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gerrit.opencord.org / freeDiameter-old / 13d9601bf947af3286764506368fc3d04672bfde / . / libfdcore / routing_dispatch.c
blob: 93df0657a6307c34a3d4308ce00df09f19e55258 [file] [log] [blame]
/*********************************************************************************************************
* Software License Agreement (BSD License) *
* Author: Sebastien Decugis <sdecugis@freediameter.net> *
* *
* Copyright (c) 2015, WIDE Project and NICT *
* All rights reserved. *
* *
* Redistribution and use of this software in source and binary forms, with or without modification, are *
* permitted provided that the following conditions are met: *
* *
* * Redistributions of source code must retain the above *
* copyright notice, this list of conditions and the *
* following disclaimer. *
* *
* * Redistributions in binary form must reproduce the above *
* copyright notice, this list of conditions and the *
* following disclaimer in the documentation and/or other *
* materials provided with the distribution. *
* *
* * Neither the name of the WIDE Project or NICT nor the *
* names of its contributors may be used to endorse or *
* promote products derived from this software without *
* specific prior written permission of WIDE Project and *
* NICT. *
* *
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED *
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A *
* PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR *
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT *
* LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS *
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR *
* TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF *
* ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. *
*********************************************************************************************************/
#include "fdcore-internal.h"
/********************************************************************************/
/* First part : handling the extensions callbacks */
/********************************************************************************/
/* Lists of the callbacks, and locks to protect them */
static pthread_rwlock_t rt_fwd_lock = PTHREAD_RWLOCK_INITIALIZER;
static struct fd_list rt_fwd_list = FD_LIST_INITIALIZER_O(rt_fwd_list, &rt_fwd_lock);
static pthread_rwlock_t rt_out_lock = PTHREAD_RWLOCK_INITIALIZER;
static struct fd_list rt_out_list = FD_LIST_INITIALIZER_O(rt_out_list, &rt_out_lock);
/* Items in the lists are the same */
struct rt_hdl {
struct fd_list chain; /* link in the rt_fwd_list or rt_out_list */
void * cbdata; /* the registered data */
union {
int order; /* This value is used to sort the list */
int dir; /* It is the direction for FWD handlers */
int prio; /* and the priority for OUT handlers */
};
union {
int (*rt_fwd_cb)(void * cbdata, struct msg ** msg);
int (*rt_out_cb)(void * cbdata, struct msg ** msg, struct fd_list * candidates);
};
};
/* Add a new entry in the list */
static int add_ordered(struct rt_hdl * new, struct fd_list * list)
{
/* The list is ordered by prio parameter */
struct fd_list * li;
CHECK_POSIX( pthread_rwlock_wrlock(list->o) );
for (li = list->next; li != list; li = li->next) {
struct rt_hdl * h = (struct rt_hdl *) li;
if (new->order <= h->order)
break;
}
fd_list_insert_before(li, &new->chain);
CHECK_POSIX( pthread_rwlock_unlock(list->o) );
return 0;
}
/* Register a new FWD callback */
int fd_rt_fwd_register ( int (*rt_fwd_cb)(void * cbdata, struct msg ** msg), void * cbdata, enum fd_rt_fwd_dir dir, struct fd_rt_fwd_hdl ** handler )
{
struct rt_hdl * new;
TRACE_ENTRY("%p %p %d %p", rt_fwd_cb, cbdata, dir, handler);
CHECK_PARAMS( rt_fwd_cb );
CHECK_PARAMS( (dir >= RT_FWD_REQ) && ( dir <= RT_FWD_ANS) );
/* Create a new container */
CHECK_MALLOC(new = malloc(sizeof(struct rt_hdl)));
memset(new, 0, sizeof(struct rt_hdl));
/* Write the content */
fd_list_init(&new->chain, NULL);
new->cbdata = cbdata;
new->dir = dir;
new->rt_fwd_cb = rt_fwd_cb;
/* Save this in the list */
CHECK_FCT( add_ordered(new, &rt_fwd_list) );
/* Give it back to the extension if needed */
if (handler)
*handler = (void *)new;
return 0;
}
/* Remove it */
int fd_rt_fwd_unregister ( struct fd_rt_fwd_hdl * handler, void ** cbdata )
{
struct rt_hdl * del;
TRACE_ENTRY( "%p %p", handler, cbdata);
CHECK_PARAMS( handler );
del = (struct rt_hdl *)handler;
CHECK_PARAMS( del->chain.head == &rt_fwd_list );
/* Unlink */
CHECK_POSIX( pthread_rwlock_wrlock(&rt_fwd_lock) );
fd_list_unlink(&del->chain);
CHECK_POSIX( pthread_rwlock_unlock(&rt_fwd_lock) );
if (cbdata)
*cbdata = del->cbdata;
free(del);
return 0;
}
/* Register a new OUT callback */
int fd_rt_out_register ( int (*rt_out_cb)(void * cbdata, struct msg ** pmsg, struct fd_list * candidates), void * cbdata, int priority, struct fd_rt_out_hdl ** handler )
{
struct rt_hdl * new;
TRACE_ENTRY("%p %p %d %p", rt_out_cb, cbdata, priority, handler);
CHECK_PARAMS( rt_out_cb );
/* Create a new container */
CHECK_MALLOC(new = malloc(sizeof(struct rt_hdl)));
memset(new, 0, sizeof(struct rt_hdl));
/* Write the content */
fd_list_init(&new->chain, NULL);
new->cbdata = cbdata;
new->prio = priority;
new->rt_out_cb = rt_out_cb;
/* Save this in the list */
CHECK_FCT( add_ordered(new, &rt_out_list) );
