/* conn.c - handles connections to remote targets */
/* $OpenLDAP$ */
/* This work is part of OpenLDAP Software .
*
* Copyright 2016-2024 The OpenLDAP Foundation.
* Portions Copyright 2016 Symas Corporation.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted only as authorized by the OpenLDAP
* Public License.
*
* A copy of this license is available in the file LICENSE in the
* top-level directory of the distribution or, alternatively, at
* .
*/
/* ACKNOWLEDGEMENTS:
+ * This work was developed by Symas Corporation
+ * based on back-meta module for inclusion in OpenLDAP Software.
+ * This work was sponsored by Ericsson. */
#include "portable.h"
#include
#include
#include
#include
#include "slap.h"
#include "../../../libraries/libldap/ldap-int.h"
#include "../back-ldap/back-ldap.h"
#include "back-asyncmeta.h"
/*
* asyncmeta_conn_alloc
*
* Allocates a connection structure, making room for all the referenced targets
*/
static a_metaconn_t *
asyncmeta_conn_alloc(
a_metainfo_t *mi)
{
a_metaconn_t *mc;
int ntargets = mi->mi_ntargets;
assert( ntargets > 0 );
/* malloc all in one */
mc = ( a_metaconn_t * )ch_calloc( 1, sizeof( a_metaconn_t ) + ntargets * sizeof( a_metasingleconn_t ));
if ( mc == NULL ) {
return NULL;
}
mc->mc_info = mi;
ldap_pvt_thread_mutex_init( &mc->mc_om_mutex);
mc->mc_authz_target = META_BOUND_NONE;
mc->mc_conns = (a_metasingleconn_t *)(mc+1);
return mc;
}
/*
* asyncmeta_init_one_conn
*
* Initializes one connection
*/
int
asyncmeta_init_one_conn(
Operation *op,
SlapReply *rs,
a_metaconn_t *mc,
int candidate,
int ispriv,
ldap_back_send_t sendok,
int dolock)
{
a_metainfo_t *mi = mc->mc_info;
a_metatarget_t *mt = mi->mi_targets[ candidate ];
a_metasingleconn_t *msc = NULL;
int version;
a_dncookie dc;
int isauthz = ( candidate == mc->mc_authz_target );
int do_return = 0;
#ifdef HAVE_TLS
int is_ldaps = 0;
int do_start_tls = 0;
#endif /* HAVE_TLS */
/* if the server is quarantined, and
* - the current interval did not expire yet, or
* - no more retries should occur,
* don't return the connection */
if ( mt->mt_isquarantined ) {
slap_retry_info_t *ri = &mt->mt_quarantine;
int dont_retry = 0;
if ( mt->mt_quarantine.ri_interval ) {
ldap_pvt_thread_mutex_lock( &mt->mt_quarantine_mutex );
dont_retry = ( mt->mt_isquarantined > LDAP_BACK_FQ_NO );
if ( dont_retry ) {
dont_retry = ( ri->ri_num[ ri->ri_idx ] == SLAP_RETRYNUM_TAIL
|| slap_get_time() < ri->ri_last + ri->ri_interval[ ri->ri_idx ] );
if ( !dont_retry ) {
Debug(LDAP_DEBUG_ANY,
"%s asyncmeta_init_one_conn[%d]: quarantine " "retry block #%d try #%d.\n",
op->o_log_prefix,
candidate, ri->ri_idx,
ri->ri_count );
mt->mt_isquarantined = LDAP_BACK_FQ_RETRYING;
}
}
ldap_pvt_thread_mutex_unlock( &mt->mt_quarantine_mutex );
}
if ( dont_retry ) {
rs->sr_err = LDAP_UNAVAILABLE;
rs->sr_text = "Target is quarantined";
Debug( LDAP_DEBUG_ANY, "%s asyncmeta_init_one_conn: Target is quarantined\n",
op->o_log_prefix );
if ( op->o_conn && ( sendok & LDAP_BACK_SENDERR ) ) {
send_ldap_result( op, rs );
}
return rs->sr_err;
}
}
msc = &mc->mc_conns[candidate];
/*
* Already init'ed
*/
if ( LDAP_BACK_CONN_ISBOUND( msc )
|| LDAP_BACK_CONN_ISANON( msc ) )
{
assert( msc->msc_ld != NULL );
rs->sr_err = LDAP_SUCCESS;
do_return = 1;
} else if ( META_BACK_CONN_CREATING( msc )
|| LDAP_BACK_CONN_BINDING( msc ) )
{
rs->sr_err = LDAP_SUCCESS;
do_return = 1;
} else if ( META_BACK_CONN_INITED( msc ) ) {
assert( msc->msc_ld != NULL );
rs->sr_err = LDAP_SUCCESS;
do_return = 1;
} else {
/*
* creating...
