View Source ei_connect
Communicate with distributed Erlang.
Description
This module enables C-programs to communicate with Erlang nodes, using the Erlang distribution over TCP/IP.
A C-node appears to Erlang as a hidden node. That is, Erlang processes that
know the name of the C-node can communicate with it in a normal manner, but the
node name is not shown in the listing provided by erlang:nodes/0
in ERTS
.
The environment variable ERL_EPMD_PORT
can be used to indicate which logical
cluster a C-node belongs to.
Time-Out Functions
Most functions appear in a version with the suffix _tmo
appended to the
function name. Those functions take an extra argument, a time-out in
milliseconds. The semantics is this: for each communication primitive involved
in the operation, if the primitive does not complete within the time specified,
the function returns an error and erl_errno
is set to ETIMEDOUT
. With
communication primitive is meant an operation on the socket, like connect
,
accept
, recv
, or send
.
Clearly the time-outs are for implementing fault tolerance, not to keep hard
real-time promises. The _tmo
functions are for detecting non-responsive peers
and to avoid blocking on socket operations.
A time-out value of 0
(zero) means that time-outs are disabled. Calling a
_tmo
function with the last argument as 0
is therefore the same thing as
calling the function without the _tmo
suffix.
As with all other functions starting with ei_
, you are not expected to put
the socket in non-blocking mode yourself in the program. Every use of
non-blocking mode is embedded inside the time-out functions. The socket will
always be back in blocking mode after the operations are completed (regardless
of the result). To avoid problems, leave the socket options alone. ei
handles
any socket options that need modification.
In all other senses, the _tmo
functions inherit all the return values and the
semantics from the functions without the _tmo
suffix.
User Supplied Socket Implementation
By default ei
supplies a TCP/IPv4 socket interface that is used when
communicating. The user can however plug in his/her own IPv4 socket
implementation. This, for example, in order to communicate over TLS. A user
supplied socket implementation is plugged in by passing a
callback structure to either
ei_connect_init_ussi()
or
ei_connect_xinit_ussi()
.
All callbacks in the ei_socket_callbacks
structure should return zero on
success; and a posix error code on failure.
The addr
argument of the listen
, accept
, and connect
callbacks refer to
appropriate address structure for currently used protocol. Currently ei
only
supports IPv4. That is, at this time addr
always points to a
struct sockaddr_in
structure.
The
ei_socket_callbacks
structure may be
enlarged in the future. All fields not set, needs to be zeroed out. Currently
the following fields exist:
flags
- Flags informingei
about the behaviour of the callbacks. Flags should be bitwise or:ed together. If no flag, is set, theflags
field should contain0
. Currently, supported flags:EI_SCLBK_FLG_FULL_IMPL
- If set, theaccept()
,connect()
,writev()
,write()
, andread()
callbacks implements timeouts. The timeout is passed in thetmo
argument and is given in milli seconds. Note that thetmo
argument to these callbacks differ from the timeout arguments in theei
API. Zero means a zero timeout. That is, poll and timeout immediately unless the operation is successful.EI_SCLBK_INF_TMO
(maxunsigned
) means infinite timeout. The file descriptor is in blocking mode when a callback is called, and it must be in blocking mode when the callback returns.If not set,
ei
will implement the timeout usingselect()
in order to determine when to call the callbacks and when to time out. Thetmo
arguments of theaccept()
,connect()
,writev()
,write()
, andread()
callbacks should be ignored. The callbacks may be called in non-blocking mode. The callbacks are not allowed to change between blocking and non-blocking mode. In order for this to work,select()
needs to interact with the socket primitives used the same way as it interacts with the ordinary socket primitives. If this is not the case, the callbacks need to implement timeouts and this flag should be set.
More flags may be introduced in the future.
int (*socket)(void **ctx, void *setup_ctx)
- Create a socket and a context for the socket.On success it should set
*ctx
to point to a context for the created socket. This context will be passed to all other socket callbacks. This function will be passed the samesetup_context
as passed to the precedingei_connect_init_ussi()
orei_connect_xinit_ussi()
call.Note
During the lifetime of a socket, the pointer
*ctx
has to remain the same. That is, it cannot later be relocated.This callback is mandatory.
int (*close)(void *ctx)
- Close the socket identified byctx
and destroy the context.This callback is mandatory.
