreadRestrictions::AssertIOAllowed(); // Windows compatibility: if to_path exists, from_path and to_path // must be the same type, either both files, or both directories. stat_wrapper_t to_file_info; if (CallStat(to_path.value().c_str(), &to_file_info) == 0) { stat_wrapper_t from_file_info; if (CallStat(from_path.value().c_str(), &from_file_info) == 0) { if (S_ISDIR(to_file_info.st_mode) != S_ISDIR(from_file_info.st_mode)) return false; } else { return false; } } if (rename(from_path.value().c_str(), to_path.value().c_str()) == 0) return true; if (!CopyDirectory(from_path, to_path, true)) return false; DeleteFile(from_path, true); return true; } #if !defined(OS_MACOSX) // Mac has its own implementation, this is for all other Posix systems. bool CopyFileUnsafe(const FilePath& from_path, const FilePath& to_path) { ThreadRestrictions::AssertIOAllowed(); int infile = HANDLE_EINTR(open(from_path.value().c_str(), O_RDONLY)); if (infile < 0) return false; int outfile = HANDLE_EINTR(creat(to_path.value().c_str(), 0666)); if (outfile < 0) { close(infile); return false; } const size_t kBufferSize = 32768; std::vector buffer(kBufferSize); bool result = true; while (result) { ssize_t bytes_read = HANDLE_EINTR(read(infile, &buffer[0], buffer.size())); if (bytes_read < 0) { result = false; break; } if (bytes_read == 0) break; // Allow for partial writes ssize_t bytes_written_per_read = 0; do { ssize_t bytes_written_partial = HANDLE_EINTR(write( outfile, &buffer[bytes_written_per_read], bytes_read - bytes_written_per_read)); if (bytes_written_partial < 0) { result = false; break; } bytes_written_per_read += bytes_written_partial; } while (bytes_written_per_read < bytes_read); } if (IGNORE_EINTR(close(infile)) < 0) result = false; if (IGNORE_EINTR(close(outfile)) < 0) result = false; return result; } #endif // !defined(OS_MACOSX) } // namespace internal } // namespace base