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zig/std/os.zig
Andrew Kelley 6096dc5f94
move some of the installation from cmake to zig build 
This moves the installation of shipped source files from large
CMakeLists.txt lists to zig build recursive directory installation.

On my computer a cmake `make install` takes 2.4 seconds even when it has
to do nothing, and prints a lot of unnecessary lines to stdout that say
"up-to-date: [some file it is installing]".

After this commit, the default output of `make` is down to 1
second, and it does not print any junk to stdout. Further, a `make
install` is no longer required and `make` is sufficient.

This closes #2874.

It also closes #2585. `make` now always invokes `zig build` for
installing files and libuserland.a, and zig's own caching system makes
that go fast.
2019-07-15 01:45:26 -04:00

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// This file contains thin wrappers around OS-specific APIs, with these
// specific goals in mind:
// * Convert "errno"-style error codes into Zig errors.
// * When null-terminated byte buffers are required, provide APIs which accept
// slices as well as APIs which accept null-terminated byte buffers. Same goes
// for UTF-16LE encoding.
// * Where operating systems share APIs, e.g. POSIX, these thin wrappers provide
// cross platform abstracting.
// * When there exists a corresponding libc function and linking libc, the libc
// implementation is used. Exceptions are made for known buggy areas of libc.
// On Linux libc can be side-stepped by using `std.os.linux` directly.
// * For Windows, this file represents the API that libc would provide for
// Windows. For thin wrappers around Windows-specific APIs, see `std.os.windows`.
// Note: The Zig standard library does not support POSIX thread cancellation, and
// in general EINTR is handled by trying again.
const std = @import("std.zig");
const builtin = @import("builtin");
const assert = std.debug.assert;
const math = std.math;
const mem = std.mem;
const elf = std.elf;
const dl = @import("dynamic_library.zig");
const MAX_PATH_BYTES = std.fs.MAX_PATH_BYTES;
comptime {
assert(@import("std") == std); // std lib tests require --override-std-dir
}
pub const darwin = @import("os/darwin.zig");
pub const freebsd = @import("os/freebsd.zig");
pub const linux = @import("os/linux.zig");
pub const netbsd = @import("os/netbsd.zig");
pub const uefi = @import("os/uefi.zig");
pub const wasi = @import("os/wasi.zig");
pub const windows = @import("os/windows.zig");
pub const zen = @import("os/zen.zig");
/// When linking libc, this is the C API. Otherwise, it is the OS-specific system interface.
pub const system = if (builtin.link_libc) std.c else switch (builtin.os) {
.macosx, .ios, .watchos, .tvos => darwin,
.freebsd => freebsd,
.linux => linux,
.netbsd => netbsd,
.wasi => wasi,
.windows => windows,
.zen => zen,
else => struct {},
};
pub usingnamespace @import("os/bits.zig");
/// See also `getenv`. Populated by startup code before main().
pub var environ: [][*]u8 = undefined;
/// Populated by startup code before main().
/// Not available on Windows. See `std.process.args`
/// for obtaining the process arguments.
pub var argv: [][*]u8 = undefined;
/// To obtain errno, call this function with the return value of the
/// system function call. For some systems this will obtain the value directly
/// from the return code; for others it will use a thread-local errno variable.
/// Therefore, this function only returns a well-defined value when it is called
/// directly after the system function call which one wants to learn the errno
/// value of.
pub const errno = system.getErrno;
/// Closes the file descriptor.
/// This function is not capable of returning any indication of failure. An
/// application which wants to ensure writes have succeeded before closing
/// must call `fsync` before `close`.
/// Note: The Zig standard library does not support POSIX thread cancellation.
pub fn close(fd: fd_t) void {
if (windows.is_the_target) {
return windows.CloseHandle(fd);
}
if (wasi.is_the_target) {
_ = wasi.fd_close(fd);
}
if (darwin.is_the_target) {
// This avoids the EINTR problem.
switch (darwin.getErrno(darwin.@"close$NOCANCEL"(fd))) {
EBADF => unreachable, // Always a race condition.
else => return,
}
}
switch (errno(system.close(fd))) {
EBADF => unreachable, // Always a race condition.
EINTR => return, // This is still a success. See https://github.com/ziglang/zig/issues/2425
else => return,
}
}
pub const GetRandomError = OpenError;
/// Obtain a series of random bytes. These bytes can be used to seed user-space
/// random number generators or for cryptographic purposes.
/// When linking against libc, this calls the
/// appropriate OS-specific library call. Otherwise it uses the zig standard
/// library implementation.
pub fn getrandom(buf: []u8) GetRandomError!void {
if (windows.is_the_target) {
return windows.RtlGenRandom(buf);
}
if (linux.is_the_target) {
while (true) {
const err = if (std.c.versionCheck(builtin.Version{ .major = 2, .minor = 25, .patch = 0 }).ok) blk: {
break :blk errno(std.c.getrandom(buf.ptr, buf.len, 0));
} else blk: {
break :blk linux.getErrno(linux.getrandom(buf.ptr, buf.len, 0));
};
switch (err) {
0 => return,
EINVAL => unreachable,
EFAULT => unreachable,
EINTR => continue,
ENOSYS => return getRandomBytesDevURandom(buf),
else => return unexpectedErrno(err),
}
}
}
if (wasi.is_the_target) {
switch (wasi.random_get(buf.ptr, buf.len)) {
0 => return,
else => |err| return unexpectedErrno(err),
}
}
return getRandomBytesDevURandom(buf);
}
fn getRandomBytesDevURandom(buf: []u8) !void {
const fd = try openC(c"/dev/urandom", O_RDONLY | O_CLOEXEC, 0);
defer close(fd);
const stream = &std.fs.File.openHandle(fd).inStream().stream;
stream.readNoEof(buf) catch return error.Unexpected;
}
/// Causes abnormal process termination.
/// If linking against libc, this calls the abort() libc function. Otherwise
/// it raises SIGABRT followed by SIGKILL and finally lo
pub fn abort() noreturn {
@setCold(true);
// MSVCRT abort() sometimes opens a popup window which is undesirable, so
// even when linking libc on Windows we use our own abort implementation.
// See https://github.com/ziglang/zig/issues/2071 for more details.
if (windows.is_the_target) {
if (builtin.mode == .Debug) {
@breakpoint();
}
windows.kernel32.ExitProcess(3);
}
if (builtin.link_libc) {
system.abort();
}
if (builtin.os == .uefi) {
// TODO there must be a better thing to do here than loop forever
while (true) {}
}
raise(SIGABRT) catch {};
// TODO the rest of the implementation of abort() from musl libc here
raise(SIGKILL) catch {};
exit(127);
}
pub const RaiseError = error{Unexpected};
pub fn raise(sig: u8) RaiseError!void {
if (builtin.link_libc) {
switch (errno(system.raise(sig))) {
0 => return,
else => |err| return unexpectedErrno(err),
}
}
if (wasi.is_the_target) {
switch (wasi.proc_raise(SIGABRT)) {
0 => return,
else => |err| return unexpectedErrno(err),
}
}
if (linux.is_the_target) {
var set: linux.sigset_t = undefined;
linux.blockAppSignals(&set);
const tid = linux.syscall0(linux.SYS_gettid);
const rc = linux.syscall2(linux.SYS_tkill, tid, sig);
linux.restoreSignals(&set);
switch (errno(rc)) {
0 => return,
else => |err| return unexpectedErrno(err),
}
}
@compileError("std.os.raise unimplemented for this target");
}
pub const KillError = error{
PermissionDenied,
Unexpected,
};
pub fn kill(pid: pid_t, sig: u8) KillError!void {
switch (errno(system.kill(pid, sig))) {
0 => return,
EINVAL => unreachable, // invalid signal
EPERM => return error.PermissionDenied,
ESRCH => unreachable, // always a race condition
else => |err| return unexpectedErrno(err),
}
}
/// Exits the program cleanly with the specified status code.
pub fn exit(status: u8) noreturn {
if (builtin.link_libc) {
system.exit(status);
}
if (windows.is_the_target) {
windows.kernel32.ExitProcess(status);
}
if (wasi.is_the_target) {
wasi.proc_exit(status);
}
if (linux.is_the_target and !builtin.single_threaded) {
linux.exit_group(status);
}
system.exit(status);
}
pub const ReadError = error{
InputOutput,
SystemResources,
IsDir,
OperationAborted,
BrokenPipe,
Unexpected,
};
/// Returns the number of bytes that were read, which can be less than
/// buf.len. If 0 bytes were read, that means EOF.
/// This function is for blocking file descriptors only. For non-blocking, see
/// `readAsync`.
pub fn read(fd: fd_t, buf: []u8) ReadError!usize {
if (windows.is_the_target) {
return windows.ReadFile(fd, buf);
}
if (wasi.is_the_target and !builtin.link_libc) {
const iovs = [1]iovec{iovec{
.iov_base = buf.ptr,
.iov_len = buf.len,
}};
var nread: usize = undefined;
switch (wasi.fd_read(fd, &iovs, iovs.len, &nread)) {
0 => return nread,
else => |err| return unexpectedErrno(err),
}
}
// Linux can return EINVAL when read amount is > 0x7ffff000
// See https://github.com/ziglang/zig/pull/743#issuecomment-363158274
// TODO audit this. Shawn Landden says that this is not actually true.
// if this logic should stay, move it to std.os.linux
const max_buf_len = 0x7ffff000;
var index: usize = 0;
while (index < buf.len) {
const want_to_read = math.min(buf.len - index, usize(max_buf_len));
const rc = system.read(fd, buf.ptr + index, want_to_read);
switch (errno(rc)) {
0 => {
const amt_read = @intCast(usize, rc);
index += amt_read;
if (amt_read == want_to_read) continue;
// Read returned less than buf.len.
return index;
},
EINTR => continue,
EINVAL => unreachable,
EFAULT => unreachable,
EAGAIN => unreachable, // This function is for blocking reads.
EBADF => unreachable, // Always a race condition.
EIO => return error.InputOutput,
EISDIR => return error.IsDir,
ENOBUFS => return error.SystemResources,
ENOMEM => return error.SystemResources,
else => |err| return unexpectedErrno(err),
}
}
return index;
}
/// Number of bytes read is returned. Upon reading end-of-file, zero is returned.
/// This function is for blocking file descriptors only. For non-blocking, see
/// `preadvAsync`.
pub fn preadv(fd: fd_t, iov: []const iovec, offset: u64) ReadError!usize {
if (darwin.is_the_target) {
// Darwin does not have preadv but it does have pread.
var off: usize = 0;
var iov_i: usize = 0;
var inner_off: usize = 0;
while (true) {
const v = iov[iov_i];
const rc = darwin.pread(fd, v.iov_base + inner_off, v.iov_len - inner_off, offset + off);
const err = darwin.getErrno(rc);
switch (err) {
0 => {
const amt_read = @bitCast(usize, rc);
off += amt_read;
inner_off += amt_read;
if (inner_off == v.iov_len) {
iov_i += 1;
inner_off = 0;
if (iov_i == iov.len) {
return off;
}
}
if (rc == 0) return off; // EOF
continue;
},
EINTR => continue,
EINVAL => unreachable,
EFAULT => unreachable,
ESPIPE => unreachable, // fd is not seekable
EAGAIN => unreachable, // This function is for blocking reads.
