Module Async_unix.Unix

module Fd = Fd
include Async_unix__.Unix_syscalls
module Syscall_result = Core.Unix.Syscall_result
module Exit = Core.Unix.Exit
module Exit_or_signal = Core.Unix.Exit_or_signal
module Exit_or_signal_or_stop = Core.Unix.Exit_or_signal_or_stop
val system : string -> Exit_or_signal.t Async_unix__.Import.Deferred.t
val system_exn : string -> unit Async_unix__.Import.Deferred.t
val getpid : unit -> Core.Pid.t
val getppid : unit -> Core.Pid.t option
val getppid_exn : unit -> Core.Pid.t
val this_process_became_child_of_init : ?⁠poll_delay:Core.Time.Span.t -> unit -> unit Async_unix__.Import.Deferred.t

this_process_became_child_of_init returns a deferred that becomes determined when the current process becomes a child of init(8). This is useful for determining whether one's parent has died, because in that case init will become one's parent.

See Linux_ext.pr_set_pdeathsig : Signal.t -> unit for a related way to get information about parent death.

?poll_delay controls how often to check.

val nice : int -> int
val cores : (unit -> int Async_unix__.Import.Deferred.t) Core.Or_error.t

cores () Returns the number of cores.

type open_flag = [
| `Rdonly
| `Wronly
| `Rdwr
| `Nonblock
| `Append
| `Creat
| `Trunc
| `Excl
| `Noctty
| `Dsync
| `Sync
| `Rsync
]
type file_perm = int
val openfile : ?⁠perm:file_perm -> string -> mode:open_flag list -> Fd.t Async_unix__.Import.Deferred.t
val with_file : ?⁠lock:Lock.t -> ?⁠perm:file_perm -> string -> mode:open_flag list -> f:(Fd.t -> 'a Async_unix__.Import.Deferred.t) -> 'a Async_unix__.Import.Deferred.t

with_file file ~mode ~perm ~f opens file, and applies f to the resulting file descriptor. When the result of f becomes determined, it closes the descriptor and returns the result of f.

If lock is supplied, then the file descriptor is locked before calling f with the specified lock_mechanism. Note that it is not unlocked before close, which might be significant if this file descriptior is held elsewhere (e.g., by fork() or dup()).

module Open_flags = Core.Unix.Open_flags
val fcntl_getfl : Fd.t -> Open_flags.t Async_unix__.Import.Deferred.t

fcntl_getfl and fcntl_setf are deferred wrappers around the corresponding functions in Core.Unix for accessing the open-file-descriptor table.

val fcntl_setfl : Fd.t -> Open_flags.t -> unit Async_unix__.Import.Deferred.t
include module type of Fd.Close
type socket_handling =
| Shutdown_socket
| Do_not_shutdown_socket
type file_descriptor_handling =
| Close_file_descriptor of socket_handling
| Do_not_close_file_descriptor
val close : ?⁠file_descriptor_handling:file_descriptor_handling -> Fd.t -> unit Async_unix__.Import.Deferred.t

close t prevents further use of t, and makes shutdown() and close() system calls on t's underlying file descriptor according to the file_descriptor_handling argument and whether or not t is a socket, i.e., kind t = Socket `Active:

        | file_descriptor_handling                     | shutdown() | close() |
        |----------------------------------------------+------------+---------|
        | Do_not_close_file_descriptor                 | no         | no      |
        | Close_file_descriptor Shutdown_socket        | if socket  | yes     |
        | Close_file_descriptor Do_not_shutdown_socket | no         | yes     |

The result of close becomes determined once the system calls complete. It is OK to call close multiple times on the same t; calls subsequent to the initial call will have no effect, but will return the same deferred as the original call.

val lseek : Fd.t -> int64 -> mode:[< `Set | `Cur | `End ] -> int64 Async_unix__.Import.Deferred.t
val truncate : string -> len:int64 -> unit Async_unix__.Import.Deferred.t
val ftruncate : Fd.t -> len:int64 -> unit Async_unix__.Import.Deferred.t
val fsync : Fd.t -> unit Async_unix__.Import.Deferred.t
val fdatasync : Fd.t -> unit Async_unix__.Import.Deferred.t
val sync : unit -> unit Async_unix__.Import.Deferred.t
val lockf : ?⁠len:Core.Int64.t -> Fd.t -> Lock_mode.t -> unit Async_unix__.Import.Deferred.t

lockf fd lock_mode ?len locks the section of the open file fd specified by the current file position and len (see man lockf). It returns when the lock has been acquired. It raises if fd is closed.

