Lwt_unix
Cooperative system calls
This modules maps system calls, like those of the standard library's Unix
module, to cooperative ones, which will not block the program.
The semantics of all operations is the following: if the action (for example reading from a file descriptor) can be performed immediately, it is performed and returns an already resolved promise, otherwise it returns a pending promise which is resolved when the operation completes.
Most operations on sockets and pipes (on Windows it is only sockets) are cancelable, meaning you can cancel them with Lwt.cancel
. For example if you want to read something from a file descriptor with a timeout, you can cancel the action after the timeout and the reading will not be performed if not already done.
For example, consider that you have two sockets sock1
and sock2
. You want to read something from sock1
or exclusively from sock2
and fail with an exception if a timeout of 1 second expires, without reading anything from sock1
and sock2
, even if they become readable in the future.
Then you can do:
Lwt.pick
[Lwt_unix.timeout 1.0;
read sock1 buf1 ofs1 len1;
read sock2 buf2 ofs2 len2]
In this case, it is guaranteed that exactly one of the three operations will complete, and the others will be cancelled.
Same as Unix.handle_unix_error
but catches lwt-level exceptions
val sleep : float -> unit Lwt.t
sleep d
is a promise that remains in a pending state for d
seconds after which it is resolved with value ()
.
val yield : unit -> unit Lwt.t
yield ()
is a promise in a pending state. It resumes itself as soon as possible and resolves with value ()
.
val auto_yield : float -> unit -> unit Lwt.t
val auto_pause : float -> unit -> unit Lwt.t
auto_pause timeout
returns a function f
, and f ()
has the following behavior:
timeout
seconds since the last time f ()
behaved like Lwt.pause
, f ()
calls Lwt.pause
.timeout
seconds, f ()
behaves like Lwt.return_unit
, i.e. it does not yield.val timeout : float -> 'a Lwt.t
timeout d
is a promise that remains pending for d
seconds and then is rejected with Timeout
.
with_timeout d f
is a short-hand for:
Lwt.pick [Lwt_unix.timeout d; f ()]
The abstract type for file descriptors. A Lwt file descriptor is a pair of a unix file descriptor (of type Unix.file_descr
) and a state.
A file descriptor may be:
type state =
| Opened
The file descriptor is opened
*)| Closed
| Aborted of exn
The file descriptor has been aborted, the only operation possible is close
, all others will fail.
State of a file descriptor
val state : file_descr -> state
state fd
returns the state
of fd
.
val unix_file_descr : file_descr -> Unix.file_descr
Returns the underlying unix file descriptor. It always succeeds, even if the file descriptor's state is not Opened
.
val of_unix_file_descr :
?blocking:bool ->
?set_flags:bool ->
Unix.file_descr ->
file_descr
Wraps a Unix
file descriptor fd
in an Lwt file_descr
fd'
.
~blocking
controls the internal strategy Lwt uses to perform I/O on the underlying fd
. Regardless of ~blocking
, at the API level, Lwt_unix.read
, Lwt_unix.write
, etc. on fd'
always block the Lwt promise, but never block the whole process. However, for performance reasons, it is important that ~blocking
match the actual blocking mode of fd
.
If ~blocking
is not specified, of_unix_file_descr
chooses non-blocking mode for Unix sockets, Unix pipes, and Windows sockets, and blocking mode for everything else. Note: not specifying ~blocking
causes fstat
to be lazily called on fd
, the first time your code performs I/O on fd'
. This fstat
call can be expensive, so if you use of_unix_file_descr
a lot, be sure to specify ~blocking
explicitly.
of_unix_file_descr
runs a system call to set the specified or chosen blocking mode on the underlying fd
.
To prevent of_unix_file_descr
from running this system call, you can pass ~set_flags:false
. Note that, in this case, if ~blocking
, whether passed explicitly or chosen by Lwt, does not match the true blocking mode of the underlying fd
, I/O on fd'
will suffer performance degradation.
Note that ~set_flags
is effectively always false
if running on Windows and fd
is not a socket.
Generally, non-blocking I/O is faster: for blocking I/O, Lwt typically has to run system calls in worker threads to avoid blocking the process. See your system documentation for whether particular kinds of file descriptors support non-blocking I/O.
val blocking : file_descr -> bool Lwt.t
blocking fd
indicates whether Lwt is internally using blocking or non-blocking I/O with fd
.
