zig/std/os/index.zig

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pub const windows = @import("windows.zig");
pub const darwin = @import("darwin.zig");
pub const linux = @import("linux.zig");
pub const posix = switch(@compileVar("os")) {
Os.linux => linux,
Os.darwin, Os.macosx, Os.ios => darwin,
Os.windows => windows,
else => @compileError("Unsupported OS"),
};
pub const max_noalloc_path_len = 1024;
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pub const ChildProcess = @import("child_process.zig").ChildProcess;
const debug = @import("../debug.zig");
const assert = debug.assert;
const errno = @import("errno.zig");
const linking_libc = @import("../target.zig").linking_libc;
const c = @import("../c/index.zig");
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const mem = @import("../mem.zig");
const Allocator = mem.Allocator;
const BufMap = @import("../buf_map.zig").BufMap;
const cstr = @import("../cstr.zig");
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error Unexpected;
error SystemResources;
error AccessDenied;
error InvalidExe;
error FileSystem;
error IsDir;
error FileNotFound;
error FileBusy;
error LinkPathAlreadyExists;
error SymLinkLoop;
error ReadOnlyFileSystem;
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/// Fills `buf` with random bytes. If linking against libc, this calls the
/// appropriate OS-specific library call. Otherwise it uses the zig standard
/// library implementation.
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pub fn getRandomBytes(buf: []u8) -> %void {
while (true) {
const err = switch (@compileVar("os")) {
Os.linux => {
if (linking_libc) {
if (c.getrandom(buf.ptr, buf.len, 0) == -1) *c._errno() else 0
} else {
posix.getErrno(posix.getrandom(buf.ptr, buf.len, 0))
}
},
Os.darwin, Os.macosx, Os.ios => {
if (linking_libc) {
if (posix.getrandom(buf.ptr, buf.len) == -1) *c._errno() else 0
} else {
posix.getErrno(posix.getrandom(buf.ptr, buf.len))
}
},
Os.windows => {
var hCryptProv: windows.HCRYPTPROV = undefined;
if (!windows.CryptAcquireContext(&hCryptProv, null, null, windows.PROV_RSA_FULL, 0)) {
return error.Unexpected;
}
defer _ = windows.CryptReleaseContext(hCryptProv, 0);
if (!windows.CryptGenRandom(hCryptProv, windows.DWORD(buf.len), buf.ptr)) {
return error.Unexpected;
}
return;
},
else => @compileError("Unsupported OS"),
};
if (err > 0) {
return switch (err) {
errno.EINVAL => unreachable,
errno.EFAULT => unreachable,
errno.EINTR => continue,
else => error.Unexpected,
}
}
return;
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}
}
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/// Raises a signal in the current kernel thread, ending its execution.
/// If linking against libc, this calls the abort() libc function. Otherwise
/// it uses the zig standard library implementation.
pub coldcc fn abort() -> noreturn {
if (linking_libc) {
c.abort();
}
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switch (@compileVar("os")) {
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Os.linux, Os.darwin, Os.macosx, Os.ios => {
_ = posix.raise(posix.SIGABRT);
_ = posix.raise(posix.SIGKILL);
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while (true) {}
},
else => @compileError("Unsupported OS"),
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}
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}
/// Calls POSIX close, and keeps trying if it gets interrupted.
pub fn posixClose(fd: i32) {
while (true) {
const err = posix.getErrno(posix.close(fd));
if (err == errno.EINTR) {
continue;
} else {
return;
}
}
}
/// Calls POSIX write, and keeps trying if it gets interrupted.
pub fn posixWrite(fd: i32, bytes: []const u8) -> %void {
while (true) {
const write_ret = posix.write(fd, bytes.ptr, bytes.len);
const write_err = posix.getErrno(write_ret);
if (write_err > 0) {
return switch (write_err) {
errno.EINTR => continue,
errno.EINVAL => unreachable,
errno.EDQUOT => error.DiskQuota,
errno.EFBIG => error.FileTooBig,
errno.EIO => error.Io,
errno.ENOSPC => error.NoSpaceLeft,
errno.EPERM => error.BadPerm,
errno.EPIPE => error.PipeFail,
else => error.Unexpected,
}
}
return;
}
}
/// ::path may need to be copied in memory to add a null terminating byte. In this case
/// a fixed size buffer of size ::max_noalloc_path_len is an attempted solution. If the fixed
/// size buffer is too small, and the provided allocator is null, ::error.NameTooLong is returned.
/// otherwise if the fixed size buffer is too small, allocator is used to obtain the needed memory.