EBADF => unreachable, // always a race condition
EIO => return error.InputOutput,
EISDIR => return error.IsDir,
ENOBUFS => return error.SystemResources,
ENOMEM => return error.SystemResources,
else => return unexpectedErrno(err),
}
}
}
while (true) {
// TODO handle the case when iov_len is too large and get rid of this @intCast
const rc = system.preadv(fd, iov.ptr, @intCast(u32, iov.len), offset);
switch (errno(rc)) {
0 => return @bitCast(usize, rc),
EINTR => continue,
EINVAL => unreachable,
EFAULT => unreachable,
EAGAIN => unreachable, // This function is for blocking reads.
EBADF => unreachable, // always a race condition
EIO => return error.InputOutput,
EISDIR => return error.IsDir,
ENOBUFS => return error.SystemResources,
ENOMEM => return error.SystemResources,
else => |err| return unexpectedErrno(err),
}
}
}
pub const WriteError = error{
DiskQuota,
FileTooBig,
InputOutput,
NoSpaceLeft,
AccessDenied,
BrokenPipe,
SystemResources,
OperationAborted,
Unexpected,
};
/// Write to a file descriptor. Keeps trying if it gets interrupted.
/// This function is for blocking file descriptors only. For non-blocking, see
/// `writeAsync`.
pub fn write(fd: fd_t, bytes: []const u8) WriteError!void {
if (windows.is_the_target) {
return windows.WriteFile(fd, bytes);
}
if (wasi.is_the_target and !builtin.link_libc) {
const ciovs = [1]iovec_const{iovec_const{
.iov_base = bytes.ptr,
.iov_len = bytes.len,
}};
var nwritten: usize = undefined;
switch (wasi.fd_write(fd, &ciovs, ciovs.len, &nwritten)) {
0 => return,
else => |err| return unexpectedErrno(err),
}
}
// Linux can return EINVAL when write amount is > 0x7ffff000
// See https://github.com/ziglang/zig/pull/743#issuecomment-363165856
// TODO audit this. Shawn Landden says that this is not actually true.
// if this logic should stay, move it to std.os.linux
const max_bytes_len = 0x7ffff000;
var index: usize = 0;
while (index < bytes.len) {
const amt_to_write = math.min(bytes.len - index, usize(max_bytes_len));
const rc = system.write(fd, bytes.ptr + index, amt_to_write);
switch (errno(rc)) {
0 => {
index += @intCast(usize, rc);
continue;
},
EINTR => continue,
EINVAL => unreachable,
EFAULT => unreachable,
EAGAIN => unreachable, // This function is for blocking writes.
EBADF => unreachable, // Always a race condition.
EDESTADDRREQ => unreachable, // `connect` was never called.
EDQUOT => return error.DiskQuota,
EFBIG => return error.FileTooBig,
EIO => return error.InputOutput,
ENOSPC => return error.NoSpaceLeft,
EPERM => return error.AccessDenied,
EPIPE => return error.BrokenPipe,
else => |err| return unexpectedErrno(err),
}
}
}
/// Write multiple buffers to a file descriptor. Keeps trying if it gets interrupted.
/// This function is for blocking file descriptors only. For non-blocking, see
/// `pwritevAsync`.
pub fn pwritev(fd: fd_t, iov: []const iovec_const, offset: u64) WriteError!void {
if (darwin.is_the_target) {
// Darwin does not have pwritev but it does have pwrite.
var off: usize = 0;
var iov_i: usize = 0;
var inner_off: usize = 0;
while (true) {
const v = iov[iov_i];
const rc = darwin.pwrite(fd, v.iov_base + inner_off, v.iov_len - inner_off, offset + off);
const err = darwin.getErrno(rc);
switch (err) {
0 => {
const amt_written = @bitCast(usize, rc);
off += amt_written;
inner_off += amt_written;
if (inner_off == v.iov_len) {
iov_i += 1;
inner_off = 0;
if (iov_i == iov.len) {
return;
}
}
continue;
},
EINTR => continue,
ESPIPE => unreachable, // `fd` is not seekable.
EINVAL => unreachable,
EFAULT => unreachable,
EAGAIN => unreachable, // This function is for blocking writes.
EBADF => unreachable, // Always a race condition.
EDESTADDRREQ => unreachable, // `connect` was never called.
EDQUOT => return error.DiskQuota,
EFBIG => return error.FileTooBig,
EIO => return error.InputOutput,
ENOSPC => return error.NoSpaceLeft,
EPERM => return error.AccessDenied,
EPIPE => return error.BrokenPipe,
else => return unexpectedErrno(err),
}
}
}
while (true) {
// TODO handle the case when iov_len is too large and get rid of this @intCast
const rc = system.pwritev(fd, iov.ptr, @intCast(u32, iov.len), offset);
switch (errno(rc)) {
0 => return,
EINTR => continue,
EINVAL => unreachable,
EFAULT => unreachable,
EAGAIN => unreachable, // This function is for blocking writes.
EBADF => unreachable, // Always a race condition.
EDESTADDRREQ => unreachable, // `connect` was never called.
EDQUOT => return error.DiskQuota,
EFBIG => return error.FileTooBig,
EIO => return error.InputOutput,
ENOSPC => return error.NoSpaceLeft,
EPERM => return error.AccessDenied,
EPIPE => return error.BrokenPipe,
else => |err| return unexpectedErrno(err),
}
}
}
pub const OpenError = error{
AccessDenied,
FileTooBig,
IsDir,
SymLinkLoop,
ProcessFdQuotaExceeded,
NameTooLong,
SystemFdQuotaExceeded,
NoDevice,
FileNotFound,
SystemResources,
NoSpaceLeft,
NotDir,
PathAlreadyExists,
DeviceBusy,
Unexpected,
};
/// Open and possibly create a file. Keeps trying if it gets interrupted.
/// `file_path` needs to be copied in memory to add a null terminating byte.
/// See also `openC`.
pub fn open(file_path: []const u8, flags: u32, perm: usize) OpenError!fd_t {
const file_path_c = try toPosixPath(file_path);
return openC(&file_path_c, flags, perm);
}
/// Open and possibly create a file. Keeps trying if it gets interrupted.
/// See also `open`.
/// TODO https://github.com/ziglang/zig/issues/265
pub fn openC(file_path: [*]const u8, flags: u32, perm: usize) OpenError!fd_t {
while (true) {
const rc = system.open(file_path, flags, perm);
switch (errno(rc)) {
0 => return @intCast(fd_t, rc),
EINTR => continue,
EFAULT => unreachable,
EINVAL => unreachable,
EACCES => return error.AccessDenied,
EFBIG => return error.FileTooBig,
EOVERFLOW => return error.FileTooBig,
EISDIR => return error.IsDir,
ELOOP => return error.SymLinkLoop,
EMFILE => return error.ProcessFdQuotaExceeded,
ENAMETOOLONG => return error.NameTooLong,
ENFILE => return error.SystemFdQuotaExceeded,
ENODEV => return error.NoDevice,
ENOENT => return error.FileNotFound,
ENOMEM => return error.SystemResources,
ENOSPC => return error.NoSpaceLeft,
ENOTDIR => return error.NotDir,
EPERM => return error.AccessDenied,
EEXIST => return error.PathAlreadyExists,
EBUSY => return error.DeviceBusy,
else => |err| return unexpectedErrno(err),
}
}
}
pub fn dup2(old_fd: fd_t, new_fd: fd_t) !void {
while (true) {
switch (errno(system.dup2(old_fd, new_fd))) {
0 => return,
EBUSY, EINTR => continue,
EMFILE => return error.ProcessFdQuotaExceeded,
EINVAL => unreachable,
else => |err| return unexpectedErrno(err),
}
}
}
/// This function must allocate memory to add a null terminating bytes on path and each arg.
/// It must also convert to KEY=VALUE\0 format for environment variables, and include null
/// pointers after the args and after the environment variables.
/// `argv[0]` is the executable path.
/// This function also uses the PATH environment variable to get the full path to the executable.
/// TODO provide execveC which does not take an allocator
pub fn execve(allocator: *mem.Allocator, argv_slice: []const []const u8, env_map: *const std.BufMap) !void {
const argv_buf = try allocator.alloc(?[*]u8, argv_slice.len + 1);
mem.set(?[*]u8, argv_buf, null);
defer {
for (argv_buf) |arg| {
const arg_buf = if (arg) |ptr| mem.toSlice(u8, ptr) else break;
allocator.free(arg_buf);
}
allocator.free(argv_buf);
}
for (argv_slice) |arg, i| {
const arg_buf = try allocator.alloc(u8, arg.len + 1);
@memcpy(arg_buf.ptr, arg.ptr, arg.len);
arg_buf[arg.len] = 0;
argv_buf[i] = arg_buf.ptr;
}
argv_buf[argv_slice.len] = null;
const envp_buf = try createNullDelimitedEnvMap(allocator, env_map);
defer freeNullDelimitedEnvMap(allocator, envp_buf);
const exe_path = argv_slice[0];
if (mem.indexOfScalar(u8, exe_path, '/') != null) {
return execveErrnoToErr(errno(system.execve(argv_buf[0].?, argv_buf.ptr, envp_buf.ptr)));
}
const PATH = getenv("PATH") orelse "/usr/local/bin:/bin/:/usr/bin";
// PATH.len because it is >= the largest search_path
// +1 for the / to join the search path and exe_path
// +1 for the null terminating byte
const path_buf = try allocator.alloc(u8, PATH.len + exe_path.len + 2);
defer allocator.free(path_buf);
var it = mem.tokenize(PATH, ":");
var seen_eacces = false;
var err: usize = undefined;
while (it.next()) |search_path| {
mem.copy(u8, path_buf, search_path);
path_buf[search_path.len] = '/';
mem.copy(u8, path_buf[search_path.len + 1 ..], exe_path);
path_buf[search_path.len + exe_path.len + 1] = 0;
err = errno(system.execve(path_buf.ptr, argv_buf.ptr, envp_buf.ptr));
assert(err > 0);
if (err == EACCES) {
seen_eacces = true;
} else if (err != ENOENT) {
return execveErrnoToErr(err);
}
}
if (seen_eacces) {
err = EACCES;
}
return execveErrnoToErr(err);
}
pub fn createNullDelimitedEnvMap(allocator: *mem.Allocator, env_map: *const std.BufMap) ![]?[*]u8 {
const envp_count = env_map.count();
const envp_buf = try allocator.alloc(?[*]u8, envp_count + 1);
mem.set(?[*]u8, envp_buf, null);
errdefer freeNullDelimitedEnvMap(allocator, envp_buf);
{
var it = env_map.iterator();
var i: usize = 0;
while (it.next()) |pair| : (i += 1) {
const env_buf = try allocator.alloc(u8, pair.key.len + pair.value.len + 2);
@memcpy(env_buf.ptr, pair.key.ptr, pair.key.len);
env_buf[pair.key.len] = '=';
@memcpy(env_buf.ptr + pair.key.len + 1, pair.value.ptr, pair.value.len);
env_buf[env_buf.len - 1] = 0;
envp_buf[i] = env_buf.ptr;
}
assert(i == envp_count);
}
assert(envp_buf[envp_count] == null);
return envp_buf;
}
pub fn freeNullDelimitedEnvMap(allocator: *mem.Allocator, envp_buf: []?[*]u8) void {
for (envp_buf) |env| {
const env_buf = if (env) |ptr| ptr[0 .. mem.len(u8, ptr) + 1] else break;
allocator.free(env_buf);
}
allocator.free(envp_buf);
}
pub const ExecveError = error{
SystemResources,
AccessDenied,
InvalidExe,
FileSystem,
IsDir,
FileNotFound,
NotDir,
FileBusy,
ProcessFdQuotaExceeded,
SystemFdQuotaExceeded,
NameTooLong,
Unexpected,
};
fn execveErrnoToErr(err: usize) ExecveError {
assert(err > 0);
switch (err) {
EFAULT => unreachable,
E2BIG => return error.SystemResources,
EMFILE => return error.ProcessFdQuotaExceeded,
ENAMETOOLONG => return error.NameTooLong,
ENFILE => return error.SystemFdQuotaExceeded,
ENOMEM => return error.SystemResources,
EACCES => return error.AccessDenied,
EPERM => return error.AccessDenied,
EINVAL => return error.InvalidExe,
ENOEXEC => return error.InvalidExe,
EIO => return error.FileSystem,
ELOOP => return error.FileSystem,
EISDIR => return error.IsDir,
ENOENT => return error.FileNotFound,
ENOTDIR => return error.NotDir,
ETXTBSY => return error.FileBusy,
else => return unexpectedErrno(err),
}
}
/// Get an environment variable.