Note that this may differ from the blocking mode of the underlying Unix file descriptor (i.e. unix_file_descr fd
).
See of_unix_file_descr
for details.
val set_blocking : ?set_flags:bool -> file_descr -> bool -> unit
set_blocking fd b
causes Lwt to internally use blocking or non-blocking I/O with fd
, according to the value of b
.
If ~set_flags
is true
(the default), Lwt also makes a system call to set the underlying file descriptor's blocking mode to match. Otherwise, set_blocking
is only informational for Lwt.
It is important that the underlying file descriptor actually have the same blocking mode as that indicated by b
.
See of_unix_file_descr
for details.
val abort : file_descr -> exn -> unit
abort fd exn
makes all current and further uses of the file descriptor fail with the given exception. This put the file descriptor into the Aborted
state.
If the file descriptor is closed, this does nothing, if it is aborted, this replace the abort exception by exn
.
Note that this only works for reading and writing operations on file descriptors supporting non-blocking mode.
fork ()
does the same as Unix.fork
. You must use this function instead of Unix.fork
when you want to use Lwt in the child process, even if you have not started using Lwt before the fork.
Notes:
Lwt_unix
I/O jobs are abandoned. This may cause the child's copy of their associated promises to remain forever pending.Lwt_io.flush_all
before callling fork
to avoid double-flush.Lwt_main.Exit_hooks.remove_all
to avoid Lwt calling Lwt_main.run
during process exit.exec
. Indeed, in that case, it is not even necessary to use Lwt_unix.fork
. You can use Unix.fork
.Lwt_main.abandon_yielded_and_paused
.val wait : unit -> (int * process_status) Lwt.t
Wrapper for Unix.wait
val waitpid : wait_flag list -> int -> (int * process_status) Lwt.t
A promise-returning analog to Unix.waitpid
. This call is non-blocking on Unix-like systems, but is always blocking on Windows.
Resource usages
val wait4 :
wait_flag list ->
int ->
(int * process_status * resource_usage) Lwt.t
wait4 flags pid
returns (pid, status, rusage)
where (pid, status)
is the same result as Unix.waitpid flags pid
, and rusage
contains accounting information about the child.
On windows it will always returns { utime = 0.0; stime = 0.0 }
.
Returns the number of promises waiting for a child process to terminate.
val system : string -> process_status Lwt.t
Executes the given command, waits until it terminates, and return its termination status. The string is interpreted by the shell /bin/sh
on Unix and cmd.exe
on Windows. The result WEXITED 127
indicates that the shell couldn't be executed.
val stdin : file_descr
The file descriptor for standard input.
val stdout : file_descr
The file descriptor for standard output.
val stderr : file_descr
The file descriptor for standard error.
type file_perm = Unix.file_perm
type open_flag = Unix.open_flag =
val openfile : string -> open_flag list -> file_perm -> file_descr Lwt.t
Wrapper for Unix.openfile
.
val close : file_descr -> unit Lwt.t
Close a file descriptor. This close the underlying unix file descriptor and set its state to Closed
.
val read : file_descr -> bytes -> int -> int -> int Lwt.t
read fd buf ofs len
reads up to len
bytes from fd
, and writes them to buf
, starting at offset ofs
. The function immediately evaluates to an Lwt promise which waits for the operation to complete. If it completes successfully, the promise resolves to the number of bytes actually read, or zero if the end of file has been reached.
Note that the Lwt promise waits for data (or end of file) even if the underlying file descriptor is in non-blocking mode. See of_unix_file_descr
for a discussion of non-blocking I/O and Lwt.
If Lwt is using blocking I/O on fd
, read
writes data into a temporary buffer, then copies it into buf
.
The promise can be rejected with any exception that can be raised by Unix.read
, except Unix.Unix_error Unix.EAGAIN
, Unix.Unix_error Unix.EWOULDBLOCK
or Unix.Unix_error Unix.EINTR
.
val pread : file_descr -> bytes -> file_offset:int -> int -> int -> int Lwt.t
pread fd buf ~file_offset ofs len
on file descriptors allowing seek, reads up to len
bytes from fd
at offset file_offset
from the beginning of the file, and writes them to buf
, starting at offset ofs
.
