/* acl.c - routines to parse and check acl's */ /* $OpenLDAP$ */ /* This work is part of OpenLDAP Software . * * Copyright 1998-2012 The OpenLDAP Foundation. * 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 * . */ /* Portions Copyright (c) 1995 Regents of the University of Michigan. * All rights reserved. * * Redistribution and use in source and binary forms are permitted * provided that this notice is preserved and that due credit is given * to the University of Michigan at Ann Arbor. The name of the University * may not be used to endorse or promote products derived from this * software without specific prior written permission. This software * is provided ``as is'' without express or implied warranty. */ #include "portable.h" #include #include #include #include #include "slap.h" #include "sets.h" #include "lber_pvt.h" #include "lutil.h" #define ACL_BUF_SIZE 1024 /* use most appropriate size */ static const struct berval acl_bv_ip_eq = BER_BVC( "IP=" ); #ifdef LDAP_PF_INET6 static const struct berval acl_bv_ipv6_eq = BER_BVC( "IP=[" ); #endif /* LDAP_PF_INET6 */ #ifdef LDAP_PF_LOCAL static const struct berval acl_bv_path_eq = BER_BVC("PATH="); #endif /* LDAP_PF_LOCAL */ static AccessControl * slap_acl_get( AccessControl *ac, int *count, Operation *op, Entry *e, AttributeDescription *desc, struct berval *val, AclRegexMatches *matches, slap_mask_t *mask, AccessControlState *state ); static slap_control_t slap_acl_mask( AccessControl *ac, AccessControl *prev, slap_mask_t *mask, Operation *op, Entry *e, AttributeDescription *desc, struct berval *val, AclRegexMatches *matches, int count, AccessControlState *state, slap_access_t access ); static int regex_matches( struct berval *pat, char *str, struct berval *dn_matches, struct berval *val_matches, AclRegexMatches *matches); typedef struct AclSetCookie { SetCookie asc_cookie; #define asc_op asc_cookie.set_op Entry *asc_e; } AclSetCookie; SLAP_SET_GATHER acl_set_gather; SLAP_SET_GATHER acl_set_gather2; /* * access_allowed - check whether op->o_ndn is allowed the requested access * to entry e, attribute attr, value val. if val is null, access to * the whole attribute is assumed (all values). * * This routine loops through all access controls and calls * slap_acl_mask() on each applicable access control. * The loop exits when a definitive answer is reached or * or no more controls remain. * * returns: * 0 access denied * 1 access granted * * Notes: * - can be legally called with op == NULL * - can be legally called with op->o_bd == NULL */ int slap_access_always_allowed( Operation *op, Entry *e, AttributeDescription *desc, struct berval *val, slap_access_t access, AccessControlState *state, slap_mask_t *maskp ) { assert( maskp != NULL ); /* assign all */ ACL_LVL_ASSIGN_MANAGE( *maskp ); return 1; } #define MATCHES_DNMAXCOUNT(m) \ ( sizeof ( (m)->dn_data ) / sizeof( *(m)->dn_data ) ) #define MATCHES_VALMAXCOUNT(m) \ ( sizeof ( (m)->val_data ) / sizeof( *(m)->val_data ) ) #define MATCHES_MEMSET(m) do { \ memset( (m)->dn_data, '\0', sizeof( (m)->dn_data ) ); \ memset( (m)->val_data, '\0', sizeof( (m)->val_data ) ); \ (m)->dn_count = MATCHES_DNMAXCOUNT( (m) ); \ (m)->val_count = MATCHES_VALMAXCOUNT( (m) ); \ } while ( 0 /* CONSTCOND */ ) int slap_access_allowed( Operation *op, Entry *e, AttributeDescription *desc, struct berval *val, slap_access_t access, AccessControlState *state, slap_mask_t *maskp ) { int ret = 1; int count; AccessControl *a, *prev; #ifdef LDAP_DEBUG char accessmaskbuf[ACCESSMASK_MAXLEN]; #endif slap_mask_t mask; slap_control_t control; slap_access_t access_level; const char *attr; AclRegexMatches matches; AccessControlState acl_state = ACL_STATE_INIT; static AccessControlState state_init = ACL_STATE_INIT; assert( op != NULL ); assert( e != NULL ); assert( desc != NULL ); assert( maskp != NULL ); access_level = ACL_LEVEL( access ); attr = desc->ad_cname.bv_val; assert( attr != NULL ); ACL_INIT( mask ); /* grant database root access */ if ( be_isroot( op ) ) { Debug( LDAP_DEBUG_ACL, "<= root access granted\n", 0, 0, 0 ); mask = ACL_LVL_MANAGE; goto done; } /* * no-user-modification operational attributes are ignored * by ACL_WRITE checking as any found here are not provided * by the user * * NOTE: but they are not ignored for ACL_MANAGE, because * if we get here it means a non-root user is trying to * manage data, so we need to check its privileges. */ if ( access_level == ACL_WRITE && is_at_no_user_mod( desc->ad_type ) && desc != slap_schema.si_ad_entry && desc != slap_schema.si_ad_children ) { Debug( LDAP_DEBUG_ACL, "NoUserMod Operational attribute:" " %s access granted\n", attr, 0, 0 ); goto done; } /* use backend default access if no backend acls */ if ( op->o_bd->be_acl == NULL && frontendDB->be_acl == NULL ) { int i; Debug( LDAP_DEBUG_ACL, "=> slap_access_allowed: backend default %s " "access %s to \"%s\"\n", access2str( access ), op->o_bd->be_dfltaccess >= access_level ? "granted" : "denied", op->o_dn.bv_val ? op->o_dn.bv_val : "(anonymous)" ); ret = op->o_bd->be_dfltaccess >= access_level; mask = ACL_PRIV_LEVEL; for ( i = ACL_NONE; i <= op->o_bd->be_dfltaccess; i++ ) { ACL_PRIV_SET( mask, ACL_ACCESS2PRIV( i ) ); } goto done; } ret = 0; control = ACL_BREAK; if ( state == NULL ) state = &acl_state; if ( state->as_desc == desc && state->as_access == access && state->as_vd_acl_present ) { a = state->as_vd_acl; count = state->as_vd_acl_count; if ( state->as_fe_done ) state->as_fe_done--; ACL_PRIV_ASSIGN( mask, state->as_vd_mask ); } else { *state = state_init; a = NULL; count = 0; ACL_PRIV_ASSIGN( mask, *maskp ); } MATCHES_MEMSET( &matches ); prev = a; while ( ( a = slap_acl_get( a, &count, op, e, desc, val, &matches, &mask, state ) ) != NULL ) { int i; int dnmaxcount = MATCHES_DNMAXCOUNT( &matches ); int valmaxcount = MATCHES_VALMAXCOUNT( &matches ); regmatch_t *dn_data = matches.dn_data; regmatch_t *val_data = matches.val_data; /* DN matches */ for ( i = 0; i < dnmaxcount && dn_data[i].rm_eo > 0; i++ ) { char *data = e->e_ndn; Debug( LDAP_DEBUG_ACL, "=> match[dn%d]: %d %d ", i, (int)dn_data[i].rm_so, (int)dn_data[i].rm_eo ); if ( dn_data[i].rm_so <= dn_data[0].rm_eo ) { int n; for ( n = dn_data[i].rm_so; n < dn_data[i].rm_eo; n++ ) { Debug( LDAP_DEBUG_ACL, "%c", data[n], 0, 0 ); } } Debug( LDAP_DEBUG_ACL, "\n", 0, 0, 0 ); } /* val matches */ for ( i = 0; i < valmaxcount && val_data[i].rm_eo > 0; i++ ) { char *data = val->bv_val; Debug( LDAP_DEBUG_ACL, "=> match[val%d]: %d %d ", i, (int)val_data[i].rm_so, (int)val_data[i].rm_eo ); if ( val_data[i].rm_so <= val_data[0].rm_eo ) { int n; for ( n = val_data[i].rm_so; n < val_data[i].rm_eo; n++ ) { Debug( LDAP_DEBUG_ACL, "%c", data[n], 0, 0 ); } } Debug( LDAP_DEBUG_ACL, "\n", 0, 0, 0 ); } control = slap_acl_mask( a, prev, &mask, op, e, desc, val, &matches, count, state, access ); if ( control != ACL_BREAK ) { break; } MATCHES_MEMSET( &matches ); prev = a; } if ( ACL_IS_INVALID( mask ) ) { Debug( LDAP_DEBUG_ACL, "=> slap_access_allowed: \"%s\" (%s) invalid!\n", e->e_dn, attr, 0 ); ACL_PRIV_ASSIGN( mask, *maskp ); } else if ( control == ACL_BREAK ) { Debug( LDAP_DEBUG_ACL, "=> slap_access_allowed: no more rules\n", 0, 0, 0 ); goto done; } ret = ACL_GRANT( mask, access ); Debug( LDAP_DEBUG_ACL, "=> slap_access_allowed: %s access %s by %s\n", access2str( access ), ret ? "granted" : "denied", accessmask2str( mask, accessmaskbuf, 1 ) ); done: ACL_PRIV_ASSIGN( *maskp, mask ); return ret; } int fe_access_allowed( Operation *op, Entry *e, AttributeDescription *desc, struct berval *val, slap_access_t access, AccessControlState *state, slap_mask_t *maskp ) { BackendDB *be_orig; int rc; /* * NOTE: control gets here if FIXME * if an appropriate backend cannot be selected for the operation, * we assume that the frontend should handle this * FIXME: should select_backend() take care of this, * and return frontendDB instead of NULL? maybe for some value * of the flags? */ be_orig = op->o_bd; if ( op->o_bd == NULL ) { op->o_bd = select_backend( &op->o_req_ndn, 0 ); if ( op->o_bd == NULL ) op->o_bd = frontendDB; } rc = slap_access_allowed( op, e, desc, val, access, state, maskp ); op->o_bd = be_orig; return rc; } int access_allowed_mask( Operation *op, Entry *e, AttributeDescription *desc, struct berval *val, slap_access_t access, AccessControlState *state, slap_mask_t *maskp ) { int ret = 1; int be_null = 0; #ifdef LDAP_DEBUG char accessmaskbuf[ACCESSMASK_MAXLEN]; #endif slap_mask_t mask; slap_access_t access_level; const char *attr; assert( e != NULL ); assert( desc != NULL ); access_level = ACL_LEVEL( access ); assert( access_level > ACL_NONE ); ACL_INIT( mask ); if ( maskp ) ACL_INVALIDATE( *maskp ); attr = desc->ad_cname.bv_val; assert( attr != NULL ); if ( op ) { if ( op->o_acl_priv != ACL_NONE ) { access = op->o_acl_priv; } else if ( op->o_is_auth_check && ( access_level == ACL_SEARCH || access_level == ACL_READ ) ) { access = ACL_AUTH; } else if ( get_relax( op ) && access_level == ACL_WRITE && desc == slap_schema.si_ad_entry ) { access = ACL_MANAGE; } } if ( state != NULL ) { if ( state->as_desc == desc && state->as_access == access && state->as_result != -1 && !state->as_vd_acl_present ) { Debug( LDAP_DEBUG_ACL, "=> access_allowed: result was in cache (%s)\n", attr, 0, 0 ); return state->as_result; } else { Debug( LDAP_DEBUG_ACL, "=> access_allowed: result not in cache (%s)\n", attr, 0, 0 ); } } Debug( LDAP_DEBUG_ACL, "=> access_allowed: %s access to \"%s\" \"%s\" requested\n", access2str( access ), e->e_dn, attr ); if ( op == NULL ) { /* no-op call */ goto done; } if ( op->o_bd == NULL ) { op->o_bd = LDAP_STAILQ_FIRST( &backendDB ); be_null = 1; /* FIXME: experimental; use first backend rules * iff there is no global_acl (ITS#3100) */ if ( frontendDB->be_acl != NULL ) { op->o_bd = frontendDB; } } assert( op->o_bd != NULL ); /* this is enforced in backend_add() */ if ( op->o_bd->bd_info->bi_access_allowed ) { /* delegate to backend */ ret = op->o_bd->bd_info->bi_access_allowed( op, e, desc, val, access, state, &mask ); } else { /* use default (but pass through frontend * for global ACL overlays) */ ret = frontendDB->bd_info->bi_access_allowed( op, e, desc, val, access, state, &mask ); } if ( !ret ) { if ( ACL_IS_INVALID( mask ) ) { Debug( LDAP_DEBUG_ACL, "=> access_allowed: \"%s\" (%s) invalid!\n", e->e_dn, attr, 0 ); ACL_INIT( mask ); } else { Debug( LDAP_DEBUG_ACL, "=> access_allowed: no more rules\n", 0, 0, 0 ); goto done; } } Debug( LDAP_DEBUG_ACL, "=> access_allowed: %s access %s by %s\n", access2str( access ), ret ? "granted" : "denied", accessmask2str( mask, accessmaskbuf, 1 ) ); done: if ( state != NULL ) { state->as_access = access; state->as_result = ret; state->as_desc = desc; } if ( be_null ) op->o_bd = NULL; if ( maskp ) ACL_PRIV_ASSIGN( *maskp, mask ); return ret; } /* * slap_acl_get - return the acl applicable to entry e, attribute * attr. the acl returned is suitable for use in subsequent calls to * acl_access_allowed(). */ static AccessControl * slap_acl_get( AccessControl *a, int *count, Operation *op, Entry *e, AttributeDescription *desc, struct berval *val, AclRegexMatches *matches, slap_mask_t *mask, AccessControlState *state ) { const char *attr; ber_len_t dnlen; AccessControl *prev; assert( e != NULL ); assert( count != NULL ); assert( desc != NULL ); assert( state != NULL ); attr = desc->ad_cname.bv_val; assert( attr != NULL ); if( a == NULL ) { if( op->o_bd == NULL || op->o_bd->be_acl == NULL ) { a = frontendDB->be_acl; } else { a = op->o_bd->be_acl; } prev = NULL; assert( a != NULL ); if ( a == frontendDB->be_acl ) state->as_fe_done = 1; } else { prev = a; a = a->acl_next; } dnlen = e->e_nname.bv_len; retry: for ( ; a != NULL; prev = a, a = a->acl_next ) { (*count) ++; if ( a != frontendDB->be_acl && state->as_fe_done ) state->as_fe_done++; if ( a->acl_dn_pat.bv_len || ( a->acl_dn_style != ACL_STYLE_REGEX )) { if ( a->acl_dn_style == ACL_STYLE_REGEX ) { Debug( LDAP_DEBUG_ACL, "=> dnpat: [%d] %s nsub: %d\n", *count, a->acl_dn_pat.bv_val, (int) a->acl_dn_re.re_nsub ); if ( regexec ( &a->acl_dn_re, e->e_ndn, matches->dn_count, matches->dn_data, 0 ) ) continue; } else { ber_len_t patlen; Debug( LDAP_DEBUG_ACL, "=> dn: [%d] %s\n", *count, a->acl_dn_pat.bv_val, 0 ); patlen = a->acl_dn_pat.bv_len; if ( dnlen < patlen ) continue; if ( a->acl_dn_style == ACL_STYLE_BASE ) { /* base dn -- entire object DN must match */ if ( dnlen != patlen ) continue; } else if ( a->acl_dn_style == ACL_STYLE_ONE ) { ber_len_t rdnlen = 0; ber_len_t sep = 0; if ( dnlen <= patlen ) continue; if ( patlen > 0 ) { if ( !DN_SEPARATOR( e->e_ndn[dnlen - patlen - 1] ) ) continue; sep = 1; } rdnlen = dn_rdnlen( NULL, &e->e_nname ); if ( rdnlen + patlen + sep != dnlen ) continue; } else if ( a->acl_dn_style == ACL_STYLE_SUBTREE ) { if ( dnlen > patlen && !DN_SEPARATOR( e->e_ndn[dnlen - patlen - 1] ) ) continue; } else if ( a->acl_dn_style == ACL_STYLE_CHILDREN ) { if ( dnlen <= patlen ) continue; if ( !DN_SEPARATOR( e->e_ndn[dnlen - patlen - 1] ) ) continue; } if ( strcmp( a->acl_dn_pat.bv_val, e->e_ndn + dnlen - patlen ) != 0 ) continue; } Debug( LDAP_DEBUG_ACL, "=> acl_get: [%d] matched\n", *count, 0, 0 ); } if ( a->acl_attrs && !ad_inlist( desc, a->acl_attrs ) ) { matches->dn_data[0].rm_so = -1; matches->dn_data[0].rm_eo = -1; matches->val_data[0].rm_so = -1; matches->val_data[0].rm_eo = -1; continue; } /* Is this ACL only for a specific value? */ if ( a->acl_attrval.bv_len ) { if ( val == NULL ) { continue; } if ( !state->as_vd_acl_present ) { state->as_vd_acl_present = 1; state->as_vd_acl = prev; state->as_vd_acl_count = *count - 1; ACL_PRIV_ASSIGN ( state->as_vd_mask, *mask ); } if ( a->acl_attrval_style == ACL_STYLE_REGEX ) { Debug( LDAP_DEBUG_ACL, "acl_get: valpat %s\n", a->acl_attrval.bv_val, 0, 0 ); if ( regexec ( &a->acl_attrval_re, val->bv_val, matches->val_count, matches->val_data, 0 ) ) { continue; } } else { int match = 0; const char *text; Debug( LDAP_DEBUG_ACL, "acl_get: val %s\n", a->acl_attrval.bv_val, 0, 0 ); if ( a->acl_attrs[0].an_desc->ad_type->sat_syntax != slap_schema.si_syn_distinguishedName ) { if (value_match( &match, desc, a->acl_attrval_mr, 0, val, &a->acl_attrval, &text ) != LDAP_SUCCESS || match ) continue; } else { ber_len_t patlen, vdnlen; patlen = a->acl_attrval.bv_len; vdnlen = val->bv_len; if ( vdnlen < patlen ) continue; if ( a->acl_attrval_style == ACL_STYLE_BASE ) { if ( vdnlen > patlen ) continue; } else if ( a->acl_attrval_style == ACL_STYLE_ONE ) { ber_len_t rdnlen = 0; if ( !DN_SEPARATOR( val->bv_val[vdnlen - patlen - 1] ) ) continue; rdnlen = dn_rdnlen( NULL, val ); if ( rdnlen + patlen + 1 != vdnlen ) continue; } else if ( a->acl_attrval_style == ACL_STYLE_SUBTREE ) { if ( vdnlen > patlen && !DN_SEPARATOR( val->bv_val[vdnlen - patlen - 1] ) ) continue; } else if ( a->acl_attrval_style == ACL_STYLE_CHILDREN ) { if ( vdnlen <= patlen ) continue; if ( !DN_SEPARATOR( val->bv_val[vdnlen - patlen - 1] ) ) continue; } if ( strcmp( a->acl_attrval.bv_val, val->bv_val + vdnlen - patlen ) ) continue; } } } if ( a->acl_filter != NULL ) { ber_int_t rc = test_filter( NULL, e, a->acl_filter ); if ( rc != LDAP_COMPARE_TRUE ) { continue; } } Debug( LDAP_DEBUG_ACL, "=> acl_get: [%d] attr %s\n", *count, attr, 0); return a; } if ( !state->as_fe_done ) { state->as_fe_done = 1; a = frontendDB->be_acl; goto retry; } Debug( LDAP_DEBUG_ACL, "<= acl_get: done.