const builtin = @import("builtin"); const std = @import("std.zig"); const os = std.os; const mem = std.mem; const base64 = std.base64; const crypto = std.crypto; const Allocator = std.mem.Allocator; const assert = std.debug.assert; const math = std.math; pub const path = @import("fs/path.zig"); pub const File = @import("fs/file.zig").File; pub const symLink = os.symlink; pub const symLinkC = os.symlinkC; pub const rename = os.rename; pub const renameC = os.renameC; pub const renameW = os.renameW; pub const realpath = os.realpath; pub const realpathC = os.realpathC; pub const realpathW = os.realpathW; pub const getAppDataDir = @import("fs/get_app_data_dir.zig").getAppDataDir; pub const GetAppDataDirError = @import("fs/get_app_data_dir.zig").GetAppDataDirError; /// This represents the maximum size of a UTF-8 encoded file path. /// All file system operations which return a path are guaranteed to /// fit into a UTF-8 encoded array of this length. /// The byte count includes room for a null sentinel byte. pub const MAX_PATH_BYTES = switch (builtin.os) { .linux, .macosx, .ios, .freebsd, .netbsd, .dragonfly => os.PATH_MAX, // Each UTF-16LE character may be expanded to 3 UTF-8 bytes. // If it would require 4 UTF-8 bytes, then there would be a surrogate // pair in the UTF-16LE, and we (over)account 3 bytes for it that way. // +1 for the null byte at the end, which can be encoded in 1 byte. .windows => os.windows.PATH_MAX_WIDE * 3 + 1, else => @compileError("Unsupported OS"), }; // here we replace the standard +/ with -_ so that it can be used in a file name const b64_fs_encoder = base64.Base64Encoder.init("ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789-_", base64.standard_pad_char); /// TODO remove the allocator requirement from this API pub fn atomicSymLink(allocator: *Allocator, existing_path: []const u8, new_path: []const u8) !void { if (symLink(existing_path, new_path)) { return; } else |err| switch (err) { error.PathAlreadyExists => {}, else => return err, // TODO zig should know this set does not include PathAlreadyExists } const dirname = path.dirname(new_path) orelse "."; var rand_buf: [12]u8 = undefined; const tmp_path = try allocator.alloc(u8, dirname.len + 1 + base64.Base64Encoder.calcSize(rand_buf.len)); defer allocator.free(tmp_path); mem.copy(u8, tmp_path[0..], dirname); tmp_path[dirname.len] = path.sep; while (true) { try crypto.randomBytes(rand_buf[0..]); b64_fs_encoder.encode(tmp_path[dirname.len + 1 ..], &rand_buf); if (symLink(existing_path, tmp_path)) { return rename(tmp_path, new_path); } else |err| switch (err) { error.PathAlreadyExists => continue, else => return err, // TODO zig should know this set does not include PathAlreadyExists } } } // TODO fix enum literal not casting to error union const PrevStatus = enum { stale, fresh, }; pub fn updateFile(source_path: []const u8, dest_path: []const u8) !PrevStatus { return updateFileMode(source_path, dest_path, null); } /// Check the file size, mtime, and mode of `source_path` and `dest_path`. If they are equal, does nothing. /// Otherwise, atomically copies `source_path` to `dest_path`. The destination file gains the mtime, /// atime, and mode of the source file so that the next call to `updateFile` will not need a copy. /// Returns the previous status of the file before updating. /// If any of the directories do not exist for dest_path, they are created. /// TODO https://github.com/ziglang/zig/issues/2885 pub fn updateFileMode(source_path: []const u8, dest_path: []const u8, mode: ?File.Mode) !PrevStatus { const my_cwd = cwd(); var src_file = try my_cwd.openFile(source_path, .{}); defer src_file.close(); const src_stat = try src_file.stat(); check_dest_stat: { const dest_stat = blk: { var dest_file = my_cwd.openFile(dest_path, .{}) catch |err| switch (err) { error.FileNotFound => break :check_dest_stat, else => |e| return e, }; defer dest_file.close(); break :blk try dest_file.stat(); }; if (src_stat.size == dest_stat.size and src_stat.mtime == dest_stat.mtime and src_stat.mode == dest_stat.mode) { return PrevStatus.fresh; } } const actual_mode = mode orelse src_stat.mode; // TODO this logic could be made more efficient by calling makePath, once // that API does not require an allocator var atomic_file = make_atomic_file: while (true) { const af = AtomicFile.init(dest_path, actual_mode) catch |err| switch (err) { error.FileNotFound => { var p = dest_path; while (path.dirname(p)) |dirname| { makeDir(dirname) catch |e| switch (e) { error.FileNotFound => { p = dirname; continue; }, else => return e, }; continue :make_atomic_file; } else { return err; } }, else => |e| return e, }; break af; } else unreachable; defer atomic_file.deinit(); const in_stream = &src_file.inStream().stream; var buf: [mem.page_size * 6]u8 = undefined; while (true) { const amt = try in_stream.readFull(buf[0..]); try atomic_file.file.write(buf[0..amt]); if (amt != buf.len) { try atomic_file.file.updateTimes(src_stat.atime, src_stat.mtime); try atomic_file.finish(); return PrevStatus.stale; } } } /// Guaranteed to be atomic. However until https://patchwork.kernel.org/patch/9636735/ is /// merged and readily available, /// there is a possibility of power loss or application termination leaving temporary files present /// in the same directory as dest_path. /// Destination file will have the same mode as the source file. pub fn copyFile(source_path: []const u8, dest_path: []const u8) !void { var in_file = try cwd().openFile(source_path, .{}); defer in_file.close(); const mode = try in_file.mode(); const in_stream = &in_file.inStream().stream; var atomic_file = try AtomicFile.init(dest_path, mode); defer atomic_file.deinit(); var buf: [mem.page_size]u8 = undefined; while (true) { const amt = try in_stream.readFull(buf[0..]); try atomic_file.file.write(buf[0..amt]); if (amt != buf.len) { return atomic_file.finish(); } } } /// Guaranteed to be atomic. However until https://patchwork.kernel.org/patch/9636735/ is /// merged and readily available, /// there is a possibility of power loss or application termination leaving temporary files present pub fn copyFileMode(source_path: []const u8, dest_path: []const u8, mode: File.Mode) !void { var in_file = try cwd().openFile(source_path, .