On Unix systems, the file descriptor position is unaffected. On Windows it is changed to be just after the last read position.
The promise can be rejected with any exception that can be raised by read
or lseek
.
val write : file_descr -> bytes -> int -> int -> int Lwt.t
write fd buf ofs len
writes up to len
bytes to fd
from buf
, starting at buffer offset ofs
. The function immediately evaluates to an Lwt promise which waits for the operation to complete. If the operation completes successfully, the promise resolves to the number of bytes actually written, which may be less than len
.
Note that the Lwt promise waits to write even if the underlying file descriptor is in non-blocking mode. See of_unix_file_descr
for a discussion of non-blocking I/O and Lwt.
If Lwt is using blocking I/O on fd
, buf
is copied before writing.
The promise can be rejected with any exception that can be raised by Unix.single_write
, except Unix.Unix_error Unix.EAGAIN
, Unix.Unix_error Unix.EWOULDBLOCK
or Unix.Unix_error Unix.EINTR
.
val pwrite : file_descr -> bytes -> file_offset:int -> int -> int -> int Lwt.t
pwrite fd buf ~file_offset ofs len
on file descriptors allowing seek, writes up to len
bytes to fd
from buf
, starting at buffer offset ofs
. The data is written at offset file_offset
from the beginning of fd
.
On Unix systems, the file descriptor position is unaffected. On Windows it is changed to be just after the last written position.
The promise can be rejected with any exception that can be raised by write
or lseek
.
val write_string : file_descr -> string -> int -> int -> int Lwt.t
See write
.
val pwrite_string :
file_descr ->
string ->
file_offset:int ->
int ->
int ->
int Lwt.t
See pwrite
.
module IO_vectors : sig ... end
Sequences of buffer slices for writev
.
val readv : file_descr -> IO_vectors.t -> int Lwt.t
readv fd vs
reads bytes from fd
into the buffer slices vs
. If the operation completes successfully, the resulting promise resolves to the number of bytes read.
Data is always read directly into Bigarray
slices. If the Unix file descriptor underlying fd
is in non-blocking mode, data is also read directly into bytes
slices. Otherwise, data for bytes
slices is first read into temporary buffers, then copied.
Note that the returned Lwt promise is pending until failure or a successful read, even if the underlying file descriptor is in non-blocking mode. See of_unix_file_descr
for a discussion of non-blocking I/O and Lwt.
If IO_vectors.system_limit
is Some n
and the count of slices in vs
exceeds n
, then Lwt_unix.readv
reads only into the first n
slices of vs
.
Not implemented on Windows. It should be possible to implement, upon request, for Windows sockets only.
See readv(3p)
.
val writev : file_descr -> IO_vectors.t -> int Lwt.t
writev fd vs
writes the bytes in the buffer slices vs
to the file descriptor fd
. If the operation completes successfully, the resulting promise resolves to the number of bytes written.
If the Unix file descriptor underlying fd
is in non-blocking mode, writev
does not make a copy the bytes before writing. Otherwise, it copies bytes
slices, but not Bigarray
slices.
Note that the returned Lwt promise is pending until failure or a successful write, even if the underlying descriptor is in non-blocking mode. See of_unix_file_descr
for a discussion of non-blocking I/O and Lwt.
If IO_vectors.system_limit
is Some n
and the count of slices in vs
exceeds n
, then Lwt_unix.writev
passes only the first n
slices in vs
to the underlying writev
system call.
Not implemented on Windows. It should be possible to implement, upon request, for Windows sockets only.
The behavior of writev
when vs
has zero slices depends on the system, and may change in future versions of Lwt. On Linux, writev
will succeed and write zero bytes. On BSD (including macOS), writev
will fail with Unix.Unix_error (Unix.EINVAL, "writev", ...)
.
See writev(3p)
.
val readable : file_descr -> bool
Returns whether the given file descriptor is currently readable.
val writable : file_descr -> bool
Returns whether the given file descriptor is currently writable.
val wait_read : file_descr -> unit Lwt.t
Waits (without blocking other promises) until there is something to read from the file descriptor.
