// Copyright 2013 Dolphin Emulator Project / 2014 Citra Emulator Project // Licensed under GPLv2 or any later version // Refer to the license.txt file included. #include #include #include #include #include #include #include #include #include #include "common/assert.h" #include "common/common_funcs.h" #include "common/common_paths.h" #include "common/error.h" #include "common/file_util.h" #include "common/logging/log.h" #include "common/scope_exit.h" #include "common/string_util.h" #ifdef _WIN32 #include // windows.h needs to be included before other windows headers #include // getcwd #include #include #include #include // for SHGetFolderPath #include #include "common/string_util.h" #ifdef _MSC_VER // 64 bit offsets for MSVC #define fseeko _fseeki64 #define ftello _ftelli64 #define fileno _fileno #endif // 64 bit offsets for MSVC and MinGW. MinGW also needs this for using _wstat64 #ifndef __MINGW64__ #define stat _stat64 #define fstat _fstat64 #endif #else #ifdef __APPLE__ #include #endif #include #include #include #include #include #include #include #endif #if defined(__APPLE__) // CFURL contains __attribute__ directives that gcc does not know how to parse, so we need to just // ignore them if we're not using clang. The macro is only used to prevent linking against // functions that don't exist on older versions of macOS, and the worst case scenario is a linker // error, so this is perfectly safe, just inconvenient. #ifndef __clang__ #define availability(...) #endif #include #include #include #ifdef availability #undef availability #endif #endif #ifdef ANDROID #include "common/android_storage.h" #include "common/string_util.h" #endif #include #include #ifndef S_ISDIR #define S_ISDIR(m) (((m)&S_IFMT) == S_IFDIR) #endif // This namespace has various generic functions related to files and paths. // The code still needs a ton of cleanup. // REMEMBER: strdup considered harmful! namespace FileUtil { using Common::GetLastErrorMsg; // Remove any ending forward slashes from directory paths // Modifies argument. static void StripTailDirSlashes(std::string& fname) { if (fname.length() <= 1) { return; } std::size_t i = fname.length(); while (i > 0 && fname[i - 1] == DIR_SEP_CHR) { --i; } fname.resize(i); } bool Exists(const std::string& filename) { std::string copy(filename); StripTailDirSlashes(copy); #ifdef _WIN32 struct stat file_info; // Windows needs a slash to identify a driver root if (copy.size() != 0 && copy.back() == ':') copy += DIR_SEP_CHR; int result = _wstat64(Common::UTF8ToUTF16W(copy).c_str(), &file_info); #elif ANDROID int result = AndroidStorage::FileExists(filename) ? 0 : -1; #else struct stat file_info; int result = stat(copy.c_str(), &file_info); #endif return (result == 0); } bool IsDirectory(const std::string& filename) { #ifdef ANDROID return AndroidStorage::IsDirectory(filename); #endif struct stat file_info; std::string copy(filename); StripTailDirSlashes(copy); #ifdef _WIN32 // Windows needs a slash to identify a driver root if (copy.size() != 0 && copy.back() == ':') copy += DIR_SEP_CHR; int result = _wstat64(Common::UTF8ToUTF16W(copy).c_str(), &file_info); #else int result = stat(copy.c_str(), &file_info); #endif if (result < 0) { LOG_DEBUG(Common_Filesystem, "stat failed on {}: {}", filename, GetLastErrorMsg()); return false; } return S_ISDIR(file_info.st_mode); } bool Delete(const std::string& filename) { LOG_TRACE(Common_Filesystem, "file {}", filename); // Return true because we care about the file no // being there, not the actual delete. if (!Exists(filename)) { LOG_DEBUG(Common_Filesystem, "{} does not exist", filename); return true; } // We can't delete a directory if (IsDirectory(filename)) { LOG_ERROR(Common_Filesystem, "Failed: {} is a directory", filename); return false; } #ifdef _WIN32 if (!DeleteFileW(Common::UTF8ToUTF16W(filename).c_str())) { LOG_ERROR(Common_Filesystem, "DeleteFile failed on {}: {}", filename, GetLastErrorMsg()); return false; } #elif ANDROID if (!AndroidStorage::DeleteDocument(filename)) { LOG_ERROR(Common_Filesystem, "unlink failed on {}", filename); return false; } #else if (unlink(filename.c_str()) == -1) { LOG_ERROR(Common_Filesystem, "unlink failed on {}: {}", filename, GetLastErrorMsg()); return false; } #endif return true; } bool CreateDir(const std::string& path) { LOG_TRACE(Common_Filesystem, "directory {}", path); #ifdef _WIN32 if (::CreateDirectoryW(Common::UTF8ToUTF16W(path).c_str(), nullptr)) return true; DWORD error = GetLastError(); if (error == ERROR_ALREADY_EXISTS) { LOG_DEBUG(Common_Filesystem, "CreateDirectory failed on {}: already exists", path); return true; } LOG_ERROR(Common_Filesystem, "CreateDirectory failed on {}: {}", path, error); return false; #elif ANDROID std::string directory = path; std::string filename = path; if (Common::EndsWith(path, "/")) { directory = GetParentPath(path); filename = GetParentPath(path); } directory = GetParentPath(directory); filename = GetFilename(filename); // If directory path is empty, set it to root. if (directory.empty()) { directory = "/"; } if (!AndroidStorage::CreateDir(directory, filename)) { LOG_ERROR(Common_Filesystem, "mkdir failed on {}", path); return false; }; return true; #else if (mkdir(path.c_str(), 0755) == 0) return true; int err = errno; if (err == EEXIST) { LOG_DEBUG(Common_Filesystem, "mkdir failed on {}: already exists", path); return true; } LOG_ERROR(Common_Filesystem, "mkdir failed on {}: {}", path, strerror(err)); return false; #endif } bool CreateFullPath(const std::string& fullPath) { int panicCounter = 100; LOG_TRACE(Common_Filesystem, "path {}", fullPath); if (FileUtil::Exists(fullPath)) { LOG_DEBUG(Common_Filesystem, "path exists {}", fullPath); return true; } std::size_t position = 0; while (true) { // Find next sub path position = fullPath.find(DIR_SEP_CHR, position); // we're done, yay! if (position == fullPath.npos) return true; // Include the '/' so the first call is CreateDir("/") rather than CreateDir("") std::string const subPath(fullPath.substr(0, position + 1)); if (!FileUtil::IsDirectory(subPath) && !FileUtil::CreateDir(subPath)) { LOG_ERROR(Common, "CreateFullPath: directory creation failed"); return false; } // A safety check panicCounter--; if (panicCounter <= 0) { LOG_ERROR(Common, "CreateFullPath: directory structure is too deep"); return false; } position++; } } bool DeleteDir(const std::string& filename) { LOG_TRACE(Common_Filesystem, "directory {}", filename); // check if a directory if (!FileUtil::IsDirectory(filename)) { LOG_ERROR(Common_Filesystem, "Not a directory {}", filename); return false; } #ifdef _WIN32 if (::RemoveDirectoryW(Common::UTF8ToUTF16W(filename).c_str())) return true; #elif ANDROID if (AndroidStorage::DeleteDocument(filename)) return true; #else if (rmdir(filename.c_str()) == 0) return true; #endif LOG_ERROR(Common_Filesystem, "failed {}: {}", filename, GetLastErrorMsg()); return false; } bool Rename(const std::string& srcFilename, const std::string& destFilename) { LOG_TRACE(Common_Filesystem, "{} --> {}", srcFilename, destFilename); #ifdef _WIN32 if (_wrename(Common::UTF8ToUTF16W(srcFilename).c_str(), Common::UTF8ToUTF16W(destFilename).c_str()) == 0) return true; #elif ANDROID if (AndroidStorage::RenameFile(srcFilename, std::string(GetFilename(destFilename)))) return true; #else if (rename(srcFilename.c_str(), destFilename.c_str()) == 0) return true; #endif LOG_ERROR(Common_Filesystem, "failed {} --> {}: {}", srcFilename, destFilename, GetLastErrorMsg()); return false; } bool Copy(const std::string& srcFilename, const std::string& destFilename) { LOG_TRACE(Common_Filesystem, "{} --> {}", srcFilename, destFilename); #ifdef _WIN32 if (CopyFileW(Common::UTF8ToUTF16W(srcFilename).c_str(), Common::UTF8ToUTF16W(destFilename).c_str(), FALSE)) return true; LOG_ERROR(Common_Filesystem, "failed {} --> {}: {}", srcFilename, destFilename, GetLastErrorMsg()); return false; #elif ANDROID return