int (*listen)(void *ctx, void *addr, int *len, int backlog)
- Bind the socket identified byctx
to a local interface and then listen on it.The
addr
andlen
arguments are both input and output arguments. When calledaddr
points to an address structure of length*len
containing information on how to bind the socket. Upon return this callback should have updated the structure referred byaddr
with information on how the socket actually was bound.*len
should be updated to reflect the size of*addr
updated.backlog
identifies the size of the backlog for the listen socket.This callback is mandatory.
int (*accept)(void **ctx, void *addr, int *len, unsigned tmo)
- Accept connections on the listen socket identified by*ctx
.When a connection is accepted, a new context for the accepted connection should be created and
*ctx
should be updated to point to the new context for the accepted connection. When calledaddr
points to an uninitialized address structure of length*len
. Upon return this callback should have updated this structure with information about the client address.*len
should be updated to reflect the size of*addr
updated.If the
EI_SCLBK_FLG_FULL_IMPL
flag has been set,tmo
contains timeout time in milliseconds.Note
During the lifetime of a socket, the pointer
*ctx
has to remain the same. That is, it cannot later be relocated.This callback is mandatory.
int (*connect)(void *ctx, void *addr, int len, unsigned tmo)
- Connect the socket identified byctx
to the address identified byaddr
.When called
addr
points to an address structure of lengthlen
containing information on where to connect.If the
EI_SCLBK_FLG_FULL_IMPL
flag has been set,tmo
contains timeout time in milliseconds.This callback is mandatory.
int (*writev)(void *ctx, const void *iov, long iovcnt, ssize_t *len, unsigned tmo)
- Write data on the connected socket identified byctx
.iov
points to an array ofstruct iovec
structures of lengthiovcnt
containing data to write to the socket. On success, this callback should set*len
to the amount of bytes successfully written on the socket.If the
EI_SCLBK_FLG_FULL_IMPL
flag has been set,tmo
contains timeout time in milliseconds.This callback is optional. Set the
writev
field in the theei_socket_callbacks
structure toNULL
if not implemented.int (*write)(void *ctx, const char *buf, ssize_t *len, unsigned tmo)
- Write data on the connected socket identified byctx
.When called
buf
points to a buffer of length*len
containing the data to write on the socket. On success, this callback should set*len
to the amount of bytes successfully written on the socket.If the
EI_SCLBK_FLG_FULL_IMPL
flag has been set,tmo
contains timeout time in milliseconds.This callback is mandatory.
int (*read)(void *ctx, char *buf, ssize_t *len, unsigned tmo)
- Read data on the connected socket identified byctx
.buf
points to a buffer of length*len
where the read data should be placed. On success, this callback should update*len
to the amount of bytes successfully read on the socket.If the
EI_SCLBK_FLG_FULL_IMPL
flag has been set,tmo
contains timeout time in milliseconds.This callback is mandatory.
int (*handshake_packet_header_size)(void *ctx, int *sz)
- Inform about handshake packet header size to use during the Erlang distribution handshake.On success,
*sz
should be set to the handshake packet header size to use. Valid values are2
and4
. Erlang TCP distribution use a handshake packet size of2
and Erlang TLS distribution use a handshake packet size of4
.This callback is mandatory.
int (*connect_handshake_complete)(void *ctx)
- Called when a locally started handshake has completed successfully.This callback is optional. Set the
connect_handshake_complete
field in theei_socket_callbacks
structure toNULL
if not implemented.int (*accept_handshake_complete)(void *ctx)
- Called when a remotely started handshake has completed successfully.This callback is optional. Set the
accept_handshake_complete
field in theei_socket_callbacks
structure toNULL
if not implemented.int (*get_fd)(void *ctx, int *fd)
- Inform about file descriptor used by the socket which is identified byctx
.Note
During the lifetime of a socket, the file descriptor has to remain the same. That is, repeated calls to this callback with the same context
should
always report the same file descriptor.The file descriptor has to be a real file descriptor. That is, no other operation should be able to get the same file descriptor until it has been released by the
close()
callback.This callback is mandatory.
