View Source Erl_Interface

This section outlines an example of how to solve the example problem in Problem Example by using a port and Erl_Interface. It is necessary to read the port example in Ports before reading this section.

Erlang Program

The following example shows an Erlang program communicating with a C program over a plain port with home made encoding:

-module(complex1).
-export([start/1, stop/0, init/1]).
-export([foo/1, bar/1]).

start(ExtPrg) ->
    spawn(?MODULE, init, [ExtPrg]).
stop() ->
    complex ! stop.

foo(X) ->
    call_port({foo, X}).
bar(Y) ->
    call_port({bar, Y}).

call_port(Msg) ->
    complex ! {call, self(), Msg},
    receive
	{complex, Result} ->
	    Result
    end.

init(ExtPrg) ->
    register(complex, self()),
    process_flag(trap_exit, true),
    Port = open_port({spawn, ExtPrg}, [{packet, 2}]),
    loop(Port).

loop(Port) ->
    receive
	{call, Caller, Msg} ->
	    Port ! {self(), {command, encode(Msg)}},
	    receive
		{Port, {data, Data}} ->
		    Caller ! {complex, decode(Data)}
	    end,
	    loop(Port);
	stop ->
	    Port ! {self(), close},
	    receive
		{Port, closed} ->
		    exit(normal)
	    end;
	{'EXIT', Port, Reason} ->
	    exit(port_terminated)
    end.

encode({foo, X}) -> [1, X];
encode({bar, Y}) -> [2, Y].

decode([Int]) -> Int.

There are two differences when using Erl_Interface on the C side compared to the example in Ports, using only the plain port:

  • As Erl_Interface operates on the Erlang external term format, the port must be set to use binaries.
  • Instead of inventing an encoding/decoding scheme, the term_to_binary/1 and binary_to_term/1 BIFs are to be used.

That is:

open_port({spawn, ExtPrg}, [{packet, 2}])

is replaced with:

open_port({spawn, ExtPrg}, [{packet, 2}, binary])

And:

Port ! {self(), {command, encode(Msg)}},
receive
  {Port, {data, Data}} ->
    Caller ! {complex, decode(Data)}
end

is replaced with:

Port ! {self(), {command, term_to_binary(Msg)}},
receive
  {Port, {data, Data}} ->
    Caller ! {complex, binary_to_term(Data)}
end

The resulting Erlang program is as follows:

-module(complex2).
-export([start/1, stop/0, init/1]).
-export([foo/1, bar/1]).

start(ExtPrg) ->
    spawn(?MODULE, init, [ExtPrg]).
stop() ->
    complex ! stop.

foo(X) ->
    call_port({foo, X}).
bar(Y) ->
    call_port({bar, Y}).

call_port(Msg) ->
    complex ! {call, self(), Msg},
    receive
	{complex, Result} ->
	    Result
    end.

init(ExtPrg) ->
    register(complex, self()),
    process_flag(trap_exit, true),
    Port = open_port({spawn, ExtPrg}, [{packet, 2}, binary]),
    loop(Port).

loop(Port) ->
    receive
	{call, Caller, Msg} ->
	    Port ! {self(), {command, term_to_binary(Msg)}},
	    receive
		{Port, {data, Data}} ->
		    Caller ! {complex, binary_to_term(Data)}
	    end,
	    loop(Port);
	stop ->
	    Port ! {self(), close},
	    receive
		{Port, closed} ->
		    exit(normal)
	    end;
	{'EXIT', Port, Reason} ->
	    exit(port_terminated)
    end.

Notice that calling complex2:foo/1 and complex2:bar/1 results in the tuple {foo,X} or {bar,Y} being sent to the complex process, which codes them as binaries and sends them to the port. This means that the C program must be able to handle these two tuples.