/* Give it back to the extension if needed */
if (handler)
*handler = (void *)new;
return 0;
}
/* Remove it */
int fd_rt_out_unregister ( struct fd_rt_out_hdl * handler, void ** cbdata )
{
struct rt_hdl * del;
TRACE_ENTRY( "%p %p", handler, cbdata);
CHECK_PARAMS( handler );
del = (struct rt_hdl *)handler;
CHECK_PARAMS( del->chain.head == &rt_out_list );
/* Unlink */
CHECK_POSIX( pthread_rwlock_wrlock(&rt_out_lock) );
fd_list_unlink(&del->chain);
CHECK_POSIX( pthread_rwlock_unlock(&rt_out_lock) );
if (cbdata)
*cbdata = del->cbdata;
free(del);
return 0;
}
/********************************************************************************/
/* Some default OUT routing callbacks */
/********************************************************************************/
/* Prevent sending to peers that do not support the message application */
static int dont_send_if_no_common_app(void * cbdata, struct msg ** pmsg, struct fd_list * candidates)
{
struct msg * msg = *pmsg;
struct fd_list * li;
struct msg_hdr * hdr;
TRACE_ENTRY("%p %p %p", cbdata, msg, candidates);
CHECK_PARAMS(msg && candidates);
CHECK_FCT( fd_msg_hdr(msg, &hdr) );
/* For Base Diameter Protocol, every peer is supposed to support it, so skip */
if (hdr->msg_appl == 0)
return 0;
/* Otherwise, check that the peers support the application */
for (li = candidates->next; li != candidates; li = li->next) {
struct rtd_candidate *c = (struct rtd_candidate *) li;
struct fd_peer * peer;
struct fd_app *found;
CHECK_FCT( fd_peer_getbyid( c->diamid, c->diamidlen, 0, (void *)&peer ) );
if (peer && !peer->p_hdr.info.runtime.pir_relay) {
/* Check if the remote peer advertised the message's appli */
CHECK_FCT( fd_app_check(&peer->p_hdr.info.runtime.pir_apps, hdr->msg_appl, &found) );
if (!found)
c->score += FD_SCORE_NO_DELIVERY;
}
}
return 0;
}
/* Detect if the Destination-Host and Destination-Realm match the peer */
static int score_destination_avp(void * cbdata, struct msg ** pmsg, struct fd_list * candidates)
{
struct msg * msg = *pmsg;
struct fd_list * li;
struct avp * avp;
union avp_value *dh = NULL, *dr = NULL;
TRACE_ENTRY("%p %p %p", cbdata, msg, candidates);
CHECK_PARAMS(msg && candidates);
/* Search the Destination-Host and Destination-Realm AVPs -- we could also use fd_msg_search_avp here, but this one is slightly more efficient */
CHECK_FCT( fd_msg_browse(msg, MSG_BRW_FIRST_CHILD, &avp, NULL) );
while (avp) {
struct avp_hdr * ahdr;
CHECK_FCT( fd_msg_avp_hdr( avp, &ahdr ) );
if (! (ahdr->avp_flags & AVP_FLAG_VENDOR)) {
switch (ahdr->avp_code) {
case AC_DESTINATION_HOST:
/* Parse this AVP */
CHECK_FCT( fd_msg_parse_dict ( avp, fd_g_config->cnf_dict, NULL ) );
ASSERT( ahdr->avp_value );
dh = ahdr->avp_value;
break;
case AC_DESTINATION_REALM:
/* Parse this AVP */
CHECK_FCT( fd_msg_parse_dict ( avp, fd_g_config->cnf_dict, NULL ) );
ASSERT( ahdr->avp_value );
dr = ahdr->avp_value;
break;
}
}
if (dh && dr)
break;
/* Go to next AVP */
CHECK_FCT( fd_msg_browse(avp, MSG_BRW_NEXT, &avp, NULL) );
}
/* Now, check each candidate against these AVP values */
for (li = candidates->next; li != candidates; li = li->next) {
struct rtd_candidate *c = (struct rtd_candidate *) li;
#if 0 /* this is actually useless since the sending process will also ensure that the peer is still available */
struct fd_peer * peer;
/* Since the candidates list comes from the peers list, we do not have any issue with upper/lower case to find the peer object */
CHECK_FCT( fd_peer_getbyid( c->diamid, c->diamidlen, 0, (void *)&peer ) );
if (!peer)
continue; /* it has been deleted since the candidate list was generated; avoid sending to this one in that case. */
#endif /* 0 */
/* In the AVPs, the value comes from the network, so let's be case permissive */
if (dh && !fd_os_almostcasesrch(dh->os.data, dh->os.len, c->diamid, c->diamidlen, NULL) ) {
/* The candidate is the Destination-Host */
c->score += FD_SCORE_FINALDEST;
} else {
if (dr && !fd_os_almostcasesrch(dr->os.data, dr->os.len, c->realm, c->realmlen, NULL) ) {
/* The candidate's realm matchs the Destination-Realm */
c->score += FD_SCORE_REALM;
}
}
}
return 0;
}
/********************************************************************************/
/* Helper functions */
/********************************************************************************/
/* Find (first) '!' and '@' positions in a UTF-8 encoded string (User-Name AVP value) */
static void nai_get_indexes(union avp_value * un, int * excl_idx, int * at_idx)
{
int i;
TRACE_ENTRY("%p %p %p", un, excl_idx, at_idx);
CHECK_PARAMS_DO( un && excl_idx && at_idx, return );
*excl_idx = 0;
*at_idx = 0;
/* Search if there is a '!' before any '@' -- do we need to check it contains a '.' ? */
for (i = 0; i < un->os.len; i++) {
/* The '!' marks the decorated NAI */
if ( un->os.data[i] == (unsigned char) '!' ) {
if (!*excl_idx)
*excl_idx = i;
continue;
}
/* If we reach the realm part, we can stop */
if ( un->os.data[i] == (unsigned char) '@' ) {
*at_idx = i;
break;
}
/* Stop if we find a \0 in the middle */
if ( un->os.data[i] == 0 ) {
return;
}
/* Skip escaped characters */
if ( un->os.data[i] == (unsigned char) '\\' ) {
i++;
continue;
}
}
return;
}
/* Test if a User-Name AVP contains a Decorated NAI -- RFC4282, RFC5729 */
/* Create new User-Name and Destination-Realm values */