Data Types
ei_cnode
- Opaque data type representing a C-node. Aei_cnode
structure is initialized by callingei_connect_init()
or friends.ei_socket_callbacks
typedef struct { int flags; int (*socket)(void **ctx, void *setup_ctx); int (*close)(void *ctx); int (*listen)(void *ctx, void *addr, int *len, int backlog); int (*accept)(void **ctx, void *addr, int *len, unsigned tmo); int (*connect)(void *ctx, void *addr, int len, unsigned tmo); int (*writev)(void *ctx, const void *iov, int iovcnt, ssize_t *len, unsigned tmo); int (*write)(void *ctx, const char *buf, ssize_t *len, unsigned tmo); int (*read)(void *ctx, char *buf, ssize_t *len, unsigned tmo); int (*handshake_packet_header_size)(void *ctx, int *sz); int (*connect_handshake_complete)(void *ctx); int (*accept_handshake_complete)(void *ctx); int (*get_fd)(void *ctx, int *fd); } ei_socket_callbacks;
Callbacks functions for a User Supplied Socket Implementation. Documentation of each field can be found in the User Supplied Socket Implementation section above.
ErlConnect
typedef struct { char ipadr[4]; /* Ip v4 address in network byte order */ char nodename[MAXNODELEN]; } ErlConnect;
IP v4 address and nodename.
Erl_IpAddr
typedef struct { unsigned s_addr; /* Ip v4 address in network byte order */ } Erl_IpAddr;
IP v4 address.
erlang_msg
typedef struct { long msgtype; erlang_pid from; erlang_pid to; char toname[MAXATOMLEN+1]; char cookie[MAXATOMLEN+1]; erlang_trace token; } erlang_msg;
Information about a message received via
ei_receive_msg()
or friends.
ei_gethostbyaddr()
ei_gethostbyaddr_r()
ei_gethostbyname()
ei_gethostbyname_r()
struct hostent * ei_gethostbyaddr(const char *addr, int len, int type);
struct hostent * ei_gethostbyaddr_r(const char *addr, int length, int type,
struct hostent *hostp, char *buffer, int buflen, int *h_errnop);
struct hostent * ei_gethostbyname(const char *name);
struct hostent * ei_gethostbyname_r(const char *name, struct hostent *hostp,
char *buffer, int buflen, int *h_errnop);
Convenience functions for some common name lookup functions.
ei_accept()
int ei_accept(ei_cnode *ec, int listensock, ErlConnect *conp);
Used by a server process to accept a connection from a client process.
ec
is the C-node structure.listensock
is an open socket descriptor on whichlisten()
has previously been called.conp
is a pointer to anErlConnect
struct.
On success, conp
is filled in with the address and node name of the connecting
client and a file descriptor is returned. On failure, ERL_ERROR
is returned
and erl_errno
is set to EIO
.
ei_accept_tmo()
int ei_accept_tmo(ei_cnode *ec, int listensock, ErlConnect *conp, unsigned timeout_ms);
Equivalent to ei_accept
with an optional time-out argument, see the
description at the beginning of this manual page.
ei_close_connection()
int ei_close_connection(int fd);
Closes a previously opened connection or listen socket.
Available since OTP 21.3
ei_connect()
ei_xconnect()
ei_connect_host_port()
Available since OTP 23.0
ei_xconnect_host_port()
int ei_connect(ei_cnode* ec, char *nodename);
int ei_xconnect(ei_cnode* ec, Erl_IpAddr adr, char *alivename);
int ei_connect_host_port(ei_cnode* ec, char *hostname, int port);
int ei_xconnect_host_port(ei_cnode* ec, Erl_IpAddr adr, int port);
Sets up a connection to an Erlang node.
ei_xconnect()
requires the IP address of the remote host and the alive name of
the remote node to be specified. ei_connect()
provides an alternative
interface and determines the information from the node name provided. The
ei_xconnect_host_port()
function provides yet another alternative that will
work even if there is no EPMD instance on the host where the remote node is
running. The ei_xconnect_host_port()
function requires the IP address and port
of the remote node to be specified. The ei_connect_host_port()
function is an
alternative to ei_xconnect_host_port()
that lets the user specify a hostname
instead of an IP address.
adr
is the 32-bit IP address of the remote host.alive
is the alivename of the remote node.node
is the name of the remote node.port
is the port number of the remote node.
These functions return an open file descriptor on success, or a negative value
indicating that an error occurred. In the latter case they set erl_errno
to
one of the following:
EHOSTUNREACH
- The remote hostnode
is unreachable.ENOMEM
- No more memory is available.EIO
- I/O error.
Also, errno
values from socket(2)
and connect(2)
system calls may be
propagated into erl_errno
.