Note that, despite the name, this function does not call the UNIX lockf() system call; rather it calls fcntl() with F_SETLKW

val try_lockf : ?⁠len:Core.Int64.t -> Fd.t -> Lock_mode.t -> bool

try_lockf fd lock_mode ?len attempts to lock the section of the open file fd specified by the current file position and len (see man lockf). It returns true if it acquired the lock. It raises if fd is closed.

Note that, despite the name, this function does not call the UNIX lockf() system call; rather it calls fcntl() with F_SETLK

val test_lockf : ?⁠len:Core.Int64.t -> Fd.t -> bool

test_lockf fd ?len checks the lock on section of the open file fd specified by the current file position and len. If the section is unlocked or locked by this process, it returns true, else it returns false. It raises if fd is closed.

Note that, despite the name, this function does not call the UNIX lockf() system call; rather it calls fcntl() with F_GETLK

val unlockf : ?⁠len:Core.Int64.t -> Fd.t -> unit

unlockf fd ?len unlocks the section of the open file fd specified by the current file position and len. It raises if fd is closed.

Note that, despite the name, this function does not call the UNIX lockf() system call; rather it calls fcntl() with F_UNLCK

val flock : Fd.t -> Lock_mode.t -> unit Async_unix__.Import.Deferred.t

flock fd lock_mode locks the open file fd (see man 2 flock). It returns when the lock has been acquired. It raises if fd is closed.

val try_flock : Fd.t -> Lock_mode.t -> bool

try_flock fd lock_mode attempts to lock the open file fd (see man 2 flock). It returns true if it acquired the lock or false if a conflicting lock was already present. It raises if fd is closed.

val funlock : Fd.t -> unit

funlock fd unlocks the open file fd (see man 2 flock). It raises if fd is closed.

val fstat : Fd.t -> Stats.t Async_unix__.Import.Deferred.t
val stat : string -> Stats.t Async_unix__.Import.Deferred.t
val lstat : string -> Stats.t Async_unix__.Import.Deferred.t
val isatty : Fd.t -> bool Async_unix__.Import.Deferred.t
val remove : string -> unit Async_unix__.Import.Deferred.t
val rename : src:string -> dst:string -> unit Async_unix__.Import.Deferred.t
val chmod : string -> perm:file_perm -> unit Async_unix__.Import.Deferred.t
val fchmod : Fd.t -> perm:file_perm -> unit Async_unix__.Import.Deferred.t
val chown : string -> uid:int -> gid:int -> unit Async_unix__.Import.Deferred.t
val fchown : Fd.t -> uid:int -> gid:int -> unit Async_unix__.Import.Deferred.t
val access : string -> [ `Read | `Write | `Exec | `Exists ] list -> (unit, exn) Core.Result.t Async_unix__.Import.Deferred.t
val access_exn : string -> [ `Read | `Write | `Exec | `Exists ] list -> unit Async_unix__.Import.Deferred.t
val set_close_on_exec : Fd.t -> unit
val clear_close_on_exec : Fd.t -> unit
val mkdir : ?⁠p:unit -> ?⁠perm:file_perm -> string -> unit Async_unix__.Import.Deferred.t
val rmdir : string -> unit Async_unix__.Import.Deferred.t
val chdir : string -> unit Async_unix__.Import.Deferred.t
val getcwd : unit -> string Async_unix__.Import.Deferred.t
val chroot : string -> unit Async_unix__.Import.Deferred.t
type dir_handle = Core.Unix.dir_handle
val opendir : string -> dir_handle Async_unix__.Import.Deferred.t
val readdir_opt : dir_handle -> string option Async_unix__.Import.Deferred.t

readdir_opt dir_handle returns the next directory member, or None when there are no more directory members to return.

val rewinddir : dir_handle -> unit Async_unix__.Import.Deferred.t
val closedir : dir_handle -> unit Async_unix__.Import.Deferred.t
val pipe : Core.Info.t -> ([ `Reader of Fd.t ] * [ `Writer of Fd.t ]) Async_unix__.Import.Deferred.t

The info supplied to pipe is debugging information that will be included in the returned Fds.

val mkfifo : ?⁠perm:file_perm -> string -> unit Async_unix__.Import.Deferred.t

Create a named pipe with the given permissions.

val mkstemp : string -> (string * Fd.t) Async_unix__.Import.Deferred.t

mkstemp prefix creates and opens a unique temporary file with prefix, automatically appending a suffix of six random characters to make the name unique. Unlike C's mkstemp, prefix should not include six X's at the end.

raises Unix_error

on errors.

val mkdtemp : string -> string Async_unix__.Import.Deferred.t
val getgrouplist : string -> int -> int array Async_unix__.Import.Deferred.t
type process_times = Core.Unix.process_times = {
tms_utime : float;

User time for the process

tms_stime : float;

System time for the process

tms_cutime : float;

User time for the children processes

tms_cstime : float;

System time for the children processes

}

Time functions.