AndroidStorage::CopyFile(srcFilename, std::string(GetParentPath(destFilename)), std::string(GetFilename(destFilename))); #else // Open input file FILE* input = fopen(srcFilename.c_str(), "rb"); if (!input) { LOG_ERROR(Common_Filesystem, "opening input failed {} --> {}: {}", srcFilename, destFilename, GetLastErrorMsg()); return false; } SCOPE_EXIT({ fclose(input); }); // open output file FILE* output = fopen(destFilename.c_str(), "wb"); if (!output) { LOG_ERROR(Common_Filesystem, "opening output failed {} --> {}: {}", srcFilename, destFilename, GetLastErrorMsg()); return false; } SCOPE_EXIT({ fclose(output); }); // copy loop std::array buffer; while (!feof(input)) { // read input std::size_t rnum = fread(buffer.data(), sizeof(char), buffer.size(), input); if (rnum != buffer.size()) { if (ferror(input) != 0) { LOG_ERROR(Common_Filesystem, "failed reading from source, {} --> {}: {}", srcFilename, destFilename, GetLastErrorMsg()); return false; } } // write output std::size_t wnum = fwrite(buffer.data(), sizeof(char), rnum, output); if (wnum != rnum) { LOG_ERROR(Common_Filesystem, "failed writing to output, {} --> {}: {}", srcFilename, destFilename, GetLastErrorMsg()); return false; } } return true; #endif } u64 GetSize(const std::string& filename) { if (!Exists(filename)) { LOG_ERROR(Common_Filesystem, "failed {}: No such file", filename); return 0; } if (IsDirectory(filename)) { LOG_ERROR(Common_Filesystem, "failed {}: is a directory", filename); return 0; } struct stat buf; #ifdef _WIN32 if (_wstat64(Common::UTF8ToUTF16W(filename).c_str(), &buf) == 0) #elif ANDROID u64 result = AndroidStorage::GetSize(filename); LOG_TRACE(Common_Filesystem, "{}: {}", filename, result); return result; #else if (stat(filename.c_str(), &buf) == 0) #endif { LOG_TRACE(Common_Filesystem, "{}: {}", filename, buf.st_size); return buf.st_size; } LOG_ERROR(Common_Filesystem, "Stat failed {}: {}", filename, GetLastErrorMsg()); return 0; } u64 GetSize(const int fd) { struct stat buf; if (fstat(fd, &buf) != 0) { LOG_ERROR(Common_Filesystem, "GetSize: stat failed {}: {}", fd, GetLastErrorMsg()); return 0; } return buf.st_size; } u64 GetSize(FILE* f) { // can't use off_t here because it can be 32-bit u64 pos = ftello(f); if (fseeko(f, 0, SEEK_END) != 0) { LOG_ERROR(Common_Filesystem, "GetSize: seek failed {}: {}", fmt::ptr(f), GetLastErrorMsg()); return 0; } u64 size = ftello(f); if ((size != pos) && (fseeko(f, pos, SEEK_SET) != 0)) { LOG_ERROR(Common_Filesystem, "GetSize: seek failed {}: {}", fmt::ptr(f), GetLastErrorMsg()); return 0; } return size; } bool CreateEmptyFile(const std::string& filename) { LOG_TRACE(Common_Filesystem, "{}", filename); if (!FileUtil::IOFile(filename, "wb").IsOpen()) { LOG_ERROR(Common_Filesystem, "failed {}: {}", filename, GetLastErrorMsg()); return false; } return true; } bool ForeachDirectoryEntry(u64* num_entries_out, const std::string& directory, DirectoryEntryCallable callback) { LOG_TRACE(Common_Filesystem, "directory {}", directory); // How many files + directories we found u64 found_entries = 0; // Save the status of callback function bool callback_error = false; #ifdef _WIN32 // Find the first file in the directory. WIN32_FIND_DATAW ffd; HANDLE handle_find = FindFirstFileW(Common::UTF8ToUTF16W(directory + "\\*").c_str(), &ffd); if (handle_find == INVALID_HANDLE_VALUE) { FindClose(handle_find); return false; } // windows loop do { const std::string virtual_name(Common::UTF16ToUTF8(ffd.cFileName)); #elif ANDROID // android loop auto result = AndroidStorage::GetFilesName(directory); for (auto virtual_name : result) { #else DIR* dirp = opendir(directory.c_str()); if (!dirp) return false; // non windows loop while (struct dirent* result = readdir(dirp)) { const std::string virtual_name(result->d_name); #endif if (virtual_name == "." || virtual_name == "..") continue; u64 ret_entries = 0; if (!callback(&ret_entries, directory, virtual_name)) { callback_error = true; break; } found_entries += ret_entries; #ifdef _WIN32 } while (FindNextFileW(handle_find, &ffd) != 