Example:
#define NODE "madonna@chivas.du.etx.ericsson.se"
#define ALIVE "madonna"
#define IP_ADDR "150.236.14.75"
/*** Variant 1 ***/
int fd = ei_connect(&ec, NODE);
/*** Variant 2 ***/
struct in_addr addr;
addr.s_addr = inet_addr(IP_ADDR);
fd = ei_xconnect(&ec, &addr, ALIVE);
Available since OTP 23.0
ei_connect_init()
ei_connect_init_ussi()
Available since OTP 21.3
ei_connect_xinit()
ei_connect_xinit_ussi()
int ei_connect_init(ei_cnode* ec, const char* this_node_name, const char *cookie, unsigned creation);
int ei_connect_init_ussi(ei_cnode* ec, const char* this_node_name, const char *cookie,
unsigned creation, ei_socket_callbacks *cbs, int cbs_sz, void *setup_context);
int ei_connect_xinit(ei_cnode* ec, const char *thishostname, const char *thisalivename,
const char *thisnodename, Erl_IpAddr thisipaddr, const char *cookie, unsigned creation);
int ei_connect_xinit_ussi(ei_cnode* ec, const char *thishostname, const char *thisalivename,
const char *thisnodename, Erl_IpAddr thisipaddr, const char *cookie, unsigned creation,
ei_socket_callbacks *cbs, int cbs_sz, void *setup_context);
Initializes the ec
structure, to identify the node name and cookie of the
server. One of them must be called before other functions that works on the
ei_cnode
type or a file descriptor associated with a connection to another
node is used.
ec
is a structure containing information about the C-node. It is used in otherei
functions for connecting and receiving data.this_node_name
is the name of the C-node (the name before '@' in the full node name).cookie
is the cookie for the node.creation
identifies a specific instance of a C-node. It can help prevent the node from receiving messages sent to an earlier process with the same registered name.Note
The type of the
creation
argument was changed fromshort
(16 bit) tounsigned int
(32 bit) in OTP 25. This should cause no practical problem other than maybe a compiler warning.thishostname
is the name of the machine we are running on. If long names are to be used, they are to be fully qualified (that is,durin.erix.ericsson.se
instead ofdurin
).thisalivename
is the name of the local C-node (the name before '@' in the full node name). Can beNULL
(from OTP 23) to get a dynamically assigned name from the peer node.thisnodename
is the full name of the local C-node, that is,mynode@myhost
. Can beNULL
ifthisalivename
isNULL
.thispaddr
if the IP address of the host.cbs
is a pointer to a callback structure implementing and alternative socket interface.cbs_sz
is the size of the structure pointed to bycbs
.setup_context
is a pointer to a structure that will be passed as second argument to thesocket
callback in thecbs
structure.
A C-node acting as a server is assigned a creation number when it calls
ei_publish()
.
A connection is closed by simply closing the socket. For information about how to close the socket gracefully (when there are outgoing packets before close), see the relevant system documentation.
These functions return a negative value indicating that an error occurred.
Example 1:
unsigned n = 0;
struct in_addr addr;
ei_cnode ec;
addr.s_addr = inet_addr("150.236.14.75");
if (ei_connect_xinit(&ec,
"chivas",
"madonna",
"madonna@chivas.du.etx.ericsson.se",
&addr;
"cookie...",
n++) < 0) {
fprintf(stderr,"ERROR when initializing: %d",erl_errno);
exit(-1);
}
Example 2:
if (ei_connect_init(&ec, "madonna", "cookie...", n++) < 0) {
fprintf(stderr,"ERROR when initializing: %d",erl_errno);
exit(-1);
}
Available since OTP 21.3
ei_connect_tmo()
ei_xconnect_tmo()
ei_connect_host_port_tmo()
Available since OTP 23.0
ei_xconnect_host_port_tmo()
int ei_connect_tmo(ei_cnode* ec, char *nodename, unsigned timeout_ms);
int ei_xconnect_tmo(ei_cnode* ec, Erl_IpAddr adr, char *alivename, unsigned timeout_ms);
int ei_connect_host_port_tmo(ei_cnode* ec, char *hostname, int port, unsigned ms);
int ei_xconnect_host_port_tmo(ei_cnode* ec, Erl_IpAddr adr, int port, unsigned ms);
Equivalent to ei_connect
, ei_xconnect
, ei_connect_host_port
and
ei_xconnect_host_port
with an optional time-out argument, see the description
at the beginning of this manual page.
Available since OTP 23.0
ei_get_tracelevel()
Available since OTP R13B04
ei_set_tracelevel()
int ei_get_tracelevel(void);
void ei_set_tracelevel(int level);
Used to set tracing on the distribution. The levels are different verbosity levels. A higher level means more information. See also section Debug Information.