Note that you don't need to use this function if you are using Lwt I/O functions for reading, since they provide non-blocking waiting automatically.
The intended use case for this function is interfacing with existing libraries that are known to be blocking.
val wait_write : file_descr -> unit Lwt.t
Waits (without blocking other promises) until it is possible to write on the file descriptor.
Note that you don't need to use this function if you are using Lwt I/O functions for writing, since they provide non-blocking waiting automatically.
The intended use case for this function is interfacing with existing libraries that are known to be blocking.
val lseek : file_descr -> int -> seek_command -> int Lwt.t
Wrapper for Unix.lseek
val truncate : string -> int -> unit Lwt.t
Wrapper for Unix.truncate
val ftruncate : file_descr -> int -> unit Lwt.t
Wrapper for Unix.ftruncate
val fsync : file_descr -> unit Lwt.t
Synchronise all data and metadata of the file descriptor with the disk. On Windows it uses FlushFileBuffers
.
val fdatasync : file_descr -> unit Lwt.t
Synchronise all data (but not metadata) of the file descriptor with the disk.
Note that fdatasync
is not available on Windows and OS X.
type stats = Unix.stats = {
st_dev : int;
st_ino : int;
st_kind : file_kind;
st_perm : file_perm;
st_nlink : int;
st_uid : int;
st_gid : int;
st_rdev : int;
st_size : int;
st_atime : float;
st_mtime : float;
st_ctime : float;
}
Wrapper for Unix.lstat
val fstat : file_descr -> stats Lwt.t
Wrapper for Unix.fstat
val file_exists : string -> bool Lwt.t
file_exists name
tests if a file named name
exists.
Note that file_exists
behaves similarly to Sys.file_exists
:
file_exists name
will return false
in circumstances that would make stat
raise a Unix.Unix_error
exception.val utimes : string -> float -> float -> unit Lwt.t
utimes path atime mtime
updates the access and modification times of the file at path
. The access time is set to atime
and the modification time to mtime
. To set both to the current time, call utimes path 0. 0.
.
This function corresponds to Unix.utimes
. See also utimes(3p)
.
val isatty : file_descr -> bool Lwt.t
Wrapper for Unix.isatty
module LargeFile : sig ... end
val unlink : string -> unit Lwt.t
Wrapper for Unix.unlink
val rename : string -> string -> unit Lwt.t
Wrapper for Unix.rename
Wrapper for Unix.chmod
val fchmod : file_descr -> file_perm -> unit Lwt.t
Wrapper for Unix.fchmod
val chown : string -> int -> int -> unit Lwt.t
Wrapper for Unix.chown
val fchown : file_descr -> int -> int -> unit Lwt.t
Wrapper for Unix.fchown
val access : string -> access_permission list -> unit Lwt.t
Wrapper for Unix.access
val dup : ?cloexec:bool -> file_descr -> file_descr
Wrapper for Unix.dup
val dup2 : ?cloexec:bool -> file_descr -> file_descr -> unit
Wrapper for Unix.dup2
val set_close_on_exec : file_descr -> unit
Wrapper for Unix.set_close_on_exec
val clear_close_on_exec : file_descr -> unit
Wrapper for Unix.clear_close_on_exec
Wrapper for Unix.mkdir
val rmdir : string -> unit Lwt.t
Wrapper for Unix.rmdir
val chdir : string -> unit Lwt.t
Wrapper for Unix.chdir
val getcwd : unit -> string Lwt.t
Wrapper for Unix.getcwd
val chroot : string -> unit Lwt.t
Wrapper for Unix.chroot
type dir_handle = Unix.dir_handle
val opendir : string -> dir_handle Lwt.t
Opens a directory for listing. Directories opened with this function must be explicitly closed with closedir
. This is a cooperative analog of Unix.opendir
.
val readdir : dir_handle -> string Lwt.t
Reads the next directory entry from the given directory. Special entries such as .
and ..
are included. If all entries have been read, raises End_of_file
. This is a cooperative analog of Unix.readdir
.
val readdir_n : dir_handle -> int -> string array Lwt.t
readdir_n handle count
reads at most count
entries from the given directory. It is more efficient than calling readdir
count
times. If the length of the returned array is smaller than count
, this means that the end of the directory has been reached.