static int process_decorated_NAI(int * was_nai, union avp_value * un, union avp_value * dr)
{
int at_idx, sep_idx;
unsigned char * old_un;
TRACE_ENTRY("%p %p %p", was_nai, un, dr);
CHECK_PARAMS(was_nai && un && dr);
/* Save the decorated User-Name, for example 'homerealm.example.net!user@otherrealm.example.net' */
old_un = un->os.data;
/* Search the positions of the first '!' and the '@' in the string */
nai_get_indexes(un, &sep_idx, &at_idx);
if ((!sep_idx) || (sep_idx > at_idx) || !fd_os_is_valid_DiameterIdentity(old_un, sep_idx /* this is the new realm part */)) {
*was_nai = 0;
return 0;
}
*was_nai = 1;
/* Create the new User-Name value */
CHECK_MALLOC( un->os.data = malloc( at_idx ) );
memcpy( un->os.data, old_un + sep_idx + 1, at_idx - sep_idx ); /* user@ */
memcpy( un->os.data + at_idx - sep_idx, old_un, sep_idx ); /* homerealm.example.net */
/* Create the new Destination-Realm value */
CHECK_MALLOC( dr->os.data = realloc(dr->os.data, sep_idx) );
memcpy( dr->os.data, old_un, sep_idx );
dr->os.len = sep_idx;
TRACE_DEBUG(FULL, "Processed Decorated NAI : '%.*s' became '%.*s' (%.*s)",
(int)un->os.len, old_un,
(int)at_idx, un->os.data,
(int)dr->os.len, dr->os.data);
un->os.len = at_idx;
free(old_un);
return 0;
}
/* Function to return an error to an incoming request */
static int return_error(struct msg ** pmsg, char * error_code, char * error_message, struct avp * failedavp)
{
struct fd_peer * peer;
int is_loc = 0;
/* Get the source of the message */
{
DiamId_t id;
size_t idlen;
CHECK_FCT( fd_msg_source_get( *pmsg, &id, &idlen ) );
if (id == NULL) {
is_loc = 1; /* The message was issued locally */
} else {
/* Search the peer with this id */
CHECK_FCT( fd_peer_getbyid( id, idlen, 0, (void *)&peer ) );
if (!peer) {
char buf[256];
snprintf(buf, sizeof(buf), "Unable to send error '%s' to deleted peer '%s' in reply to this message.", error_code, id);
fd_hook_call(HOOK_MESSAGE_DROPPED, *pmsg, NULL, buf, fd_msg_pmdl_get(*pmsg));
fd_msg_free(*pmsg);
*pmsg = NULL;
return 0;
}
}
}
/* Create the error message */
CHECK_FCT( fd_msg_new_answer_from_req ( fd_g_config->cnf_dict, pmsg, MSGFL_ANSW_ERROR ) );
/* Set the error code */
CHECK_FCT( fd_msg_rescode_set(*pmsg, error_code, error_message, failedavp, 1 ) );
/* Send the answer */
if (is_loc) {
CHECK_FCT( fd_fifo_post(fd_g_incoming, pmsg) );
} else {
CHECK_FCT( fd_out_send(pmsg, NULL, peer, 1) );
}
/* Done */
return 0;
}
/****************************************************************************/
/* Second part : threads moving messages in the daemon */
/****************************************************************************/
/* The DISPATCH message processing */
static int msg_dispatch(struct msg * msg)
{
struct msg_hdr * hdr;
int is_req = 0;
struct session * sess;
enum disp_action action;
char * ec = NULL;
char * em = NULL;
struct msg *msgptr = msg, *error = NULL;
/* Read the message header */
CHECK_FCT( fd_msg_hdr(msg, &hdr) );
is_req = hdr->msg_flags & CMD_FLAG_REQUEST;
/* Note: if the message is for local delivery, we should test for duplicate
(draft-asveren-dime-dupcons-00). This may conflict with path validation decisions, no clear answer yet */
/* At this point, we need to understand the message content, so parse it */
CHECK_FCT_DO( fd_msg_parse_or_error( &msgptr, &error ),
{
int rescue = 0;
if (__ret__ != EBADMSG) {
fd_hook_call(HOOK_MESSAGE_DROPPED, msgptr, NULL, "Error while parsing received answer", fd_msg_pmdl_get(msgptr));
fd_msg_free(msgptr);
} else {
if (!msgptr) {
fd_hook_call(HOOK_MESSAGE_PARSING_ERROR2, error, NULL, NULL, fd_msg_pmdl_get(error));
/* error now contains the answer message to send back */
CHECK_FCT( fd_fifo_post(fd_g_outgoing, &error) );
} else if (!error) {
/* We have received an invalid answer to our query */
fd_hook_call(HOOK_MESSAGE_DROPPED, msgptr, NULL, "Received answer failed the dictionary / rules parsing", fd_msg_pmdl_get(msgptr));
fd_msg_free(msgptr);
} else {
/* We will pass the invalid received error to the application */
rescue = 1;
}
}
if (!rescue)
return 0; /* We are done with this message, go to the next */
} );
/* First, if the original request was registered with a callback and we receive the answer, call it. */
if ( ! is_req ) {
struct msg * qry;
void (*anscb)(void *, struct msg **) = NULL;
void * data = NULL;
/* Retrieve the corresponding query */
CHECK_FCT( fd_msg_answ_getq( msgptr, &qry ) );
/* Retrieve any registered handler */
CHECK_FCT( fd_msg_anscb_get( qry, &anscb, NULL, &data ) );
/* If a callback was registered, pass the message to it */
if (anscb != NULL) {
TRACE_DEBUG(FULL, "Calling callback registered when query was sent (%p, %p)", anscb, data);
(*anscb)(data, &msgptr);
/* If the message is processed, we're done */
if (msgptr == NULL) {
return 0;
}
/* otherwise continue the dispatching --hoping that the anscb callback did not mess with our message :) */
}
}
/* Retrieve the session of the message */
CHECK_FCT( fd_msg_sess_get(fd_g_config->cnf_dict, msgptr, &sess, NULL) );
/* Now, call any callback registered for the message */
CHECK_FCT( fd_msg_dispatch ( &msgptr, sess, &action, &ec, &em, &error) );
/* Now, act depending on msg and action and ec */
if (msgptr) {
switch ( action ) {
case DISP_ACT_CONT:
/* No callback has handled the message, let's reply with a generic error or relay it */
if (!fd_g_config->cnf_flags.no_fwd) {