These functions are not thread safe.
Available since OTP R13B04
ei_listen()
Available since OTP 21.3
ei_xlisten()
int ei_listen(ei_cnode *ec, int *port, int backlog);
int ei_xlisten(ei_cnode *ec, Erl_IpAddr adr, int *port, int backlog);
Used by a server process to setup a listen socket which later can be used for accepting connections from client processes.
ec
is the C-node structure.adr
is local interface to bind to.port
is a pointer to an integer containing the port number to bind to. If*port
equals0
when callingei_listen()
, the socket will be bound to an ephemeral port. On success,ei_listen()
will update the value of*port
to the port actually bound to.backlog
is maximum backlog of pending connections.
ei_listen
will create a socket, bind to a port on the local interface
identified by adr
(or all local interfaces if ei_listen()
is called), and
mark the socket as a passive socket (that is, a socket that will be used for
accepting incoming connections).
On success, a file descriptor is returned which can be used in a call to
ei_accept()
. On failure, ERL_ERROR
is returned and erl_errno
is set to
EIO
.
Available since OTP 21.3
ei_make_pid()
int ei_make_pid(ei_cnode *ec, erlang_pid *pid);
Creates a new process identifier in the argument pid
. This process identifier
refers to a conseptual process residing on the C-node identified by the argument
ec
. On success 0
is returned. On failure ERL_ERROR
is returned and
erl_errno
is set.
The C-node identified by ec
must have been initialized and must have received
a name prior to the call to ei_make_pid()
. Initialization of the C-node is
done by a call to ei_connect_init()
or
friends. If the name is dynamically assigned from the peer node, the C-node also
has to be connected.
Available since OTP 23.0
ei_make_ref()
int ei_make_ref(ei_cnode *ec, erlang_ref *ref);
Creates a new reference in the argument ref
. This reference originates from
the C-node identified by the argument ec
. On success 0
is returned. On
failure ERL_ERROR
is returned and erl_errno
is set.
The C-node identified by ec
must have been initialized and must have received
a name prior to the call to ei_make_ref()
. Initialization of the C-node is
done by a call to ei_connect_init()
or
friends. If the name is dynamically assigned from the peer node, the C-node also
has to be connected.
Available since OTP 23.0
ei_publish()
int ei_publish(ei_cnode *ec, int port);
Used by a server process to register with the local name server EPMD, thereby
allowing other processes to send messages by using the registered name. Before
calling either of these functions, the process should have called bind()
and
listen()
on an open socket.
ec
is the C-node structure.port
is the local name to register, and is to be the same as the port number that was previously bound to the socket.addr
is the 32-bit IP address of the local host.
To unregister with EPMD, simply close the returned descriptor. Do not use
ei_unpublish()
, which is deprecated anyway.
On success, the function returns a descriptor connecting the calling process to
EPMD. On failure, -1
is returned and erl_errno
is set to EIO
.
Also, errno
values from socket(2)
and connect(2)
system calls may be
propagated into erl_errno
.
ei_publish_tmo()
int ei_publish_tmo(ei_cnode *ec, int port, unsigned timeout_ms);
Equivalent to ei_publish
with an optional time-out argument, see the
description at the beginning of this manual page.
ei_receive()
int ei_receive(int fd, unsigned char* bufp, int bufsize);
Receives a message consisting of a sequence of bytes in the Erlang external format.
fd
is an open descriptor to an Erlang connection. It is obtained from a previousei_connect
orei_accept
.bufp
is a buffer large enough to hold the expected message.bufsize
indicates the size ofbufp
.
If a tick occurs, that is, the Erlang node on the other end of the connection
has polled this node to see if it is still alive, the function returns
ERL_TICK
and no message is placed in the buffer. Also, erl_errno
is set to
EAGAIN
.
On success, the message is placed in the specified buffer and the function
returns the number of bytes actually read. On failure, the function returns
ERL_ERROR
and sets erl_errno
to one of the following:
EAGAIN
- Temporary error: Try again.EMSGSIZE
- Buffer is too small.EIO
- I/O error.
ei_receive_encoded()
int ei_receive_encoded(int fd, char **mbufp, int *bufsz, erlang_msg *msg, int *msglen);
This function is retained for compatibility with code generated by the interface compiler and with code following examples in the same application.