val rewinddir : dir_handle -> unit Lwt.t
Resets the given directory handle, so that directory listing can be restarted. Cooperative analog of Unix.rewinddir
.
val closedir : dir_handle -> unit Lwt.t
Closes a directory handle. Cooperative analog of Unix.closedir
.
val files_of_directory : string -> string Lwt_stream.t
files_of_directory dir
returns the stream of all files of dir
.
val pipe : ?cloexec:bool -> unit -> file_descr * file_descr
pipe ()
creates pipe using Unix.pipe
and returns two lwt file descriptors created from unix file_descriptor
val pipe_in : ?cloexec:bool -> unit -> file_descr * Unix.file_descr
pipe_in ()
is the same as pipe
but maps only the unix file descriptor for reading into a lwt one. The second is not put into non-blocking mode. You usually want to use this before forking to receive data from the child process.
val pipe_out : ?cloexec:bool -> unit -> Unix.file_descr * file_descr
pipe_out ()
is the inverse of pipe_in
. You usually want to use this before forking to send data to the child process
Wrapper for Unix.mkfifo
val symlink : ?to_dir:bool -> string -> string -> unit Lwt.t
Wrapper for Unix.symlink
val readlink : string -> string Lwt.t
Wrapper for Unix.readlink
val lockf : file_descr -> lock_command -> int -> unit Lwt.t
Wrapper for Unix.lockf
type passwd_entry = Unix.passwd_entry = {
pw_name : string;
pw_passwd : string;
pw_uid : int;
pw_gid : int;
pw_gecos : string;
pw_dir : string;
pw_shell : string;
}
val getlogin : unit -> string Lwt.t
Wrapper for Unix.getlogin
val getpwnam : string -> passwd_entry Lwt.t
Wrapper for Unix.getpwnam
val getgrnam : string -> group_entry Lwt.t
Wrapper for Unix.getgrnam
val getpwuid : int -> passwd_entry Lwt.t
Wrapper for Unix.getpwuid
val getgrgid : int -> group_entry Lwt.t
Wrapper for Unix.getgrgid
val on_signal : int -> (int -> unit) -> signal_handler_id
on_signal signum f
calls f
each time the signal with numnber signum
is received by the process. It returns a signal handler identifier that can be used to stop monitoring signum
.
val on_signal_full :
int ->
(signal_handler_id -> int -> unit) ->
signal_handler_id
on_signal_full f
is the same as on_signal f
except that f
also receive the signal handler identifier as argument so it can disable it.
val disable_signal_handler : signal_handler_id -> unit
Stops receiving this signal
reinstall_signal_handler signum
if any signal handler is registered for this signal with on_signal
, it reinstall the signal handler (with Sys.set_signal
). This is useful in case another part of the program install another signal handler.
handle_signal signum
acts as if Lwt had received the signum
signal. This allows another IO library to install the handler, perform its own handling, but still notify Lwt. It is particularly useful for SIGCHLD, where several IO libraries may be spawning sub-processes.
This function is thread-safe.
type inet_addr = Unix.inet_addr
val socket : ?cloexec:bool -> socket_domain -> socket_type -> int -> file_descr
socket domain type proto
is the same as Unix.socket
but maps the result into a lwt file descriptor
val socketpair :
?cloexec:bool ->
socket_domain ->
socket_type ->
int ->
file_descr * file_descr
Wrapper for Unix.socketpair
val bind : file_descr -> sockaddr -> unit Lwt.t
val listen : file_descr -> int -> unit
Wrapper for Unix.listen
val accept : ?cloexec:bool -> file_descr -> (file_descr * sockaddr) Lwt.t
Wrapper for Unix.accept
val accept_n :
?cloexec:bool ->
file_descr ->
int ->
((file_descr * sockaddr) list * exn option) Lwt.t
accept_n fd count
accepts up to count
connections at one time.
count
are available, it returns all of themcount
are available, it returns the next count
of themaccept_n
has the advantage of improving performance. If you want a more detailed description, you can have a look at:
val connect : file_descr -> sockaddr -> unit Lwt.t
Wrapper for Unix.connect
val shutdown : file_descr -> shutdown_command -> unit
Wrapper for Unix.shutdown
val getsockname : file_descr -> sockaddr
Wrapper for Unix.getsockname
val getpeername : file_descr -> sockaddr
Wrapper for Unix.getpeername
val recv : file_descr -> bytes -> int -> int -> msg_flag list -> int Lwt.t
Wrapper for Unix.recv
.