/// See also `getenvC`.
/// TODO make this go through libc when we have it
pub fn getenv(key: []const u8) ?[]const u8 {
for (environ) |ptr| {
var line_i: usize = 0;
while (ptr[line_i] != 0 and ptr[line_i] != '=') : (line_i += 1) {}
const this_key = ptr[0..line_i];
if (!mem.eql(u8, key, this_key)) continue;
var end_i: usize = line_i;
while (ptr[end_i] != 0) : (end_i += 1) {}
const this_value = ptr[line_i + 1 .. end_i];
return this_value;
}
return null;
}
/// Get an environment variable with a null-terminated name.
/// See also `getenv`.
/// TODO https://github.com/ziglang/zig/issues/265
pub fn getenvC(key: [*]const u8) ?[]const u8 {
if (builtin.link_libc) {
const value = system.getenv(key) orelse return null;
return mem.toSliceConst(u8, value);
}
return getenv(mem.toSliceConst(u8, key));
}
pub const GetCwdError = error{
NameTooLong,
CurrentWorkingDirectoryUnlinked,
Unexpected,
};
/// The result is a slice of out_buffer, indexed from 0.
pub fn getcwd(out_buffer: []u8) GetCwdError![]u8 {
if (windows.is_the_target) {
return windows.GetCurrentDirectory(out_buffer);
}
const err = if (builtin.link_libc) blk: {
break :blk if (std.c.getcwd(out_buffer.ptr, out_buffer.len)) |_| 0 else std.c._errno().*;
} else blk: {
break :blk errno(system.getcwd(out_buffer.ptr, out_buffer.len));
};
switch (err) {
0 => return mem.toSlice(u8, out_buffer.ptr),
EFAULT => unreachable,
EINVAL => unreachable,
ENOENT => return error.CurrentWorkingDirectoryUnlinked,
ERANGE => return error.NameTooLong,
else => return unexpectedErrno(@intCast(usize, err)),
}
}
pub const SymLinkError = error{
AccessDenied,
DiskQuota,
PathAlreadyExists,
FileSystem,
SymLinkLoop,
FileNotFound,
SystemResources,
NoSpaceLeft,
ReadOnlyFileSystem,
NotDir,
NameTooLong,
InvalidUtf8,
BadPathName,
Unexpected,
};
/// Creates a symbolic link named `sym_link_path` which contains the string `target_path`.
/// A symbolic link (also known as a soft link) may point to an existing file or to a nonexistent
/// one; the latter case is known as a dangling link.
/// If `sym_link_path` exists, it will not be overwritten.
/// See also `symlinkC` and `symlinkW`.
pub fn symlink(target_path: []const u8, sym_link_path: []const u8) SymLinkError!void {
if (windows.is_the_target) {
const target_path_w = try windows.sliceToPrefixedFileW(target_path);
const sym_link_path_w = try windows.sliceToPrefixedFileW(sym_link_path);
return windows.CreateSymbolicLinkW(&sym_link_path_w, &target_path_w, 0);
} else {
const target_path_c = try toPosixPath(target_path);
const sym_link_path_c = try toPosixPath(sym_link_path);
return symlinkC(&target_path_c, &sym_link_path_c);
}
}
/// This is the same as `symlink` except the parameters are null-terminated pointers.
/// See also `symlink`.
pub fn symlinkC(target_path: [*]const u8, sym_link_path: [*]const u8) SymLinkError!void {
if (windows.is_the_target) {
const target_path_w = try windows.cStrToPrefixedFileW(target_path);
const sym_link_path_w = try windows.cStrToPrefixedFileW(sym_link_path);
return windows.CreateSymbolicLinkW(&sym_link_path_w, &target_path_w, 0);
}
switch (errno(system.symlink(target_path, sym_link_path))) {
0 => return,
EFAULT => unreachable,
EINVAL => unreachable,
EACCES => return error.AccessDenied,
EPERM => return error.AccessDenied,
EDQUOT => return error.DiskQuota,
EEXIST => return error.PathAlreadyExists,
EIO => return error.FileSystem,
ELOOP => return error.SymLinkLoop,
ENAMETOOLONG => return error.NameTooLong,
ENOENT => return error.FileNotFound,
ENOTDIR => return error.NotDir,
ENOMEM => return error.SystemResources,
ENOSPC => return error.NoSpaceLeft,
EROFS => return error.ReadOnlyFileSystem,
else => |err| return unexpectedErrno(err),
}
}
pub fn symlinkat(target_path: []const u8, newdirfd: fd_t, sym_link_path: []const u8) SymLinkError!void {
const target_path_c = try toPosixPath(target_path);
const sym_link_path_c = try toPosixPath(sym_link_path);
return symlinkatC(target_path_c, newdirfd, sym_link_path_c);
}
pub fn symlinkatC(target_path: [*]const u8, newdirfd: fd_t, sym_link_path: [*]const u8) SymLinkError!void {
switch (errno(system.symlinkat(target_path, newdirfd, sym_link_path))) {
0 => return,
EFAULT => unreachable,
EINVAL => unreachable,
EACCES => return error.AccessDenied,
EPERM => return error.AccessDenied,
EDQUOT => return error.DiskQuota,
EEXIST => return error.PathAlreadyExists,
EIO => return error.FileSystem,
ELOOP => return error.SymLinkLoop,
ENAMETOOLONG => return error.NameTooLong,
ENOENT => return error.FileNotFound,
ENOTDIR => return error.NotDir,
ENOMEM => return error.SystemResources,
ENOSPC => return error.NoSpaceLeft,
EROFS => return error.ReadOnlyFileSystem,
else => |err| return unexpectedErrno(err),
}
}
pub const UnlinkError = error{
FileNotFound,
AccessDenied,
FileBusy,
FileSystem,
IsDir,
SymLinkLoop,
NameTooLong,
NotDir,
SystemResources,
ReadOnlyFileSystem,
Unexpected,
/// On Windows, file paths must be valid Unicode.
InvalidUtf8,
/// On Windows, file paths cannot contain these characters:
/// '/', '*', '?', '"', '<', '>', '|'
BadPathName,
};
/// Delete a name and possibly the file it refers to.
/// See also `unlinkC`.
pub fn unlink(file_path: []const u8) UnlinkError!void {
if (windows.is_the_target) {
const file_path_w = try windows.sliceToPrefixedFileW(file_path);
return windows.DeleteFileW(&file_path_w);
} else {
const file_path_c = try toPosixPath(file_path);
return unlinkC(&file_path_c);
}
}
/// Same as `unlink` except the parameter is a null terminated UTF8-encoded string.
pub fn unlinkC(file_path: [*]const u8) UnlinkError!void {
if (windows.is_the_target) {
const file_path_w = try windows.cStrToPrefixedFileW(file_path);
return windows.DeleteFileW(&file_path_w);
}
switch (errno(system.unlink(file_path))) {
0 => return,
EACCES => return error.AccessDenied,
EPERM => return error.AccessDenied,
EBUSY => return error.FileBusy,
EFAULT => unreachable,
EINVAL => unreachable,
EIO => return error.FileSystem,
EISDIR => return error.IsDir,
ELOOP => return error.SymLinkLoop,
ENAMETOOLONG => return error.NameTooLong,
ENOENT => return error.FileNotFound,
ENOTDIR => return error.NotDir,
ENOMEM => return error.SystemResources,
EROFS => return error.ReadOnlyFileSystem,
else => |err| return unexpectedErrno(err),
}
}
const RenameError = error{
AccessDenied,
FileBusy,
DiskQuota,
IsDir,
SymLinkLoop,
LinkQuotaExceeded,
NameTooLong,
FileNotFound,
NotDir,
SystemResources,
NoSpaceLeft,
PathAlreadyExists,
ReadOnlyFileSystem,
RenameAcrossMountPoints,
InvalidUtf8,
BadPathName,
Unexpected,
};
/// Change the name or location of a file.
pub fn rename(old_path: []const u8, new_path: []const u8) RenameError!void {
if (windows.is_the_target) {
const old_path_w = try windows.sliceToPrefixedFileW(old_path);
const new_path_w = try windows.sliceToPrefixedFileW(new_path);
return renameW(&old_path_w, &new_path_w);
} else {
const old_path_c = try toPosixPath(old_path);
const new_path_c = try toPosixPath(new_path);
return renameC(&old_path_c, &new_path_c);
}
}
/// Same as `rename` except the parameters are null-terminated byte arrays.
pub fn renameC(old_path: [*]const u8, new_path: [*]const u8) RenameError!void {
if (windows.is_the_target) {
const old_path_w = try windows.cStrToPrefixedFileW(old_path);
const new_path_w = try windows.cStrToPrefixedFileW(new_path);
return renameW(&old_path_w, &new_path_w);
}
switch (errno(system.rename(old_path, new_path))) {
0 => return,
EACCES => return error.AccessDenied,
EPERM => return error.AccessDenied,
EBUSY => return error.FileBusy,
EDQUOT => return error.DiskQuota,
EFAULT => unreachable,
EINVAL => unreachable,
EISDIR => return error.IsDir,
ELOOP => return error.SymLinkLoop,
EMLINK => return error.LinkQuotaExceeded,
ENAMETOOLONG => return error.NameTooLong,
ENOENT => return error.FileNotFound,
ENOTDIR => return error.NotDir,
ENOMEM => return error.SystemResources,
ENOSPC => return error.NoSpaceLeft,
EEXIST => return error.PathAlreadyExists,
ENOTEMPTY => return error.PathAlreadyExists,
EROFS => return error.ReadOnlyFileSystem,
EXDEV => return error.RenameAcrossMountPoints,
else => |err| return unexpectedErrno(err),
}
}
/// Same as `rename` except the parameters are null-terminated UTF16LE encoded byte arrays.
/// Assumes target is Windows.
pub fn renameW(old_path: [*]const u16, new_path: [*]const u16) RenameError!void {
const flags = windows.MOVEFILE_REPLACE_EXISTING | windows.MOVEFILE_WRITE_THROUGH;
return windows.MoveFileExW(old_path, new_path, flags);
}
pub const MakeDirError = error{
AccessDenied,
DiskQuota,
PathAlreadyExists,
SymLinkLoop,
LinkQuotaExceeded,
NameTooLong,
FileNotFound,
SystemResources,
NoSpaceLeft,
NotDir,
ReadOnlyFileSystem,
InvalidUtf8,
BadPathName,
Unexpected,
};
/// Create a directory.