0); FindClose(handle_find); #elif ANDROID } #else } closedir(dirp); #endif if (callback_error) return false; // num_entries_out is allowed to be specified nullptr, in which case we shouldn't try to set it if (num_entries_out != nullptr) *num_entries_out = found_entries; return true; } u64 ScanDirectoryTree(const std::string& directory, FSTEntry& parent_entry, unsigned int recursion) { const auto callback = [recursion, &parent_entry](u64* num_entries_out, const std::string& directory, const std::string& virtual_name) -> bool { FSTEntry entry; entry.virtualName = virtual_name; entry.physicalName = directory + DIR_SEP + virtual_name; if (IsDirectory(entry.physicalName)) { entry.isDirectory = true; // is a directory, lets go inside if we didn't recurse to often if (recursion > 0) { entry.size = ScanDirectoryTree(entry.physicalName, entry, recursion - 1); *num_entries_out += entry.size; } else { entry.size = 0; } } else { // is a file entry.isDirectory = false; entry.size = GetSize(entry.physicalName); } (*num_entries_out)++; // Push into the tree parent_entry.children.push_back(std::move(entry)); return true; }; u64 num_entries; return ForeachDirectoryEntry(&num_entries, directory, callback) ? num_entries : 0; } void GetAllFilesFromNestedEntries(FSTEntry& directory, std::vector& output) { std::vector files; for (auto& entry : directory.children) { if (entry.isDirectory) { GetAllFilesFromNestedEntries(entry, output); } else { output.push_back(entry); } } } bool DeleteDirRecursively(const std::string& directory, unsigned int recursion) { const auto callback = [recursion]([[maybe_unused]] u64* num_entries_out, const std::string& directory, const std::string& virtual_name) -> bool { std::string new_path = directory + DIR_SEP_CHR + virtual_name; if (IsDirectory(new_path)) { if (recursion == 0) return false; return DeleteDirRecursively(new_path, recursion - 1); } return Delete(new_path); }; if (!ForeachDirectoryEntry(nullptr, directory, callback)) return false; // Delete the outermost directory FileUtil::DeleteDir(directory); return true; } void CopyDir([[maybe_unused]] const std::string& source_path, [[maybe_unused]] const std::string& dest_path) { #ifndef _WIN32 if (source_path == dest_path) return; if (!FileUtil::Exists(source_path)) return; if (!FileUtil::Exists(dest_path)) FileUtil::CreateFullPath(dest_path); #ifdef ANDROID auto result = AndroidStorage::GetFilesName(source_path); for (auto virtualName : result) { #else DIR* dirp = opendir(source_path.c_str()); if (!dirp) return; while (struct dirent* result = readdir(dirp)) { const std::string virtualName(result->d_name); #endif // ANDROID // check for "." and ".." if (((virtualName[0] == '.') && (virtualName[1] == '\0')) || ((virtualName[0] == '.') && (virtualName[1] == '.') && (virtualName[2] == '\0'))) continue; std::string source, dest; source = source_path + virtualName; dest = dest_path + virtualName; if (IsDirectory(source)) { source += '/'; dest += '/'; if (!FileUtil::Exists(dest)) FileUtil::CreateFullPath(dest); CopyDir(source, dest); } else if (!FileUtil::Exists(dest)) FileUtil::Copy(source, dest); } #ifndef ANDROID closedir(dirp); #endif // ANDROID #endif // _WIN32 } std::optional GetCurrentDir() { // Get the current working directory (getcwd uses malloc) #ifdef _WIN32 wchar_t* dir = _wgetcwd(nullptr, 0); if (!dir) { #else char* dir = getcwd(nullptr, 0); if (!dir) { #endif LOG_ERROR(Common_Filesystem, "GetCurrentDirectory failed: {}", GetLastErrorMsg()); return {}; } #ifdef _WIN32 std::string strDir = Common::UTF16ToUTF8(dir); #else std::string strDir = dir; #endif free(dir); return strDir; } // namespace FileUtil bool SetCurrentDir(const std::string& directory) { #ifdef _WIN32 return _wchdir(Common::UTF8ToUTF16W(directory).c_str()) == 0; #else return chdir(directory.c_str()) == 0; #endif } #if defined(__APPLE__) std::string GetBundleDirectory() { CFURLRef BundleRef; char AppBundlePath[MAXPATHLEN]; // Get the main bundle for the app