On Windows, recv
writes data into a temporary buffer, then copies it into the given one.
val recvfrom :
file_descr ->
bytes ->
int ->
int ->
msg_flag list ->
(int * sockaddr) Lwt.t
Wrapper for Unix.recvfrom
.
On Windows, recvfrom
writes data into a temporary buffer, then copies it into the given one.
val send : file_descr -> bytes -> int -> int -> msg_flag list -> int Lwt.t
Wrapper for Unix.send
.
On Windows, send
copies the given buffer before writing.
val sendto :
file_descr ->
bytes ->
int ->
int ->
msg_flag list ->
sockaddr ->
int Lwt.t
Wrapper for Unix.sendto
.
On Windows, sendto
copies the given buffer before writing.
val recv_msg :
socket:file_descr ->
io_vectors:IO_vectors.t ->
(int * Unix.file_descr list) Lwt.t
recv_msg ~socket ~io_vectors
receives data into a list of io-vectors, plus any file-descriptors that may accompany the messages. It returns a tuple whose first field is the number of bytes received and second is a list of received file descriptors. The messages themselves will be recorded in the provided io_vectors
list. Data is written directly into the iov_buffer
buffers.
Not implemented on Windows.
val send_msg :
socket:file_descr ->
io_vectors:IO_vectors.t ->
fds:Unix.file_descr list ->
int Lwt.t
send_msg ~socket ~io_vectors ~fds
sends data from a list of io-vectors, accompanied with a list of file-descriptors. It returns the number of bytes sent. If fd-passing is not possible on the current system and fds
is not empty, it raises Lwt_sys.Not_available "fd_passing"
. Data is written directly from the io_vectors
buffers.
Not implemented on Windows.
val send_msgto :
socket:file_descr ->
io_vectors:IO_vectors.t ->
fds:Unix.file_descr list ->
dest:Unix.sockaddr ->
int Lwt.t
send_msgto ~socket ~io_vectors ~fds ~dest
is similar to send_msg
but takes an additional dest
argument to set the address when using a connection-less socket.
Not implemented on Windows.
val get_credentials : file_descr -> credentials
get_credentials fd
returns credentials information from the given socket. On some platforms, obtaining the peer pid is not possible and it will be set to -1
. If obtaining credentials is not possible on the current system, it raises Lwt_sys.Not_available "get_credentials"
.
This call is not available on windows.
type socket_bool_option = Unix.socket_bool_option =
type socket_int_option = Unix.socket_int_option =
type socket_float_option = Unix.socket_float_option =
| SO_RCVTIMEO
| SO_SNDTIMEO
Note: these options are provided for the sake of completeness only. Lwt places all sockets in non-blocking mode, for which these options are meaningless. Use Lwt.pick
with Lwt_unix.sleep
or Lwt_unix.timeout
for timeouts.
val getsockopt : file_descr -> socket_bool_option -> bool
Wrapper for Unix.getsockopt
val setsockopt : file_descr -> socket_bool_option -> bool -> unit
Wrapper for Unix.setsockopt
val getsockopt_int : file_descr -> socket_int_option -> int
Wrapper for Unix.getsockopt_int
val setsockopt_int : file_descr -> socket_int_option -> int -> unit
Wrapper for Unix.setsockopt_int
val getsockopt_optint : file_descr -> socket_optint_option -> int option
Wrapper for Unix.getsockopt_optint
val setsockopt_optint :
file_descr ->
socket_optint_option ->
int option ->
unit
Wrapper for Unix.setsockopt_optint
val getsockopt_float : file_descr -> socket_float_option -> float
Wrapper for Unix.getsockopt_float
val setsockopt_float : file_descr -> socket_float_option -> float -> unit
Wrapper for Unix.setsockopt_float
val getsockopt_error : file_descr -> Unix.error option
Wrapper for Unix.getsockopt_error
val mcast_set_loop : file_descr -> bool -> unit
Whether sent multicast messages are received by the sending host
val mcast_set_ttl : file_descr -> int -> unit
Set TTL/hops value
val mcast_add_membership :
file_descr ->
?ifname:Unix.inet_addr ->
Unix.inet_addr ->
unit
mcast_add_membership fd ~ifname addr
joins the multicast group addr
on the network interface ifname
.