*/
META_BACK_CONN_CREATING_SET( msc );
}
if ( do_return ) {
if ( rs->sr_err != LDAP_SUCCESS
&& op->o_conn
&& ( sendok & LDAP_BACK_SENDERR ) )
{
send_ldap_result( op, rs );
}
return rs->sr_err;
}
assert( msc->msc_ld == NULL );
/*
* Attempts to initialize the connection to the target ds
*/
ldap_pvt_thread_mutex_lock( &mt->mt_uri_mutex );
rs->sr_err = ldap_initialize( &msc->msc_ld, mt->mt_uri );
#ifdef HAVE_TLS
is_ldaps = ldap_is_ldaps_url( mt->mt_uri );
#endif /* HAVE_TLS */
ldap_pvt_thread_mutex_unlock( &mt->mt_uri_mutex );
if ( rs->sr_err != LDAP_SUCCESS ) {
Debug( LDAP_DEBUG_ANY, "%s asyncmeta_init_one_conn: ldap_initialize failed err=%d\n",
op->o_log_prefix, rs->sr_err );
goto error_return;
}
ldap_set_option( msc->msc_ld, LDAP_OPT_KEEPCONN, LDAP_OPT_ON);
msc->msc_ldr = ldap_dup(msc->msc_ld);
if (!msc->msc_ldr) {
ldap_ld_free(msc->msc_ld, 0, NULL, NULL);
rs->sr_err = LDAP_NO_MEMORY;
goto error_return;
}
/*
* Set LDAP version. This will always succeed: If the client
* bound with a particular version, then so can we.
*/
if ( mt->mt_version != 0 ) {
version = mt->mt_version;
} else if ( op->o_conn->c_protocol != 0 ) {
version = op->o_conn->c_protocol;
} else {
version = LDAP_VERSION3;
}
ldap_set_option( msc->msc_ld, LDAP_OPT_PROTOCOL_VERSION, &version );
ldap_set_urllist_proc( msc->msc_ld, mt->mt_urllist_f, mt->mt_urllist_p );
/* automatically chase referrals ("chase-referrals [{yes|no}]" statement) */
ldap_set_option( msc->msc_ld, LDAP_OPT_REFERRALS,
META_BACK_TGT_CHASE_REFERRALS( mt ) ? LDAP_OPT_ON : LDAP_OPT_OFF );
slap_client_keepalive(msc->msc_ld, &mt->mt_tls.sb_keepalive);
if ( mt->mt_tls.sb_tcp_user_timeout > 0 ) {
ldap_set_option( msc->msc_ld, LDAP_OPT_TCP_USER_TIMEOUT,
&mt->mt_tls.sb_tcp_user_timeout );
}
#ifdef HAVE_TLS
{
slap_bindconf *sb = NULL;
if ( ispriv ) {
sb = &mt->mt_idassert.si_bc;
} else {
sb = &mt->mt_tls;
}
bindconf_tls_set( sb, msc->msc_ld );
if ( !is_ldaps ) {
if ( META_BACK_TGT_USE_TLS( mt )
|| ( op->o_conn->c_is_tls && META_BACK_TGT_PROPAGATE_TLS( mt ) ) )
{
do_start_tls = 1;
}
}
}
/* start TLS ("tls [try-]{start|propagate}" statement) */
if ( do_start_tls ) {
#ifdef SLAP_STARTTLS_ASYNCHRONOUS
/*
* use asynchronous StartTLS; in case, chase referral
* FIXME: OpenLDAP does not return referral on StartTLS yet
*/
int msgid;
rs->sr_err = ldap_start_tls( msc->msc_ld, NULL, NULL, &msgid );
if ( rs->sr_err == LDAP_SUCCESS ) {
LDAPMessage *res = NULL;
int rc, nretries = mt->mt_nretries;
struct timeval tv;
LDAP_BACK_TV_SET( &tv );
retry:;
rc = ldap_result( msc->msc_ld, msgid, LDAP_MSG_ALL, &tv, &res );
switch ( rc ) {
case -1:
rs->sr_err = LDAP_OTHER;
break;
case 0:
if ( nretries != 0 ) {
if ( nretries > 0 ) {
nretries--;
}
LDAP_BACK_TV_SET( &tv );
goto retry;
}
rs->sr_err = LDAP_OTHER;
break;
default:
/* only touch when activity actually took place... */
if ( mi->mi_idle_timeout != 0 ) {
asyncmeta_set_msc_time(msc);
}
break;
}
if ( rc == LDAP_RES_EXTENDED ) {
struct berval *data = NULL;
/* NOTE: right now, data is unused, so don't get it */
rs->sr_err = ldap_parse_extended_result( msc->msc_ld,
res, NULL, NULL /* &data */ , 0 );
if ( rs->sr_err == LDAP_SUCCESS ) {
int err;
/* FIXME: matched? referrals? response controls? */
rs->sr_err = ldap_parse_result( msc->msc_ld,
res, &err, NULL, NULL, NULL, NULL, 1 );
res = NULL;
if ( rs->sr_err == LDAP_SUCCESS ) {
rs->sr_err = err;
}
rs->sr_err = slap_map_api2result( rs );
/* FIXME: in case a referral
* is returned, should we try
* using it instead of the
* configured URI? */
if ( rs->sr_err == LDAP_SUCCESS ) {
rs->sr_err = ldap_install_tls( msc->msc_ld );
} else if ( rs->sr_err == LDAP_REFERRAL ) {
/* FIXME: LDAP_OPERATIONS_ERROR? */
rs->sr_err = LDAP_OTHER;
rs->sr_text = "Unwilling to chase referral "
"returned by Start TLS exop";
}
if ( data ) {
ber_bvfree( data );
}
}
} else {
rs->sr_err = LDAP_OTHER;
}
if ( res != NULL ) {
ldap_msgfree( res );
}
}
#else /* ! SLAP_STARTTLS_ASYNCHRONOUS */
/*
* use synchronous StartTLS
*/
rs->sr_err = ldap_start_tls_s( msc->msc_ld, NULL, NULL );
#endif /* ! SLAP_STARTTLS_ASYNCHRONOUS */