/* requeue to fd_g_outgoing */
fd_hook_call(HOOK_MESSAGE_ROUTING_FORWARD, msgptr, NULL, NULL, fd_msg_pmdl_get(msgptr));
CHECK_FCT( fd_fifo_post(fd_g_outgoing, &msgptr) );
break;
}
/* We don't relay => reply error */
em = "The message was not handled by any extension callback";
ec = "DIAMETER_COMMAND_UNSUPPORTED";
/* and continue as if an error occurred... */
case DISP_ACT_ERROR:
/* We have a problem with delivering the message */
if (ec == NULL) {
ec = "DIAMETER_UNABLE_TO_COMPLY";
}
if (!is_req) {
fd_hook_call(HOOK_MESSAGE_DROPPED, msgptr, NULL, "Internal error: Answer received to locally issued request, but not handled by any handler.", fd_msg_pmdl_get(msgptr));
fd_msg_free(msgptr);
break;
}
/* Create an answer with the error code and message */
CHECK_FCT( fd_msg_new_answer_from_req ( fd_g_config->cnf_dict, &msgptr, 0 ) );
CHECK_FCT( fd_msg_rescode_set(msgptr, ec, em, NULL, 1 ) );
case DISP_ACT_SEND:
/* Now, send the message */
CHECK_FCT( fd_fifo_post(fd_g_outgoing, &msgptr) );
}
} else if (em) {
fd_hook_call(HOOK_MESSAGE_DROPPED, error, NULL, em, fd_msg_pmdl_get(error));
fd_msg_free(error);
}
/* We're done with dispatching this message */
return 0;
}
/* The ROUTING-IN message processing */
static int msg_rt_in(struct msg * msg)
{
struct msg_hdr * hdr;
int is_req = 0;
int is_err = 0;
DiamId_t qry_src = NULL;
struct msg *msgptr = msg;
/* Read the message header */
CHECK_FCT( fd_msg_hdr(msg, &hdr) );
is_req = hdr->msg_flags & CMD_FLAG_REQUEST;
is_err = hdr->msg_flags & CMD_FLAG_ERROR;
/* Handle incorrect bits */
if (is_req && is_err) {
fd_hook_call(HOOK_MESSAGE_PARSING_ERROR, msgptr, NULL, "R & E bits were set", fd_msg_pmdl_get(msgptr));
CHECK_FCT( return_error( &msgptr, "DIAMETER_INVALID_HDR_BITS", "R & E bits were set", NULL) );
return 0;
}
/* If it is a request, we must analyze its content to decide what we do with it */
if (is_req) {
struct avp * avp, *un = NULL;
union avp_value * un_val = NULL, *dr_val = NULL;
enum status { UNKNOWN, YES, NO };
/* Are we Destination-Host? */
enum status is_dest_host = UNKNOWN;
/* Are we Destination-Realm? */
enum status is_dest_realm = UNKNOWN;
/* Do we support the application of the message? */
enum status is_local_app = UNKNOWN;
/* Check if we have local support for the message application */
if ( (hdr->msg_appl == 0) || (hdr->msg_appl == AI_RELAY) ) {
fd_hook_call(HOOK_MESSAGE_PARSING_ERROR, msgptr, NULL, "Received a routable message with application id 0 or " _stringize(AI_RELAY) " (relay)", fd_msg_pmdl_get(msgptr));
CHECK_FCT( return_error( &msgptr, "DIAMETER_APPLICATION_UNSUPPORTED", "Routable message with application id 0 or relay", NULL) );
return 0;
} else {
struct fd_app * app;
CHECK_FCT( fd_app_check(&fd_g_config->cnf_apps, hdr->msg_appl, &app) );
is_local_app = (app ? YES : NO);
}
/* Parse the message for Dest-Host, Dest-Realm, and Route-Record */
CHECK_FCT( fd_msg_browse(msgptr, MSG_BRW_FIRST_CHILD, &avp, NULL) );
while (avp) {
struct avp_hdr * ahdr;
struct fd_pei error_info;
int ret;
memset(&error_info, 0, sizeof(struct fd_pei));
CHECK_FCT( fd_msg_avp_hdr( avp, &ahdr ) );
if (! (ahdr->avp_flags & AVP_FLAG_VENDOR)) {
switch (ahdr->avp_code) {
case AC_DESTINATION_HOST:
/* Parse this AVP */
CHECK_FCT_DO( ret = fd_msg_parse_dict ( avp, fd_g_config->cnf_dict, &error_info ),
{
if (error_info.pei_errcode) {
fd_hook_call(HOOK_MESSAGE_PARSING_ERROR, msgptr, NULL, error_info.pei_message ?: error_info.pei_errcode, fd_msg_pmdl_get(msgptr));
CHECK_FCT( return_error( &msgptr, error_info.pei_errcode, error_info.pei_message, error_info.pei_avp) );
if (error_info.pei_avp_free) { fd_msg_free(error_info.pei_avp); }
return 0;
} else {
fd_hook_call(HOOK_MESSAGE_PARSING_ERROR, msgptr, NULL, "Unspecified error while parsing Destination-Host AVP", fd_msg_pmdl_get(msgptr));
return ret;
}
} );
ASSERT( ahdr->avp_value );
/* Compare the Destination-Host AVP of the message with our identity */
if (!fd_os_almostcasesrch(ahdr->avp_value->os.data, ahdr->avp_value->os.len, fd_g_config->cnf_diamid, fd_g_config->cnf_diamid_len, NULL)) {
is_dest_host = YES;
} else {
is_dest_host = NO;
}
break;
case AC_DESTINATION_REALM:
/* Parse this AVP */
CHECK_FCT_DO( ret = fd_msg_parse_dict ( avp, fd_g_config->cnf_dict, &error_info ),
{
if (error_info.pei_errcode) {
fd_hook_call(HOOK_MESSAGE_PARSING_ERROR, msgptr, NULL, error_info.pei_message ?: error_info.pei_errcode, fd_msg_pmdl_get(msgptr));
CHECK_FCT( return_error( &msgptr, error_info.pei_errcode, error_info.pei_message, error_info.pei_avp) );
if (error_info.pei_avp_free) { fd_msg_free(error_info.pei_avp); }
return 0;
} else {
fd_hook_call(HOOK_MESSAGE_PARSING_ERROR, msgptr, NULL, "Unspecified error while parsing Destination-Realm AVP", fd_msg_pmdl_get(msgptr));
return ret;
}
} );
ASSERT( ahdr->avp_value );
dr_val = ahdr->avp_value;
/* Compare the Destination-Realm AVP of the message with our identity */
if (!fd_os_almostcasesrch(dr_val->os.data, dr_val->os.len, fd_g_config->cnf_diamrlm, fd_g_config->cnf_diamrlm_len, NULL)) {
is_dest_realm = YES;
} else {
is_dest_realm = NO;
}
break;
/* we also use User-Name for decorated NAI */
case AC_USER_NAME:
/* Parse this AVP */
CHECK_FCT_DO( ret = fd_msg_parse_dict ( avp, fd_g_config->cnf_dict, &error_info ),
{
if (error_info.pei_errcode) {