/// `mode` is ignored on Windows.
pub fn mkdir(dir_path: []const u8, mode: u32) MakeDirError!void {
if (windows.is_the_target) {
const dir_path_w = try windows.sliceToPrefixedFileW(dir_path);
return windows.CreateDirectoryW(&dir_path_w, null);
} else {
const dir_path_c = try toPosixPath(dir_path);
return mkdirC(&dir_path_c, mode);
}
}
/// Same as `mkdir` but the parameter is a null-terminated UTF8-encoded string.
pub fn mkdirC(dir_path: [*]const u8, mode: u32) MakeDirError!void {
if (windows.is_the_target) {
const dir_path_w = try windows.cStrToPrefixedFileW(dir_path);
return windows.CreateDirectoryW(&dir_path_w, null);
}
switch (errno(system.mkdir(dir_path, mode))) {
0 => return,
EACCES => return error.AccessDenied,
EPERM => return error.AccessDenied,
EDQUOT => return error.DiskQuota,
EEXIST => return error.PathAlreadyExists,
EFAULT => unreachable,
ELOOP => return error.SymLinkLoop,
EMLINK => return error.LinkQuotaExceeded,
ENAMETOOLONG => return error.NameTooLong,
ENOENT => return error.FileNotFound,
ENOMEM => return error.SystemResources,
ENOSPC => return error.NoSpaceLeft,
ENOTDIR => return error.NotDir,
EROFS => return error.ReadOnlyFileSystem,
else => |err| return unexpectedErrno(err),
}
}
pub const DeleteDirError = error{
AccessDenied,
FileBusy,
SymLinkLoop,
NameTooLong,
FileNotFound,
SystemResources,
NotDir,
DirNotEmpty,
ReadOnlyFileSystem,
InvalidUtf8,
BadPathName,
Unexpected,
};
/// Deletes an empty directory.
pub fn rmdir(dir_path: []const u8) DeleteDirError!void {
if (windows.is_the_target) {
const dir_path_w = try windows.sliceToPrefixedFileW(dir_path);
return windows.RemoveDirectoryW(&dir_path_w);
} else {
const dir_path_c = try toPosixPath(dir_path);
return rmdirC(&dir_path_c);
}
}
/// Same as `rmdir` except the parameter is null-terminated.
pub fn rmdirC(dir_path: [*]const u8) DeleteDirError!void {
if (windows.is_the_target) {
const dir_path_w = try windows.cStrToPrefixedFileW(dir_path);
return windows.RemoveDirectoryW(&dir_path_w);
}
switch (errno(system.rmdir(dir_path))) {
0 => return,
EACCES => return error.AccessDenied,
EPERM => return error.AccessDenied,
EBUSY => return error.FileBusy,
EFAULT => unreachable,
EINVAL => unreachable,
ELOOP => return error.SymLinkLoop,
ENAMETOOLONG => return error.NameTooLong,
ENOENT => return error.FileNotFound,
ENOMEM => return error.SystemResources,
ENOTDIR => return error.NotDir,
EEXIST => return error.DirNotEmpty,
ENOTEMPTY => return error.DirNotEmpty,
EROFS => return error.ReadOnlyFileSystem,
else => |err| return unexpectedErrno(err),
}
}
pub const ChangeCurDirError = error{
AccessDenied,
FileSystem,
SymLinkLoop,
NameTooLong,
FileNotFound,
SystemResources,
NotDir,
Unexpected,
};
/// Changes the current working directory of the calling process.
/// `dir_path` is recommended to be a UTF-8 encoded string.
pub fn chdir(dir_path: []const u8) ChangeCurDirError!void {
if (windows.is_the_target) {
const dir_path_w = try windows.sliceToPrefixedFileW(dir_path);
@compileError("TODO implement chdir for Windows");
} else {
const dir_path_c = try toPosixPath(dir_path);
return chdirC(&dir_path_c);
}
}
/// Same as `chdir` except the parameter is null-terminated.
pub fn chdirC(dir_path: [*]const u8) ChangeCurDirError!void {
if (windows.is_the_target) {
const dir_path_w = try windows.cStrToPrefixedFileW(dir_path);
@compileError("TODO implement chdir for Windows");
}
switch (errno(system.chdir(dir_path))) {
0 => return,
EACCES => return error.AccessDenied,
EFAULT => unreachable,
EIO => return error.FileSystem,
ELOOP => return error.SymLinkLoop,
ENAMETOOLONG => return error.NameTooLong,
ENOENT => return error.FileNotFound,
ENOMEM => return error.SystemResources,
ENOTDIR => return error.NotDir,
else => |err| return unexpectedErrno(err),
}
}
pub const ReadLinkError = error{
AccessDenied,
FileSystem,
SymLinkLoop,
NameTooLong,
FileNotFound,
SystemResources,
NotDir,
Unexpected,
};
/// Read value of a symbolic link.
/// The return value is a slice of `out_buffer` from index 0.
pub fn readlink(file_path: []const u8, out_buffer: []u8) ReadLinkError![]u8 {
if (windows.is_the_target) {
const file_path_w = try windows.sliceToPrefixedFileW(file_path);
@compileError("TODO implement readlink for Windows");
} else {
const file_path_c = try toPosixPath(file_path);
return readlinkC(&file_path_c, out_buffer);
}
}
/// Same as `readlink` except `file_path` is null-terminated.
pub fn readlinkC(file_path: [*]const u8, out_buffer: []u8) ReadLinkError![]u8 {
if (windows.is_the_target) {
const file_path_w = try windows.cStrToPrefixedFileW(file_path);
@compileError("TODO implement readlink for Windows");
}
const rc = system.readlink(file_path, out_buffer.ptr, out_buffer.len);
switch (errno(rc)) {
0 => return out_buffer[0..@bitCast(usize, rc)],
EACCES => return error.AccessDenied,
EFAULT => unreachable,
EINVAL => unreachable,
EIO => return error.FileSystem,
ELOOP => return error.SymLinkLoop,
ENAMETOOLONG => return error.NameTooLong,
ENOENT => return error.FileNotFound,
ENOMEM => return error.SystemResources,
ENOTDIR => return error.NotDir,
else => |err| return unexpectedErrno(err),
}
}
pub const SetIdError = error{
ResourceLimitReached,
InvalidUserId,
PermissionDenied,
Unexpected,
};
pub fn setuid(uid: u32) SetIdError!void {
switch (errno(system.setuid(uid))) {
0 => return,
EAGAIN => return error.ResourceLimitReached,
EINVAL => return error.InvalidUserId,
EPERM => return error.PermissionDenied,
else => |err| return unexpectedErrno(err),
}
}
pub fn setreuid(ruid: u32, euid: u32) SetIdError!void {
switch (errno(system.setreuid(ruid, euid))) {
0 => return,
EAGAIN => return error.ResourceLimitReached,
EINVAL => return error.InvalidUserId,
EPERM => return error.PermissionDenied,
else => |err| return unexpectedErrno(err),
}
}
pub fn setgid(gid: u32) SetIdError!void {
switch (errno(system.setgid(gid))) {
0 => return,
EAGAIN => return error.ResourceLimitReached,
EINVAL => return error.InvalidUserId,
EPERM => return error.PermissionDenied,
else => |err| return unexpectedErrno(err),
}
}
pub fn setregid(rgid: u32, egid: u32) SetIdError!void {
switch (errno(system.setregid(rgid, egid))) {
0 => return,
EAGAIN => return error.ResourceLimitReached,
EINVAL => return error.InvalidUserId,
EPERM => return error.PermissionDenied,
else => |err| return unexpectedErrno(err),
}
}
/// Test whether a file descriptor refers to a terminal.
pub fn isatty(handle: fd_t) bool {
if (windows.is_the_target) {
if (isCygwinPty(handle))
return true;
var out: windows.DWORD = undefined;
return windows.kernel32.GetConsoleMode(handle, &out) != 0;
}
if (builtin.link_libc) {
return system.isatty(handle) != 0;
}
if (wasi.is_the_target) {
@compileError("TODO implement std.os.isatty for WASI");
}
if (linux.is_the_target) {
var wsz: linux.winsize = undefined;
return linux.syscall3(linux.SYS_ioctl, @bitCast(usize, isize(handle)), linux.TIOCGWINSZ, @ptrToInt(&wsz)) == 0;
}
unreachable;
}
pub fn isCygwinPty(handle: fd_t) bool {
if (!windows.is_the_target) return false;
const size = @sizeOf(windows.FILE_NAME_INFO);
var name_info_bytes align(@alignOf(windows.FILE_NAME_INFO)) = [_]u8{0} ** (size + windows.MAX_PATH);
if (windows.kernel32.GetFileInformationByHandleEx(
handle,
windows.FileNameInfo,
@ptrCast(*c_void, &name_info_bytes),
name_info_bytes.len,
) == 0) {
return false;
}
const name_info = @ptrCast(*const windows.FILE_NAME_INFO, &name_info_bytes[0]);
const name_bytes = name_info_bytes[size .. size + usize(name_info.FileNameLength)];
const name_wide = @bytesToSlice(u16, name_bytes);
return mem.indexOf(u16, name_wide, [_]u16{ 'm', 's', 'y', 's', '-' }) != null or
mem.indexOf(u16, name_wide, [_]u16{ '-', 'p', 't', 'y' }) != null;
}
pub const SocketError = error{
/// Permission to create a socket of the specified type and/or
/// protocol is denied.
PermissionDenied,
/// The implementation does not support the specified address family.
AddressFamilyNotSupported,
/// Unknown protocol, or protocol family not available.
ProtocolFamilyNotAvailable,
/// The per-process limit on the number of open file descriptors has been reached.
ProcessFdQuotaExceeded,
/// The system-wide limit on the total number of open files has been reached.
SystemFdQuotaExceeded,
/// Insufficient memory is available. The socket cannot be created until sufficient
/// resources are freed.
SystemResources,
/// The protocol type or the specified protocol is not supported within this domain.
ProtocolNotSupported,
Unexpected,
};
pub fn socket(domain: u32, socket_type: u32, protocol: u32) SocketError!i32 {
const rc = system.socket(domain, socket_type, protocol);
switch (errno(rc)) {
0 => return @intCast(i32, rc),
EACCES => return error.PermissionDenied,
EAFNOSUPPORT => return error.AddressFamilyNotSupported,
EINVAL => return error.ProtocolFamilyNotAvailable,
EMFILE => return error.ProcessFdQuotaExceeded,
ENFILE => return error.SystemFdQuotaExceeded,
ENOBUFS, ENOMEM => return error.SystemResources,
EPROTONOSUPPORT => return error.ProtocolNotSupported,
else => |err| return unexpectedErrno(err),
}
}
pub const BindError = error{
/// The address is protected, and the user is not the superuser.
/// For UNIX domain sockets: Search permission is denied on a component
/// of the path prefix.
AccessDenied,
/// The given address is already in use, or in the case of Internet domain sockets,
/// The port number was specified as zero in the socket
/// address structure, but, upon attempting to bind to an ephemeral port, it was
/// determined that all port numbers in the ephemeral port range are currently in
/// use. See the discussion of /proc/sys/net/ipv4/ip_local_port_range ip(7).
AddressInUse,
/// A nonexistent interface was requested or the requested address was not local.
AddressNotAvailable,
/// Too many symbolic links were encountered in resolving addr.
SymLinkLoop,
/// addr is too long.