val mcast_drop_membership :
file_descr ->
?ifname:Unix.inet_addr ->
Unix.inet_addr ->
unit
mcast_drop_membership fd ~ifname addr
leaves the multicast group addr
on the network interface ifname
.
type host_entry = Unix.host_entry = {
h_name : string;
h_aliases : string array;
h_addrtype : socket_domain;
h_addr_list : inet_addr array;
}
val gethostname : unit -> string Lwt.t
Wrapper for Unix.gethostname
val gethostbyname : string -> host_entry Lwt.t
Wrapper for Unix.gethostbyname
val gethostbyaddr : inet_addr -> host_entry Lwt.t
Wrapper for Unix.gethostbyaddr
val getprotobyname : string -> protocol_entry Lwt.t
Wrapper for Unix.getprotobyname
val getprotobynumber : int -> protocol_entry Lwt.t
Wrapper for Unix.getprotobynumber
val getservbyname : string -> string -> service_entry Lwt.t
Wrapper for Unix.getservbyname
val getservbyport : int -> string -> service_entry Lwt.t
Wrapper for Unix.getservbyport
type addr_info = Unix.addr_info = {
ai_family : socket_domain;
ai_socktype : socket_type;
ai_protocol : int;
ai_addr : sockaddr;
ai_canonname : string;
}
type getaddrinfo_option = Unix.getaddrinfo_option =
| AI_FAMILY of socket_domain
| AI_SOCKTYPE of socket_type
| AI_PROTOCOL of int
| AI_NUMERICHOST
| AI_CANONNAME
| AI_PASSIVE
val getaddrinfo :
string ->
string ->
getaddrinfo_option list ->
addr_info list Lwt.t
Wrapper for Unix.getaddrinfo
type getnameinfo_option = Unix.getnameinfo_option =
val getnameinfo : sockaddr -> getnameinfo_option list -> name_info Lwt.t
Wrapper for Unix.getnameinfo
type terminal_io = Unix.terminal_io = {
mutable c_ignbrk : bool;
mutable c_brkint : bool;
mutable c_ignpar : bool;
mutable c_parmrk : bool;
mutable c_inpck : bool;
mutable c_istrip : bool;
mutable c_inlcr : bool;
mutable c_igncr : bool;
mutable c_icrnl : bool;
mutable c_ixon : bool;
mutable c_ixoff : bool;
mutable c_opost : bool;
mutable c_obaud : int;
mutable c_ibaud : int;
mutable c_csize : int;
mutable c_cstopb : int;
mutable c_cread : bool;
mutable c_parenb : bool;
mutable c_parodd : bool;
mutable c_hupcl : bool;
mutable c_clocal : bool;
mutable c_isig : bool;
mutable c_icanon : bool;
mutable c_noflsh : bool;
mutable c_echo : bool;
mutable c_echoe : bool;
mutable c_echok : bool;
mutable c_echonl : bool;
mutable c_vintr : char;
mutable c_vquit : char;
mutable c_verase : char;
mutable c_vkill : char;
mutable c_veof : char;
mutable c_veol : char;
mutable c_vmin : int;
mutable c_vtime : int;
mutable c_vstart : char;
mutable c_vstop : char;
}
val tcgetattr : file_descr -> terminal_io Lwt.t
Wrapper for Unix.tcgetattr
val tcsetattr : file_descr -> setattr_when -> terminal_io -> unit Lwt.t
Wrapper for Unix.tcsetattr
val tcsendbreak : file_descr -> int -> unit Lwt.t
Wrapper for Unix.tcsendbreak
val tcdrain : file_descr -> unit Lwt.t
Wrapper for Unix.tcdrain
val tcflush : file_descr -> flush_queue -> unit Lwt.t
Wrapper for Unix.tcflush
val tcflow : file_descr -> flow_action -> unit Lwt.t
Wrapper for Unix.tcflow
For system calls that cannot be made asynchronously, Lwt uses one of the following method:
val default_async_method : unit -> async_method
Returns the default async method.