In essence, the function performs the same operation as ei_xreceive_msg
, but
instead of using an ei_x_buff
, the function expects a pointer to a character
pointer (mbufp
), where the character pointer is to point to a memory area
allocated by malloc
. Argument bufsz
is to be a pointer to an integer
containing the exact size (in bytes) of the memory area. The function may
reallocate the memory area and will in such cases put the new size in *bufsz
and update *mbufp
.
Returns either ERL_TICK
or the msgtype
field of the erlang_msg *msg
. The
length of the message is put in *msglen
. On error a value < 0
is returned.
It is recommended to use ei_xreceive_msg
instead when possible, for the sake
of readability. However, the function will be retained in the interface for
compatibility and will not be removed in future releases without prior notice.
ei_receive_encoded_tmo()
int ei_receive_encoded_tmo(int fd, char **mbufp, int *bufsz, erlang_msg *msg,
int *msglen, unsigned timeout_ms);
Equivalent to ei_receive_encoded
with an optional time-out argument, see the
description at the beginning of this manual page.
ei_receive_msg()
ei_xreceive_msg()
int ei_receive_msg(int fd, erlang_msg* msg, ei_x_buff* x);
int ei_xreceive_msg(int fd, erlang_msg* msg, ei_x_buff* x);
Receives a message to the buffer in x
. ei_xreceive_msg
allows the buffer in
x
to grow, but ei_receive_msg
fails if the message is larger than the
pre-allocated buffer in x
.
fd
is an open descriptor to an Erlang connection.msg
is a pointer to anerlang_msg
structure and contains information on the message received.x
is buffer obtained fromei_x_new
.
On success, the functions return ERL_MSG
and the
msg
struct is initialized.
msgtype
identifies the type of message, and is one of the following:
ERL_SEND
- Indicates that an ordinary send operation has occurred.msg->to
contains the pid of the recipient (the C-node).ERL_REG_SEND
- A registered send operation occurred.msg->from
contains the pid of the sender.ERL_LINK
orERL_UNLINK
-msg->to
andmsg->from
contain the pids of the sender and recipient of the link or unlink.ERL_EXIT
- Indicates a broken link.msg->to
andmsg->from
contain the pids of the linked processes.
The return value is the same as for ei_receive
.
ei_receive_msg_tmo()
ei_xreceive_msg_tmo()
int ei_receive_msg_tmo(int fd, erlang_msg* msg, ei_x_buff* x, unsigned imeout_ms);
int ei_xreceive_msg_tmo(int fd, erlang_msg* msg, ei_x_buff* x, unsigned timeout_ms);
Equivalent to ei_receive_msg
and ei_xreceive_msg
with an optional time-out
argument, see the description at the beginning of this manual page.
ei_receive_tmo()
int ei_receive_tmo(int fd, unsigned char* bufp, int bufsize, unsigned timeout_ms);
Equivalent to ei_receive
with an optional time-out argument, see the
description at the beginning of this manual page.
ei_reg_send()
int ei_reg_send(ei_cnode* ec, int fd, char* server_name, char* buf, int len);
Sends an Erlang term to a registered process.
fd
is an open descriptor to an Erlang connection.server_name
is the registered name of the intended recipient.buf
is the buffer containing the term in binary format.len
is the length of the message in bytes.
Returns 0
if successful, otherwise -1
. In the latter case it sets
erl_errno
to EIO
.
Example:
Send the atom "ok" to the process "worker":
ei_x_buff x;
ei_x_new_with_version(&x);
ei_x_encode_atom(&x, "ok");
if (ei_reg_send(&ec, fd, x.buff, x.index) < 0)
handle_error();
ei_reg_send_tmo()
int ei_reg_send_tmo(ei_cnode* ec, int fd, char* server_name, char* buf, int len,
unsigned timeout_ms);
Equivalent to ei_reg_send
with an optional time-out argument, see the
description at the beginning of this manual page.
ei_rpc()
ei_rpc_to()
ei_xrpc_to()
Available since OTP 24.0
ei_rpc_from()
int ei_rpc(ei_cnode *ec, int fd, char *mod, char *fun, const char *argbuf,
int argbuflen, ei_x_buff *x);
int ei_rpc_to(ei_cnode *ec, int fd, char *mod, char *fun, const char *argbuf,
int argbuflen);
int ei_xrpc_to(ei_cnode *ec, int fd, char *mod, char *fun, const char *argbuf,
int argbuflen, int flags);
int ei_rpc_from(ei_cnode *ec, int fd, int timeout, erlang_msg *msg, ei_x_buff *x);
Supports calling Erlang functions on remote nodes. ei_rpc_to()
sends an RPC
request to a remote node and ei_rpc_from()
receives the results of such a
call. ei_rpc()
combines the functionality of these two functions by sending an
RPC request and waiting for the results.