NameTooLong,
/// A component in the directory prefix of the socket pathname does not exist.
FileNotFound,
/// Insufficient kernel memory was available.
SystemResources,
/// A component of the path prefix is not a directory.
NotDir,
/// The socket inode would reside on a read-only filesystem.
ReadOnlyFileSystem,
Unexpected,
};
/// addr is `*const T` where T is one of the sockaddr
pub fn bind(fd: i32, addr: *const sockaddr) BindError!void {
const rc = system.bind(fd, addr, @sizeOf(sockaddr));
switch (errno(rc)) {
0 => return,
EACCES => return error.AccessDenied,
EADDRINUSE => return error.AddressInUse,
EBADF => unreachable, // always a race condition if this error is returned
EINVAL => unreachable,
ENOTSOCK => unreachable,
EADDRNOTAVAIL => return error.AddressNotAvailable,
EFAULT => unreachable,
ELOOP => return error.SymLinkLoop,
ENAMETOOLONG => return error.NameTooLong,
ENOENT => return error.FileNotFound,
ENOMEM => return error.SystemResources,
ENOTDIR => return error.NotDir,
EROFS => return error.ReadOnlyFileSystem,
else => |err| return unexpectedErrno(err),
}
}
const ListenError = error{
/// Another socket is already listening on the same port.
/// For Internet domain sockets, the socket referred to by sockfd had not previously
/// been bound to an address and, upon attempting to bind it to an ephemeral port, it
/// was determined that all port numbers in the ephemeral port range are currently in
/// use. See the discussion of /proc/sys/net/ipv4/ip_local_port_range in ip(7).
AddressInUse,
/// The file descriptor sockfd does not refer to a socket.
FileDescriptorNotASocket,
/// The socket is not of a type that supports the listen() operation.
OperationNotSupported,
Unexpected,
};
pub fn listen(sockfd: i32, backlog: u32) ListenError!void {
const rc = system.listen(sockfd, backlog);
switch (errno(rc)) {
0 => return,
EADDRINUSE => return error.AddressInUse,
EBADF => unreachable,
ENOTSOCK => return error.FileDescriptorNotASocket,
EOPNOTSUPP => return error.OperationNotSupported,
else => |err| return unexpectedErrno(err),
}
}
pub const AcceptError = error{
ConnectionAborted,
/// The per-process limit on the number of open file descriptors has been reached.
ProcessFdQuotaExceeded,
/// The system-wide limit on the total number of open files has been reached.
SystemFdQuotaExceeded,
/// Not enough free memory. This often means that the memory allocation is limited
/// by the socket buffer limits, not by the system memory.
SystemResources,
/// The file descriptor sockfd does not refer to a socket.
FileDescriptorNotASocket,
/// The referenced socket is not of type SOCK_STREAM.
OperationNotSupported,
ProtocolFailure,
/// Firewall rules forbid connection.
BlockedByFirewall,
Unexpected,
};
/// Accept a connection on a socket. `fd` must be opened in blocking mode.
/// See also `accept4_async`.
pub fn accept4(fd: i32, addr: *sockaddr, flags: u32) AcceptError!i32 {
while (true) {
var sockaddr_size = u32(@sizeOf(sockaddr));
const rc = system.accept4(fd, addr, &sockaddr_size, flags);
switch (errno(rc)) {
0 => return @intCast(i32, rc),
EINTR => continue,
else => |err| return unexpectedErrno(err),
EAGAIN => unreachable, // This function is for blocking only.
EBADF => unreachable, // always a race condition
ECONNABORTED => return error.ConnectionAborted,
EFAULT => unreachable,
EINVAL => unreachable,
EMFILE => return error.ProcessFdQuotaExceeded,
ENFILE => return error.SystemFdQuotaExceeded,
ENOBUFS => return error.SystemResources,
ENOMEM => return error.SystemResources,
ENOTSOCK => return error.FileDescriptorNotASocket,
EOPNOTSUPP => return error.OperationNotSupported,
EPROTO => return error.ProtocolFailure,
EPERM => return error.BlockedByFirewall,
}
}
}
/// This is the same as `accept4` except `fd` is expected to be non-blocking.
/// Returns -1 if would block.
pub fn accept4_async(fd: i32, addr: *sockaddr, flags: u32) AcceptError!i32 {
while (true) {
var sockaddr_size = u32(@sizeOf(sockaddr));
const rc = system.accept4(fd, addr, &sockaddr_size, flags);
switch (errno(rc)) {
0 => return @intCast(i32, rc),
EINTR => continue,
else => |err| return unexpectedErrno(err),
EAGAIN => return -1,
EBADF => unreachable, // always a race condition
ECONNABORTED => return error.ConnectionAborted,
EFAULT => unreachable,
EINVAL => unreachable,
EMFILE => return error.ProcessFdQuotaExceeded,
ENFILE => return error.SystemFdQuotaExceeded,
ENOBUFS => return error.SystemResources,
ENOMEM => return error.SystemResources,
ENOTSOCK => return error.FileDescriptorNotASocket,
EOPNOTSUPP => return error.OperationNotSupported,
EPROTO => return error.ProtocolFailure,
EPERM => return error.BlockedByFirewall,
}
}
}
pub const EpollCreateError = error{
/// The per-user limit on the number of epoll instances imposed by
/// /proc/sys/fs/epoll/max_user_instances was encountered. See epoll(7) for further
/// details.
/// Or, The per-process limit on the number of open file descriptors has been reached.
ProcessFdQuotaExceeded,
/// The system-wide limit on the total number of open files has been reached.
SystemFdQuotaExceeded,
/// There was insufficient memory to create the kernel object.
SystemResources,
Unexpected,
};
pub fn epoll_create1(flags: u32) EpollCreateError!i32 {
const rc = system.epoll_create1(flags);
switch (errno(rc)) {
0 => return @intCast(i32, rc),
else => |err| return unexpectedErrno(err),
EINVAL => unreachable,
EMFILE => return error.ProcessFdQuotaExceeded,
ENFILE => return error.SystemFdQuotaExceeded,
ENOMEM => return error.SystemResources,
}
}
pub const EpollCtlError = error{
/// op was EPOLL_CTL_ADD, and the supplied file descriptor fd is already registered
/// with this epoll instance.
FileDescriptorAlreadyPresentInSet,
/// fd refers to an epoll instance and this EPOLL_CTL_ADD operation would result in a
/// circular loop of epoll instances monitoring one another.
OperationCausesCircularLoop,
/// op was EPOLL_CTL_MOD or EPOLL_CTL_DEL, and fd is not registered with this epoll
/// instance.
FileDescriptorNotRegistered,
/// There was insufficient memory to handle the requested op control operation.
SystemResources,
/// The limit imposed by /proc/sys/fs/epoll/max_user_watches was encountered while
/// trying to register (EPOLL_CTL_ADD) a new file descriptor on an epoll instance.
/// See epoll(7) for further details.
UserResourceLimitReached,
/// The target file fd does not support epoll. This error can occur if fd refers to,
/// for example, a regular file or a directory.
FileDescriptorIncompatibleWithEpoll,
Unexpected,
};
pub fn epoll_ctl(epfd: i32, op: u32, fd: i32, event: ?*epoll_event) EpollCtlError!void {
const rc = system.epoll_ctl(epfd, op, fd, event);
switch (errno(rc)) {
0 => return,
else => |err| return unexpectedErrno(err),
EBADF => unreachable, // always a race condition if this happens
EEXIST => return error.FileDescriptorAlreadyPresentInSet,
EINVAL => unreachable,
ELOOP => return error.OperationCausesCircularLoop,
ENOENT => return error.FileDescriptorNotRegistered,
ENOMEM => return error.SystemResources,
ENOSPC => return error.UserResourceLimitReached,
EPERM => return error.FileDescriptorIncompatibleWithEpoll,
}
}
/// Waits for an I/O event on an epoll file descriptor.
/// Returns the number of file descriptors ready for the requested I/O,
/// or zero if no file descriptor became ready during the requested timeout milliseconds.
pub fn epoll_wait(epfd: i32, events: []epoll_event, timeout: i32) usize {
while (true) {
// TODO get rid of the @intCast
const rc = system.epoll_wait(epfd, events.ptr, @intCast(u32, events.len), timeout);
switch (errno(rc)) {
0 => return @intCast(usize, rc),
EINTR => continue,
EBADF => unreachable,
EFAULT => unreachable,
EINVAL => unreachable,
else => unreachable,
}
}
}
pub const EventFdError = error{
SystemResources,
ProcessFdQuotaExceeded,
SystemFdQuotaExceeded,
Unexpected,
};
pub fn eventfd(initval: u32, flags: u32) EventFdError!i32 {
const rc = system.eventfd(initval, flags);
switch (errno(rc)) {
0 => return @intCast(i32, rc),
else => |err| return unexpectedErrno(err),
EINVAL => unreachable, // invalid parameters
EMFILE => return error.ProcessFdQuotaExceeded,
ENFILE => return error.SystemFdQuotaExceeded,
ENODEV => return error.SystemResources,
ENOMEM => return error.SystemResources,
}
}
pub const GetSockNameError = error{
/// Insufficient resources were available in the system to perform the operation.
SystemResources,
Unexpected,
};
pub fn getsockname(sockfd: i32) GetSockNameError!sockaddr {
var addr: sockaddr = undefined;
var addrlen: socklen_t = @sizeOf(sockaddr);
switch (errno(system.getsockname(sockfd, &addr, &addrlen))) {
0 => return addr,
else => |err| return unexpectedErrno(err),
EBADF => unreachable, // always a race condition
EFAULT => unreachable,
EINVAL => unreachable, // invalid parameters
ENOTSOCK => unreachable,
ENOBUFS => return error.SystemResources,
}
}
pub const ConnectError = error{
/// For UNIX domain sockets, which are identified by pathname: Write permission is denied on the socket
/// file, or search permission is denied for one of the directories in the path prefix.
/// or
/// The user tried to connect to a broadcast address without having the socket broadcast flag enabled or
/// the connection request failed because of a local firewall rule.
PermissionDenied,
/// Local address is already in use.
AddressInUse,
/// (Internet domain sockets) The socket referred to by sockfd had not previously been bound to an
/// address and, upon attempting to bind it to an ephemeral port, it was determined that all port numbers
/// in the ephemeral port range are currently in use. See the discussion of
/// /proc/sys/net/ipv4/ip_local_port_range in ip(7).
AddressNotAvailable,
/// The passed address didn't have the correct address family in its sa_family field.
AddressFamilyNotSupported,
/// Insufficient entries in the routing cache.
SystemResources,
/// A connect() on a stream socket found no one listening on the remote address.
ConnectionRefused,
/// Network is unreachable.
NetworkUnreachable,
/// Timeout while attempting connection. The server may be too busy to accept new connections. Note
/// that for IP sockets the timeout may be very long when syncookies are enabled on the server.
ConnectionTimedOut,
Unexpected,
};
/// Initiate a connection on a socket.
/// This is for blocking file descriptors only.
/// For non-blocking, see `connect_async`.
pub fn connect(sockfd: i32, sock_addr: *sockaddr, len: socklen_t) ConnectError!void {
while (true) {
switch (errno(system.connect(sockfd, sock_addr, @sizeOf(sockaddr)))) {
0 => return,
EACCES => return error.PermissionDenied,
EPERM => return error.PermissionDenied,
EADDRINUSE => return error.AddressInUse,
EADDRNOTAVAIL => return error.AddressNotAvailable,
EAFNOSUPPORT => return error.AddressFamilyNotSupported,
EAGAIN => return error.SystemResources,
EALREADY => unreachable, // The socket is nonblocking and a previous connection attempt has not yet been completed.