This can be initialized using the environment variable "LWT_ASYNC_METHOD"
with possible values "none"
, "detach"
and "switch"
.
val set_default_async_method : async_method -> unit
Sets the default async method.
val async_method : unit -> async_method
async_method ()
returns the async method used in the current thread.
val async_method_key : async_method Lwt.key
The key for storing the local async method.
with_async_none f
is a shorthand for:
Lwt.with_value async_method_key (Some Async_none) f
with_async_detach f
is a shorthand for:
Lwt.with_value async_method_key (Some Async_detach) f
with_async_switch f
is a shorthand for:
Lwt.with_value async_method_key (Some Async_switch) f
If an action raises Retry
, it will be requeued until the file descriptor becomes readable/writable again.
If an action raises Retry_read
, it will be requeued until the file descriptor becomes readable.
If an action raises Retry_read
, it will be requeued until the file descriptor becomes writables.
val wrap_syscall : io_event -> file_descr -> (unit -> 'a) -> 'a Lwt.t
wrap_syscall set fd action
wrap an action on a file descriptor. It tries to execute action, and if it can not be performed immediately without blocking, it is registered for later.
In the latter case, if the promise is canceled, action
is removed from set
.
val check_descriptor : file_descr -> unit
check_descriptor fd
raise an exception if fd
is not in the state Open
.
val register_action : io_event -> file_descr -> (unit -> 'a) -> 'a Lwt.t
register_action set fd action
registers action
on fd
. When fd
becomes readable
/writable
action
is called.
Note:
check_descriptor fd
before calling register_action
wrap_syscall
Type of job descriptions. A job description describe how to call a C function and how to get its result. The C function may be executed in another system thread.
val run_job : ?async_method:async_method -> 'a job -> 'a Lwt.t
run_job ?async_method job
starts job
and wait for its termination.
The ~async_method
argument will be ignored in Lwt 5.0.0, and this function will always act as if ~async_method:Async_detach
is passed.
The async method is chosen follow:
async_method
is specified, it is used,async_method_key
is set in the current thread, it is used,default_async_method
) is used.If the method is Async_none
then the job is run synchronously and may block the current system thread, thus blocking all Lwt threads.
If the method is Async_detach
then the job is run in another system thread, unless the the maximum number of worker threads has been reached (as given by pool_size
).
If the method is Async_switch
then the job is run synchronously and if it blocks, execution will continue in another system thread (unless the limit is reached).
abort_jobs exn
make all pending jobs to fail with exn. Note that this does not abort the real job (i.e. the C function executing it), just the lwt thread for it.
val wait_for_jobs : unit -> unit Lwt.t
Wait for all pending jobs to terminate.
val execute_job :
?async_method:async_method ->
job:'a job ->
result:('a job -> 'b) ->
free:('a job -> unit) ->
'b Lwt.t
Lwt internally use a pipe to send notification to the main thread. The following functions allow to use this pipe.
make_notification ?once f
registers a new notifier. It returns the id of the notifier. Each time a notification with this id is received, f
is called.
if once
is specified, then the notification is stopped after the first time it is received. It defaults to false
.
send_notification id
sends a notification.
This function is thread-safe.
Stop the given notification. Note that you should not reuse the id after the notification has been stopped, the result is unspecified if you do so.
Call the handler associated to the given notification. Note that if the notification was defined with once = true
it is removed.
set_notification id f
replace the function associated to the notification by f
. It raises Not_found
if the given notification is not found.
If the program is using the async method Async_detach
or Async_switch
, Lwt will launch system threads to execute blocking system calls asynchronously.
Maximum number of system threads that can be started. If this limit is reached, jobs will be executed synchronously.
get_affinity ?pid ()
returns the list of CPUs the process with pid pid
is allowed to run on. If pid
is not specified then the affinity of the current process is returned.
set_affinity ?pid cpus
sets the list of CPUs the given process is allowed to run on.
module Versioned : sig ... end
Versioned variants of APIs undergoing breaking changes.