/// Calls POSIX open, keeps trying if it gets interrupted, and translates
/// the return value into zig errors.
pub fn posixOpen(path: []const u8, flags: usize, perm: usize, allocator: ?&Allocator) -> %i32 {
var stack_buf: [max_noalloc_path_len]u8 = undefined;
var path0: []u8 = undefined;
var need_free = false;
if (path.len < stack_buf.len) {
path0 = stack_buf[0...path.len + 1];
} else if (const a ?= allocator) {
path0 = %return a.alloc(u8, path.len + 1);
need_free = true;
} else {
return error.NameTooLong;
}
defer if (need_free) {
(??allocator).free(path0);
};
mem.copy(u8, path0, path);
path0[path.len] = 0;
while (true) {
const result = posix.open(path0.ptr, flags, perm);
const err = posix.getErrno(result);
if (err > 0) {
return switch (err) {
errno.EINTR => continue,
errno.EFAULT => unreachable,
errno.EINVAL => unreachable,
errno.EACCES => error.BadPerm,
errno.EFBIG, errno.EOVERFLOW => error.FileTooBig,
errno.EISDIR => error.IsDir,
errno.ELOOP => error.SymLinkLoop,
errno.EMFILE => error.ProcessFdQuotaExceeded,
errno.ENAMETOOLONG => error.NameTooLong,
errno.ENFILE => error.SystemFdQuotaExceeded,
errno.ENODEV => error.NoDevice,
errno.ENOENT => error.PathNotFound,
errno.ENOMEM => error.SystemResources,
errno.ENOSPC => error.NoSpaceLeft,
errno.ENOTDIR => error.NotDir,
errno.EPERM => error.BadPerm,
else => error.Unexpected,
}
}
return i32(result);
}
}
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pub fn posixDup2(old_fd: i32, new_fd: i32) -> %void {
while (true) {
const err = posix.getErrno(posix.dup2(old_fd, new_fd));
if (err > 0) {
return switch (err) {
errno.EBUSY, errno.EINTR => continue,
errno.EMFILE => error.SystemResources,
errno.EINVAL => unreachable,
else => error.Unexpected,
};
}
return;
}
}
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/// 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.
/// Also make the first arg equal to exe_path.
/// This function also uses the PATH environment variable to get the full path to the executable.
pub fn posixExecve(exe_path: []const u8, argv: []const []const u8, env_map: &const BufMap,
allocator: &Allocator) -> %void
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{
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const argv_buf = %return allocator.alloc(?&const u8, argv.len + 2);
mem.set(?&const u8, argv_buf, null);
defer {
for (argv_buf) |arg| {
const arg_buf = if (const ptr ?= arg) ptr[0...cstr.len(ptr)] else break;
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allocator.free(arg_buf);
}
allocator.free(argv_buf);
}
{
// Add exe_path to the first argument.
const arg_buf = %return allocator.alloc(u8, exe_path.len + 1);
@memcpy(&arg_buf[0], exe_path.ptr, exe_path.len);
arg_buf[exe_path.len] = 0;
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argv_buf[0] = arg_buf.ptr;
}
for (argv) |arg, i| {
const arg_buf = %return allocator.alloc(u8, arg.len + 1);
@memcpy(&arg_buf[0], arg.ptr, arg.len);
arg_buf[arg.len] = 0;
argv_buf[i + 1] = arg_buf.ptr;
}
argv_buf[argv.len + 1] = null;
const envp_count = env_map.count();
const envp_buf = %return allocator.alloc(?&const u8, envp_count + 1);
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mem.set(?&const u8, envp_buf, null);
defer {
for (envp_buf) |env| {
const env_buf = if (const ptr ?= env) ptr[0...cstr.len(ptr)] else break;
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allocator.free(env_buf);
}
allocator.free(envp_buf);
}
{
var it = env_map.iterator();
var i: usize = 0;
while (true; i += 1) {
const pair = it.next() ?? break;
const env_buf = %return allocator.alloc(u8, pair.key.len + pair.value.len + 2);
@memcpy(&env_buf[0], pair.key.ptr, pair.key.len);
env_buf[pair.key.len] = '=';
@memcpy(&env_buf[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);
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}
envp_buf[envp_count] = null;
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if (mem.indexOfScalar(u8, exe_path, '/') != null) {
// +1 for the null terminating byte
const path_buf = %return allocator.alloc(u8, exe_path.len + 1);
defer allocator.free(path_buf);
@memcpy(&path_buf[0], &exe_path[0], exe_path.len);
path_buf[exe_path.len] = 0;
return posixExecveErrnoToErr(posix.getErrno(posix.execve(path_buf.ptr, argv_buf.ptr, envp_buf.ptr)));