fd_hook_call(HOOK_MESSAGE_PARSING_ERROR, msgptr, NULL, error_info.pei_message ?: error_info.pei_errcode, fd_msg_pmdl_get(msgptr));
CHECK_FCT( return_error( &msgptr, error_info.pei_errcode, error_info.pei_message, error_info.pei_avp) );
if (error_info.pei_avp_free) { fd_msg_free(error_info.pei_avp); }
return 0;
} else {
fd_hook_call(HOOK_MESSAGE_PARSING_ERROR, msgptr, NULL, "Unspecified error while parsing User-Name AVP", fd_msg_pmdl_get(msgptr));
return ret;
}
} );
ASSERT( ahdr->avp_value );
un = avp;
un_val = ahdr->avp_value;
break;
case AC_ROUTE_RECORD:
/* Parse this AVP */
CHECK_FCT_DO( ret = fd_msg_parse_dict ( avp, fd_g_config->cnf_dict, &error_info ),
{
if (error_info.pei_errcode) {
fd_hook_call(HOOK_MESSAGE_PARSING_ERROR, msgptr, NULL, error_info.pei_message ?: error_info.pei_errcode, fd_msg_pmdl_get(msgptr));
CHECK_FCT( return_error( &msgptr, error_info.pei_errcode, error_info.pei_message, error_info.pei_avp) );
if (error_info.pei_avp_free) { fd_msg_free(error_info.pei_avp); }
return 0;
} else {
fd_hook_call(HOOK_MESSAGE_PARSING_ERROR, msgptr, NULL, "Unspecified error while parsing Route-Record AVP", fd_msg_pmdl_get(msgptr));
return ret;
}
} );
ASSERT( ahdr->avp_value );
/* Is this our own name ? */
if (!fd_os_almostcasesrch(ahdr->avp_value->os.data, ahdr->avp_value->os.len, fd_g_config->cnf_diamid, fd_g_config->cnf_diamid_len, NULL)) {
/* Yes: then we must return DIAMETER_LOOP_DETECTED according to Diameter RFC */
char * error = "DIAMETER_LOOP_DETECTED";
fd_hook_call(HOOK_MESSAGE_PARSING_ERROR, msgptr, NULL, error, fd_msg_pmdl_get(msgptr));
CHECK_FCT( return_error( &msgptr, error, NULL, NULL) );
return 0;
}
break;
}
}
/* Stop when we found all 3 AVPs -- they are supposed to be at the beginning of the message, so this should be fast */
if ((is_dest_host != UNKNOWN) && (is_dest_realm != UNKNOWN) && un)
break;
/* Go to next AVP */
CHECK_FCT( fd_msg_browse(avp, MSG_BRW_NEXT, &avp, NULL) );
}
/* OK, now decide what we do with the request */
/* Handle the missing routing AVPs first */
if ( is_dest_realm == UNKNOWN ) {
fd_hook_call(HOOK_MESSAGE_PARSING_ERROR, msgptr, NULL, "Non-routable message not supported (invalid bit ? missing Destination-Realm ?)", fd_msg_pmdl_get(msgptr));
CHECK_FCT( return_error( &msgptr, "DIAMETER_COMMAND_UNSUPPORTED", "Non-routable message not supported (invalid bit ? missing Destination-Realm ?)", NULL) );
return 0;
}
/* If we are listed as Destination-Host */
if (is_dest_host == YES) {
if (is_local_app == YES) {
/* Ok, give the message to the dispatch thread */
fd_hook_call(HOOK_MESSAGE_ROUTING_LOCAL, msgptr, NULL, NULL, fd_msg_pmdl_get(msgptr));
CHECK_FCT( fd_fifo_post(fd_g_local, &msgptr) );
} else {
/* We don't support the application, reply an error */
fd_hook_call(HOOK_MESSAGE_PARSING_ERROR, msgptr, NULL, "Application unsupported", fd_msg_pmdl_get(msgptr));
CHECK_FCT( return_error( &msgptr, "DIAMETER_APPLICATION_UNSUPPORTED", NULL, NULL) );
}
return 0;
}
/* If the message is explicitely for someone else */
if ((is_dest_host == NO) || (is_dest_realm == NO)) {
if (fd_g_config->cnf_flags.no_fwd) {
fd_hook_call(HOOK_MESSAGE_ROUTING_ERROR, msgptr, NULL, "Message for another realm/host", fd_msg_pmdl_get(msgptr));
CHECK_FCT( return_error( &msgptr, "DIAMETER_UNABLE_TO_DELIVER", "I am not a Diameter agent", NULL) );
return 0;
}
} else {
/* Destination-Host was not set, and Destination-Realm is matching : we may handle or pass to a fellow peer */
int is_nai = 0;
/* test for decorated NAI (RFC5729 section 4.4) */
/* Handle the decorated NAI */
if (un_val) {
CHECK_FCT_DO( process_decorated_NAI(&is_nai, un_val, dr_val),
{
/* If the process failed, we assume it is because of the AVP format */
fd_hook_call(HOOK_MESSAGE_PARSING_ERROR, msgptr, NULL, "Failed to process decorated NAI", fd_msg_pmdl_get(msgptr));
CHECK_FCT( return_error( &msgptr, "DIAMETER_INVALID_AVP_VALUE", "Failed to process decorated NAI", un) );
return 0;
} );
}
if (is_nai) {
/* We have transformed the AVP, now submit it again in the queue */
CHECK_FCT(fd_fifo_post(fd_g_incoming, &msgptr) );
return 0;
}
if (is_local_app == YES) {
/* Handle localy since we are able to */
fd_hook_call(HOOK_MESSAGE_ROUTING_LOCAL, msgptr, NULL, NULL, fd_msg_pmdl_get(msgptr));
CHECK_FCT(fd_fifo_post(fd_g_local, &msgptr) );
return 0;
}
if (fd_g_config->cnf_flags.no_fwd) {
/* We return an error */
fd_hook_call(HOOK_MESSAGE_ROUTING_ERROR, msgptr, NULL, "Application unsupported", fd_msg_pmdl_get(msgptr));
CHECK_FCT( return_error( &msgptr, "DIAMETER_APPLICATION_UNSUPPORTED", NULL, NULL) );
return 0;
}
}
/* From that point, for requests, we will call the registered callbacks, then forward to another peer */
} else {
/* The message is an answer */
struct msg * qry;
/* Retrieve the corresponding query and its origin */
CHECK_FCT( fd_msg_answ_getq( msgptr, &qry ) );
CHECK_FCT( fd_msg_source_get( qry, &qry_src, NULL ) );
if ((!qry_src) && (!is_err)) {
/* The message is a normal answer to a request issued localy, we do not call the callbacks chain on it. */
fd_hook_call(HOOK_MESSAGE_ROUTING_LOCAL, msgptr, NULL, NULL, fd_msg_pmdl_get(msgptr));
CHECK_FCT(fd_fifo_post(fd_g_local, &msgptr) );
return 0;
}
/* From that point, for answers, we will call the registered callbacks, then pass it to the dispatch module or forward it */
}
/* Call all registered callbacks for this message */
{
struct fd_list * li;