The ei_xrpc_to()
function is equivalent to ei_rpc_to()
when its flags
parameter is set to 0
. When the flags parameter of ei_xrpc_to()
is set to
EI_RPC_FETCH_STDOUT
, stdout (standard output) data are forwarded. See the
documentation for the flags parameter for more information about the
EI_RPC_FETCH_STDOUT
flag.
See also rpc:call/4
in Kernel.
ec
is the C-node structure previously initiated by a call toei_connect_init()
orei_connect_xinit()
.fd
is an open descriptor to an Erlang connection.timeout
is the maximum time (in milliseconds) to wait for results. SpecifyERL_NO_TIMEOUT
to wait forever.ei_rpc()
waits infinitely for the answer, that is, the call will never time out.mod
is the name of the module containing the function to be run on the remote node.fun
is the name of the function to run.argbuf
is a pointer to a buffer with an encoded Erlang list, without a version magic number, containing the arguments to be passed to the function.argbuflen
is the length of the buffer containing the encoded Erlang list.msg
is structure of typeerlang_msg
and contains information on the message received. For a description of theerlang_msg
format, seeei_receive_msg
.x
points to the dynamic buffer that receives the result. Forei_rpc()
this is the result without the version magic number. For anei_rpc_from()
call the result consists of a version magic number and a 2-tuple. The 2-tuple can be in one of the following two forms:{rex,Reply}
- This response value means that the RPC has completed. The result value is theReply
term. This is the only type of response that one can get from an RPC triggered by a call toei_rpc_to()
orei_xrpc_to()
without theEI_RPC_FETCH_STDOUT
flag. If the RPC was triggered by a call toei_xrpc_to()
with theEI_RPC_FETCH_STDOUT
flag set, then all forwarded stdout data has been received.{rex_stdout,StdOutUTF8Binary}
- This response value can only be obtained if the RPC call was triggered by a call toei_xrpc_to()
with theEI_RPC_FETCH_STDOUT
flag set. This response value means that forwarded stdout data has been received. The stdout data is stored in a binary and is UTF-8 encoded. One may need to callei_rpc_from()
multiple times to read all the stdout data. The stdout data is received in the same order as it was written. All forwarded stdout data have been received when a{rex,Reply}
tuple has been obtained from anei_rpc_from()
call.
flags
The flagEI_RPC_FETCH_STDOUT
is currently the only flag that is supported byei_xrpc_to()
. WhenEI_RPC_FETCH_STDOUT
is set, the called function is executed in a new process with a group leader that forwards all stdout data. This means that stdout data that are written during the execution of the called function, by the called function and by descendant processes, will be forwarded (given that the group leader has not been changed by a call toerlang:group_leader/2
). The forwarded stdout data need to be collected by a sequence of calls toei_rpc_from()
. See the description of thex
parameter for howei_rpc_from()
is used to receive stdout data. See the documentation of the the I/O protocol, for more information about the group leader concept.Note
The flag
EI_RPC_FETCH_STDOUT
only works when interacting with a node with a version greater or equal to OTP-24.
ei_rpc()
returns the number of bytes in the result on success and -1
on
failure. ei_rpc_from()
returns the number of bytes, otherwise one of
ERL_TICK
, ERL_TIMEOUT
, and ERL_ERROR
. The functions ei_rpc_to()
and
ei_xrpc_to()
returns 0 if successful, otherwise -1. When failing, all four
functions set erl_errno
to one of the following:
EIO
- I/O error.ETIMEDOUT
- Time-out expired.EAGAIN
- Temporary error: Try again.
Example:
Check to see if an Erlang process is alive:
int index = 0, is_alive;
ei_x_buff args, result;
ei_x_new(&result);
ei_x_new(&args);
ei_x_encode_list_header(&args, 1);
ei_x_encode_pid(&args, &check_pid);
ei_x_encode_empty_list(&args);
if (ei_rpc(&ec, fd, "erlang", "is_process_alive",
args.buff, args.index, &result) < 0)
handle_error();
if (ei_decode_version(result.buff, &index) < 0
|| ei_decode_bool(result.buff, &index, &is_alive) < 0)
handle_error();
ei_self()
erlang_pid * ei_self(ei_cnode *ec);
Retrieves a generic pid of the C-node. Every C-node has a (pseudo) pid used in
ei_send_reg
, ei_rpc()
, and others. This is contained in a field in the ec
structure. Do not modify this structure.