{}); defer in_file.close(); var atomic_file = try AtomicFile.init(dest_path, mode); defer atomic_file.deinit(); var buf: [mem.page_size * 6]u8 = undefined; while (true) { const amt = try in_file.read(buf[0..]); try atomic_file.file.write(buf[0..amt]); if (amt != buf.len) { return atomic_file.finish(); } } } pub const AtomicFile = struct { file: File, tmp_path_buf: [MAX_PATH_BYTES]u8, dest_path: []const u8, finished: bool, const InitError = File.OpenError; /// dest_path must remain valid for the lifetime of AtomicFile /// call finish to atomically replace dest_path with contents pub fn init(dest_path: []const u8, mode: File.Mode) InitError!AtomicFile { const dirname = path.dirname(dest_path); var rand_buf: [12]u8 = undefined; const dirname_component_len = if (dirname) |d| d.len + 1 else 0; const encoded_rand_len = comptime base64.Base64Encoder.calcSize(rand_buf.len); const tmp_path_len = dirname_component_len + encoded_rand_len; var tmp_path_buf: [MAX_PATH_BYTES]u8 = undefined; if (tmp_path_len >= tmp_path_buf.len) return error.NameTooLong; if (dirname) |dir| { mem.copy(u8, tmp_path_buf[0..], dir); tmp_path_buf[dir.len] = path.sep; } tmp_path_buf[tmp_path_len] = 0; const my_cwd = cwd(); while (true) { try crypto.randomBytes(rand_buf[0..]); b64_fs_encoder.encode(tmp_path_buf[dirname_component_len..tmp_path_len], &rand_buf); // TODO https://github.com/ziglang/zig/issues/3770 to clean up this @ptrCast const file = my_cwd.createFileC( @ptrCast([*:0]u8, &tmp_path_buf), .{ .mode = mode, .exclusive = true }, ) catch |err| switch (err) { error.PathAlreadyExists => continue, else => |e| return e, }; return AtomicFile{ .file = file, .tmp_path_buf = tmp_path_buf, .dest_path = dest_path, .finished = false, }; } } /// always call deinit, even after successful finish() pub fn deinit(self: *AtomicFile) void { if (!self.finished) { self.file.close(); cwd().deleteFileC(@ptrCast([*:0]u8, &self.tmp_path_buf)) catch {}; self.finished = true; } } pub fn finish(self: *AtomicFile) !void { assert(!self.finished); self.file.close(); self.finished = true; if (builtin.os == .windows) { const dest_path_w = try os.windows.sliceToPrefixedFileW(self.dest_path); const tmp_path_w = try os.windows.cStrToPrefixedFileW(@ptrCast([*:0]u8, &self.tmp_path_buf)); return os.renameW(&tmp_path_w, &dest_path_w); } const dest_path_c = try os.toPosixPath(self.dest_path); return os.renameC(@ptrCast([*:0]u8, &self.tmp_path_buf), &dest_path_c); } }; const default_new_dir_mode = 0o755; /// Create a new directory. pub fn makeDir(dir_path: []const u8) !void { return os.mkdir(dir_path, default_new_dir_mode); } /// Same as `makeDir` except the parameter is a null-terminated UTF8-encoded string. pub fn makeDirC(dir_path: [*:0]const u8) !void { return os.mkdirC(dir_path, default_new_dir_mode); } /// Same as `makeDir` except the parameter is a null-terminated UTF16LE-encoded string. pub fn makeDirW(dir_path: [*:0]const u16) !void { return os.mkdirW(dir_path, default_new_dir_mode); } /// Calls makeDir recursively to make an entire path. Returns success if the path /// already exists and is a directory. /// This function is not atomic, and if it returns an error, the file system may /// have been modified regardless. /// TODO determine if we can remove the allocator requirement from this function pub fn makePath(allocator: *Allocator, full_path: []const u8) !void { const resolved_path = try path.resolve(allocator, &[_][]const u8{full_path}); defer allocator.free(resolved_path); var end_index: usize = resolved_path.len; while (true) { makeDir(resolved_path[0..end_index]) catch |err| switch (err) { error.PathAlreadyExists => { // TODO stat the file and return an error if it's not a directory // this is important because otherwise a dangling symlink // could cause an infinite loop if (end_index == resolved_path.len) return; }, error.FileNotFound => { // march end_index backward until next path component while (true) { end_index -= 1; if (path.isSep(resolved_path[end_index])) break; } continue; }, else => return err, }; if (end_index == resolved_path.len) return; // march end_index forward until next path component while (true) { end_index += 1; if (end_index == resolved_path.len or path.isSep(resolved_path[end_index])) break; } } } /// Returns `error.DirNotEmpty` if the directory is not empty. /// To delete a directory recursively, see `deleteTree`. pub fn deleteDir(dir_path: []const u8) !void { return os.rmdir(dir_path); } /// Same as `deleteDir` except the parameter is a null-terminated UTF8-encoded string. pub fn deleteDirC(dir_path: [*:0]const u8) !void { return os.rmdirC(dir_path); } /// Same as `deleteDir` except the parameter is a null-terminated UTF16LE-encoded string. pub fn deleteDirW(dir_path: [*:0]const u16) !void { return os.rmdirW(dir_path); } /// Removes a symlink, file, or directory. /// If `full_path` is relative, this is equivalent to `Dir.deleteTree` with the /// current working directory as the open directory handle. /// If `full_path` is absolute, this is equivalent to `Dir.deleteTree` with the /// base directory. pub fn deleteTree(full_path: []const u8) !void { if (path.isAbsolute(full_path)) { const dirname = path.dirname(full_path) orelse return error{ /// Attempt to remove the root file system path. /// This error is unreachable if `full_path` is relative. CannotDeleteRootDirectory, }.CannotDeleteRootDirectory; var dir = try cwd().openDirList(dirname); defer dir.close(); return dir.deleteTree(path.basename(full_path)); } else { return cwd().deleteTree(full_path); } } pub const Dir = struct { fd: os.fd_t, pub const Entry = struct { name: []const u8, kind: Kind, pub const Kind = enum { BlockDevice, CharacterDevice, Directory, NamedPipe, SymLink, File, UnixDomainSocket, Whiteout, Unknown, }; }; const IteratorError = error{AccessDenied} || os.UnexpectedError; pub const Iterator = switch (builtin.os) { .macosx, .ios, .freebsd, .netbsd, .dragonfly => struct { dir: Dir, seek: i64, buf: [8192]u8, // TODO align(@alignOf(os.dirent)), index: usize, end_index: usize, const Self = @This(); pub const Error = IteratorError; /// Memory such as file names referenced in this returned entry becomes invalid /// with subsequent calls to `next`, as well as when this `Dir` is deinitialized. pub fn next(self: *Self) Error!?Entry { switch (builtin.os) { .macosx, .ios => return self.nextDarwin(), .freebsd, .netbsd, .dragonfly => return self.nextBsd(), else => @compileError("unimplemented"), } } fn nextDarwin(self: *Self) !?Entry { start_over: while (true) { if (self.index >= self.end_index) { const rc = os.system.