CHECK_FCT( pthread_rwlock_rdlock( &rt_fwd_lock ) );
pthread_cleanup_push( fd_cleanup_rwlock, &rt_fwd_lock );
/* requests: dir = 1 & 2 => in order; answers = 3 & 2 => in reverse order */
for ( li = (is_req ? rt_fwd_list.next : rt_fwd_list.prev) ; msgptr && (li != &rt_fwd_list) ; li = (is_req ? li->next : li->prev) ) {
struct rt_hdl * rh = (struct rt_hdl *)li;
int ret;
if (is_req && (rh->dir > RT_FWD_ALL))
break;
if ((!is_req) && (rh->dir < RT_FWD_ALL))
break;
/* Ok, call this cb */
TRACE_DEBUG(ANNOYING, "Calling next FWD callback on %p : %p", msgptr, rh->rt_fwd_cb);
CHECK_FCT_DO( ret = (*rh->rt_fwd_cb)(rh->cbdata, &msgptr),
{
char buf[256];
snprintf(buf, sizeof(buf), "A FWD routing callback returned an error: %s", strerror(ret));
fd_hook_call(HOOK_MESSAGE_ROUTING_ERROR, msgptr, NULL, buf, fd_msg_pmdl_get(msgptr));
fd_hook_call(HOOK_MESSAGE_DROPPED, msgptr, NULL, buf, fd_msg_pmdl_get(msgptr));
fd_msg_free(msgptr);
msgptr = NULL;
break;
} );
}
pthread_cleanup_pop(0);
CHECK_FCT( pthread_rwlock_unlock( &rt_fwd_lock ) );
/* If a callback has handled the message, we stop now */
if (!msgptr)
return 0;
}
/* Now pass the message to the next step: either forward to another peer, or dispatch to local extensions */
if (is_req || qry_src) {
fd_hook_call(HOOK_MESSAGE_ROUTING_FORWARD, msgptr, NULL, NULL, fd_msg_pmdl_get(msgptr));
CHECK_FCT(fd_fifo_post(fd_g_outgoing, &msgptr) );
} else {
fd_hook_call(HOOK_MESSAGE_ROUTING_LOCAL, msgptr, NULL, NULL, fd_msg_pmdl_get(msgptr));
CHECK_FCT(fd_fifo_post(fd_g_local, &msgptr) );
}
/* We're done with this message */
return 0;
}
/* The ROUTING-OUT message processing */
static int msg_rt_out(struct msg * msg)
{
struct rt_data * rtd = NULL;
struct msg_hdr * hdr;
int is_req = 0;
int ret;
struct fd_list * li, *candidates;
struct avp * avp;
struct rtd_candidate * c;
struct msg *msgptr = msg;
DiamId_t qry_src = NULL;
size_t qry_src_len = 0;
/* Read the message header */
CHECK_FCT( fd_msg_hdr(msgptr, &hdr) );
is_req = hdr->msg_flags & CMD_FLAG_REQUEST;
/* For answers, the routing is very easy */
if ( ! is_req ) {
struct msg * qry;
struct msg_hdr * qry_hdr;
struct fd_peer * peer = NULL;
/* Retrieve the corresponding query and its origin */
CHECK_FCT( fd_msg_answ_getq( msgptr, &qry ) );
CHECK_FCT( fd_msg_source_get( qry, &qry_src, &qry_src_len ) );
ASSERT( qry_src ); /* if it is NULL, the message should have been in the LOCAL queue! */
/* Find the peer corresponding to this name */
CHECK_FCT( fd_peer_getbyid( qry_src, qry_src_len, 0, (void *) &peer ) );
if (fd_peer_getstate(peer) != STATE_OPEN && fd_peer_getstate(peer) != STATE_CLOSING_GRACE) {
char buf[128];
snprintf(buf, sizeof(buf), "Unable to forward answer to deleted / closed peer '%s'.", qry_src);
fd_hook_call(HOOK_MESSAGE_ROUTING_ERROR, msgptr, NULL, buf, fd_msg_pmdl_get(msgptr));
fd_hook_call(HOOK_MESSAGE_DROPPED, msgptr, NULL, buf, fd_msg_pmdl_get(msgptr));
fd_msg_free(msgptr);
return 0;
}
/* We must restore the hop-by-hop id */
CHECK_FCT( fd_msg_hdr(qry, &qry_hdr) );
hdr->msg_hbhid = qry_hdr->msg_hbhid;
/* Push the message into this peer */
CHECK_FCT( fd_out_send(&msgptr, NULL, peer, 1) );
/* We're done with this answer */
return 0;
}
/* From that point, the message is a request */
CHECK_FCT( fd_msg_source_get( msgptr, &qry_src, &qry_src_len ) );
/* if qry_src != NULL, this message is relayed, otherwise it is locally issued */
/* Get the routing data out of the message if any (in case of re-transmit) */
CHECK_FCT( fd_msg_rt_get ( msgptr, &rtd ) );
/* If there is no routing data already, let's create it */
if (rtd == NULL) {
CHECK_FCT( fd_rtd_init(&rtd) );
/* Add all peers currently in OPEN state */
CHECK_FCT( pthread_rwlock_rdlock(&fd_g_activ_peers_rw) );
for (li = fd_g_activ_peers.next; li != &fd_g_activ_peers; li = li->next) {
struct fd_peer * p = (struct fd_peer *)li->o;
CHECK_FCT_DO( ret = fd_rtd_candidate_add(rtd,
p->p_hdr.info.pi_diamid,
p->p_hdr.info.pi_diamidlen,
p->p_hdr.info.runtime.pir_realm,
p->p_hdr.info.runtime.pir_realmlen),
{ CHECK_FCT_DO( pthread_rwlock_unlock(&fd_g_activ_peers_rw), ); return ret; } );
}
CHECK_FCT( pthread_rwlock_unlock(&fd_g_activ_peers_rw) );
/* Now let's remove all peers from the Route-Records */
CHECK_FCT( fd_msg_browse(msgptr, MSG_BRW_FIRST_CHILD, &avp, NULL) );
while (avp) {
struct avp_hdr * ahdr;
struct fd_pei error_info;
CHECK_FCT( fd_msg_avp_hdr( avp, &ahdr ) );
if ((ahdr->avp_code == AC_ROUTE_RECORD) && (! (ahdr->avp_flags & AVP_FLAG_VENDOR)) ) {
/* Parse this AVP */
CHECK_FCT_DO( ret = fd_msg_parse_dict ( avp, fd_g_config->cnf_dict, &error_info ),
{
if (error_info.pei_errcode) {
CHECK_FCT( return_error( &msgptr, error_info.pei_errcode, error_info.pei_message, error_info.pei_avp) );
if (error_info.pei_avp_free) { fd_msg_free(error_info.pei_avp); }
return 0;
} else {
return ret;
}
} );
ASSERT( ahdr->avp_value );
/* Remove this value from the list. We don't need to pay special attention to the contents here. */
fd_rtd_candidate_del(rtd, ahdr->avp_value->os.data, ahdr->avp_value->os.len);
}
/* Go to next AVP */
CHECK_FCT( fd_msg_browse(avp, MSG_BRW_NEXT, &avp, NULL) );
}
/* Save the routing information in the message */
CHECK_FCT( fd_msg_rt_associate ( msgptr, rtd ) );
}
/* Note: we reset the scores and pass the message to the callbacks, maybe we could re-use the saved scores when we have received an error ? -- TODO */