if (rs->sr_err != LDAP_SUCCESS) {
Debug( LDAP_DEBUG_ANY, "%s asyncmeta_init_one_conn: ldap_start_tls_s failed err=%d\n",
op->o_log_prefix, rs->sr_err );
}
/* if StartTLS is requested, only attempt it if the URL
* is not "ldaps://"; this may occur not only in case
* of misconfiguration, but also when used in the chain
* overlay, where the "uri" can be parsed out of a referral */
if ( rs->sr_err == LDAP_SERVER_DOWN
|| ( rs->sr_err != LDAP_SUCCESS
&& META_BACK_TGT_TLS_CRITICAL( mt ) ) )
{
#ifdef DEBUG_205
Debug( LDAP_DEBUG_ANY,
"### %s asyncmeta_init_one_conn(TLS) "
"ldap_unbind_ext[%d] ld=%p\n",
op->o_log_prefix, candidate,
(void *)msc->msc_ld );
#endif /* DEBUG_205 */
/* need to trash a failed Start TLS */
asyncmeta_clear_one_msc( op, mc, candidate, 1, __FUNCTION__ );
goto error_return;
}
}
#endif /* HAVE_TLS */
/*
* Set the network timeout if set
*/
if ( mt->mt_network_timeout != 0 ) {
struct timeval network_timeout;
network_timeout.tv_sec = 0;
network_timeout.tv_usec = mt->mt_network_timeout*1000;
ldap_set_option( msc->msc_ld, LDAP_OPT_NETWORK_TIMEOUT,
(void *)&network_timeout );
}
/*
* If the connection DN is not null, an attempt to rewrite it is made
*/
if ( ispriv ) {
if ( !BER_BVISNULL( &mt->mt_idassert_authcDN ) ) {
ber_bvreplace( &msc->msc_bound_ndn, &mt->mt_idassert_authcDN );
if ( !BER_BVISNULL( &mt->mt_idassert_passwd ) ) {
if ( !BER_BVISNULL( &msc->msc_cred ) ) {
memset( msc->msc_cred.bv_val, 0,
msc->msc_cred.bv_len );
}
ber_bvreplace( &msc->msc_cred, &mt->mt_idassert_passwd );
}
LDAP_BACK_CONN_ISIDASSERT_SET( msc );
} else {
ber_bvreplace( &msc->msc_bound_ndn, &slap_empty_bv );
}
} else {
if ( !BER_BVISNULL( &msc->msc_cred ) ) {
memset( msc->msc_cred.bv_val, 0, msc->msc_cred.bv_len );
ber_memfree_x( msc->msc_cred.bv_val, NULL );
BER_BVZERO( &msc->msc_cred );
}
if ( !BER_BVISNULL( &msc->msc_bound_ndn ) ) {
ber_memfree_x( msc->msc_bound_ndn.bv_val, NULL );
BER_BVZERO( &msc->msc_bound_ndn );
}
if ( !BER_BVISEMPTY( &op->o_ndn )
&& isauthz )
{
dc.op = op;
dc.target = mt;
dc.memctx = NULL;
dc.to_from = MASSAGE_REQ;
/*
* Rewrite the bind dn if needed
*/
asyncmeta_dn_massage( &dc, &op->o_conn->c_dn, &msc->msc_bound_ndn );
/* copy the DN if needed */
if ( msc->msc_bound_ndn.bv_val == op->o_conn->c_dn.bv_val ) {
ber_dupbv( &msc->msc_bound_ndn, &op->o_conn->c_dn );
}
} else {
ber_dupbv( &msc->msc_bound_ndn, (struct berval *)&slap_empty_bv );
}
}
assert( !BER_BVISNULL( &msc->msc_bound_ndn ) );
error_return:;
if (msc != NULL) {
META_BACK_CONN_CREATING_CLEAR( msc );
}
if ( rs->sr_err == LDAP_SUCCESS && msc != NULL) {
META_BACK_CONN_INITED_SET( msc );
}
if ( rs->sr_err != LDAP_SUCCESS ) {
rs->sr_err = slap_map_api2result( rs );
if ( sendok & LDAP_BACK_SENDERR ) {
send_ldap_result( op, rs );
}
}
return rs->sr_err;
}
static int
asyncmeta_get_candidate(
Operation *op,
SlapReply *rs,
struct berval *ndn )
{
a_metainfo_t *mi = ( a_metainfo_t * )op->o_bd->be_private;
long candidate;
/*
* tries to get a unique candidate
* (takes care of default target)
*/
candidate = asyncmeta_select_unique_candidate( mi, ndn );
/*
* if any is found, inits the connection
*/
if ( candidate == META_TARGET_NONE ) {
rs->sr_err = LDAP_NO_SUCH_OBJECT;
rs->sr_text = "No suitable candidate target found";
} else {
rs->sr_err = LDAP_SUCCESS;
}
return candidate;
}
/*
* asyncmeta_getconn
*
* Prepares the connection structure
*
* RATIONALE:
*
* - determine what DN is being requested:
*
* op requires candidate checks
*
* add unique parent of o_req_ndn
* bind unique^*[/all] o_req_ndn [no check]
* compare unique^+ o_req_ndn
* delete unique o_req_ndn
* modify unique o_req_ndn
* search any o_req_ndn
* modrdn unique[, unique] o_req_ndn[, orr_nnewSup]
*
* - for ops that require the candidate to be unique, in case of multiple
* occurrences an internal search with sizeLimit=1 is performed
* if a unique candidate can actually be determined. If none is found,
* the operation aborts; if multiple are found, the default target
* is used if defined and candidate; otherwise the operation aborts.