BundleRef = CFBundleCopyBundleURL(CFBundleGetMainBundle()); CFStringRef BundlePath = CFURLCopyFileSystemPath(BundleRef, kCFURLPOSIXPathStyle); CFStringGetFileSystemRepresentation(BundlePath, AppBundlePath, sizeof(AppBundlePath)); CFRelease(BundleRef); CFRelease(BundlePath); return AppBundlePath; } #endif #ifdef _WIN32 const std::string& GetExeDirectory() { static std::string exe_path; if (exe_path.empty()) { wchar_t wchar_exe_path[2048]; GetModuleFileNameW(nullptr, wchar_exe_path, 2048); exe_path = Common::UTF16ToUTF8(wchar_exe_path); exe_path = exe_path.substr(0, exe_path.find_last_of('\\')); } return exe_path; } std::string AppDataRoamingDirectory() { PWSTR pw_local_path = nullptr; // Only supported by Windows Vista or later SHGetKnownFolderPath(FOLDERID_RoamingAppData, 0, nullptr, &pw_local_path); std::string local_path = Common::UTF16ToUTF8(pw_local_path); CoTaskMemFree(pw_local_path); return local_path; } #else /** * @return The user’s home directory on POSIX systems */ static const std::string& GetHomeDirectory() { static std::string home_path; if (home_path.empty()) { const char* envvar = getenv("HOME"); if (envvar) { home_path = envvar; } else { auto pw = getpwuid(getuid()); ASSERT_MSG(pw, "$HOME isn’t defined, and the current user can’t be found in /etc/passwd."); home_path = pw->pw_dir; } } return home_path; } /** * Follows the XDG Base Directory Specification to get a directory path * @param envvar The XDG environment variable to get the value from * @return The directory path * @sa http://standards.freedesktop.org/basedir-spec/basedir-spec-latest.html */ [[maybe_unused]] static const std::string GetUserDirectory(const std::string& envvar) { const char* directory = getenv(envvar.c_str()); std::string user_dir; if (directory) { user_dir = directory; } else { std::string subdirectory; if (envvar == "XDG_DATA_HOME") subdirectory = DIR_SEP ".local" DIR_SEP "share"; else if (envvar == "XDG_CONFIG_HOME") subdirectory = DIR_SEP ".config"; else if (envvar == "XDG_CACHE_HOME") subdirectory = DIR_SEP ".cache"; else ASSERT_MSG(false, "Unknown XDG variable {}.", envvar); user_dir = GetHomeDirectory() + subdirectory; } ASSERT_MSG(!user_dir.empty(), "User directory {} musn’t be empty.", envvar); ASSERT_MSG(user_dir[0] == '/', "User directory {} must be absolute.", envvar); return user_dir; } #endif std::string GetSysDirectory() { std::string sysDir; #if defined(__APPLE__) sysDir = GetBundleDirectory(); sysDir += DIR_SEP; sysDir += SYSDATA_DIR; #else sysDir = SYSDATA_DIR; #endif sysDir += DIR_SEP; LOG_DEBUG(Common_Filesystem, "Setting to {}:", sysDir); return sysDir; } namespace { std::unordered_map g_paths; std::unordered_map g_default_paths; } // namespace void SetUserPath(const std::string& path) { std::string& user_path = g_paths[UserPath::UserDir]; if (!path.empty() && CreateFullPath(path)) { LOG_INFO(Common_Filesystem, "Using {} as the user directory", path); user_path = path; g_paths.emplace(UserPath::ConfigDir, user_path + CONFIG_DIR DIR_SEP); g_paths.emplace(UserPath::CacheDir, user_path + CACHE_DIR DIR_SEP); } else { #ifdef _WIN32 user_path = GetExeDirectory() + DIR_SEP USERDATA_DIR DIR_SEP; if (!FileUtil::IsDirectory(user_path)) { user_path = AppDataRoamingDirectory() + DIR_SEP EMU_DATA_DIR DIR_SEP; } else { LOG_INFO(Common_Filesystem, "Using the local user directory"); } g_paths.emplace(UserPath::ConfigDir, user_path + CONFIG_DIR DIR_SEP); g_paths.emplace(UserPath::CacheDir, user_path + CACHE_DIR DIR_SEP); #elif ANDROID user_path = "/"; g_paths.emplace(UserPath::ConfigDir, user_path + CONFIG_DIR DIR_SEP); g_paths.emplace(UserPath::CacheDir, user_path + CACHE_DIR DIR_SEP); #else if (FileUtil::Exists(ROOT_DIR DIR_SEP USERDATA_DIR)) { user_path = ROOT_DIR DIR_SEP USERDATA_DIR DIR_SEP; g_paths.emplace(UserPath::ConfigDir, user_path + CONFIG_DIR DIR_SEP); g_paths.emplace(UserPath::CacheDir, user_path + CACHE_DIR DIR_SEP); } else { std::string data_dir = GetUserDirectory("XDG_DATA_HOME") + DIR_SEP EMU_DATA_DIR