EBADF => unreachable, // sockfd is not a valid open file descriptor.
ECONNREFUSED => return error.ConnectionRefused,
EFAULT => unreachable, // The socket structure address is outside the user's address space.
EINPROGRESS => unreachable, // The socket is nonblocking and the connection cannot be completed immediately.
EINTR => continue,
EISCONN => unreachable, // The socket is already connected.
ENETUNREACH => return error.NetworkUnreachable,
ENOTSOCK => unreachable, // The file descriptor sockfd does not refer to a socket.
EPROTOTYPE => unreachable, // The socket type does not support the requested communications protocol.
ETIMEDOUT => return error.ConnectionTimedOut,
else => |err| return unexpectedErrno(err),
}
}
}
/// Same as `connect` except it is for blocking socket file descriptors.
/// It expects to receive EINPROGRESS`.
pub fn connect_async(sockfd: i32, sock_addr: *sockaddr, len: socklen_t) ConnectError!void {
while (true) {
switch (errno(system.connect(sockfd, sock_addr, @sizeOf(sockaddr)))) {
EINTR => continue,
0, EINPROGRESS => return,
EACCES => return error.PermissionDenied,
EPERM => return error.PermissionDenied,
EADDRINUSE => return error.AddressInUse,
EADDRNOTAVAIL => return error.AddressNotAvailable,
EAFNOSUPPORT => return error.AddressFamilyNotSupported,
EAGAIN => return error.SystemResources,
EALREADY => unreachable, // The socket is nonblocking and a previous connection attempt has not yet been completed.
EBADF => unreachable, // sockfd is not a valid open file descriptor.
ECONNREFUSED => return error.ConnectionRefused,
EFAULT => unreachable, // The socket structure address is outside the user's address space.
EISCONN => unreachable, // The socket is already connected.
ENETUNREACH => return error.NetworkUnreachable,
ENOTSOCK => unreachable, // The file descriptor sockfd does not refer to a socket.
EPROTOTYPE => unreachable, // The socket type does not support the requested communications protocol.
ETIMEDOUT => return error.ConnectionTimedOut,
else => |err| return unexpectedErrno(err),
}
}
}
pub fn getsockoptError(sockfd: i32) ConnectError!void {
var err_code: u32 = undefined;
var size: u32 = @sizeOf(u32);
const rc = system.getsockopt(sockfd, SOL_SOCKET, SO_ERROR, @ptrCast([*]u8, &err_code), &size);
assert(size == 4);
switch (errno(rc)) {
0 => switch (err_code) {
0 => return,
EACCES => return error.PermissionDenied,
EPERM => return error.PermissionDenied,
EADDRINUSE => return error.AddressInUse,
EADDRNOTAVAIL => return error.AddressNotAvailable,
EAFNOSUPPORT => return error.AddressFamilyNotSupported,
EAGAIN => return error.SystemResources,
EALREADY => unreachable, // The socket is nonblocking and a previous connection attempt has not yet been completed.
EBADF => unreachable, // sockfd is not a valid open file descriptor.
ECONNREFUSED => return error.ConnectionRefused,
EFAULT => unreachable, // The socket structure address is outside the user's address space.
EISCONN => unreachable, // The socket is already connected.
ENETUNREACH => return error.NetworkUnreachable,
ENOTSOCK => unreachable, // The file descriptor sockfd does not refer to a socket.
EPROTOTYPE => unreachable, // The socket type does not support the requested communications protocol.
ETIMEDOUT => return error.ConnectionTimedOut,
else => |err| return unexpectedErrno(err),
},
EBADF => unreachable, // The argument sockfd is not a valid file descriptor.
EFAULT => unreachable, // The address pointed to by optval or optlen is not in a valid part of the process address space.
EINVAL => unreachable,
ENOPROTOOPT => unreachable, // The option is unknown at the level indicated.
ENOTSOCK => unreachable, // The file descriptor sockfd does not refer to a socket.
else => |err| return unexpectedErrno(err),
}
}
pub fn waitpid(pid: i32, flags: u32) u32 {
// TODO allow implicit pointer cast from *u32 to *c_uint ?
const Status = if (builtin.link_libc) c_uint else u32;
var status: Status = undefined;
while (true) {
switch (errno(system.waitpid(pid, &status, flags))) {
0 => return @bitCast(u32, status),
EINTR => continue,
ECHILD => unreachable, // The process specified does not exist. It would be a race condition to handle this error.
EINVAL => unreachable, // The options argument was invalid
else => unreachable,
}
}
}
pub const FStatError = error{
SystemResources,
Unexpected,
};
pub fn fstat(fd: fd_t) FStatError!Stat {
var stat: Stat = undefined;
if (darwin.is_the_target) {
switch (darwin.getErrno(darwin.@"fstat$INODE64"(fd, &stat))) {
0 => return stat,
EBADF => unreachable, // Always a race condition.
ENOMEM => return error.SystemResources,
else => |err| return unexpectedErrno(err),
}
}
switch (errno(system.fstat(fd, &stat))) {
0 => return stat,
EBADF => unreachable, // Always a race condition.
ENOMEM => return error.SystemResources,
else => |err| return unexpectedErrno(err),
}
}
pub const KQueueError = error{
/// The per-process limit on the number of open file descriptors has been reached.
ProcessFdQuotaExceeded,
/// The system-wide limit on the total number of open files has been reached.
SystemFdQuotaExceeded,
Unexpected,
};
pub fn kqueue() KQueueError!i32 {
const rc = system.kqueue();
switch (errno(rc)) {
0 => return @intCast(i32, rc),
EMFILE => return error.ProcessFdQuotaExceeded,
ENFILE => return error.SystemFdQuotaExceeded,
else => |err| return unexpectedErrno(err),
}
}
pub const KEventError = error{
/// The process does not have permission to register a filter.
AccessDenied,
/// The event could not be found to be modified or deleted.
EventNotFound,
/// No memory was available to register the event.
SystemResources,
/// The specified process to attach to does not exist.
ProcessNotFound,
/// changelist or eventlist had too many items on it.
/// TODO remove this possibility
Overflow,
};
pub fn kevent(
kq: i32,
changelist: []const Kevent,
eventlist: []Kevent,
timeout: ?*const timespec,
) KEventError!usize {
while (true) {
const rc = system.kevent(
kq,
changelist.ptr,
try math.cast(c_int, changelist.len),
eventlist.ptr,
try math.cast(c_int, eventlist.len),
timeout,
);
switch (errno(rc)) {
0 => return @intCast(usize, rc),
EACCES => return error.AccessDenied,
EFAULT => unreachable,
EBADF => unreachable, // Always a race condition.
EINTR => continue,
EINVAL => unreachable,
ENOENT => return error.EventNotFound,
ENOMEM => return error.SystemResources,
ESRCH => return error.ProcessNotFound,
else => unreachable,
}
}
}
pub const INotifyInitError = error{
ProcessFdQuotaExceeded,
SystemFdQuotaExceeded,
SystemResources,
Unexpected,
};
/// initialize an inotify instance
pub fn inotify_init1(flags: u32) INotifyInitError!i32 {
const rc = system.inotify_init1(flags);
switch (errno(rc)) {
0 => return @intCast(i32, rc),
EINVAL => unreachable,
EMFILE => return error.ProcessFdQuotaExceeded,
ENFILE => return error.SystemFdQuotaExceeded,
ENOMEM => return error.SystemResources,
else => |err| return unexpectedErrno(err),
}
}
pub const INotifyAddWatchError = error{
AccessDenied,
NameTooLong,
FileNotFound,
SystemResources,
UserResourceLimitReached,
Unexpected,
};
/// add a watch to an initialized inotify instance
pub fn inotify_add_watch(inotify_fd: i32, pathname: []const u8, mask: u32) INotifyAddWatchError!i32 {
const pathname_c = try toPosixPath(pathname);
return inotify_add_watchC(inotify_fd, &pathname_c, mask);
}
/// Same as `inotify_add_watch` except pathname is null-terminated.
pub fn inotify_add_watchC(inotify_fd: i32, pathname: [*]const u8, mask: u32) INotifyAddWatchError!i32 {
const rc = system.inotify_add_watch(inotify_fd, pathname, mask);
switch (errno(rc)) {
0 => return @intCast(i32, rc),
EACCES => return error.AccessDenied,
EBADF => unreachable,
EFAULT => unreachable,
EINVAL => unreachable,
ENAMETOOLONG => return error.NameTooLong,
ENOENT => return error.FileNotFound,
ENOMEM => return error.SystemResources,
ENOSPC => return error.UserResourceLimitReached,
else => |err| return unexpectedErrno(err),
}
}
/// remove an existing watch from an inotify instance
pub fn inotify_rm_watch(inotify_fd: i32, wd: i32) void {
switch (errno(system.inotify_rm_watch(inotify_fd, wd))) {
0 => return,
EBADF => unreachable,
EINVAL => unreachable,
else => unreachable,
}
}
pub const MProtectError = error{
/// The memory cannot be given the specified access. This can happen, for example, if you
/// mmap(2) a file to which you have read-only access, then ask mprotect() to mark it
/// PROT_WRITE.
AccessDenied,
/// Changing the protection of a memory region would result in the total number of map
/// pings with distinct attributes (e.g., read versus read/write protection) exceeding the
/// allowed maximum. (For example, making the protection of a range PROT_READ in the mid
/// dle of a region currently protected as PROT_READ|PROT_WRITE would result in three map
/// pings: two read/write mappings at each end and a read-only mapping in the middle.)
OutOfMemory,
Unexpected,
};
/// `memory.len` must be page-aligned.
pub fn mprotect(memory: []align(mem.page_size) u8, protection: u32) MProtectError!void {
assert(mem.isAligned(memory.len, mem.page_size));
switch (errno(system.mprotect(memory.ptr, memory.len, protection))) {
0 => return,
EINVAL => unreachable,
EACCES => return error.AccessDenied,
ENOMEM => return error.OutOfMemory,
else => |err| return unexpectedErrno(err),
}
}
pub const ForkError = error{
SystemResources,
Unexpected,
};
pub fn fork() ForkError!pid_t {
const rc = system.fork();
switch (errno(rc)) {
0 => return @intCast(pid_t, rc),
EAGAIN => return error.SystemResources,
ENOMEM => return error.SystemResources,
else => |err| return unexpectedErrno(err),
}
}
pub const MMapError = error{
/// The underlying filesystem of the specified file does not support memory mapping.
MemoryMappingNotSupported,
/// A file descriptor refers to a non-regular file. Or a file mapping was requested,
/// but the file descriptor is not open for reading. Or `MAP_SHARED` was requested
/// and `PROT_WRITE` is set, but the file descriptor is not open in `O_RDWR` mode.
/// Or `PROT_WRITE` is set, but the file is append-only.
AccessDenied,
/// The `prot` argument asks for `PROT_EXEC` but the mapped area belongs to a file on
/// a filesystem that was mounted no-exec.
PermissionDenied,
LockedMemoryLimitExceeded,
OutOfMemory,
Unexpected,
};
/// Map files or devices into memory.
/// Use of a mapped region can result in these signals:
/// * SIGSEGV - Attempted write into a region mapped as read-only.