*
* *^note: actually, the bind operation is handled much like a search;
* i.e. the bind is broadcast to all candidate targets.
*
* +^note: actually, the compare operation is handled much like a search;
* i.e. the compare is broadcast to all candidate targets, while checking
* that exactly none (noSuchObject) or one (TRUE/FALSE/UNDEFINED) is
* returned.
*/
a_metaconn_t *
asyncmeta_getconn(
Operation *op,
SlapReply *rs,
SlapReply *candidates,
int *candidate,
ldap_back_send_t sendok,
int alloc_new)
{
a_metainfo_t *mi = ( a_metainfo_t * )op->o_bd->be_private;
a_metaconn_t *mc = NULL,
mc_curr = {{ 0 }};
int cached = META_TARGET_NONE,
i = META_TARGET_NONE,
err = LDAP_SUCCESS,
new_conn = 0,
ncandidates = 0;
meta_op_type op_type = META_OP_REQUIRE_SINGLE;
enum {
META_DNTYPE_ENTRY,
META_DNTYPE_PARENT,
META_DNTYPE_NEWPARENT
} dn_type = META_DNTYPE_ENTRY;
struct berval ndn = op->o_req_ndn,
pndn;
if (alloc_new > 0) {
mc = asyncmeta_conn_alloc(mi);
new_conn = 0;
} else {
mc = asyncmeta_get_next_mc(mi);
}
ldap_pvt_thread_mutex_lock(&mc->mc_om_mutex);
/* Internal searches are privileged and shared. So is root. */
if ( ( !BER_BVISEMPTY( &op->o_ndn ) && META_BACK_PROXYAUTHZ_ALWAYS( mi ) )
|| ( BER_BVISEMPTY( &op->o_ndn ) && META_BACK_PROXYAUTHZ_ANON( mi ) )
|| op->o_do_not_cache || be_isroot( op ) )
{
LDAP_BACK_CONN_ISPRIV_SET( &mc_curr );
LDAP_BACK_PCONN_ROOTDN_SET( &mc_curr, op );
} else if ( BER_BVISEMPTY( &op->o_ndn ) && META_BACK_PROXYAUTHZ_NOANON( mi ) )
{
LDAP_BACK_CONN_ISANON_SET( &mc_curr );
LDAP_BACK_PCONN_ANON_SET( &mc_curr, op );
} else {
/* Explicit binds must not be shared */
if ( !BER_BVISEMPTY( &op->o_ndn )
|| op->o_tag == LDAP_REQ_BIND
|| SLAP_IS_AUTHZ_BACKEND( op ) )
{
//mc_curr.mc_conn = op->o_conn;
} else {
LDAP_BACK_CONN_ISANON_SET( &mc_curr );
LDAP_BACK_PCONN_ANON_SET( &mc_curr, op );
}
}
switch ( op->o_tag ) {
case LDAP_REQ_ADD:
/* if we go to selection, the entry must not exist,
* and we must be able to resolve the parent */
dn_type = META_DNTYPE_PARENT;
dnParent( &ndn, &pndn );
break;
case LDAP_REQ_MODRDN:
/* if nnewSuperior is not NULL, it must resolve
* to the same candidate as the req_ndn */
if ( op->orr_nnewSup ) {
dn_type = META_DNTYPE_NEWPARENT;
}
break;
case LDAP_REQ_BIND:
/* if bound as rootdn, the backend must bind to all targets
* with the administrative identity
* (unless pseoudoroot-bind-defer is TRUE) */
if ( op->orb_method == LDAP_AUTH_SIMPLE && be_isroot_pw( op ) ) {
op_type = META_OP_REQUIRE_ALL;
}
break;
case LDAP_REQ_COMPARE:
case LDAP_REQ_DELETE:
case LDAP_REQ_MODIFY:
/* just a unique candidate */
break;
case LDAP_REQ_SEARCH:
/* allow multiple candidates for the searchBase */
op_type = META_OP_ALLOW_MULTIPLE;
break;
default:
/* right now, just break (exop?) */
break;
}
/*
* require all connections ...