}
const PATH = getEnv("PATH") ?? "/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 = %return allocator.alloc(u8, PATH.len + exe_path.len + 2);
defer allocator.free(path_buf);
var it = mem.split(PATH, ':');
var seen_eacces = false;
var err: usize = undefined;
while (true) {
const search_path = it.next() ?? break;
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 + 2] = 0;
err = posix.getErrno(posix.execve(path_buf.ptr, argv_buf.ptr, envp_buf.ptr));
assert(err > 0);
if (err == errno.EACCES) {
seen_eacces = true;
} else if (err != errno.ENOENT) {
return posixExecveErrnoToErr(err);
}
}
if (seen_eacces) {
err = errno.EACCES;
}
return posixExecveErrnoToErr(err);
}
fn posixExecveErrnoToErr(err: usize) -> error {
assert(err > 0);
return switch (err) {
errno.EFAULT => unreachable,
errno.E2BIG, errno.EMFILE, errno.ENAMETOOLONG, errno.ENFILE, errno.ENOMEM => error.SystemResources,
errno.EACCES, errno.EPERM => error.AccessDenied,
errno.EINVAL, errno.ENOEXEC => error.InvalidExe,
errno.EIO, errno.ELOOP => error.FileSystem,
errno.EISDIR => error.IsDir,
errno.ENOENT, errno.ENOTDIR => error.FileNotFound,
errno.ETXTBSY => error.FileBusy,
else => error.Unexpected,
};
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}
pub var environ_raw: []&u8 = undefined;
pub fn getEnvMap(allocator: &Allocator) -> %BufMap {
var result = BufMap.init(allocator);
%defer result.deinit();
for (environ_raw) |ptr| {
var line_i: usize = 0;
while (ptr[line_i] != 0 and ptr[line_i] != '='; line_i += 1) {}
const key = ptr[0...line_i];
var end_i: usize = line_i;
while (ptr[end_i] != 0; end_i += 1) {}
const value = ptr[line_i + 1...end_i];
%return result.set(key, value);
}
return result;
}
pub fn getEnv(key: []const u8) -> ?[]const u8 {
for (environ_raw) |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;
}
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pub const args = struct {
pub var raw: []&u8 = undefined;
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pub fn count() -> usize {
return raw.len;
}
pub fn at(i: usize) -> []const u8 {
const s = raw[i];
return s[0...cstr.len(s)];
}
};
/// Caller must free the returned memory.
pub fn getCwd(allocator: &Allocator) -> %[]u8 {
var buf = %return allocator.alloc(u8, 1024);
%defer allocator.free(buf);
while (true) {
const err = posix.getErrno(posix.getcwd(buf.ptr, buf.len));
if (err == errno.ERANGE) {
buf = %return allocator.realloc(u8, buf, buf.len * 2);
continue;
} else if (err > 0) {
return error.Unexpected;
}
return buf;
}
}
pub fn symLink(allocator: &Allocator, existing_path: []const u8, new_path: []const u8) -> %void {
const full_buf = %return allocator.alloc(u8, existing_path.len + new_path.len + 2);
defer allocator.free(full_buf);
const existing_buf = full_buf;
mem.copy(u8, existing_buf, existing_path);
existing_buf[existing_path.len] = 0;
const new_buf = full_buf[existing_path.len + 1...];
mem.copy(u8, new_buf, new_path);
new_buf[new_path.len] = 0;
const err = posix.getErrno(posix.symlink(existing_buf.ptr, new_buf.ptr));
if (err > 0) {
return switch (err) {
errno.EFAULT, errno.EINVAL => unreachable,
errno.EACCES, errno.EPERM => error.AccessDenied,
errno.EDQUOT => error.DiskQuota,
errno.EEXIST => error.LinkPathAlreadyExists,
errno.EIO => error.FileSystem,
errno.ELOOP => error.SymLinkLoop,
errno.ENAMETOOLONG => error.NameTooLong,
errno.ENOENT, errno.ENOTDIR => error.FileNotFound,
errno.ENOMEM => error.SystemResources,
errno.ENOSPC => error.NoSpaceLeft,
errno.EROFS => error.ReadOnlyFileSystem,
else => error.Unexpected,
};
}
}
pub fn deleteFile(allocator: &Allocator, path: []const u8) -> %void {
const buf = %return allocator.alloc(u8, path.len + 1);
defer allocator.free(buf);
mem.copy(u8, buf, path);
buf[path.len] = 0;
const err = posix.getErrno(posix.unlink(buf.ptr));
if (err > 0) {
return switch (err) {
errno.EACCES, errno.EPERM => error.AccessDenied,
errno.EBUSY => error.FileBusy,
errno.EFAULT, errno.EINVAL => unreachable,
errno.EIO => error.FileSystem,
errno.EISDIR => error.IsDir,
errno.ELOOP => error.SymLinkLoop,
errno.ENAMETOOLONG => error.NameTooLong,
errno.ENOENT, errno.ENOTDIR => error.FileNotFound,
errno.ENOMEM => error.SystemResources,
errno.EROFS => error.ReadOnlyFileSystem,
else => error.Unexpected,
};
}
}