/// * SIGBUS - Attempted access to a portion of the buffer that does not correspond to the file
pub fn mmap(
ptr: ?[*]align(mem.page_size) u8,
length: usize,
prot: u32,
flags: u32,
fd: fd_t,
offset: isize,
) MMapError![]align(mem.page_size) u8 {
const err = if (builtin.link_libc) blk: {
const rc = std.c.mmap(ptr, length, prot, flags, fd, offset);
if (rc != std.c.MAP_FAILED) return @ptrCast([*]align(mem.page_size) u8, @alignCast(mem.page_size, rc))[0..length];
break :blk @intCast(usize, system._errno().*);
} else blk: {
const rc = system.mmap(ptr, length, prot, flags, fd, offset);
const err = errno(rc);
if (err == 0) return @intToPtr([*]align(mem.page_size) u8, rc)[0..length];
break :blk err;
};
switch (err) {
ETXTBSY => return error.AccessDenied,
EACCES => return error.AccessDenied,
EPERM => return error.PermissionDenied,
EAGAIN => return error.LockedMemoryLimitExceeded,
EBADF => unreachable, // Always a race condition.
EOVERFLOW => unreachable, // The number of pages used for length + offset would overflow.
ENODEV => return error.MemoryMappingNotSupported,
EINVAL => unreachable, // Invalid parameters to mmap()
ENOMEM => return error.OutOfMemory,
else => return unexpectedErrno(err),
}
}
/// Deletes the mappings for the specified address range, causing
/// further references to addresses within the range to generate invalid memory references.
/// Note that while POSIX allows unmapping a region in the middle of an existing mapping,
/// Zig's munmap function does not, for two reasons:
/// * It violates the Zig principle that resource deallocation must succeed.
/// * The Windows function, VirtualFree, has this restriction.
pub fn munmap(memory: []align(mem.page_size) u8) void {
switch (errno(system.munmap(memory.ptr, memory.len))) {
0 => return,
EINVAL => unreachable, // Invalid parameters.
ENOMEM => unreachable, // Attempted to unmap a region in the middle of an existing mapping.
else => unreachable,
}
}
pub const AccessError = error{
PermissionDenied,
FileNotFound,
NameTooLong,
InputOutput,
SystemResources,
BadPathName,
/// On Windows, file paths must be valid Unicode.
InvalidUtf8,
Unexpected,
};
/// check user's permissions for a file
/// TODO currently this assumes `mode` is `F_OK` on Windows.
pub fn access(path: []const u8, mode: u32) AccessError!void {
if (windows.is_the_target) {
const path_w = try windows.sliceToPrefixedFileW(path);
_ = try windows.GetFileAttributesW(&path_w);
return;
}
const path_c = try toPosixPath(path);
return accessC(&path_c, mode);
}
/// Same as `access` except `path` is null-terminated.
pub fn accessC(path: [*]const u8, mode: u32) AccessError!void {
if (windows.is_the_target) {
const path_w = try windows.cStrToPrefixedFileW(path);
_ = try windows.GetFileAttributesW(&path_w);
return;
}
switch (errno(system.access(path, mode))) {
0 => return,
EACCES => return error.PermissionDenied,
EROFS => return error.PermissionDenied,
ELOOP => return error.PermissionDenied,
ETXTBSY => return error.PermissionDenied,
ENOTDIR => return error.FileNotFound,
ENOENT => return error.FileNotFound,
ENAMETOOLONG => return error.NameTooLong,
EINVAL => unreachable,
EFAULT => unreachable,
EIO => return error.InputOutput,
ENOMEM => return error.SystemResources,
else => |err| return unexpectedErrno(err),
}
}
pub const PipeError = error{
SystemFdQuotaExceeded,
ProcessFdQuotaExceeded,
Unexpected,
};
/// Creates a unidirectional data channel that can be used for interprocess communication.
pub fn pipe() PipeError![2]fd_t {
var fds: [2]fd_t = undefined;
switch (errno(system.pipe(&fds))) {
0 => return fds,
EINVAL => unreachable, // Invalid parameters to pipe()
EFAULT => unreachable, // Invalid fds pointer
ENFILE => return error.SystemFdQuotaExceeded,
EMFILE => return error.ProcessFdQuotaExceeded,
else => |err| return unexpectedErrno(err),
}
}
pub fn pipe2(flags: u32) PipeError![2]fd_t {
var fds: [2]fd_t = undefined;
switch (errno(system.pipe2(&fds, flags))) {
0 => return fds,
EINVAL => unreachable, // Invalid flags
EFAULT => unreachable, // Invalid fds pointer
ENFILE => return error.SystemFdQuotaExceeded,
EMFILE => return error.ProcessFdQuotaExceeded,
else => |err| return unexpectedErrno(err),
}
}
pub const SysCtlError = error{
PermissionDenied,
SystemResources,
NameTooLong,
Unexpected,
};
pub fn sysctl(
name: []const c_int,
oldp: ?*c_void,
oldlenp: ?*usize,
newp: ?*c_void,
newlen: usize,
) SysCtlError!void {
const name_len = math.cast(c_uint, name.len) catch return error.NameTooLong;
switch (errno(system.sysctl(name.ptr, name_len, oldp, oldlenp, newp, newlen))) {
0 => return,
EFAULT => unreachable,
EPERM => return error.PermissionDenied,
ENOMEM => return error.SystemResources,
else => |err| return unexpectedErrno(err),
}
}
pub fn sysctlbynameC(
name: [*]const u8,
oldp: ?*c_void,
oldlenp: ?*usize,
newp: ?*c_void,
newlen: usize,
) SysCtlError!void {
switch (errno(system.sysctlbyname(name, oldp, oldlenp, newp, newlen))) {
0 => return,
EFAULT => unreachable,
EPERM => return error.PermissionDenied,
ENOMEM => return error.SystemResources,
else => |err| return unexpectedErrno(err),
}
}
pub fn gettimeofday(tv: ?*timeval, tz: ?*timezone) void {
switch (errno(system.gettimeofday(tv, tz))) {
0 => return,
EINVAL => unreachable,
else => unreachable,
}
}
pub const SeekError = error{
Unseekable,
Unexpected,
};
/// Repositions read/write file offset relative to the beginning.
pub fn lseek_SET(fd: fd_t, offset: u64) SeekError!void {
if (linux.is_the_target and !builtin.link_libc and @sizeOf(usize) == 4) {
switch (errno(system.llseek(fd, offset, null, SEEK_SET))) {
0 => return,
EBADF => unreachable, // always a race condition
EINVAL => return error.Unseekable,
EOVERFLOW => return error.Unseekable,
ESPIPE => return error.Unseekable,
ENXIO => return error.Unseekable,
else => |err| return unexpectedErrno(err),
}
}
if (windows.is_the_target) {
return windows.SetFilePointerEx_BEGIN(fd, offset);
}
const ipos = @bitCast(i64, offset); // the OS treats this as unsigned
switch (errno(system.lseek(fd, ipos, SEEK_SET))) {
0 => return,
EBADF => unreachable, // always a race condition
EINVAL => return error.Unseekable,
EOVERFLOW => return error.Unseekable,
ESPIPE => return error.Unseekable,
ENXIO => return error.Unseekable,
else => |err| return unexpectedErrno(err),
}
}
/// Repositions read/write file offset relative to the current offset.
pub fn lseek_CUR(fd: fd_t, offset: i64) SeekError!void {
if (linux.is_the_target and !builtin.link_libc and @sizeOf(usize) == 4) {
switch (errno(system.llseek(fd, @bitCast(u64, offset), null, SEEK_CUR))) {
0 => return,
EBADF => unreachable, // always a race condition
EINVAL => return error.Unseekable,
EOVERFLOW => return error.Unseekable,
ESPIPE => return error.Unseekable,
ENXIO => return error.Unseekable,
else => |err| return unexpectedErrno(err),
}
}
if (windows.is_the_target) {
return windows.SetFilePointerEx_CURRENT(fd, offset);
}
switch (errno(system.lseek(fd, offset, SEEK_CUR))) {
0 => return,
EBADF => unreachable, // always a race condition
EINVAL => return error.Unseekable,
EOVERFLOW => return error.Unseekable,
ESPIPE => return error.Unseekable,
ENXIO => return error.Unseekable,
else => |err| return unexpectedErrno(err),
}
}
/// Repositions read/write file offset relative to the end.
pub fn lseek_END(fd: fd_t, offset: i64) SeekError!void {
if (linux.is_the_target and !builtin.link_libc and @sizeOf(usize) == 4) {
switch (errno(system.llseek(fd, @bitCast(u64, offset), null, SEEK_END))) {
EBADF => unreachable, // always a race condition
EINVAL => return error.Unseekable,
EOVERFLOW => return error.Unseekable,
ESPIPE => return error.Unseekable,
ENXIO => return error.Unseekable,
else => |err| return unexpectedErrno(err),
}
}
if (windows.is_the_target) {
return windows.SetFilePointerEx_END(fd, offset);
}
switch (errno(system.lseek(fd, offset, SEEK_END))) {
0 => return,
EBADF => unreachable, // always a race condition
EINVAL => return error.Unseekable,
EOVERFLOW => return error.Unseekable,
ESPIPE => return error.Unseekable,
ENXIO => return error.Unseekable,
else => |err| return unexpectedErrno(err),
}
}
/// Returns the read/write file offset relative to the beginning.
pub fn lseek_CUR_get(fd: fd_t) SeekError!u64 {
if (linux.is_the_target and !builtin.link_libc and @sizeOf(usize) == 4) {
var result: u64 = undefined;
switch (errno(system.llseek(fd, 0, &result, SEEK_CUR))) {
0 => return result,
EBADF => unreachable, // always a race condition
EINVAL => return error.Unseekable,
EOVERFLOW => return error.Unseekable,
ESPIPE => return error.Unseekable,
ENXIO => return error.Unseekable,
else => |err| return unexpectedErrno(err),
}
}
if (windows.is_the_target) {
return windows.SetFilePointerEx_CURRENT_get(fd);
}
const rc = system.lseek(fd, 0, SEEK_CUR);
switch (errno(rc)) {
0 => return @bitCast(u64, rc),
EBADF => unreachable, // always a race condition
EINVAL => return error.Unseekable,
EOVERFLOW => return error.Unseekable,
ESPIPE => return error.Unseekable,
ENXIO => return error.Unseekable,
else => |err| return unexpectedErrno(err),
}
}
pub const RealPathError = error{
FileNotFound,
AccessDenied,
NameTooLong,
NotSupported,
NotDir,
SymLinkLoop,
InputOutput,
FileTooBig,
IsDir,
ProcessFdQuotaExceeded,
SystemFdQuotaExceeded,
NoDevice,
SystemResources,
NoSpaceLeft,
FileSystem,
BadPathName,
DeviceBusy,
SharingViolation,
PipeBusy,
/// On Windows, file paths must be valid Unicode.
InvalidUtf8,
PathAlreadyExists,
Unexpected,
};
/// Return the canonicalized absolute pathname.
/// Expands all symbolic links and resolves references to `.`, `..`, and
/// extra `/` characters in `pathname`.
/// The return value is a slice of `out_buffer`, but not necessarily from the beginning.