*/
if ( op_type == META_OP_REQUIRE_ALL ) {
if ( LDAP_BACK_CONN_ISPRIV( &mc_curr ) ) {
LDAP_BACK_CONN_ISPRIV_SET( mc );
} else if ( LDAP_BACK_CONN_ISANON( &mc_curr ) ) {
LDAP_BACK_CONN_ISANON_SET( mc );
}
for ( i = 0; i < mi->mi_ntargets; i++ ) {
/*
* The target is activated; if needed, it is
* also init'd
*/
candidates[ i ].sr_err = asyncmeta_init_one_conn( op,
rs, mc, i, LDAP_BACK_CONN_ISPRIV( &mc_curr ),
LDAP_BACK_DONTSEND, !new_conn );
if ( candidates[ i ].sr_err == LDAP_SUCCESS ) {
if ( new_conn && ( sendok & LDAP_BACK_BINDING ) ) {
LDAP_BACK_CONN_BINDING_SET( &mc->mc_conns[ i ] );
}
META_CANDIDATE_SET( &candidates[ i ] );
ncandidates++;
} else {
/*
* FIXME: in case one target cannot
* be init'd, should the other ones
* be tried?
*/
META_CANDIDATE_RESET( &candidates[ i ] );
err = candidates[ i ].sr_err;
continue;
}
}
if ( ncandidates == 0 ) {
rs->sr_err = LDAP_NO_SUCH_OBJECT;
rs->sr_text = "Unable to select valid candidates";
if ( sendok & LDAP_BACK_SENDERR ) {
if ( rs->sr_err == LDAP_NO_SUCH_OBJECT ) {
rs->sr_matched = mi->mi_suffix.bv_val;
}
send_ldap_result( op, rs );
rs->sr_matched = NULL;
}
ldap_pvt_thread_mutex_unlock(&mc->mc_om_mutex);
if ( alloc_new > 0) {
asyncmeta_back_conn_free( mc );
}
return NULL;
}
goto done;
}
/*
* looks in cache, if any
*/
if ( mi->mi_cache.ttl != META_DNCACHE_DISABLED ) {
cached = i = asyncmeta_dncache_get_target( &mi->mi_cache, &op->o_req_ndn );
}
if ( op_type == META_OP_REQUIRE_SINGLE ) {
int j;
for ( j = 0; j < mi->mi_ntargets; j++ ) {
META_CANDIDATE_RESET( &candidates[ j ] );
}
/*
* tries to get a unique candidate
* (takes care of default target)
*/
if ( i == META_TARGET_NONE ) {
i = asyncmeta_get_candidate( op, rs, &ndn );
if ( rs->sr_err == LDAP_NO_SUCH_OBJECT && dn_type == META_DNTYPE_PARENT ) {
i = asyncmeta_get_candidate( op, rs, &pndn );
}
if ( i < 0 || rs->sr_err != LDAP_SUCCESS ) {
if ( sendok & LDAP_BACK_SENDERR ) {
if ( rs->sr_err == LDAP_NO_SUCH_OBJECT ) {
rs->sr_matched = mi->mi_suffix.bv_val;
}
send_ldap_result( op, rs );
rs->sr_matched = NULL;
}
ldap_pvt_thread_mutex_unlock(&mc->mc_om_mutex);
if ( mc != NULL && alloc_new ) {
asyncmeta_back_conn_free( mc );
}
return NULL;
}
}
if ( dn_type == META_DNTYPE_NEWPARENT && asyncmeta_get_candidate( op, rs, op->orr_nnewSup ) != i )
{
rs->sr_err = LDAP_UNWILLING_TO_PERFORM;
rs->sr_text = "Cross-target rename not supported";
if ( sendok & LDAP_BACK_SENDERR ) {
send_ldap_result( op, rs );
}
ldap_pvt_thread_mutex_unlock(&mc->mc_om_mutex);
if ( mc != NULL && alloc_new > 0 ) {
asyncmeta_back_conn_free( mc );
}
return NULL;
}
Debug( LDAP_DEBUG_TRACE,
"==>asyncmeta__getconn: got target=%d for ndn=\"%s\" from cache\n",
i, op->o_req_ndn.bv_val );
if ( LDAP_BACK_CONN_ISPRIV( &mc_curr ) ) {
LDAP_BACK_CONN_ISPRIV_SET( mc );
} else if ( LDAP_BACK_CONN_ISANON( &mc_curr ) ) {
LDAP_BACK_CONN_ISANON_SET( mc );
}
/*
* Clear all other candidates
*/
( void )asyncmeta_clear_unused_candidates( op, i , mc, candidates);
/*
* The target is activated; if needed, it is
* also init'd. In case of error, asyncmeta_init_one_conn
* sends the appropriate result.
*/
err = asyncmeta_init_one_conn( op, rs, mc, i,
LDAP_BACK_CONN_ISPRIV( &mc_curr ), sendok, !new_conn );
if ( err != LDAP_SUCCESS ) {
/*
* FIXME: in case one target cannot
* be init'd, should the other ones
* be tried?
*/
META_CANDIDATE_RESET( &candidates[ i ] );
ldap_pvt_thread_mutex_unlock(&mc->mc_om_mutex);
if ( mc != NULL && alloc_new > 0 ) {
asyncmeta_back_conn_free( mc );
}
return NULL;
}
candidates[ i ].sr_err = LDAP_SUCCESS;
META_CANDIDATE_SET( &candidates[ i ] );
ncandidates++;
if ( candidate ) {
*candidate = i;
}
/*
* if no unique candidate ...