__getdirentries64( self.dir.fd, &self.buf, self.buf.len, &self.seek, ); if (rc == 0) return null; if (rc < 0) { switch (os.errno(rc)) { os.EBADF => unreachable, os.EFAULT => unreachable, os.ENOTDIR => unreachable, os.EINVAL => unreachable, else => |err| return os.unexpectedErrno(err), } } self.index = 0; self.end_index = @intCast(usize, rc); } const darwin_entry = @ptrCast(*align(1) os.dirent, &self.buf[self.index]); const next_index = self.index + darwin_entry.reclen(); self.index = next_index; const name = @ptrCast([*]u8, &darwin_entry.d_name)[0..darwin_entry.d_namlen]; if (mem.eql(u8, name, ".") or mem.eql(u8, name, "..")) { continue :start_over; } const entry_kind = switch (darwin_entry.d_type) { os.DT_BLK => Entry.Kind.BlockDevice, os.DT_CHR => Entry.Kind.CharacterDevice, os.DT_DIR => Entry.Kind.Directory, os.DT_FIFO => Entry.Kind.NamedPipe, os.DT_LNK => Entry.Kind.SymLink, os.DT_REG => Entry.Kind.File, os.DT_SOCK => Entry.Kind.UnixDomainSocket, os.DT_WHT => Entry.Kind.Whiteout, else => Entry.Kind.Unknown, }; return Entry{ .name = name, .kind = entry_kind, }; } } fn nextBsd(self: *Self) !?Entry { start_over: while (true) { if (self.index >= self.end_index) { const rc = os.system.getdirentries( self.dir.fd, self.buf[0..].ptr, self.buf.len, &self.seek, ); switch (os.errno(rc)) { 0 => {}, os.EBADF => unreachable, os.EFAULT => unreachable, os.ENOTDIR => unreachable, os.EINVAL => unreachable, else => |err| return os.unexpectedErrno(err), } if (rc == 0) return null; self.index = 0; self.end_index = @intCast(usize, rc); } const freebsd_entry = @ptrCast(*align(1) os.dirent, &self.buf[self.index]); const next_index = self.index + freebsd_entry.reclen(); self.index = next_index; const name = @ptrCast([*]u8, &freebsd_entry.d_name)[0..freebsd_entry.d_namlen]; if (mem.eql(u8, name, ".") or mem.eql(u8, name, "..")) { continue :start_over; } const entry_kind = switch (freebsd_entry.d_type) { os.DT_BLK => Entry.Kind.BlockDevice, os.DT_CHR => Entry.Kind.CharacterDevice, os.DT_DIR => Entry.Kind.Directory, os.DT_FIFO => Entry.Kind.NamedPipe, os.DT_LNK => Entry.Kind.SymLink, os.DT_REG => Entry.Kind.File, os.DT_SOCK => Entry.Kind.UnixDomainSocket, os.DT_WHT => Entry.Kind.Whiteout, else => Entry.Kind.Unknown, }; return Entry{ .name = name, .kind = entry_kind, }; } } }, .linux => struct { dir: Dir, buf: [8192]u8, // TODO align(@alignOf(os.dirent64)), index: usize, end_index: usize, const Self = @This(); pub const Error = IteratorError; /// Memory such as file names referenced in this returned entry becomes invalid /// with subsequent calls to `next`, as well as when this `Dir` is deinitialized. pub fn next(self: *Self) Error!?Entry { start_over: while (true) { if (self.index >= self.end_index) { const rc = os.linux.getdents64(self.dir.fd, &self.buf, self.buf.len); switch (os.linux.getErrno(rc)) { 0 => {}, os.EBADF => unreachable, os.EFAULT => unreachable, os.ENOTDIR => unreachable, os.EINVAL => unreachable, else => |err| return os.unexpectedErrno(err), } if (rc == 0) return null; self.index = 0; self.end_index = rc; } const linux_entry = @ptrCast(*align(1) os.dirent64, &self.buf[self.index]); const next_index = self.index + linux_entry.reclen(); self.index = next_index; const name = mem.toSlice(u8, @ptrCast([*:0]u8, &linux_entry.d_name)); // skip . and .. entries if (mem.eql(u8, name, ".") or mem.eql(u8, name, "..")) { continue :start_over; } const entry_kind = switch (linux_entry.d_type) { os.DT_BLK => Entry.Kind.BlockDevice, os.DT_CHR => Entry.Kind.CharacterDevice, os.DT_DIR => Entry.Kind.Directory, os.DT_FIFO => Entry.Kind.NamedPipe, os.DT_LNK => Entry.Kind.SymLink, os.DT_REG => Entry.Kind.File, os.DT_SOCK => Entry.Kind.UnixDomainSocket, else => Entry.Kind.Unknown, }; return Entry{ .name = name, .kind = entry_kind, }; } } }, .windows => struct { dir: Dir, buf: [8192]u8 align(@alignOf(os.windows.FILE_BOTH_DIR_INFORMATION)), index: usize, end_index: usize, first: bool, name_data: [256]u8, const Self = @This(); pub const Error = IteratorError; pub fn next(self: *Self) Error!?Entry { start_over: while (true) { const w = os.windows; if (self.index >= self.end_index) { var io: w.IO_STATUS_BLOCK = undefined; const rc = w.ntdll.NtQueryDirectoryFile( self.dir.fd, null, null, null, &io, &self.buf, self.buf.len, .FileBothDirectoryInformation, w.FALSE, null, if (self.first) @as(w.BOOLEAN, w.TRUE) else @as(w.BOOLEAN, w.FALSE), ); self.first = false; if (io.Information == 0) return null; self.index = 0; self.end_index = io.Information; switch (rc) { w.STATUS.SUCCESS => {}, w.STATUS.ACCESS_DENIED => return error.AccessDenied, else => return w.unexpectedStatus(rc), } } const aligned_ptr = @alignCast(@alignOf(w.FILE_BOTH_DIR_INFORMATION), &self.buf[self.index]); const dir_info = @ptrCast(*w.FILE_BOTH_DIR_INFORMATION, aligned_ptr); if (dir_info.NextEntryOffset != 0) { self.index += dir_info.NextEntryOffset; } else { self.index = self.buf.len; } const name_utf16le = @ptrCast([*]u16, &dir_info.FileName)[0 .. dir_info.FileNameLength / 2]; if (mem.eql(u16, name_utf16le, &[_]u16{'.'}) or mem.eql(u16, name_utf16le, &[_]u16{ '.', '.' })) continue; // Trust that Windows gives us valid UTF-16LE const name_utf8_len = std.unicode.utf16leToUtf8(self.name_data[0..], name_utf16le) catch unreachable; const name_utf8 = self.name_data[0..name_utf8_len]; const kind = blk: { const attrs = dir_info.FileAttributes; if (attrs & w.FILE_ATTRIBUTE_DIRECTORY != 0) break :blk Entry.Kind.Directory; if (attrs & w.FILE_ATTRIBUTE_REPARSE_POINT != 0) break :blk Entry.Kind.SymLink; break :blk Entry.Kind.File; }; return Entry{ .name = name_utf8, .kind = kind, }; } } }, else => @compileError("unimplemented"), }; pub fn iterate(self: Dir) Iterator { switch (builtin.os) { .macosx, .ios, .freebsd, .netbsd, .dragonfly => return Iterator{ .dir = self, .seek = 0, .index = 0, .end_index = 0, .buf = undefined, }, .linux => return Iterator{ .dir = self, .index = 0, .end_index = 0, .buf = undefined, }, .windows => return Iterator{ .dir = self, .index = 0, .end_index = 0, .first = true, .buf = undefined, .name_data = undefined, }, else => @compileError("unimplemented"), } } pub const OpenError = error{ FileNotFound, NotDir, AccessDenied, SymLinkLoop, ProcessFdQuotaExceeded, NameTooLong, SystemFdQuotaExceeded, NoDevice, SystemResources, InvalidUtf8, BadPathName, DeviceBusy, } || os.UnexpectedError; /// Deprecated; call `cwd().openDirList` directly. pub fn open(dir_path: []const u8) OpenError!Dir { return cwd().openDirList(dir_path); } /// Deprecated; call `cwd().openDirListC` directly. pub fn openC(dir_path_c: [*:0]const u8) OpenError!Dir { return cwd().openDirListC(dir_path_c); } pub fn close(self: *Dir) void { os.close(self.fd); self.