DIR_SEP; std::string config_dir = GetUserDirectory("XDG_CONFIG_HOME") + DIR_SEP EMU_DATA_DIR DIR_SEP; std::string cache_dir = GetUserDirectory("XDG_CACHE_HOME") + DIR_SEP EMU_DATA_DIR DIR_SEP; #if defined(__APPLE__) // If XDG directories don't already exist from a previous setup, use standard macOS // paths. if (!FileUtil::Exists(data_dir) && !FileUtil::Exists(config_dir) && !FileUtil::Exists(cache_dir)) { data_dir = GetHomeDirectory() + DIR_SEP APPLE_EMU_DATA_DIR DIR_SEP; config_dir = data_dir + CONFIG_DIR DIR_SEP; cache_dir = data_dir + CACHE_DIR DIR_SEP; } #endif user_path = data_dir; g_paths.emplace(UserPath::ConfigDir, config_dir); g_paths.emplace(UserPath::CacheDir, cache_dir); } #endif } g_paths.emplace(UserPath::SDMCDir, user_path + SDMC_DIR DIR_SEP); g_paths.emplace(UserPath::NANDDir, user_path + NAND_DIR DIR_SEP); g_paths.emplace(UserPath::SysDataDir, user_path + SYSDATA_DIR DIR_SEP); // TODO: Put the logs in a better location for each OS g_paths.emplace(UserPath::LogDir, user_path + LOG_DIR DIR_SEP); g_paths.emplace(UserPath::CheatsDir, user_path + CHEATS_DIR DIR_SEP); g_paths.emplace(UserPath::DLLDir, user_path + DLL_DIR DIR_SEP); g_paths.emplace(UserPath::ShaderDir, user_path + SHADER_DIR DIR_SEP); g_paths.emplace(UserPath::DumpDir, user_path + DUMP_DIR DIR_SEP); g_paths.emplace(UserPath::LoadDir, user_path + LOAD_DIR DIR_SEP); g_paths.emplace(UserPath::StatesDir, user_path + STATES_DIR DIR_SEP); g_default_paths = g_paths; } std::string g_currentRomPath{}; void SetCurrentRomPath(const std::string& path) { g_currentRomPath = path; } bool StringReplace(std::string& haystack, const std::string& a, const std::string& b, bool swap) { const auto& needle = swap ? b : a; const auto& replacement = swap ? a : b; if (needle.empty()) { return false; } auto index = haystack.find(needle, 0); if (index == std::string::npos) { return false; } haystack.replace(index, needle.size(), replacement); return true; } std::string SerializePath(const std::string& input, bool is_saving) { auto result = input; StringReplace(result, "%CITRA_ROM_FILE%", g_currentRomPath, is_saving); StringReplace(result, "%CITRA_USER_DIR%", GetUserPath(UserPath::UserDir), is_saving); return result; } const std::string& GetUserPath(UserPath path) { // Set up all paths and files on the first run if (g_paths.empty()) SetUserPath(); return g_paths[path]; } const std::string& GetDefaultUserPath(UserPath path) { // Set up all paths and files on the first run if (g_default_paths.empty()) SetUserPath(); return g_default_paths[path]; } void UpdateUserPath(UserPath path, const std::string& filename) { if (filename.empty()) { return; } if (!FileUtil::IsDirectory(filename)) { LOG_ERROR(Common_Filesystem, "Path is not a directory. UserPath: {} filename: {}", path, filename); return; } g_paths[path] = SanitizePath(filename) + DIR_SEP; } std::size_t WriteStringToFile(bool text_file, const std::string& filename, std::string_view str) { return IOFile(filename, text_file ? "w" : "wb").WriteString(str); } std::size_t ReadFileToString(bool text_file, const std::string& filename, std::string& str) { IOFile file(filename, text_file ? "r" : "rb"); if (!file.IsOpen()) return 0; str.resize(static_cast(file.GetSize())); return file.ReadArray(str.data(), str.size()); } void SplitFilename83(const std::string& filename, std::array& short_name, std::array& extension) { const std::string forbidden_characters = ".