*/
} else {
if ( LDAP_BACK_CONN_ISPRIV( &mc_curr ) ) {
LDAP_BACK_CONN_ISPRIV_SET( mc );
} else if ( LDAP_BACK_CONN_ISANON( &mc_curr ) ) {
LDAP_BACK_CONN_ISANON_SET( mc );
}
for ( i = 0; i < mi->mi_ntargets; i++ ) {
a_metatarget_t *mt = mi->mi_targets[ i ];
META_CANDIDATE_RESET( &candidates[ i ] );
if ( i == cached
|| asyncmeta_is_candidate( mt, &op->o_req_ndn,
op->o_tag == LDAP_REQ_SEARCH ? op->ors_scope : LDAP_SCOPE_SUBTREE ) )
{
/*
* The target is activated; if needed, it is
* also init'd
*/
int lerr = asyncmeta_init_one_conn( op, rs, mc, i,
LDAP_BACK_CONN_ISPRIV( &mc_curr ),
LDAP_BACK_DONTSEND, !new_conn );
candidates[ i ].sr_err = lerr;
if ( lerr == LDAP_SUCCESS ) {
META_CANDIDATE_SET( &candidates[ i ] );
ncandidates++;
Debug( LDAP_DEBUG_TRACE, "%s: asyncmeta_getconn[%d]\n",
op->o_log_prefix, i );
} else if ( lerr == LDAP_UNAVAILABLE && !META_BACK_ONERR_STOP( mi ) ) {
META_CANDIDATE_SET( &candidates[ i ] );
Debug( LDAP_DEBUG_TRACE, "%s: asyncmeta_getconn[%d] %s\n",
op->o_log_prefix, i,
mt->mt_isquarantined != LDAP_BACK_FQ_NO ? "quarantined" : "unavailable" );
} else {
/*
* FIXME: in case one target cannot
* be init'd, should the other ones
* be tried?
*/
/* leave the target candidate, but record the error for later use */
err = lerr;
if ( lerr == LDAP_UNAVAILABLE && mt->mt_isquarantined != LDAP_BACK_FQ_NO ) {
Debug( LDAP_DEBUG_TRACE, "%s: asyncmeta_getconn[%d] quarantined err=%d\n",
op->o_log_prefix, i, lerr );
} else {
Debug( LDAP_DEBUG_ANY, "%s: asyncmeta_getconn[%d] failed err=%d\n",
op->o_log_prefix, i, lerr );
}
if ( META_BACK_ONERR_STOP( mi ) ) {
if ( sendok & LDAP_BACK_SENDERR ) {
send_ldap_result( op, rs );
}
ldap_pvt_thread_mutex_unlock(&mc->mc_om_mutex);
if ( alloc_new > 0 ) {
asyncmeta_back_conn_free( mc );
}
return NULL;
}
continue;
}
}
}
if ( ncandidates == 0 ) {
if ( rs->sr_err == LDAP_SUCCESS ) {
rs->sr_err = LDAP_NO_SUCH_OBJECT;
rs->sr_text = "Unable to select valid candidates";
}
if ( sendok & LDAP_BACK_SENDERR ) {
if ( rs->sr_err == LDAP_NO_SUCH_OBJECT ) {
rs->sr_matched = mi->mi_suffix.bv_val;
}
send_ldap_result( op, rs );
rs->sr_matched = NULL;
}
if ( alloc_new > 0 ) {
asyncmeta_back_conn_free( mc );
}
ldap_pvt_thread_mutex_unlock(&mc->mc_om_mutex);
return NULL;
}
}
done:;
rs->sr_err = LDAP_SUCCESS;
rs->sr_text = NULL;
if ( new_conn ) {
if ( !LDAP_BACK_PCONN_ISPRIV( mc ) ) {
/*
* Err could be -1 in case a duplicate metaconn is inserted
*/
switch ( err ) {
case 0:
break;
default:
LDAP_BACK_CONN_CACHED_CLEAR( mc );
if ( LogTest( LDAP_DEBUG_ANY ) ) {
char buf[STRLENOF("4294967295U") + 1] = { 0 };
mi->mi_ldap_extra->connid2str( &mc->mc_base, buf, sizeof(buf) );
Debug( LDAP_DEBUG_ANY,
"%s asyncmeta_getconn: candidates=%d conn=%s insert failed\n",
op->o_log_prefix, ncandidates, buf );
}
asyncmeta_back_conn_free( mc );
rs->sr_err = LDAP_OTHER;
rs->sr_text = "Proxy bind collision";
if ( sendok & LDAP_BACK_SENDERR ) {
send_ldap_result( op, rs );
}
return NULL;
}
}
if ( LogTest( LDAP_DEBUG_TRACE ) ) {
char buf[STRLENOF("4294967295U") + 1] = { 0 };
mi->mi_ldap_extra->connid2str( &mc->mc_base, buf, sizeof(buf) );
Debug( LDAP_DEBUG_TRACE,
"%s asyncmeta_getconn: candidates=%d conn=%s inserted\n",
op->o_log_prefix, ncandidates, buf );
}
} else {
if ( LogTest( LDAP_DEBUG_TRACE ) ) {
char buf[STRLENOF("4294967295U") + 1] = { 0 };
mi->mi_ldap_extra->connid2str( &mc->mc_base, buf, sizeof(buf) );