/* Ok, we have our list in rtd now, let's (re)initialize the scores */
fd_rtd_candidate_extract(rtd, &candidates, FD_SCORE_INI);
/* Pass the list to registered callbacks (even if it is empty list) */
{
CHECK_FCT( pthread_rwlock_rdlock( &rt_out_lock ) );
pthread_cleanup_push( fd_cleanup_rwlock, &rt_out_lock );
/* We call the cb by reverse priority order */
for ( li = rt_out_list.prev ; (msgptr != NULL) && (li != &rt_out_list) ; li = li->prev ) {
struct rt_hdl * rh = (struct rt_hdl *)li;
TRACE_DEBUG(ANNOYING, "Calling next OUT callback on %p : %p (prio %d)", msgptr, rh->rt_out_cb, rh->prio);
CHECK_FCT_DO( ret = (*rh->rt_out_cb)(rh->cbdata, &msgptr, candidates),
{
char buf[256];
snprintf(buf, sizeof(buf), "An OUT routing callback returned an error: %s", strerror(ret));
fd_hook_call(HOOK_MESSAGE_ROUTING_ERROR, msgptr, NULL, buf, fd_msg_pmdl_get(msgptr));
fd_hook_call(HOOK_MESSAGE_DROPPED, msgptr, NULL, buf, fd_msg_pmdl_get(msgptr));
fd_msg_free(msgptr);
msgptr = NULL;
} );
}
pthread_cleanup_pop(0);
CHECK_FCT( pthread_rwlock_unlock( &rt_out_lock ) );
/* If an error occurred or the callback disposed of the message, go to next message */
if (! msgptr) {
return 0;
}
}
/* Order the candidate peers by score attributed by the callbacks */
CHECK_FCT( fd_rtd_candidate_reorder(candidates) );
/* Now try sending the message */
for (li = candidates->prev; li != candidates; li = li->prev) {
struct fd_peer * peer;
c = (struct rtd_candidate *) li;
/* Stop when we have reached the end of valid candidates */
if (c->score < 0)
break;
/* Search for the peer */
CHECK_FCT( fd_peer_getbyid( c->diamid, c->diamidlen, 0, (void *)&peer ) );
if (fd_peer_getstate(peer) == STATE_OPEN) {
/* Send to this one */
CHECK_FCT_DO( fd_out_send(&msgptr, NULL, peer, 1), continue );
/* If the sending was successful */
break;
}
}
/* If the message has not been sent, return an error */
if (msgptr) {
fd_hook_call(HOOK_MESSAGE_ROUTING_ERROR, msgptr, NULL, "No remaining suitable candidate to route the message to", fd_msg_pmdl_get(msgptr));
return_error( &msgptr, "DIAMETER_UNABLE_TO_DELIVER", "No suitable candidate to route the message to", NULL);
}
/* We're done with this message */
return 0;
}
/********************************************************************************/
/* Management of the threads */
/********************************************************************************/
/* Note: in the first version, we only create one thread of each kind.
We could improve the scalability by using the threshold feature of the queues
to create additional threads if a queue is filling up, or at least giving a configurable
number of threads of each kind.
*/
/* Control of the threads */
static enum { RUN = 0, STOP = 1 } order_val = RUN;
static pthread_mutex_t order_state_lock = PTHREAD_MUTEX_INITIALIZER;
/* Threads report their status */
enum thread_state { NOTRUNNING = 0, RUNNING = 1 };
static void cleanup_state(void * state_loc)
{
CHECK_POSIX_DO( pthread_mutex_lock(&order_state_lock), );
*(enum thread_state *)state_loc = NOTRUNNING;
CHECK_POSIX_DO( pthread_mutex_unlock(&order_state_lock), );
}
/* This is the common thread code (same for routing and dispatching) */
static void * process_thr(void * arg, int (*action_cb)(struct msg * msg), struct fifo * queue, char * action_name)
{
TRACE_ENTRY("%p %p %p %p", arg, action_cb, queue, action_name);
/* Set the thread name */
{
char buf[48];
snprintf(buf, sizeof(buf), "%s (%p)", action_name, arg);
fd_log_threadname ( buf );
}
/* The thread reports its status when canceled */
CHECK_PARAMS_DO(arg, return NULL);
pthread_cleanup_push( cleanup_state, arg );
/* Mark the thread running */
CHECK_POSIX_DO( pthread_mutex_lock(&order_state_lock), );
*(enum thread_state *)arg = RUNNING;
CHECK_POSIX_DO( pthread_mutex_unlock(&order_state_lock), );
do {
struct msg * msg;
/* Test the current order */
{
int must_stop;
CHECK_POSIX_DO( pthread_mutex_lock(&order_state_lock), { ASSERT(0); } ); /* we lock to flush the caches */
must_stop = (order_val == STOP);
CHECK_POSIX_DO( pthread_mutex_unlock(&order_state_lock), { ASSERT(0); } );
if (must_stop)
goto end;
pthread_testcancel();
}
/* Ok, we are allowed to run */
/* Get the next message from the queue */
{
int ret;
struct timespec ts;
CHECK_SYS_DO( clock_gettime(CLOCK_REALTIME, &ts), goto fatal_error );
ts.tv_sec += 1;
ret = fd_fifo_timedget ( queue, &msg, &ts );
if (ret == ETIMEDOUT)
/* loop, check if the thread must stop now */
continue;
if (ret == EPIPE)
/* The queue was destroyed, we are probably exiting */
goto end;
/* check if another error occurred */
CHECK_FCT_DO( ret, goto fatal_error );
}
LOG_A("%s: Picked next message", action_name);
/* Now process the message */
CHECK_FCT_DO( (*action_cb)(msg), goto fatal_error);
/* We're done with this message */
} while (1);
fatal_error:
TRACE_DEBUG(INFO, "An unrecoverable error occurred, %s thread is terminating...", action_name);
CHECK_FCT_DO(fd_core_shutdown(), );
end:
; /* noop so that we get rid of "label at end of compund statement" warning */
/* Mark the thread as terminated */
pthread_cleanup_pop(1);
return NULL;
}
/* The dispatch thread */
static void * dispatch_thr(void * arg)
{
return process_thr(arg, msg_dispatch, fd_g_local, "Dispatch");
}
/* The (routing-in) thread -- see description in freeDiameter.h */