On success a pointer to the process identifier is returned. On failure NULL
is
returned and erl_errno
is set.
The C-node identified by ec
must have been initialized and must have received
a name prior to the call to ei_self()
. Initialization of the C-node is done by
a call to ei_connect_init()
or friends. If
the name is dynamically assigned from the peer node, the C-node also has to be
connected.
ei_send()
int ei_send(int fd, erlang_pid* to, char* buf, int len);
Sends an Erlang term to a process.
fd
is an open descriptor to an Erlang connection.to
is the pid of the intended recipient of the message.buf
is the buffer containing the term in binary format.len
is the length of the message in bytes.
Returns 0
if successful, otherwise -1
. In the latter case it sets
erl_errno
to EIO
.
ei_send_encoded()
int ei_send_encoded(int fd, erlang_pid* to, char* buf, int len);
Works exactly as ei_send
, the alternative name is retained for backward
compatibility. The function will not be removed without prior notice.
ei_send_encoded_tmo()
int ei_send_encoded_tmo(int fd, erlang_pid* to, char* buf, int len, unsigned timeout_ms);
Equivalent to ei_send_encoded
with an optional time-out argument, see the
description at the beginning of this manual page.
ei_send_reg_encoded()
int ei_send_reg_encoded(int fd, const erlang_pid *from, const char *to, const char *buf, int len);
This function is retained for compatibility with code generated by the interface compiler and with code following examples in the same application.
The function works as ei_reg_send
with one exception. Instead of taking
ei_cnode
as first argument, it takes a second argument, an erlang_pid
, which
is to be the process identifier of the sending process (in the Erlang
distribution protocol).
A suitable erlang_pid
can be retrieved from the ei_cnode
structure by
calling ei_self(cnode_pointer)
.
ei_send_reg_encoded_tmo()
int ei_send_reg_encoded_tmo(int fd, const erlang_pid *from, const char *to, const char *buf,
int len, unsigned timeout_ms);
Equivalent to ei_send_reg_encoded
with an optional time-out argument, see the
description at the beginning of this manual page.
ei_send_tmo()
int ei_send_tmo(int fd, erlang_pid* to, char* buf, int len, unsigned timeout_ms);
Equivalent to ei_send
with an optional time-out argument, see the description
at the beginning of this manual page.
ei_thisnodename()
ei_thishostname()
ei_thisalivename()
const char * ei_thisnodename(ei_cnode *ec);
const char * ei_thishostname(ei_cnode *ec);
const char * ei_thisalivename(ei_cnode *ec);
Can be used to retrieve information about the C-node. These values are initially
set with ei_connect_init()
or ei_connect_xinit()
.
These function simply fetch the appropriate field from the ec
structure. Read
the field directly will probably be safe for a long time, so these functions are
not really needed.
ei_unpublish()
int ei_unpublish(ei_cnode *ec);
Can be called by a process to unregister a specified node from EPMD on the local
host. This is, however, usually not allowed, unless EPMD was started with flag
-relaxed_command_check
, which it normally is not.
To unregister a node you have published, you should close the descriptor that
was returned by ei_publish()
.
Warning
This function is deprecated and will be removed in a future release.
ec
is the node structure of the node to unregister.
If the node was successfully unregistered from EPMD, the function returns 0
.
Otherwise, -1
is returned and erl_errno
is set to EIO
.
ei_unpublish_tmo()
int ei_unpublish_tmo(ei_cnode *ec, unsigned timeout_ms);
Equivalent to ei_unpublish
with an optional time-out argument, see the
description at the beginning of this manual page.
Debug Information
If a connection attempt fails, the following can be checked:
erl_errno
.- That the correct cookie was used
- That EPMD is running
- That the remote Erlang node on the other side is running the same version of
Erlang as the
ei
library - That environment variable
ERL_EPMD_PORT
is set correctly
The connection attempt can be traced by setting a trace level by either using
ei_set_tracelevel
or by setting environment variable EI_TRACELEVEL
. The
trace levels have the following messages:
- 1: Verbose error messages
- 2: Above messages and verbose warning messages
- 3: Above messages and progress reports for connection handling
- 4: Above messages and progress reports for communication
- 5: Above messages and progress reports for data conversion