C Program

The following example shows a C program communicating with an Erlang program over a plain port with the Erlang external term format encoding:

/* ei.c */

#include "ei.h"
#include <unistd.h>
#include <string.h>
#include <stdlib.h>

typedef unsigned char byte;

int read_cmd(byte *buf);
int write_cmd(byte *buf, int len);
int foo(int x);
int bar(int y);

static void fail(int place) {
    fprintf(stderr, "Something went wrong %d\n", place);
    exit(1);
}

int main() {
    byte buf[100];
    int index = 0;
    int version = 0;
    int arity = 0;
    char atom[128];
    long in = 0;
    int res = 0;
    ei_x_buff res_buf;
    ei_init();
    while (read_cmd(buf) > 0) {
        if (ei_decode_version(buf, &index, &version) != 0)
            fail(1);
        if (ei_decode_tuple_header(buf, &index, &arity) != 0)
            fail(2);
        if (arity != 2)
            fail(3);
        if (ei_decode_atom(buf, &index, atom) != 0)
            fail(4);
        if (ei_decode_long(buf, &index, &in) != 0)
            fail(5);
        if (strncmp(atom, "foo", 3) == 0) {
            res = foo((int)in);
        } else if (strncmp(atom, "bar", 3) == 0) {
            res = bar((int)in);
        }
        if (ei_x_new_with_version(&res_buf) != 0)
            fail(6);
        if (ei_x_encode_long(&res_buf, res) != 0)
            fail(7);
        write_cmd(res_buf.buff, res_buf.index);

        if (ei_x_free(&res_buf) != 0)
            fail(8);
        index = 0;
    }
}

The following functions, read_cmd() and write_cmd(), from the erl_comm.c example in Ports can still be used for reading from and writing to the port:

/* erl_comm.c */

#include <stdio.h>
#include <unistd.h>

typedef unsigned char byte;

int read_exact(byte *buf, int len)
{
  int i, got=0;

  do {
      if ((i = read(0, buf+got, len-got)) <= 0){
          return(i);
      }
    got += i;
  } while (got<len);

  return(len);
}

int write_exact(byte *buf, int len)
{
  int i, wrote = 0;

  do {
    if ((i = write(1, buf+wrote, len-wrote)) <= 0)
      return (i);
    wrote += i;
  } while (wrote<len);

  return (len);
}

int read_cmd(byte *buf)
{
  int len;

  if (read_exact(buf, 2) != 2)
    return(-1);
  len = (buf[0] << 8) | buf[1];
  return read_exact(buf, len);
}

int write_cmd(byte *buf, int len)
{
  byte li;

  li = (len >> 8) & 0xff;
  write_exact(&li, 1);

  li = len & 0xff;
  write_exact(&li, 1);

  return write_exact(buf, len);
}

Running the Example

Step 1. Compile the C code. This provides the paths to the include file ei.h, and also to the library ei:

$ gcc -o extprg -I/usr/local/otp/lib/erl_interface-3.9.2/include \
    -L/usr/local/otp/lib/erl_interface-3.9.2/lib \
    complex.c erl_comm.c ei.c -lei -lpthread

In Erlang/OTP R5B and later versions of OTP, the include and lib directories are situated under $OTPROOT/lib/erl_interface-VSN, where $OTPROOT is the root directory of the OTP installation (/usr/local/otp in the recent example) and VSN is the version of the Erl_interface application (3.2.1 in the recent example).

In R4B and earlier versions of OTP, include and lib are situated under $OTPROOT/usr.

Step 2. Start Erlang and compile the Erlang code:

$ erl
Erlang/OTP 26 [erts-14.2] [source] [64-bit] [smp:8:8] [ds:8:8:10] [async-threads:1] [jit:ns]

Eshell V14.2 (press Ctrl+G to abort, type help(). for help)
1> c(complex2).
{ok,complex2}

Step 3. Run the example:

2> complex2:start("./extprg").
<0.34.0>
3> complex2:foo(3).
4
4> complex2:bar(5).
10
5> complex2:bar(352).
704
6> complex2:stop().
stop