* = undefined; } /// Opens a file for reading or writing, without attempting to create a new file. /// Call `File.close` to release the resource. /// Asserts that the path parameter has no null bytes. pub fn openFile(self: Dir, sub_path: []const u8, flags: File.OpenFlags) File.OpenError!File { if (std.debug.runtime_safety) for (sub_path) |byte| assert(byte != 0); if (builtin.os == .windows) { const path_w = try os.windows.sliceToPrefixedFileW(sub_path); return self.openFileW(&path_w, flags); } const path_c = try os.toPosixPath(sub_path); return self.openFileC(&path_c, flags); } /// Same as `openFile` but the path parameter is null-terminated. pub fn openFileC(self: Dir, sub_path: [*:0]const u8, flags: File.OpenFlags) File.OpenError!File { if (builtin.os == .windows) { const path_w = try os.windows.cStrToPrefixedFileW(sub_path); return self.openFileW(&path_w, flags); } const O_LARGEFILE = if (@hasDecl(os, "O_LARGEFILE")) os.O_LARGEFILE else 0; const os_flags = O_LARGEFILE | os.O_CLOEXEC | if (flags.write and flags.read) @as(u32, os.O_RDWR) else if (flags.write) @as(u32, os.O_WRONLY) else @as(u32, os.O_RDONLY); const fd = try os.openatC(self.fd, sub_path, os_flags, 0); return File{ .handle = fd }; } /// Same as `openFile` but Windows-only and the path parameter is /// [WTF-16](https://simonsapin.github.io/wtf-8/#potentially-ill-formed-utf-16) encoded. pub fn openFileW(self: Dir, sub_path_w: [*:0]const u16, flags: File.OpenFlags) File.OpenError!File { const w = os.windows; const access_mask = w.SYNCHRONIZE | (if (flags.read) @as(u32, w.GENERIC_READ) else 0) | (if (flags.write) @as(u32, w.GENERIC_WRITE) else 0); return self.openFileWindows(sub_path_w, access_mask, w.FILE_OPEN); } /// Creates, opens, or overwrites a file with write access. /// Call `File.close` on the result when done. /// Asserts that the path parameter has no null bytes. pub fn createFile(self: Dir, sub_path: []const u8, flags: File.CreateFlags) File.OpenError!File { if (std.debug.runtime_safety) for (sub_path) |byte| assert(byte != 0); if (builtin.os == .windows) { const path_w = try os.windows.sliceToPrefixedFileW(sub_path); return self.createFileW(&path_w, flags); } const path_c = try os.toPosixPath(sub_path); return self.createFileC(&path_c, flags); } /// Same as `createFile` but the path parameter is null-terminated. pub fn createFileC(self: Dir, sub_path_c: [*:0]const u8, flags: File.CreateFlags) File.OpenError!File { if (builtin.os == .windows) { const path_w = try os.windows.cStrToPrefixedFileW(sub_path_c); return self.createFileW(&path_w, flags); } const O_LARGEFILE = if (@hasDecl(os, "O_LARGEFILE")) os.O_LARGEFILE else 0; const os_flags = O_LARGEFILE | os.O_CREAT | os.O_CLOEXEC | (if (flags.truncate) @as(u32, os.O_TRUNC) else 0) | (if (flags.read) @as(u32, os.O_RDWR) else os.O_WRONLY) | (if (flags.exclusive) @as(u32, os.O_EXCL) else 0); const fd = try os.openatC(self.fd, sub_path_c, os_flags, flags.mode); return File{ .handle = fd }; } /// Same as `createFile` but Windows-only and the path parameter is /// [WTF-16](https://simonsapin.github.io/wtf-8/#potentially-ill-formed-utf-16) encoded. pub fn createFileW(self: Dir, sub_path_w: [*:0]const u16, flags: File.CreateFlags) File.OpenError!File { const w = os.windows; const access_mask = w.SYNCHRONIZE | w.GENERIC_WRITE | (if (flags.read) @as(u32, w.GENERIC_READ) else 0); const creation = if (flags.exclusive) @as(u32, w.FILE_CREATE) else if (flags.truncate) @as(u32, w.FILE_OVERWRITE_IF) else @as(u32, w.FILE_OPEN_IF); return self.openFileWindows(sub_path_w, access_mask, creation); } /// Deprecated; call `openFile` directly. pub fn openRead(self: Dir, sub_path: []const u8) File.OpenError!File { return self.openFile(sub_path, .{}); } /// Deprecated; call `openFileC` directly. pub fn openReadC(self: Dir, sub_path: [*:0]const u8) File.OpenError!File { return self.openFileC(sub_path, .{}); } /// Deprecated; call `openFileW` directly. pub fn openReadW(self: Dir, sub_path: [*:0]const u16) File.OpenError!File { return self.openFileW(sub_path, .{}); } pub fn openFileWindows( self: Dir, sub_path_w: [*:0]const u16, access_mask: os.windows.ACCESS_MASK, creation: os.windows.ULONG, ) File.OpenError!File { const w = os.windows; var result = File{ .handle = undefined }; const path_len_bytes = math.cast(u16, mem.toSliceConst(u16, sub_path_w).len * 2) catch |err| switch (err) { error.Overflow => return error.NameTooLong, }; var nt_name = w.UNICODE_STRING{ .Length = path_len_bytes, .MaximumLength = path_len_bytes, .Buffer = @intToPtr([*]u16, @ptrToInt(sub_path_w)), }; var attr = w.OBJECT_ATTRIBUTES{ .Length = @sizeOf(w.OBJECT_ATTRIBUTES), .RootDirectory = if (path.isAbsoluteW(sub_path_w)) null else self.fd, .Attributes = 0, // Note we do not use OBJ_CASE_INSENSITIVE here. .ObjectName = &nt_name, .SecurityDescriptor = null, .SecurityQualityOfService = null, }; if (sub_path_w[0] == '.' and sub_path_w[1] == 0) { return error.IsDir; } if (sub_path_w[0] == '.' and sub_path_w[1] == '.' and sub_path_w[2] == 0) { return error.IsDir; } var io: w.IO_STATUS_BLOCK = undefined; const rc = w.ntdll.NtCreateFile( &result.handle, access_mask, &attr, &io, null, w.FILE_ATTRIBUTE_NORMAL, w.FILE_SHARE_WRITE | w.FILE_SHARE_READ | w.FILE_SHARE_DELETE, creation, w.FILE_NON_DIRECTORY_FILE | w.FILE_SYNCHRONOUS_IO_NONALERT, null, 0, ); switch (rc) { w.STATUS.SUCCESS => return result, w.STATUS.OBJECT_NAME_INVALID => unreachable, w.STATUS.OBJECT_NAME_NOT_FOUND => return error.FileNotFound, w.STATUS.OBJECT_PATH_NOT_FOUND => return error.FileNotFound, w.STATUS.INVALID_PARAMETER => unreachable, w.STATUS.SHARING_VIOLATION => return error.SharingViolation, w.STATUS.ACCESS_DENIED => return error.AccessDenied, w.STATUS.PIPE_BUSY => return error.PipeBusy, w.STATUS.OBJECT_PATH_SYNTAX_BAD => unreachable, w.STATUS.OBJECT_NAME_COLLISION => return error.PathAlreadyExists, else => return w.unexpectedStatus(rc), } } /// Deprecated; call `openDirList` directly. pub fn openDir(self: Dir, sub_path: []const u8) OpenError!Dir { return self.openDirList(sub_path); } /// Deprecated; call `openDirListC` directly. pub fn openDirC(self: Dir, sub_path_c: [*:0]const u8) OpenError!Dir { return self.openDirListC(sub_path_c); } /// Opens a directory at the given path with the ability to access subpaths /// of the result. Calling `iterate` on the result is illegal behavior; to /// list the contents of a directory, open it with `openDirList`. /// /// Call `close` on the result when done. /// /// Asserts that the path parameter has no null bytes. pub fn openDirTraverse(self: Dir, sub_path: []const u8) OpenError!Dir { if (std.debug.runtime_safety) for (sub_path) |byte| assert(byte != 0); if (builtin.os == .windows) { const sub_path_w = try os.windows.sliceToPrefixedFileW(sub_path); return self.openDirTraverseW(&sub_path_w); } const sub_path_c = try os.toPosixPath(sub_path); return self.openDirTraverseC(&sub_path_c); } /// Opens a directory at the given path with the ability to access subpaths and list contents /// of the result. If the ability to list contents is unneeded, `openDirTraverse` acts the /// same and may be more efficient. /// /// Call `close` on the result when done. /// /// Asserts that the path parameter has no null bytes. pub fn openDirList(self: Dir, sub_path: []const u8) OpenError!Dir { if (std.debug.runtime_safety) for (sub_path) |byte| assert(byte != 0); if (builtin.os == .windows) { const sub_path_w = try os.windows.sliceToPrefixedFileW(sub_path); return self.openDirListW(&sub_path_w); } const sub_path_c = try os.toPosixPath(sub_path); return self.openDirListC(&sub_path_c); } /// Same as `openDirTraverse` except the parameter is null-terminated. pub fn openDirTraverseC(self: Dir, sub_path_c: [*:0]const u8) OpenError!Dir { if (builtin.os == .windows) { const sub_path_w = try os.windows.cStrToPrefixedFileW(sub_path_c); return self.openDirTraverseW(&sub_path_w); } else { const O_PATH = if (@hasDecl(os, "O_PATH")) os.O_PATH else 0; return self.openDirFlagsC(sub_path_c, os.O_RDONLY | os.O_CLOEXEC | O_PATH); } } /// Same as `openDirList` except the parameter is null-terminated. pub fn openDirListC(self: Dir, sub_path_c: [*:0]const u8) OpenError!Dir { if (builtin.os == .windows) { const sub_path_w = try os.windows.cStrToPrefixedFileW(sub_path_c); return self.openDirListW(&sub_path_w); } else { return self.openDirFlagsC(sub_path_c, os.O_RDONLY | os.O_CLOEXEC); } } fn openDirFlagsC(self: Dir, sub_path_c: [*:0]const u8, flags: u32) OpenError!Dir { const fd = os.openatC(self.fd, sub_path_c, flags | os.O_DIRECTORY, 0) catch |err| switch (err) { error.FileTooBig => unreachable, // can't happen for directories error.IsDir => unreachable, // we're providing O_DIRECTORY error.NoSpaceLeft => unreachable, // not providing O_CREAT error.PathAlreadyExists => unreachable, // not providing O_CREAT else => |e| return e, }; return Dir{ .fd = fd }; } /// Same as `openDirTraverse` except the path parameter is UTF16LE, NT-prefixed. /// This function is Windows-only. pub fn openDirTraverseW(self: Dir, sub_path_w: [*:0]const u16) OpenError!Dir { const w = os.windows; return self.openDirAccessMaskW(sub_path_w, w.STANDARD_RIGHTS_READ | w.FILE_READ_ATTRIBUTES | w.FILE_READ_EA | w.SYNCHRONIZE | w.FILE_TRAVERSE); } /// Same as `openDirList` except the path parameter is UTF16LE, NT-prefixed. /// This function is Windows-only. pub fn openDirListW(self: Dir, sub_path_w: [*:0]const u16) OpenError!Dir { const w = os.windows; return self.openDirAccessMaskW(sub_path_w, w.STANDARD_RIGHTS_READ | w.FILE_READ_ATTRIBUTES | w.FILE_READ_EA | w.SYNCHRONIZE | w.FILE_TRAVERSE | w.FILE_LIST_DIRECTORY); } fn openDirAccessMaskW(self: Dir, sub_path_w: [*:0]const u16, access_mask: u32) OpenError!Dir { const w = os.windows; var result = Dir{ .fd = undefined, }; const path_len_bytes = @intCast(u16, mem.toSliceConst(u16, sub_path_w).len * 2); var nt_name = w.UNICODE_STRING{ .Length = path_len_bytes, .MaximumLength = path_len_bytes, .Buffer = @intToPtr([*]u16, @ptrToInt(sub_path_w)), }; var attr = w.OBJECT_ATTRIBUTES{ .Length = @sizeOf(w.OBJECT_ATTRIBUTES), .RootDirectory = if (path.isAbsoluteW(sub_path_w)) null else self.fd, .Attributes = 0, // Note we do not use OBJ_CASE_INSENSITIVE here. .ObjectName = &nt_name, .SecurityDescriptor = null, .SecurityQualityOfService = null, }; if (sub_path_w[0] == '.' and sub_path_w[1] == 0) { // Windows does not recognize this, but it does work with empty string. nt_name.Length = 0; } if (sub_path_w[0] == '.' and sub_path_w[1] == '.' and sub_path_w[2] == 0) { // If you're looking to contribute to zig and fix this, see here for an example of how to // implement this: https://git.midipix.org/ntapi/tree/src/fs/ntapi_tt_open_physical_parent_directory.c @panic("TODO opening '..' with a relative directory handle is not yet implemented on Windows"); } var io: w.IO_STATUS_BLOCK = undefined; const rc = w.ntdll.NtCreateFile( &result.fd, access_mask, &attr, &io, null, 0, w.FILE_SHARE_READ | w.FILE_SHARE_WRITE, w.FILE_OPEN, w.FILE_DIRECTORY_FILE | w.FILE_SYNCHRONOUS_IO_NONALERT | w.FILE_OPEN_FOR_BACKUP_INTENT, null, 0, ); switch (rc) { w.STATUS.SUCCESS => return result, w.STATUS.OBJECT_NAME_INVALID => unreachable, w.STATUS.OBJECT_NAME_NOT_FOUND => return error.FileNotFound, w.STATUS.OBJECT_PATH_NOT_FOUND => return error.FileNotFound, w.STATUS.INVALID_PARAMETER => unreachable, else => return w.unexpectedStatus(rc), } } pub const DeleteFileError = os.UnlinkError; /// Delete a file name and possibly the file it refers to, based on an open directory handle. /// Asserts that the path parameter has no null bytes. pub fn deleteFile(self: Dir, sub_path: []const u8) DeleteFileError!void { os.unlinkat(self.fd, sub_path, 0) catch |err| switch (err) { error.DirNotEmpty => unreachable, // not passing AT_REMOVEDIR else => |e| return e, }; } /// Same as `deleteFile` except the parameter is null-terminated. pub fn deleteFileC(self: Dir, sub_path_c: [*:0]const u8) DeleteFileError!void { os.unlinkatC(self.fd, sub_path_c, 0) catch |err| switch (err) { error.DirNotEmpty => unreachable, // not passing AT_REMOVEDIR else => |e| return e, }; } /// Same as `deleteFile` except the parameter is WTF-16 encoded. pub fn deleteFileW(self: Dir, sub_path_w: [*:0]const u16) DeleteFileError!void { os.unlinkatW(self.fd, sub_path_w, 0) catch |err| switch (err) { error.DirNotEmpty => unreachable, // not passing AT_REMOVEDIR else => |e| return e, }; } pub const DeleteDirError = error{ DirNotEmpty, FileNotFound, AccessDenied, FileBusy, FileSystem, SymLinkLoop, NameTooLong, NotDir, SystemResources, ReadOnlyFileSystem, InvalidUtf8, BadPathName, Unexpected, }; /// Returns `error.DirNotEmpty` if the directory is not empty. /// To delete a directory recursively, see `deleteTree`. /// Asserts that the path parameter has no null bytes. pub fn deleteDir(self: Dir, sub_path: []const u8) DeleteDirError!void { if (std.debug.runtime_safety) for (sub_path) |byte| assert(byte != 0); if (builtin.os == .windows) { const sub_path_w = try os.windows.sliceToPrefixedFileW(sub_path); return self.deleteDirW(&sub_path_w); } const sub_path_c = try os.toPosixPath(sub_path); return self.deleteDirC(&sub_path_c); } /// Same as `deleteDir` except the parameter is null-terminated. pub fn deleteDirC(self: Dir, sub_path_c: [*:0]const u8) DeleteDirError!void { os.unlinkatC(self.fd, sub_path_c, os.AT_REMOVEDIR) catch |err| switch (err) { error.IsDir => unreachable, // not possible since we pass AT_REMOVEDIR else => |e| return e, }; } /// Same as `deleteDir` except the parameter is UTF16LE, NT prefixed. /// This function is Windows-only. pub fn deleteDirW(self: Dir, sub_path_w: [*:0]const u16) DeleteDirError!void { os.unlinkatW(self.fd, sub_path_w, os.AT_REMOVEDIR) catch |err| switch (err) { error.IsDir => unreachable, // not possible since we pass AT_REMOVEDIR else => |e| return e, }; } /// Read value of a symbolic link. /// The return value is a slice of `buffer`, from index `0`. /// Asserts that the path parameter has no null bytes. pub fn readLink(self: Dir, sub_path: []const u8, buffer: *[MAX_PATH_BYTES]u8) ![]u8 { if (std.debug.runtime_safety) for (sub_path) |byte| assert(byte != 0); const sub_path_c = try os.toPosixPath(sub_path); return self.readLinkC(&sub_path_c, buffer); } /// Same as `readLink`, except the `pathname` parameter is null-terminated. pub fn readLinkC(self: Dir, sub_path_c: [*:0]const u8, buffer: *[MAX_PATH_BYTES]u8) ![]u8 { return os.readlinkatC(self.fd, sub_path_c, buffer); } /// On success, caller owns returned buffer. /// If the file is larger than `max_bytes`, returns `error.FileTooBig`. pub fn readFileAlloc(self: Dir, allocator: *mem.Allocator, file_path: []const u8, max_bytes: usize) ![]u8 { return self.readFileAllocAligned(allocator, file_path, max_bytes, @alignOf(u8)); } /// On success, caller owns returned buffer. /// If the file is larger than `max_bytes`, returns `error.FileTooBig`. pub fn readFileAllocAligned( self: Dir, allocator: *mem.Allocator, file_path: []const u8, max_bytes: usize, comptime A: u29, ) ![]align(A) u8 { var file = try self.openRead(file_path); defer file.close(); const size = math.cast(usize, try file.getEndPos()) catch math.maxInt(usize); if (size > max_bytes) return error.FileTooBig; const buf = try allocator.alignedAlloc(u8, A, size); errdefer allocator.free(buf); try file.inStream().stream.readNoEof(buf); return buf; } pub const DeleteTreeError = error{ AccessDenied, FileTooBig, SymLinkLoop, ProcessFdQuotaExceeded, NameTooLong, SystemFdQuotaExceeded, NoDevice, SystemResources, ReadOnlyFileSystem, FileSystem, FileBusy, DeviceBusy, /// One of the path components was not a directory. /// This error is unreachable if `sub_path` does not contain a path separator. NotDir, /// On Windows, file paths must be valid Unicode. InvalidUtf8, /// On Windows, file paths cannot contain these characters: /// '/', '*', '?', '"', '<', '>', '|' BadPathName, } || os.UnexpectedError; /// Whether `full_path` describes a symlink, file, or directory, this function /// removes it. If it cannot be removed because it is a non-empty directory, /// this function recursively removes its entries and then tries again. /// This operation is not atomic on most file systems. pub fn deleteTree(self: Dir, sub_path: []const u8) DeleteTreeError!void { start_over: while (true) { var got_access_denied = false; // First, try deleting the item as a file. This way we don't follow sym links. if (self.deleteFile(sub_path)) { return; } else |err| switch (err) { error.FileNotFound => return, error.IsDir => {}, error.AccessDenied => got_access_denied = true, error.InvalidUtf8, error.SymLinkLoop, error.NameTooLong, error.SystemResources, error.ReadOnlyFileSystem, error.NotDir, error.FileSystem, error.FileBusy, error.BadPathName, error.Unexpected, => |e| return e, } var dir = self.openDirList(sub_path) catch |err| switch (err) { error.NotDir => { if (got_access_denied) { return error.AccessDenied; } continue :start_over; }, error.FileNotFound => { // That's fine, we were trying to remove this directory anyway. continue :start_over; }, error.AccessDenied, error.SymLinkLoop, error.ProcessFdQuotaExceeded, error.NameTooLong, error.SystemFdQuotaExceeded, error.NoDevice, error.SystemResources, error.Unexpected, error.InvalidUtf8, error.BadPathName, error.DeviceBusy, => |e| return e, }; var cleanup_dir_parent: ?Dir = null; defer if (cleanup_dir_parent) |*d| d.close(); var cleanup_dir = true; defer if (cleanup_dir) dir.close(); var dir_name_buf: [MAX_PATH_BYTES]u8 = undefined; var dir_name: []const u8 = sub_path; var parent_dir = self; // Here we must avoid recursion, in order to provide O(1) memory guarantee of this function. // Go through each entry and if it is not a directory, delete it. If it is a directory, // open it, and close the original directory. Repeat. Then start the entire operation over. scan_dir: while (true) { var dir_it = dir.iterate(); while (try dir_it.next()) |entry| { if (dir.deleteFile(entry.name)) { continue; } else |err| switch (err) { error.FileNotFound => continue, // Impossible because we do not pass any path separators. error.NotDir => unreachable, error.IsDir => {}, error.AccessDenied => got_access_denied = true, error.InvalidUtf8, error.SymLinkLoop, error.NameTooLong, error.SystemResources, error.ReadOnlyFileSystem, error.FileSystem, error.FileBusy, error.BadPathName, error.Unexpected, => |e| return