Debug( LDAP_DEBUG_TRACE,
"%s asyncmeta_getconn: candidates=%d conn=%s fetched\n",
op->o_log_prefix, ncandidates, buf );
}
}
ldap_pvt_thread_mutex_unlock(&mc->mc_om_mutex);
return mc;
}
void
asyncmeta_quarantine(
Operation *op,
a_metainfo_t *mi,
SlapReply *rs,
int candidate )
{
a_metatarget_t *mt = mi->mi_targets[ candidate ];
slap_retry_info_t *ri = &mt->mt_quarantine;
ldap_pvt_thread_mutex_lock( &mt->mt_quarantine_mutex );
if ( rs->sr_err == LDAP_UNAVAILABLE ) {
time_t new_last = slap_get_time();
switch ( mt->mt_isquarantined ) {
case LDAP_BACK_FQ_NO:
if ( ri->ri_last == new_last ) {
goto done;
}
Debug( LDAP_DEBUG_ANY,
"%s asyncmeta_quarantine[%d]: enter.\n",
op->o_log_prefix, candidate );
ri->ri_idx = 0;
ri->ri_count = 0;
break;
case LDAP_BACK_FQ_RETRYING:
Debug(LDAP_DEBUG_ANY,
"%s asyncmeta_quarantine[%d]: block #%d try #%d failed.\n",
op->o_log_prefix, candidate, ri->ri_idx,
ri->ri_count );
++ri->ri_count;
if ( ri->ri_num[ ri->ri_idx ] != SLAP_RETRYNUM_FOREVER
&& ri->ri_count == ri->ri_num[ ri->ri_idx ] )
{
ri->ri_count = 0;
++ri->ri_idx;
}
break;
default:
goto done;
}
mt->mt_isquarantined = LDAP_BACK_FQ_YES;
ri->ri_last = new_last;
} else if ( mt->mt_isquarantined == LDAP_BACK_FQ_RETRYING ) {
Debug( LDAP_DEBUG_ANY,
"%s asyncmeta_quarantine[%d]: exit.\n",
op->o_log_prefix, candidate );
if ( mi->mi_quarantine_f ) {
(void)mi->mi_quarantine_f( mi, candidate,
mi->mi_quarantine_p );
}
ri->ri_count = 0;
ri->ri_idx = 0;
mt->mt_isquarantined = LDAP_BACK_FQ_NO;
mt->mt_timeout_ops = 0;
}
done:;
ldap_pvt_thread_mutex_unlock( &mt->mt_quarantine_mutex );
}
a_metaconn_t *
asyncmeta_get_next_mc( a_metainfo_t *mi )
{
a_metaconn_t *mc = NULL;
ldap_pvt_thread_mutex_lock( &mi->mi_mc_mutex );
if (mi->mi_next_conn >= mi->mi_num_conns-1) {
mi->mi_next_conn = 0;
} else {
mi->mi_next_conn++;
}
mc = &mi->mi_conns[mi->mi_next_conn];
ldap_pvt_thread_mutex_unlock( &mi->mi_mc_mutex );
return mc;
}
int asyncmeta_start_listeners(a_metaconn_t *mc, SlapReply *candidates, bm_context_t *bc)
{
int i;
for (i = 0; i < mc->mc_info->mi_ntargets; i++) {
asyncmeta_start_one_listener(mc, candidates, bc, i);
}
return LDAP_SUCCESS;
}
int asyncmeta_start_one_listener(a_metaconn_t *mc,
SlapReply *candidates,
bm_context_t *bc,
int candidate)
{
a_metasingleconn_t *msc;
ber_socket_t s;
msc = &mc->mc_conns[candidate];
if ( slapd_shutdown || !META_BACK_CONN_INITED( msc ) || msc->msc_ld == NULL
|| META_BACK_CONN_INVALID(msc) || !META_IS_CANDIDATE( &candidates[ candidate ] )) {
return LDAP_SUCCESS;
}
bc->msgids[candidate] = candidates[candidate].sr_msgid;
if ( msc->conn == NULL) {
ldap_get_option( msc->msc_ld, LDAP_OPT_DESC, &s );
if (s < 0) {
/* Todo a meaningful log pls */
return LDAP_OTHER;
}
msc->conn = connection_client_setup( s, asyncmeta_op_handle_result, mc );
}
connection_client_enable( msc->conn );
return LDAP_SUCCESS;
}
int
asyncmeta_clear_one_msc(
Operation *op,
a_metaconn_t *mc,
int candidate,
int unbind,
const char *caller)
{
a_metasingleconn_t *msc;
if (mc == NULL) {
return 0;
}
msc = &mc->mc_conns[candidate];
if ( LogTest( asyncmeta_debug ) ) {
char time_buf[ SLAP_TEXT_BUFLEN ];
asyncmeta_get_timestamp(time_buf);
Debug( asyncmeta_debug, "[%s] Resetting msc: %p, msc_ld: %p, "
"msc_bound_ndn: %s, msc->conn: %p, %s \n",
time_buf, msc, msc->msc_ld, msc->msc_bound_ndn.bv_val,
msc->conn, caller ? caller : "" );
}