val times : unit -> process_times
type tm = Core.Unix.tm = {
tm_sec : int;

Seconds 0..59

tm_min : int;

Minutes 0..59

tm_hour : int;

Hours 0..23

tm_mday : int;

Day of month 1..31

tm_mon : int;

Month of year 0..11

tm_year : int;

Year - 1900

tm_wday : int;

Day of week (Sunday is 0)

tm_yday : int;

Day of year 0..365

tm_isdst : bool;

Daylight time savings in effect

}
val time : unit -> float
val gettimeofday : unit -> float
val gmtime : float -> tm
val localtime : float -> tm
val mktime : tm -> float * tm
val utimes : string -> access:float -> modif:float -> unit Async_unix__.Import.Deferred.t
type env = Core.Unix.env
val sexp_of_env : env -> Ppx_sexp_conv_lib.Sexp.t
val env_of_sexp : Ppx_sexp_conv_lib.Sexp.t -> env
val environment : unit -> string array
val getenv : string -> string option
val getenv_exn : string -> string
val unsafe_getenv : string -> string option
val unsafe_getenv_exn : string -> string
val putenv : key:string -> data:string -> unit
val unsetenv : string -> unit
val fork_exec : prog:string -> argv:string list -> ?⁠use_path:bool -> ?⁠env:[ env | `Replace_raw of string list ] -> unit -> Core.Pid.t Async_unix__.Import.Deferred.t

fork_exec ~prog ~argv ?path ?env forks and execs prog with argv, and returns the child pid. If use_path = true (the default) and prog doesn't contain a slash, then fork_exec searches the PATH environment variable for prog. If env is supplied, it specifies the environment when prog is executed.

If env contains multiple bindings for the same variable, the last takes precedence. In the case of `Extend, bindings in env take precedence over the existing environment. See Unix.exec.

type wait_on = [
| `Any
| `Group of Core.Pid.t
| `My_group
| `Pid of Core.Pid.t
]
val sexp_of_wait_on : wait_on -> Ppx_sexp_conv_lib.Sexp.t
val wait_on_of_sexp : Ppx_sexp_conv_lib.Sexp.t -> wait_on
val __wait_on_of_sexp__ : Ppx_sexp_conv_lib.Sexp.t -> wait_on
val wait : wait_on -> (Core.Pid.t * Exit_or_signal.t) Async_unix__.Import.Deferred.t
val wait_nohang : wait_on -> (Core.Pid.t * Exit_or_signal.t) option
val wait_untraced : wait_on -> (Core.Pid.t * Exit_or_signal_or_stop.t) Async_unix__.Import.Deferred.t
val wait_nohang_untraced : wait_on -> (Core.Pid.t * Exit_or_signal_or_stop.t) option
val waitpid : Core.Pid.t -> Exit_or_signal.t Async_unix__.Import.Deferred.t

waitpid pid returns a deferred that becomes determined with the child's exit status, when the child process with process id pid exits. waitpid_exn is like waitpid, except the result only becomes determined if the child exits with status zero; it raises if the child terminates in any other way.

val waitpid_prompt : Core.Pid.t -> Exit_or_signal.t Async_unix__.Import.Deferred.t

Same as waitpid, but guarantees that the resulting Deferred is determined in the same async job as the wait system call, so that it's safe to keep using the pid if the deferred is not determined.