e, } const new_dir = dir.openDirList(entry.name) catch |err| switch (err) { error.NotDir => { if (got_access_denied) { return error.AccessDenied; } continue :scan_dir; }, error.FileNotFound => { // That's fine, we were trying to remove this directory anyway. continue :scan_dir; }, error.AccessDenied, error.SymLinkLoop, error.ProcessFdQuotaExceeded, error.NameTooLong, error.SystemFdQuotaExceeded, error.NoDevice, error.SystemResources, error.Unexpected, error.InvalidUtf8, error.BadPathName, error.DeviceBusy, => |e| return e, }; if (cleanup_dir_parent) |*d| d.close(); cleanup_dir_parent = dir; dir = new_dir; mem.copy(u8, &dir_name_buf, entry.name); dir_name = dir_name_buf[0..entry.name.len]; continue :scan_dir; } // Reached the end of the directory entries, which means we successfully deleted all of them. // Now to remove the directory itself. dir.close(); cleanup_dir = false; if (cleanup_dir_parent) |d| { d.deleteDir(dir_name) catch |err| switch (err) { // These two things can happen due to file system race conditions. error.FileNotFound, error.DirNotEmpty => continue :start_over, else => |e| return e, }; continue :start_over; } else { self.deleteDir(sub_path) catch |err| switch (err) { error.FileNotFound => return, error.DirNotEmpty => continue :start_over, else => |e| return e, }; return; } } } } /// Writes content to the file system, creating a new file if it does not exist, truncating /// if it already exists. pub fn writeFile(self: Dir, sub_path: []const u8, data: []const u8) !void { var file = try self.createFile(sub_path, .{}); defer file.close(); try file.write(data); } }; /// Returns an handle to the current working directory that is open for traversal. /// Closing the returned `Dir` is checked illegal behavior. Iterating over the result is illegal behavior. /// On POSIX targets, this function is comptime-callable. pub fn cwd() Dir { if (builtin.os == .windows) { return Dir{ .fd = os.windows.peb().ProcessParameters.CurrentDirectory.Handle }; } else { return Dir{ .fd = os.AT_FDCWD }; } } /// Opens a file for reading or writing, without attempting to create a new file, based on an absolute path. /// Call `File.close` to release the resource. /// Asserts that the path is absolute. See `Dir.openFile` for a function that /// operates on both absolute and relative paths. /// Asserts that the path parameter has no null bytes. See `openFileAbsoluteC` for a function /// that accepts a null-terminated path. pub fn openFileAbsolute(absolute_path: []const u8, flags: File.OpenFlags) File.OpenError!File { assert(path.isAbsolute(absolute_path)); return cwd().openFile(absolute_path, flags); } /// Same as `openFileAbsolute` but the path parameter is null-terminated. pub fn openFileAbsoluteC(absolute_path_c: [*:0]const u8, flags: File.OpenFlags) File.OpenError!File { assert(path.isAbsoluteC(absolute_path_c)); return cwd().openFileC(absolute_path_c, flags); } /// Same as `openFileAbsolute` but the path parameter is WTF-16 encoded. pub fn openFileAbsoluteW(absolute_path_w: [*:0]const u16, flags: File.OpenFlags) File.OpenError!File { assert(path.isAbsoluteW(absolute_path_w)); return cwd().openFileW(absolute_path_w, flags); } /// Creates, opens, or overwrites a file with write access, based on an absolute path. /// Call `File.close` to release the resource. /// Asserts that the path is absolute. See `Dir.createFile` for a function that /// operates on both absolute and relative paths. /// Asserts that the path parameter has no null bytes. See `createFileAbsoluteC` for a function /// that accepts a null-terminated path. pub fn createFileAbsolute(absolute_path: []const u8, flags: File.CreateFlags) File.OpenError!File { assert(path.isAbsolute(absolute_path)); return cwd().createFile(absolute_path, flags); } /// Same as `createFileAbsolute` but the path parameter is null-terminated. pub fn createFileAbsoluteC(absolute_path_c: [*:0]const u8, flags: File.CreateFlags) File.OpenError!File { assert(path.isAbsoluteC(absolute_path_c)); return cwd().createFileC(absolute_path_c, flags); } /// Same as `createFileAbsolute` but the path parameter is WTF-16 encoded. pub fn createFileAbsoluteW(absolute_path_w: [*:0]const u16, flags: File.CreateFlags) File.OpenError!File { assert(path.isAbsoluteW(absolute_path_w)); return cwd().createFileW(absolute_path_w, flags); } /// Delete a file name and possibly the file it refers to, based on an absolute path. /// Asserts that the path is absolute. See `Dir.deleteFile` for a function that /// operates on both absolute and relative paths. /// Asserts that the path parameter has no null bytes. pub fn deleteFileAbsolute(absolute_path: []const u8) DeleteFileError!void { assert(path.isAbsolute(absolute_path)); return cwd().deleteFile(absolute_path); } /// Same as `deleteFileAbsolute` except the parameter is null-terminated. pub fn deleteFileAbsoluteC(absolute_path_c: [*:0]const u8) DeleteFileError!void { assert(path.isAbsoluteC(absolute_path_c)); return cwd().deleteFileC(absolute_path_c); } /// Same as `deleteFileAbsolute` except the parameter is WTF-16 encoded. pub fn deleteFileAbsoluteW(absolute_path_w: [*:0]const u16) DeleteFileError!void { assert(path.isAbsoluteW(absolute_path_w)); return cwd().deleteFileW(absolute_path_w); } pub const Walker = struct { stack: std.ArrayList(StackItem), name_buffer: std.Buffer, pub const Entry = struct { /// The containing directory. This can be used to operate directly on `basename` /// rather than `path`, avoiding `error.NameTooLong` for deeply nested paths. /// The directory remains open until `next` or `deinit` is called. dir: Dir, basename: []const u8, path: []const u8, kind: Dir.Entry.Kind, }; const StackItem = struct { dir_it: Dir.Iterator, dirname_len: usize, }; /// After each call to this function, and on deinit(), the memory returned /// from this function becomes invalid. A copy must be made in order to keep /// a reference to the path. pub fn next(self: *Walker) !?Entry { while (true) { if (self.stack.len == 0) return null; // `top` becomes invalid after appending to `self.stack`. const top = &self.stack.toSlice()[self.stack.len - 1]; const dirname_len = top.dirname_len; if (try top.dir_it.next()) |base| { self.name_buffer.shrink(dirname_len); try self.name_buffer.appendByte(path.sep); try