/// See also `realpathC` and `realpathW`.
pub fn realpath(pathname: []const u8, out_buffer: *[MAX_PATH_BYTES]u8) RealPathError![]u8 {
if (windows.is_the_target) {
const pathname_w = try windows.sliceToPrefixedFileW(pathname);
return realpathW(&pathname_w, out_buffer);
}
const pathname_c = try toPosixPath(pathname);
return realpathC(&pathname_c, out_buffer);
}
/// Same as `realpath` except `pathname` is null-terminated.
pub fn realpathC(pathname: [*]const u8, out_buffer: *[MAX_PATH_BYTES]u8) RealPathError![]u8 {
if (windows.is_the_target) {
const pathname_w = try windows.cStrToPrefixedFileW(pathname);
return realpathW(&pathname_w, out_buffer);
}
if (linux.is_the_target and !builtin.link_libc) {
const fd = try openC(pathname, linux.O_PATH | linux.O_NONBLOCK | linux.O_CLOEXEC, 0);
defer close(fd);
var procfs_buf: ["/proc/self/fd/-2147483648\x00".len]u8 = undefined;
const proc_path = std.fmt.bufPrint(procfs_buf[0..], "/proc/self/fd/{}\x00", fd) catch unreachable;
return readlinkC(proc_path.ptr, out_buffer);
}
const result_path = std.c.realpath(pathname, out_buffer) orelse switch (std.c._errno().*) {
EINVAL => unreachable,
EBADF => unreachable,
EFAULT => unreachable,
EACCES => return error.AccessDenied,
ENOENT => return error.FileNotFound,
ENOTSUP => return error.NotSupported,
ENOTDIR => return error.NotDir,
ENAMETOOLONG => return error.NameTooLong,
ELOOP => return error.SymLinkLoop,
EIO => return error.InputOutput,
else => |err| return unexpectedErrno(@intCast(usize, err)),
};
return mem.toSlice(u8, result_path);
}
/// Same as `realpath` except `pathname` is null-terminated and UTF16LE-encoded.
pub fn realpathW(pathname: [*]const u16, out_buffer: *[MAX_PATH_BYTES]u8) RealPathError![]u8 {
const h_file = try windows.CreateFileW(
pathname,
windows.GENERIC_READ,
windows.FILE_SHARE_READ,
null,
windows.OPEN_EXISTING,
windows.FILE_ATTRIBUTE_NORMAL,
null,
);
defer windows.CloseHandle(h_file);
var wide_buf: [windows.PATH_MAX_WIDE]u16 = undefined;
const wide_len = try windows.GetFinalPathNameByHandleW(h_file, &wide_buf, wide_buf.len, windows.VOLUME_NAME_DOS);
assert(wide_len <= wide_buf.len);
const wide_slice = wide_buf[0..wide_len];
// Windows returns \\?\ prepended to the path.
// We strip it to make this function consistent across platforms.
const prefix = [_]u16{ '\\', '\\', '?', '\\' };
const start_index = if (mem.startsWith(u16, wide_slice, prefix)) prefix.len else 0;
// Trust that Windows gives us valid UTF-16LE.
const end_index = std.unicode.utf16leToUtf8(out_buffer, wide_slice[start_index..]) catch unreachable;
return out_buffer[0..end_index];
}
/// Spurious wakeups are possible and no precision of timing is guaranteed.
pub fn nanosleep(seconds: u64, nanoseconds: u64) void {
var req = timespec{
.tv_sec = math.cast(isize, seconds) catch math.maxInt(isize),
.tv_nsec = math.cast(isize, nanoseconds) catch math.maxInt(isize),
};
var rem: timespec = undefined;
while (true) {
switch (errno(system.nanosleep(&req, &rem))) {
EFAULT => unreachable,
EINVAL => {
// Sometimes Darwin returns EINVAL for no reason.
// We treat it as a spurious wakeup.
return;
},
EINTR => {
req = rem;
continue;
},
// This prong handles success as well as unexpected errors.
else => return,
}
}
}
pub fn dl_iterate_phdr(comptime T: type, callback: extern fn (info: *dl_phdr_info, size: usize, data: ?*T) i32, data: ?*T) isize {
// This is implemented only for systems using ELF executables
if (windows.is_the_target or builtin.os == .uefi or wasi.is_the_target or darwin.is_the_target)
@compileError("dl_iterate_phdr is not available for this target");
if (builtin.link_libc) {
return system.dl_iterate_phdr(
@ptrCast(std.c.dl_iterate_phdr_callback, callback),
@ptrCast(?*c_void, data),
);
}
const elf_base = std.process.getBaseAddress();
const ehdr = @intToPtr(*elf.Ehdr, elf_base);
// Make sure the base address points to an ELF image
assert(mem.eql(u8, ehdr.e_ident[0..4], "\x7fELF"));
const n_phdr = ehdr.e_phnum;
const phdrs = (@intToPtr([*]elf.Phdr, elf_base + ehdr.e_phoff))[0..n_phdr];
var it = dl.linkmap_iterator(phdrs) catch unreachable;
// The executable has no dynamic link segment, create a single entry for
// the whole ELF image
if (it.end()) {
var info = dl_phdr_info{
.dlpi_addr = elf_base,
.dlpi_name = c"/proc/self/exe",
.dlpi_phdr = phdrs.ptr,
.dlpi_phnum = ehdr.e_phnum,
};
return callback(&info, @sizeOf(dl_phdr_info), data);
}
// Last return value from the callback function
var last_r: isize = 0;
while (it.next()) |entry| {
var dlpi_phdr: [*]elf.Phdr = undefined;
var dlpi_phnum: u16 = undefined;
if (entry.l_addr != 0) {
const elf_header = @intToPtr(*elf.Ehdr, entry.l_addr);
dlpi_phdr = @intToPtr([*]elf.Phdr, entry.l_addr + elf_header.e_phoff);
dlpi_phnum = elf_header.e_phnum;
} else {
// This is the running ELF image
dlpi_phdr = @intToPtr([*]elf.Phdr, elf_base + ehdr.e_phoff);
dlpi_phnum = ehdr.e_phnum;
}
var info = dl_phdr_info{
.dlpi_addr = entry.l_addr,
.dlpi_name = entry.l_name,
.dlpi_phdr = dlpi_phdr,
.dlpi_phnum = dlpi_phnum,
};
last_r = callback(&info, @sizeOf(dl_phdr_info), data);
if (last_r != 0) break;
}
return last_r;
}
pub const ClockGetTimeError = error{
UnsupportedClock,
Unexpected,
};
pub fn clock_gettime(clk_id: i32, tp: *timespec) ClockGetTimeError!void {
switch (errno(system.clock_gettime(clk_id, tp))) {
0 => return,
EFAULT => unreachable,
EINVAL => return error.UnsupportedClock,
else => |err| return unexpectedErrno(err),
}
}
pub fn clock_getres(clk_id: i32, res: *timespec) ClockGetTimeError!void {
switch (errno(system.clock_getres(clk_id, res))) {
0 => return,
EFAULT => unreachable,
EINVAL => return error.UnsupportedClock,
else => |err| return unexpectedErrno(err),
}
}
pub const SchedGetAffinityError = error{
PermissionDenied,
Unexpected,
};
pub fn sched_getaffinity(pid: pid_t) SchedGetAffinityError!cpu_set_t {
var set: cpu_set_t = undefined;
switch (errno(system.sched_getaffinity(pid, @sizeOf(cpu_set_t), &set))) {
0 => return set,
EFAULT => unreachable,
EINVAL => unreachable,
ESRCH => unreachable,
EPERM => return error.PermissionDenied,
else => |err| return unexpectedErrno(err),
}
}
/// Used to convert a slice to a null terminated slice on the stack.
/// TODO https://github.com/ziglang/zig/issues/287
pub fn toPosixPath(file_path: []const u8) ![PATH_MAX]u8 {
var path_with_null: [PATH_MAX]u8 = undefined;
// >= rather than > to make room for the null byte
if (file_path.len >= PATH_MAX) return error.NameTooLong;
mem.copy(u8, &path_with_null, file_path);
path_with_null[file_path.len] = 0;
return path_with_null;
}
/// Whether or not error.Unexpected will print its value and a stack trace.
/// if this happens the fix is to add the error code to the corresponding
/// switch expression, possibly introduce a new error in the error set, and
/// send a patch to Zig.
pub const unexpected_error_tracing = builtin.mode == .Debug;
pub const UnexpectedError = error{
/// The Operating System returned an undocumented error code.
/// This error is in theory not possible, but it would be better
/// to handle this error than to invoke undefined behavior.
Unexpected,
};
/// Call this when you made a syscall or something that sets errno
/// and you get an unexpected error.
pub fn unexpectedErrno(err: usize) UnexpectedError {
if (unexpected_error_tracing) {
std.debug.warn("unexpected errno: {}\n", err);
std.debug.dumpCurrentStackTrace(null);
}
return error.Unexpected;
}
pub const SigaltstackError = error{
/// The supplied stack size was less than MINSIGSTKSZ.
SizeTooSmall,
/// Attempted to change the signal stack while it was active.
PermissionDenied,
Unexpected,
};
pub fn sigaltstack(ss: ?*stack_t, old_ss: ?*stack_t) SigaltstackError!void {
if (windows.is_the_target or uefi.is_the_target or wasi.is_the_target)
@compileError("std.os.sigaltstack not available for this target");
switch (errno(system.sigaltstack(ss, old_ss))) {
0 => return,
EFAULT => unreachable,
EINVAL => unreachable,
ENOMEM => return error.SizeTooSmall,
EPERM => return error.PermissionDenied,
else => |err| return unexpectedErrno(err),
}
}
/// Examine and change a signal action.
pub fn sigaction(sig: u6, act: *const Sigaction, oact: ?*Sigaction) void {
switch (errno(system.sigaction(sig, act, oact))) {
0 => return,
EFAULT => unreachable,
EINVAL => unreachable,
else => unreachable,
}
}
pub const FutimensError = error{
/// times is NULL, or both tv_nsec values are UTIME_NOW, and either:
/// * the effective user ID of the caller does not match the owner
/// of the file, the caller does not have write access to the
/// file, and the caller is not privileged (Linux: does not have
/// either the CAP_FOWNER or the CAP_DAC_OVERRIDE capability);
/// or,
/// * the file is marked immutable (see chattr(1)).
AccessDenied,
/// The caller attempted to change one or both timestamps to a value
/// other than the current time, or to change one of the timestamps
/// to the current time while leaving the other timestamp unchanged,
/// (i.e., times is not NULL, neither tv_nsec field is UTIME_NOW,
/// and neither tv_nsec field is UTIME_OMIT) and either:
/// * the caller's effective user ID does not match the owner of
/// file, and the caller is not privileged (Linux: does not have
/// the CAP_FOWNER capability); or,
/// * the file is marked append-only or immutable (see chattr(1)).
PermissionDenied,
ReadOnlyFileSystem,
Unexpected,
};
pub fn futimens(fd: fd_t, times: *const [2]timespec) FutimensError!void {
switch (errno(system.futimens(fd, times))) {
0 => return,
EACCES => return error.AccessDenied,
EPERM => return error.PermissionDenied,
EBADF => unreachable, // always a race condition
EFAULT => unreachable,
EINVAL => unreachable,
EROFS => return error.ReadOnlyFileSystem,
else => |err| return unexpectedErrno(err),
}
}
test "" {
_ = @import("os/darwin.zig");
_ = @import("os/freebsd.zig");
_ = @import("os/linux.zig");
_ = @import("os/netbsd.zig");
_ = @import("os/uefi.zig");
_ = @import("os/wasi.zig");
_ = @import("os/windows.zig");
_ = @import("os/zen.zig");
_ = @import("os/test.zig");
}
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