val waitpid_exn : Core.Pid.t -> unit Async_unix__.Import.Deferred.t
module Cidr = Core.Unix.Cidr
val socketpair : unit -> Fd.t * Fd.t
val bind_to_interface_exn : (Fd.t -> Linux_ext.Bound_to_interface.t -> unit) Core.Or_error.t
type socket_domain = Core.Unix.socket_domain =
| PF_UNIX
| PF_INET
| PF_INET6
val bin_shape_socket_domain : Bin_prot.Shape.t
val bin_size_socket_domain : socket_domain Bin_prot.Size.sizer
val bin_write_socket_domain : socket_domain Bin_prot.Write.writer
val bin_writer_socket_domain : socket_domain Bin_prot.Type_class.writer
val bin_read_socket_domain : socket_domain Bin_prot.Read.reader
val __bin_read_socket_domain__ : (int -> socket_domain) Bin_prot.Read.reader
val bin_reader_socket_domain : socket_domain Bin_prot.Type_class.reader
val bin_socket_domain : socket_domain Bin_prot.Type_class.t
val compare_socket_domain : socket_domain -> socket_domain -> int
val hash_fold_socket_domain : Base.Hash.state -> socket_domain -> Base.Hash.state
val hash_socket_domain : socket_domain -> Base.Hash.hash_value
val sexp_of_socket_domain : socket_domain -> Ppx_sexp_conv_lib.Sexp.t
val socket_domain_of_sexp : Ppx_sexp_conv_lib.Sexp.t -> socket_domain
type socket_type = Core.Unix.socket_type =
| SOCK_STREAM
| SOCK_DGRAM
| SOCK_RAW
| SOCK_SEQPACKET
val bin_shape_socket_type : Bin_prot.Shape.t
val bin_size_socket_type : socket_type Bin_prot.Size.sizer
val bin_write_socket_type : socket_type Bin_prot.Write.writer
val bin_writer_socket_type : socket_type Bin_prot.Type_class.writer
val bin_read_socket_type : socket_type Bin_prot.Read.reader
val __bin_read_socket_type__ : (int -> socket_type) Bin_prot.Read.reader
val bin_reader_socket_type : socket_type Bin_prot.Type_class.reader
val bin_socket_type : socket_type Bin_prot.Type_class.t
val compare_socket_type : socket_type -> socket_type -> int
val hash_fold_socket_type : Base.Hash.state -> socket_type -> Base.Hash.state
val hash_socket_type : socket_type -> Base.Hash.hash_value
val sexp_of_socket_type : socket_type -> Ppx_sexp_conv_lib.Sexp.t
val socket_type_of_sexp : Ppx_sexp_conv_lib.Sexp.t -> socket_type
type sockaddr = Core.Unix.sockaddr =
| ADDR_UNIX of string
| ADDR_INET of Inet_addr.t * int
val bin_shape_sockaddr : Bin_prot.Shape.t
val bin_size_sockaddr : sockaddr Bin_prot.Size.sizer
val bin_write_sockaddr : sockaddr Bin_prot.Write.writer
val bin_writer_sockaddr : sockaddr Bin_prot.Type_class.writer
val bin_read_sockaddr : sockaddr Bin_prot.Read.reader
val __bin_read_sockaddr__ : (int -> sockaddr) Bin_prot.Read.reader
val bin_reader_sockaddr : sockaddr Bin_prot.Type_class.reader
val bin_sockaddr : sockaddr Bin_prot.Type_class.t
val compare_sockaddr : sockaddr -> sockaddr -> int
val sexp_of_sockaddr : sockaddr -> Ppx_sexp_conv_lib.Sexp.t
type sockaddr_blocking_sexp = sockaddr

sockaddr_blocking_sexp is like sockaddr, with of_sexp that performs DNS lookup to resolve Inet_addr.t.

val bin_shape_sockaddr_blocking_sexp : Bin_prot.Shape.t
val bin_size_sockaddr_blocking_sexp : sockaddr_blocking_sexp Bin_prot.Size.sizer
val bin_write_sockaddr_blocking_sexp : sockaddr_blocking_sexp Bin_prot.Write.writer
val bin_writer_sockaddr_blocking_sexp : sockaddr_blocking_sexp Bin_prot.Type_class.writer
val bin_read_sockaddr_blocking_sexp : sockaddr_blocking_sexp Bin_prot.Read.reader
val __bin_read_sockaddr_blocking_sexp__ : (int -> sockaddr_blocking_sexp) Bin_prot.Read.reader
val bin_reader_sockaddr_blocking_sexp : sockaddr_blocking_sexp Bin_prot.Type_class.reader
val bin_sockaddr_blocking_sexp : sockaddr_blocking_sexp Bin_prot.Type_class.t
val sexp_of_sockaddr_blocking_sexp : sockaddr_blocking_sexp -> Ppx_sexp_conv_lib.Sexp.t
val sockaddr_blocking_sexp_of_sexp : Ppx_sexp_conv_lib.Sexp.t -> sockaddr_blocking_sexp
val gethostname : unit -> string
val getuid : unit -> int
val geteuid : unit -> int
val getgid : unit -> int
val getegid : unit -> int
val setuid : int -> unit
module Error = Core.Unix.Error
exception Unix_error of Error.t * string * string
module Passwd = Async_unix__.Unix_syscalls.Passwd

Structure of entries in the passwd database.

module Group = Async_unix__.Unix_syscalls.Group

Structure of entries in the groups database.

module Ifaddr = Core.Unix.Ifaddr
val getifaddrs : unit -> Ifaddr.t list Async_unix__.Import.Deferred.t

Gets the information using the socket-based netlink interface, which can block; see https://www.infradead.org/~tgr/libnl/doc/core.html.

val getlogin : unit -> string Async_unix__.Import.Deferred.t

Returns the login name of the user executing the process.

This returns a deferred because the username may need to be looked up in what is essentially a database elsewhere on the network (winbound user, or NIS).

val wordexp : (?⁠flags:[ `No_cmd | `Show_err | `Undef ] list -> string -> string array Async_unix__.Import.Deferred.t) Core.Or_error.t