View Source Port (Elixir v1.18.0)
Functions for interacting with the external world through ports.
Ports provide a mechanism to start operating system processes external to the Erlang VM and communicate with them via message passing.
Example
iex> port = Port.open({:spawn, "cat"}, [:binary])
iex> send(port, {self(), {:command, "hello"}})
iex> send(port, {self(), {:command, "world"}})
iex> flush()
{#Port<0.1444>, {:data, "hello"}}
{#Port<0.1444>, {:data, "world"}}
iex> send(port, {self(), :close})
:ok
iex> flush()
{#Port<0.1444>, :closed}
:ok
In the example above, we have created a new port that executes the
program cat
. cat
is a program available on Unix-like operating systems that
receives data from multiple inputs and concatenates them in the output.
After the port was created, we sent it two commands in the form of
messages using send/2
. The first command has the binary payload
of "hello" and the second has "world".
After sending those two messages, we invoked the IEx helper flush()
,
which printed all messages received from the port, in this case we got
"hello" and "world" back. Note that the messages are in binary because we
passed the :binary
option when opening the port in Port.open/2
. Without
such option, it would have yielded a list of bytes.
Once everything was done, we closed the port.
Elixir provides many conveniences for working with ports and some drawbacks. We will explore those below.
Message and function APIs
There are two APIs for working with ports. It can be either asynchronous via message passing, as in the example above, or by calling the functions on this module.
The messages supported by ports and their counterpart function APIs are listed below:
{pid, {:command, binary}}
- sends the given data to the port. Seecommand/3
.{pid, :close}
- closes the port. Unless the port is already closed, the port will reply with{port, :closed}
message once it has flushed its buffers and effectively closed. Seeclose/1
.{pid, {:connect, new_pid}}
- sets thenew_pid
as the new owner of the port. Once a port is opened, the port is linked and connected to the caller process and communication to the port only happens through the connected process. This message makesnew_pid
the new connected processes. Unless the port is dead, the port will reply to the old owner with{port, :connected}
. Seeconnect/2
.
On its turn, the port will send the connected process the following messages:
{port, {:data, data}}
- data sent by the port{port, :closed}
- reply to the{pid, :close}
message{port, :connected}
- reply to the{pid, {:connect, new_pid}}
message{:EXIT, port, reason}
- exit signals in case the port crashes. If reason is not:normal
, this message will only be received if the owner process is trapping exits
Open mechanisms
The port can be opened through four main mechanisms.
As a short summary, prefer to using the :spawn
and :spawn_executable
options mentioned below. The other two options, :spawn_driver
and :fd
are for advanced usage within the VM. Also consider using System.cmd/3
if all you want is to execute a program and retrieve its return value.
Windows argument splitting and untrusted arguments
On Unix systems, arguments are passed to a new operating system
process as an array of strings but on Windows it is up to the child
process to parse them and some Windows programs may apply their own
rules, which are inconsistent with the standard C runtime argv
parsing
This is particularly troublesome when invoking .bat
or .com
files
as these run implicitly through cmd.exe
, whose argument parsing is
vulnerable to malicious input and can be used to run arbitrary shell
commands.
Therefore, if you are running on Windows and you execute batch
files or .com
applications, you must not pass untrusted input as
arguments to the program. You may avoid accidentally executing them
by explicitly passing the extension of the program you want to run,
such as .exe
, and double check the program is indeed not a batch
file or .com
application.
This affects both spawn
and spawn_executable
.
spawn
The :spawn
tuple receives a binary that is going to be executed as a
full invocation. For example, we can use it to invoke "echo hello" directly:
iex> port = Port.open({:spawn, "echo hello"}, [:binary])
iex> flush()
{#Port<0.1444>, {:data, "hello\n"}}
:spawn
will retrieve the program name from the argument and traverse your
operating system $PATH
environment variable looking for a matching program.
Although the above is handy, it means it is impossible to invoke an executable
that has whitespaces on its name or in any of its arguments. For those reasons,
most times it is preferable to execute :spawn_executable
.
spawn_executable
Spawn executable is a more restricted and explicit version of spawn. It expects
full file paths to the executable you want to execute. If they are in your $PATH
,
they can be retrieved by calling System.find_executable/1
:
iex> path = System.find_executable("echo")
iex> port = Port.open({:spawn_executable, path}, [:binary, args: ["hello world"]])
iex> flush()
{#Port<0.1380>, {:data, "hello world\n"}}
When using :spawn_executable
, the list of arguments can be passed via
the :args
option as done above. For the full list of options, see the
documentation for the Erlang function :erlang.open_port/2
.
fd
The :fd
name option allows developers to access in
and out
file
descriptors used by the Erlang VM. You would use those only if you are
reimplementing core part of the Runtime System, such as the :user
and
:shell
processes.