\"/\\[]:;=, "; // On a FAT32 partition, 8.3 names are stored as a 11 bytes array, filled with spaces. short_name = {{' ', ' ', ' ', ' ', ' ', ' ', ' ', ' ', '\0'}}; extension = {{' ', ' ', ' ', '\0'}}; std::string::size_type point = filename.rfind('.'); if (point == filename.size() - 1) point = filename.rfind('.', point); // Get short name. int j = 0; for (char letter : filename.substr(0, point)) { if (forbidden_characters.find(letter, 0) != std::string::npos) continue; if (j == 8) { // TODO(Link Mauve): also do that for filenames containing a space. // TODO(Link Mauve): handle multiple files having the same short name. short_name[6] = '~'; short_name[7] = '1'; break; } short_name[j++] = Common::ToUpper(letter); } // Get extension. if (point != std::string::npos) { j = 0; for (char letter : filename.substr(point + 1, 3)) extension[j++] = Common::ToUpper(letter); } } std::vector SplitPathComponents(std::string_view filename) { std::string copy(filename); std::replace(copy.begin(), copy.end(), '\\', '/'); std::vector out; std::stringstream stream(copy); std::string item; while (std::getline(stream, item, '/')) { out.push_back(std::move(item)); } return out; } std::string_view GetParentPath(std::string_view path) { const auto name_bck_index = path.rfind('\\'); const auto name_fwd_index = path.rfind('/'); std::size_t name_index; if (name_bck_index == std::string_view::npos || name_fwd_index == std::string_view::npos) { name_index = std::min(name_bck_index, name_fwd_index); } else { name_index = std::max(name_bck_index, name_fwd_index); } return path.substr(0, name_index); } std::string_view GetPathWithoutTop(std::string_view path) { if (path.empty()) { return path; } while (path[0] == '\\' || path[0] == '/') { path.remove_prefix(1); if (path.empty()) { return path; } } const auto name_bck_index = path.find('\\'); const auto name_fwd_index = path.find('/'); return path.substr(std::min(name_bck_index, name_fwd_index) + 1); } std::string_view GetFilename(std::string_view path) { const auto name_index = path.find_last_of("\\/"); if (name_index == std::string_view::npos) { return path; } return path.substr(name_index + 1); } std::string_view GetExtensionFromFilename(std::string_view name) { const std::size_t index = name.rfind('.'); if (index == std::string_view::npos) { return {}; } return name.substr(index + 1); } std::string_view RemoveTrailingSlash(std::string_view path) { if (path.empty()) { return path; } if (path.back() == '\\' || path.back() == '/') { path.remove_suffix(1); return path; } return path; } std::string SanitizePath(std::string_view path_, DirectorySeparator directory_separator) { std::string path(path_); #ifdef ANDROID return std::string(RemoveTrailingSlash(path)); #endif char type1 = directory_separator == DirectorySeparator::BackwardSlash ? '/' : '\\'; char type2 = directory_separator == DirectorySeparator::BackwardSlash ? '\\' : '/'; if (directory_separator == DirectorySeparator::PlatformDefault) { #ifdef _WIN32 type1 = '/'; type2 = '\\'; #endif } std::replace(path.begin(), path.end(), type1, type2); auto start = path.begin(); #ifdef _WIN32 // allow network paths which start with a double backslash (e.g. \\server\share) if (start != path.end()) ++start; #endif path.erase(std::unique(start, path.end(), [type2](char c1, char c2) { return c1 == type2 && c2 == type2; }), path.end()); return std::string(RemoveTrailingSlash(path)); } IOFile::IOFile() = default; IOFile::IOFile(const std::string& filename, const char openmode[], int flags) : filename(filename), openmode(openmode), flags(flags) { Open(); } IOFile::~IOFile() { Close(); } IOFile::IOFile(IOFile&& other) noexcept { Swap(other); } IOFile& IOFile::operator=(IOFile&& other) noexcept { Swap(other); return *this; } void IOFile::Swap(IOFile& other) noexcept { std::swap(m_file, other.m_file); std::swap(m_fd, other.m_fd); std::swap(m_good, other.m_good); std::swap(filename, other.filename); std::swap(openmode, other.openmode); std::swap(flags, other.flags); } bool IOFile::Open() { Close(); #ifdef _WIN32 if (flags == 0) { flags = _SH_DENYNO; } m_file = _wfsopen(Common::UTF8ToUTF16W(filename).c_str(), Common::UTF8ToUTF16W(openmode).c_str(), flags); m_good = m_file != nullptr; #elif ANDROID // Check whether filepath is startsWith content AndroidStorage::AndroidOpenMode android_open_mode = AndroidStorage::ParseOpenmode(openmode); if (android_open_mode == AndroidStorage::AndroidOpenMode::WRITE || android_open_mode == AndroidStorage::AndroidOpenMode::READ_WRITE || android_open_mode == AndroidStorage::AndroidOpenMode::WRITE_APPEND || android_open_mode == AndroidStorage::AndroidOpenMode::WRITE_TRUNCATE || android_open_mode == AndroidStorage::AndroidOpenMode::READ_WRITE_TRUNCATE || android_open_mode == AndroidStorage::AndroidOpenMode::READ_WRITE_APPEND) { if (!FileUtil::Exists(filename)) { std::string directory(GetParentPath(filename)); std::string display_name(GetFilename(filename)); if (!AndroidStorage::CreateFile(directory, display_name)) { m_good = m_file != nullptr; return m_good; } } } m_fd = AndroidStorage::OpenContentUri(filename, android_open_mode); if (m_fd != -1) { int error_num = 0; m_file = fdopen(m_fd, openmode.c_str()); error_num = errno; if (error_num != 0 && m_file == nullptr) { LOG_ERROR(Common_Filesystem, "Error on file: {}, error: {}", filename, strerror(error_num)); } } m_good = m_file != nullptr; #else m_file = std::fopen(filename.c_str(), openmode.c_str()); m_good = m_file != nullptr; #endif return m_good; } bool IOFile::Close() { if (!IsOpen() || 0 != std::fclose(m_file)) m_good = false; m_file = nullptr; return m_good; } u64 IOFile::GetSize() const { if (IsOpen()) return FileUtil::GetSize(m_file); return 0; } bool IOFile::Seek(s64 off, int origin) { if (!IsOpen() || 0 != fseeko(m_file, off, origin)) m_good = false; return m_good; } u64 IOFile::Tell() const { if (IsOpen()) return ftello(m_file); return std::numeric_limits::max(); } bool IOFile::Flush() { if (!IsOpen() || 0 != std::fflush(m_file)) m_good = false; return m_good; } std::size_t IOFile::ReadImpl(void* data, std::size_t length, std::size_t data_size) { if (!IsOpen()) { m_good = false; return std::numeric_limits::max(); } if (length == 0) { return 0; } DEBUG_ASSERT(data != nullptr); return std::fread(data, data_size, length, m_file); } #ifdef _WIN32 static std::size_t pread(int fd, void* buf, size_t count, uint64_t offset) { long unsigned int read_bytes = 0; OVERLAPPED overlapped = {0}; HANDLE file = reinterpret_cast(_get_osfhandle(fd)); overlapped.OffsetHigh = static_cast(offset >> 32); overlapped.Offset = static_cast(offset & 0xFFFF'FFFFLL); SetLastError(0); bool ret = ReadFile(file, buf, static_cast(count), &read_bytes, &overlapped); if (!ret && GetLastError() != ERROR_HANDLE_EOF) { errno = GetLastError(); return std::numeric_limits::max(); } return read_bytes; } #else #define pread ::pread #endif std::size_t IOFile::ReadAtImpl(void* data, std::size_t length, std::size_t data_size, std::size_t offset) { if (!IsOpen()) { m_good = false; return std::numeric_limits::max(); } if (length == 0) { return 0; } DEBUG_ASSERT(data != nullptr); return pread(fileno(m_file), data, data_size * length, offset); } std::size_t IOFile::WriteImpl(const void* data, std::size_t length, std::size_t data_size) { if (!IsOpen()) { m_good = false; return std::numeric_limits::max(); } if (length == 0) { return 0; } DEBUG_ASSERT(data != nullptr); return std::fwrite(data, data_size, length, m_file); } bool IOFile::Resize(u64 size) { if (!IsOpen() || 0 != #ifdef _WIN32 // ector: _chsize sucks, not 64-bit safe // F|RES: changed to _chsize_s. i think it is 64-bit safe _chsize_s(_fileno(m_file), size) #else // TODO: handle 64bit and growing ftruncate(fileno(m_file), size) #endif ) m_good = false; return m_good; } template using boost_iostreams = boost::iostreams::stream; template <> void OpenFStream( boost_iostreams& fstream, const std::string& filename) { IOFile file(filename, "r"); if (file.GetFd() == -1) return; int fd = dup(file.GetFd()); if (fd == -1) return; boost::iostreams::file_descriptor_source file_descriptor_source(fd, boost::iostreams::close_handle); fstream.open(file_descriptor_source); } template <> void OpenFStream( boost_iostreams& fstream, const std::string& filename) { IOFile file(filename, "w"); if (file.GetFd() == -1) return; int fd = dup(file.GetFd()); if (fd == -1) return; boost::iostreams::file_descriptor_sink file_descriptor_sink(fd, boost::iostreams::close_handle); fstream.open(file_descriptor_sink); } } // namespace FileUtil