msc->msc_mscflags = 0;
if (msc->conn) {
connection_client_stop( msc->conn );
msc->conn = NULL;
}
if ( msc->msc_ld != NULL ) {
#ifdef DEBUG_205
Debug( LDAP_DEBUG_ANY, "### %s asyncmeta_clear_one_msc ldap_unbind_ext[%d] ld=%p\n",
op ? op->o_log_prefix : "", candidate, (void *)msc->msc_ld );
#endif /* DEBUG_205 */
ldap_unbind_ext( msc->msc_ld, NULL, NULL );
msc->msc_ld = NULL;
ldap_ld_free( msc->msc_ldr, 0, NULL, NULL );
msc->msc_ldr = NULL;
}
if ( !BER_BVISNULL( &msc->msc_bound_ndn ) ) {
ber_memfree_x( msc->msc_bound_ndn.bv_val, NULL );
BER_BVZERO( &msc->msc_bound_ndn );
}
if ( !BER_BVISNULL( &msc->msc_cred ) ) {
memset( msc->msc_cred.bv_val, 0, msc->msc_cred.bv_len );
ber_memfree_x( msc->msc_cred.bv_val, NULL );
BER_BVZERO( &msc->msc_cred );
}
msc->msc_time = 0;
msc->msc_binding_time = 0;
msc->msc_result_time = 0;
return 0;
}
void asyncmeta_get_timestamp(char *buf)
{
struct timespec tp;
struct tm *ttm;
clock_gettime(CLOCK_REALTIME, &tp);
ttm = gmtime(&tp.tv_sec);
sprintf(buf, "%d:%d:%d.%ld", ttm->tm_hour, ttm->tm_min, ttm->tm_sec, tp.tv_nsec/1000);
}
int
asyncmeta_reset_msc(
Operation *op,
a_metaconn_t *mc,
int candidate,
int unbind,
const char *caller)
{
a_metasingleconn_t *msc = &mc->mc_conns[candidate];
if ( LogTest( asyncmeta_debug ) ) {
char time_buf[ SLAP_TEXT_BUFLEN ];
asyncmeta_get_timestamp(time_buf);
Debug(asyncmeta_debug, "[%x] Will attempt to reset [%s] msc: %p, "
"msc->msc_binding_time: %x, msc->msc_flags:%x %s\n",
(unsigned int)slap_get_time(), time_buf, msc,
(unsigned int)msc->msc_binding_time, msc->msc_mscflags, caller );
}
if (msc->msc_active <= 1 && mc->mc_active < 1) {
bm_context_t *om;
asyncmeta_clear_one_msc(NULL, mc, candidate, 0, caller);
/* set whatever's in the queue to invalid, so the timeout loop cleans it up,
* but do not invalidate the current op*/
LDAP_STAILQ_FOREACH( om, &mc->mc_om_list, bc_next ) {
if (om->candidates[candidate].sr_msgid >= 0 && (om->op != op)) {
om->bc_invalid = 1;
}
}
return LDAP_SUCCESS;
} else {
META_BACK_CONN_INVALID_SET(msc);
Debug( asyncmeta_debug, "[%x] Failed to reset msc %p, msc_active=%d, mc_active=%d, %s\n",
(unsigned int)slap_get_time(), msc, msc->msc_active, mc->mc_active, caller );
}
return LDAP_OTHER;
}
void asyncmeta_log_msc(a_metasingleconn_t *msc)
{
ber_socket_t s = 0;
if (msc->msc_ld) {
ldap_get_option( msc->msc_ld, LDAP_OPT_DESC, &s );
}
Debug( asyncmeta_debug, "msc: %p, msc_ld: %p, msc_ld socket: %d, "
"msc_bound_ndn: %s, msc->conn: %p\n", msc, msc->msc_ld,
(int)s, msc->msc_bound_ndn.bv_val, msc->conn );
}
void asyncmeta_log_conns(a_metainfo_t *mi)
{
a_metaconn_t *mc;
int i, j;
for (i = 0; i < mi->mi_num_conns; i++) {
mc = &mi->mi_conns[i];
Debug(asyncmeta_debug, "mc: %p, mc->pending_ops: %d\n", mc, mc->pending_ops);
for (j = 0; j < mi->mi_ntargets; j++ ) {
asyncmeta_log_msc(&mc->mc_conns[j]);
}
}
}
int
asyncmeta_db_has_pending_ops(a_metainfo_t *mi)
{
int i;
if (mi->mi_ntargets == 0) {
return 0;
}
for (i = 0; i < mi->mi_num_conns; i++) {
if (mi->mi_conns[i].pending_ops > 0) {
return mi->mi_conns[i].pending_ops;
}
}
return 0;
}
int
asyncmeta_db_has_mscs(a_metainfo_t *mi)
{
int i, j;
if (mi->mi_ntargets == 0) {
return 0;
}
for (i = 0; i < mi->mi_num_conns; i++) {
for (j = 0; j < mi->mi_ntargets; j++) {
if (mi->mi_conns[i].mc_conns[j].msc_ld != NULL ||
mi->mi_conns[i].mc_conns[j].msc_ldr != NULL ) {
return 1;
}
}
}
return 0;
}