Zombie operating system processes
A port can be closed via the close/1
function or by sending a {pid, :close}
message. However, if the VM crashes, a long-running program started by the port
will have its stdin and stdout channels closed but it won't be automatically
terminated.
While most Unix command line tools will exit once its communication channels are closed, not all command line applications will do so. You can easily check this by starting the port and then shutting down the VM and inspecting your operating system to see if the port process is still running.
While we encourage graceful termination by detecting if stdin/stdout has been closed, we do not always have control over how third-party software terminates. In those cases, you can wrap the application in a script that checks for stdin. Here is such script that has been verified to work on bash shells:
#!/usr/bin/env bash
# Start the program in the background
exec "$@" &
pid1=$!
# Silence warnings from here on
exec >/dev/null 2>&1
# Read from stdin in the background and
# kill running program when stdin closes
exec 0<&0 $(
while read; do :; done
kill -KILL $pid1
) &
pid2=$!
# Clean up
wait $pid1
ret=$?
kill -KILL $pid2
exit $ret
Note the program above hijacks stdin, so you won't be able to communicate with the underlying software via stdin (on the positive side, software that reads from stdin typically terminates when stdin closes).
Now instead of:
Port.open(
{:spawn_executable, "/path/to/program"},
args: ["a", "b", "c"]
)
You may invoke:
Port.open(
{:spawn_executable, "/path/to/wrapper"},
args: ["/path/to/program", "a", "b", "c"]
)
Summary
Functions
Closes the port
.
Sends data
to the port driver port
.
Associates the port
identifier with a pid
.
Demonitors the monitor identified by the given reference
.
Returns information about the port
(or nil
if the port is closed).
Returns information about a specific field within
the port
(or nil
if the port is closed).
Returns a list of all ports in the current node.
Starts monitoring the given port
from the calling process.
Opens a port given a tuple name
and a list of options
.
Types
@type name() :: {:spawn, charlist() | binary()} | {:spawn_driver, charlist() | binary()} | {:spawn_executable, :file.name_all()} | {:fd, non_neg_integer(), non_neg_integer()}
Functions
@spec close(port()) :: true
Closes the port
.
For more information, see :erlang.port_close/1
.
Inlined by the compiler.
Sends data
to the port driver port
.
For more information, see :erlang.port_command/3
.
Inlined by the compiler.
Associates the port
identifier with a pid
.
For more information, see :erlang.port_connect/2
.
Inlined by the compiler.
Demonitors the monitor identified by the given reference
.
If monitor_ref
is a reference which the calling process
obtained by calling monitor/1
, that monitoring is turned off.
If the monitoring is already turned off, nothing happens.
See :erlang.demonitor/2
for more information.
Inlined by the compiler.
Returns information about the port
(or nil
if the port is closed).
For more information, see :erlang.port_info/1
.
Returns information about a specific field within
the port
(or nil
if the port is closed).
For more information, see :erlang.port_info/2
.
@spec list() :: [port()]
Returns a list of all ports in the current node.
Inlined by the compiler.
Starts monitoring the given port
from the calling process.
Once the monitored port process dies, a message is delivered to the monitoring process in the shape of:
{:DOWN, ref, :port, object, reason}
where:
ref
is a monitor reference returned by this function;object
is either theport
being monitored (when monitoring by port ID) or{name, node}
(when monitoring by a port name);reason
is the exit reason.
See :erlang.monitor/2
for more information.
Inlined by the compiler.
Opens a port given a tuple name
and a list of options
.
The module documentation above contains documentation and examples
for the supported name
values, summarized below:
{:spawn, command}
- runs an external program.command
must contain the program name and optionally a list of arguments separated by space. If passing programs or arguments with space in their name, use the next option.{:spawn_executable, filename}
- runs the executable given by the absolute file namefilename
. Arguments can be passed via the:args
option.{:spawn_driver, command}
- spawns so-called port drivers.{:fd, fd_in, fd_out}
- accesses file descriptors,fd_in
andfd_out
opened by the VM.
For more information and the list of options, see :erlang.open_port/2
.
Inlined by the compiler.