self.name_buffer.append(base.name); if (base.kind == .Directory) { var new_dir = top.dir_it.dir.openDirList(base.name) catch |err| switch (err) { error.NameTooLong => unreachable, // no path sep in base.name else => |e| return e, }; { errdefer new_dir.close(); try self.stack.append(StackItem{ .dir_it = new_dir.iterate(), .dirname_len = self.name_buffer.len(), }); } } return Entry{ .dir = top.dir_it.dir, .basename = self.name_buffer.toSliceConst()[dirname_len + 1 ..], .path = self.name_buffer.toSliceConst(), .kind = base.kind, }; } else { self.stack.pop().dir_it.dir.close(); } } } pub fn deinit(self: *Walker) void { while (self.stack.popOrNull()) |*item| item.dir_it.dir.close(); self.stack.deinit(); self.name_buffer.deinit(); } }; /// Recursively iterates over a directory. /// Must call `Walker.deinit` when done. /// `dir_path` must not end in a path separator. /// The order of returned file system entries is undefined. pub fn walkPath(allocator: *Allocator, dir_path: []const u8) !Walker { assert(!mem.endsWith(u8, dir_path, path.sep_str)); var dir = try cwd().openDirList(dir_path); errdefer dir.close(); var name_buffer = try std.Buffer.init(allocator, dir_path); errdefer name_buffer.deinit(); var walker = Walker{ .stack = std.ArrayList(Walker.StackItem).init(allocator), .name_buffer = name_buffer, }; try walker.stack.append(Walker.StackItem{ .dir_it = dir.iterate(), .dirname_len = dir_path.len, }); return walker; } /// Read value of a symbolic link. /// The return value is a slice of buffer, from index `0`. pub fn readLink(pathname: []const u8, buffer: *[MAX_PATH_BYTES]u8) ![]u8 { return os.readlink(pathname, buffer); } /// Same as `readLink`, except the parameter is null-terminated. pub fn readLinkC(pathname_c: [*]const u8, buffer: *[MAX_PATH_BYTES]u8) ![]u8 { return os.readlinkC(pathname_c, buffer); } pub const OpenSelfExeError = os.OpenError || os.windows.CreateFileError || SelfExePathError; pub fn openSelfExe() OpenSelfExeError!File { if (builtin.os == .linux) { return openFileAbsoluteC("/proc/self/exe", .{}); } if (builtin.os == .windows) { const wide_slice = selfExePathW(); const prefixed_path_w = try os.windows.wToPrefixedFileW(wide_slice); return cwd().openReadW(&prefixed_path_w); } var buf: [MAX_PATH_BYTES]u8 = undefined; const self_exe_path = try selfExePath(&buf); buf[self_exe_path.len] = 0; // TODO avoid @ptrCast here using slice syntax with https://github.com/ziglang/zig/issues/3770 return openFileAbsoluteC(@ptrCast([*:0]u8, self_exe_path.ptr), .{}); } test "openSelfExe" { switch (builtin.os) { .linux, .macosx, .ios, .windows, .freebsd, .dragonfly => (try openSelfExe()).close(), else => return error.SkipZigTest, // Unsupported OS. } } pub const SelfExePathError = os.ReadLinkError || os.SysCtlError; /// Get the path to the current executable. /// If you only need the directory, use selfExeDirPath. /// If you only want an open file handle, use openSelfExe. /// This function may return an error if the current executable /// was deleted after spawning. /// Returned value is a slice of out_buffer. /// /// On Linux, depends on procfs being mounted. If the currently executing binary has /// been deleted, the file path looks something like `/a/b/c/exe (deleted)`. /// TODO make the return type of this a null terminated pointer pub fn selfExePath(out_buffer: *[MAX_PATH_BYTES]u8) SelfExePathError![]u8 { if (comptime std.Target.current.isDarwin()) { var u32_len: u32 = out_buffer.len; const rc = std.c._NSGetExecutablePath(out_buffer, &u32_len); if (rc != 0) return error.NameTooLong; return mem.toSlice(u8, @ptrCast([*:0]u8, out_buffer)); } switch (builtin.os) { .linux => return os.readlinkC("/proc/self/exe", out_buffer), .freebsd, .dragonfly => { var mib = [4]c_int{ os.CTL_KERN, os.KERN_PROC, os.KERN_PROC_PATHNAME, -1 }; var out_len: usize = out_buffer.len; try os.sysctl(&mib, out_buffer, &out_len, null, 0); // TODO could this slice from 0 to out_len instead? return mem.toSlice(u8, @ptrCast([*:0]u8, out_buffer)); }, .netbsd => { var mib = [4]c_int{ os.CTL_KERN, os.KERN_PROC_ARGS, -1, os.KERN_PROC_PATHNAME }; var out_len: usize = out_buffer.len; try os.sysctl(&mib, out_buffer, &out_len, null, 0); // TODO could this slice from 0 to out_len instead? return mem.toSlice(u8, @ptrCast([*:0]u8, out_buffer)); }, .windows => { const utf16le_slice = selfExePathW(); // Trust that Windows gives us valid UTF-16LE. const end_index = std.unicode.utf16leToUtf8(out_buffer, utf16le_slice) catch unreachable; return out_buffer[0..end_index]; }, else => @compileError("std.fs.selfExePath not supported for this target"), } } /// The result is UTF16LE-encoded. pub fn selfExePathW() [:0]const u16 { const image_path_name = &os.windows.peb().ProcessParameters.ImagePathName; return mem.toSliceConst(u16, @ptrCast([*:0]const u16, image_path_name.Buffer)); } /// `selfExeDirPath` except allocates the result on the heap. /// Caller owns returned memory. pub fn selfExeDirPathAlloc(allocator: *Allocator) ![]u8 { var buf: [MAX_PATH_BYTES]u8 = undefined; return mem.dupe(allocator, u8, try selfExeDirPath(&buf)); } /// Get the directory path that contains the current executable. /// Returned value is a slice of out_buffer. pub fn selfExeDirPath(out_buffer: *[MAX_PATH_BYTES]u8) SelfExePathError![]const u8 { if (builtin.os == .linux) { // If the currently executing binary has been deleted, // the file path looks something like `/a/b/c/exe (deleted)` // This path cannot be opened, but it's valid for determining the directory // the executable was in when it was run. const full_exe_path = try os.readlinkC("/proc/self/exe", out_buffer); // Assume that /proc/self/exe has an absolute path, and therefore dirname // will not return null. return path.dirname(full_exe_path).?; } const self_exe_path = try selfExePath(out_buffer); // Assume that the OS APIs return absolute paths, and therefore dirname // will not return null. return path.dirname(self_exe_path).?; } /// `realpath`, except caller must free the returned memory. pub fn realpathAlloc(allocator: *Allocator, pathname: []const u8) ![]u8 { var buf: [MAX_PATH_BYTES]u8 = undefined; return mem.dupe(allocator, u8, try os.realpath(pathname, &buf)); } test "" { _ = @import("fs/path.zig"); _ = @import("fs/file.zig"); _ = @import("fs/get_app_data_dir.zig"); }