static void * routing_in_thr(void * arg)
{
return process_thr(arg, msg_rt_in, fd_g_incoming, "Routing-IN");
}
/* The (routing-out) thread -- see description in freeDiameter.h */
static void * routing_out_thr(void * arg)
{
return process_thr(arg, msg_rt_out, fd_g_outgoing, "Routing-OUT");
}
/********************************************************************************/
/* The functions for the other files */
/********************************************************************************/
static pthread_t * dispatch = NULL;
static enum thread_state * disp_state = NULL;
/* Later: make this more dynamic */
static pthread_t rt_out = (pthread_t)NULL;
static enum thread_state out_state = NOTRUNNING;
static pthread_t rt_in = (pthread_t)NULL;
static enum thread_state in_state = NOTRUNNING;
/* Initialize the routing and dispatch threads */
int fd_rtdisp_init(void)
{
int i;
/* Prepare the array for dispatch */
CHECK_MALLOC( disp_state = calloc(fd_g_config->cnf_dispthr, sizeof(enum thread_state)) );
CHECK_MALLOC( dispatch = calloc(fd_g_config->cnf_dispthr, sizeof(pthread_t)) );
/* Create the threads */
for (i=0; i < fd_g_config->cnf_dispthr; i++) {
CHECK_POSIX( pthread_create( &dispatch[i], NULL, dispatch_thr, &disp_state[i] ) );
}
CHECK_POSIX( pthread_create( &rt_out, NULL, routing_out_thr, &out_state) );
CHECK_POSIX( pthread_create( &rt_in, NULL, routing_in_thr, &in_state) );
/* Later: TODO("Set the thresholds for the queues to create more threads as needed"); */
/* Register the built-in callbacks */
CHECK_FCT( fd_rt_out_register( dont_send_if_no_common_app, NULL, 10, NULL ) );
CHECK_FCT( fd_rt_out_register( score_destination_avp, NULL, 10, NULL ) );
return 0;
}
/* Ask the thread to terminate after next iteration */
int fd_rtdisp_cleanstop(void)
{
CHECK_POSIX_DO( pthread_mutex_lock(&order_state_lock), );
order_val = STOP;
CHECK_POSIX_DO( pthread_mutex_unlock(&order_state_lock), );
return 0;
}
static void stop_thread_delayed(enum thread_state *st, pthread_t * thr, char * th_name)
{
TRACE_ENTRY("%p %p", st, thr);
CHECK_PARAMS_DO(st && thr, return);
int terminated;
CHECK_POSIX_DO( pthread_mutex_lock(&order_state_lock), );
terminated = (*st == NOTRUNNING);
CHECK_POSIX_DO( pthread_mutex_unlock(&order_state_lock), );
/* Wait for a second for the thread to complete, by monitoring my_state */
if (!terminated) {
TRACE_DEBUG(INFO, "Waiting for the %s thread to have a chance to terminate", th_name);
do {
struct timespec ts, ts_final;
CHECK_SYS_DO( clock_gettime(CLOCK_REALTIME, &ts), break );
ts_final.tv_sec = ts.tv_sec + 1;
ts_final.tv_nsec = ts.tv_nsec;
while (TS_IS_INFERIOR( &ts, &ts_final )) {
CHECK_POSIX_DO( pthread_mutex_lock(&order_state_lock), );
terminated = (*st == NOTRUNNING);
CHECK_POSIX_DO( pthread_mutex_unlock(&order_state_lock), );
if (terminated)
break;
usleep(100000);
CHECK_SYS_DO( clock_gettime(CLOCK_REALTIME, &ts), break );
}
} while (0);
}
/* Now stop the thread and reclaim its resources */
CHECK_FCT_DO( fd_thr_term(thr ), /* continue */);
}
/* Stop the thread after up to one second of wait */
int fd_rtdisp_fini(void)
{
int i;
/* Destroy the incoming queue */
CHECK_FCT_DO( fd_queues_fini(&fd_g_incoming), /* ignore */);
/* Stop the routing IN thread */
stop_thread_delayed(&in_state, &rt_in, "IN routing");
/* Destroy the outgoing queue */
CHECK_FCT_DO( fd_queues_fini(&fd_g_outgoing), /* ignore */);
/* Stop the routing OUT thread */
stop_thread_delayed(&out_state, &rt_out, "OUT routing");
/* Destroy the local queue */
CHECK_FCT_DO( fd_queues_fini(&fd_g_local), /* ignore */);
/* Stop the Dispatch threads */
if (dispatch != NULL) {
for (i=0; i < fd_g_config->cnf_dispthr; i++) {
stop_thread_delayed(&disp_state[i], &dispatch[i], "Dispatching");
}
free(dispatch);
dispatch = NULL;
}
if (disp_state != NULL) {
free(disp_state);
disp_state = NULL;
}
return 0;
}
/* Cleanup handlers */
int fd_rtdisp_cleanup(void)
{
/* Cleanup all remaining handlers */
while (!FD_IS_LIST_EMPTY(&rt_fwd_list)) {
CHECK_FCT_DO( fd_rt_fwd_unregister ( (void *)rt_fwd_list.next, NULL ), /* continue */ );
}
while (!FD_IS_LIST_EMPTY(&rt_out_list)) {
CHECK_FCT_DO( fd_rt_out_unregister ( (void *)rt_out_list.next, NULL ), /* continue */ );
}
fd_disp_unregister_all(); /* destroy remaining handlers */
return 0;
}
/********************************************************************************/
/* For extensions to register a new appl */
/********************************************************************************/
/* Add an application into the peer's supported apps */
int fd_disp_app_support ( struct dict_object * app, struct dict_object * vendor, int auth, int acct )
{
application_id_t aid = 0;
vendor_id_t vid = 0;
TRACE_ENTRY("%p %p %d %d", app, vendor, auth, acct);
CHECK_PARAMS( app && (auth || acct) );
{
enum dict_object_type type = 0;
struct dict_application_data data;
CHECK_FCT( fd_dict_gettype(app, &type) );
CHECK_PARAMS( type == DICT_APPLICATION );
CHECK_FCT( fd_dict_getval(app, &data) );
aid = data.application_id;
}
if (vendor) {
enum dict_object_type type = 0;
struct dict_vendor_data data;
CHECK_FCT( fd_dict_gettype(vendor, &type) );
CHECK_PARAMS( type == DICT_VENDOR );
CHECK_FCT( fd_dict_getval(vendor, &data) );
vid = data.vendor_id;
}
return fd_app_merge(&fd_g_config->cnf_apps, aid, vid, auth, acct);
}