\n", 0, 0, 0 ); return( NULL ); } /* * Record value-dependent access control state */ #define ACL_RECORD_VALUE_STATE do { \ if( state && !state->as_vd_acl_present ) { \ state->as_vd_acl_present = 1; \ state->as_vd_acl = prev; \ state->as_vd_acl_count = count - 1; \ ACL_PRIV_ASSIGN( state->as_vd_mask, *mask ); \ } \ } while( 0 ) static int acl_mask_dn( Operation *op, Entry *e, struct berval *val, AccessControl *a, AclRegexMatches *matches, slap_dn_access *bdn, struct berval *opndn ) { /* * if access applies to the entry itself, and the * user is bound as somebody in the same namespace as * the entry, OR the given dn matches the dn pattern */ /* * NOTE: styles "anonymous", "users" and "self" * have been moved to enum slap_style_t, whose * value is set in a_dn_style; however, the string * is maintained in a_dn_pat. */ if ( bdn->a_style == ACL_STYLE_ANONYMOUS ) { if ( !BER_BVISEMPTY( opndn ) ) { return 1; } } else if ( bdn->a_style == ACL_STYLE_USERS ) { if ( BER_BVISEMPTY( opndn ) ) { return 1; } } else if ( bdn->a_style == ACL_STYLE_SELF ) { struct berval ndn, selfndn; int level; if ( BER_BVISEMPTY( opndn ) || BER_BVISNULL( &e->e_nname ) ) { return 1; } level = bdn->a_self_level; if ( level < 0 ) { selfndn = *opndn; ndn = e->e_nname; level = -level; } else { ndn = *opndn; selfndn = e->e_nname; } for ( ; level > 0; level-- ) { if ( BER_BVISEMPTY( &ndn ) ) { break; } dnParent( &ndn, &ndn ); } if ( BER_BVISEMPTY( &ndn ) || !dn_match( &ndn, &selfndn ) ) { return 1; } } else if ( bdn->a_style == ACL_STYLE_REGEX ) { if ( !ber_bvccmp( &bdn->a_pat, '*' ) ) { AclRegexMatches tmp_matches, *tmp_matchesp = &tmp_matches; int rc = 0; regmatch_t *tmp_data; MATCHES_MEMSET( &tmp_matches ); tmp_data = &tmp_matches.dn_data[0]; if ( a->acl_attrval_style == ACL_STYLE_REGEX ) tmp_matchesp = matches; else switch ( a->acl_dn_style ) { case ACL_STYLE_REGEX: if ( !BER_BVISNULL( &a->acl_dn_pat ) ) { tmp_matchesp = matches; break; } /* FALLTHRU: applies also to ACL_STYLE_REGEX when pattern is "*" */ case ACL_STYLE_BASE: tmp_data[0].rm_so = 0; tmp_data[0].rm_eo = e->e_nname.bv_len; tmp_matches.dn_count = 1; break; case ACL_STYLE_ONE: case ACL_STYLE_SUBTREE: case ACL_STYLE_CHILDREN: tmp_data[0].rm_so = 0; tmp_data[0].rm_eo = e->e_nname.bv_len; tmp_data[1].rm_so = e->e_nname.bv_len - a->acl_dn_pat.bv_len; tmp_data[1].rm_eo = e->e_nname.bv_len; tmp_matches.dn_count = 2; break; default: /* error */ rc = 1; break; } if ( rc ) { return 1; } if ( !regex_matches( &bdn->a_pat, opndn->bv_val, &e->e_nname, NULL, tmp_matchesp ) ) { return 1; } } } else { struct berval pat; ber_len_t patlen, odnlen; int got_match = 0; if ( e->e_dn == NULL ) return 1; if ( bdn->a_expand ) { struct berval bv; char buf[ACL_BUF_SIZE]; AclRegexMatches tmp_matches, *tmp_matchesp = &tmp_matches; int rc = 0; regmatch_t *tmp_data; MATCHES_MEMSET( &tmp_matches ); tmp_data = &tmp_matches.dn_data[0]; bv.bv_len = sizeof( buf ) - 1; bv.bv_val = buf; /* Expand value regex */ if ( a->acl_attrval_style == ACL_STYLE_REGEX ) tmp_matchesp = matches; else switch ( a->acl_dn_style ) { case ACL_STYLE_REGEX: if ( !BER_BVISNULL( &a->acl_dn_pat ) ) { tmp_matchesp = matches; break; } /* FALLTHRU: applies also to ACL_STYLE_REGEX when pattern is "*" */ case ACL_STYLE_BASE: tmp_data[0].rm_so = 0; tmp_data[0].rm_eo = e->e_nname.bv_len; tmp_matches.dn_count = 1; break; case ACL_STYLE_ONE: case ACL_STYLE_SUBTREE: case ACL_STYLE_CHILDREN: tmp_data[0].rm_so = 0; tmp_data[0].rm_eo = e->e_nname.bv_len; tmp_data[1].rm_so = e->e_nname.bv_len - a->acl_dn_pat.bv_len; tmp_data[1].rm_eo = e->e_nname.bv_len; tmp_matches.dn_count = 2; break; default: /* error */ rc = 1; break; } if ( rc ) { return 1; } if ( acl_string_expand( &bv, &bdn->a_pat, &e->e_nname, val, tmp_matchesp ) ) { return 1; } if ( dnNormalize(0, NULL, NULL, &bv, &pat, op->o_tmpmemctx ) != LDAP_SUCCESS ) { /* did not expand to a valid dn */ return 1; } } else { pat = bdn->a_pat; } patlen = pat.bv_len; odnlen = opndn->bv_len; if ( odnlen < patlen ) { goto dn_match_cleanup; } if ( bdn->a_style == ACL_STYLE_BASE ) { /* base dn -- entire object DN must match */ if ( odnlen != patlen ) { goto dn_match_cleanup; } } else if ( bdn->a_style == ACL_STYLE_ONE ) { ber_len_t rdnlen = 0; if ( odnlen <= patlen ) { goto dn_match_cleanup; } if ( !DN_SEPARATOR( opndn->bv_val[odnlen - patlen - 1] ) ) { goto dn_match_cleanup; } rdnlen = dn_rdnlen( NULL, opndn ); if ( rdnlen - ( odnlen - patlen - 1 ) != 0 ) { goto dn_match_cleanup; } } else if ( bdn->a_style == ACL_STYLE_SUBTREE ) { if ( odnlen > patlen && !DN_SEPARATOR( opndn->bv_val[odnlen - patlen - 1] ) ) { goto dn_match_cleanup; } } else if ( bdn->a_style == ACL_STYLE_CHILDREN ) { if ( odnlen <= patlen ) { goto dn_match_cleanup; } if ( !DN_SEPARATOR( opndn->bv_val[odnlen - patlen - 1] ) ) { goto dn_match_cleanup; } } else if ( bdn->a_style == ACL_STYLE_LEVEL ) { int level = bdn->a_level; struct berval ndn; if ( odnlen <= patlen ) { goto dn_match_cleanup; } if ( level > 0 && !DN_SEPARATOR( opndn->bv_val[odnlen - patlen - 1] ) ) { goto dn_match_cleanup; } ndn = *opndn; for ( ; level > 0; level-- ) { if ( BER_BVISEMPTY( &ndn ) ) { goto dn_match_cleanup; } dnParent( &ndn, &ndn ); if ( ndn.bv_len < patlen ) { goto dn_match_cleanup; } } if ( ndn.bv_len != patlen ) { goto dn_match_cleanup; } } got_match = !strcmp( pat.bv_val, &opndn->bv_val[ odnlen - patlen ] ); dn_match_cleanup:; if ( pat.bv_val != bdn->a_pat.bv_val ) { slap_sl_free( pat.bv_val, op->o_tmpmemctx ); } if ( !got_match ) { return 1; } } return 0; } static int acl_mask_dnattr( Operation *op, Entry *e, struct berval *val, AccessControl *a, int count, AccessControlState *state, slap_mask_t *mask, slap_dn_access *bdn, struct berval *opndn ) { Attribute *at; struct berval bv; int rc, match = 0; const char *text; const char *attr = bdn->a_at->ad_cname.bv_val; assert( attr != NULL ); if ( BER_BVISEMPTY( opndn ) ) { return 1; } Debug( LDAP_DEBUG_ACL, "<= check a_dn_at: %s\n", attr, 0, 0 ); bv = *opndn; /* see if asker is listed in dnattr */ for ( at = attrs_find( e->e_attrs, bdn->a_at ); at != NULL; at = attrs_find( at->a_next, bdn->a_at ) ) { if ( attr_valfind( at, SLAP_MR_ATTRIBUTE_VALUE_NORMALIZED_MATCH | SLAP_MR_ASSERTED_VALUE_NORMALIZED_MATCH, &bv, NULL, op->o_tmpmemctx ) == 0 ) { /* found it */ match = 1; break; } } if ( match ) { /* have a dnattr match. if this is a self clause then * the target must also match the op dn. */ if ( bdn->a_self ) { /* check if the target is an attribute. */ if ( val == NULL ) return 1; /* target is attribute, check if the attribute value * is the op dn. */ rc = value_match( &match, bdn->a_at, bdn->a_at->ad_type->sat_equality, 0, val, &bv, &text ); /* on match error or no match, fail the ACL clause */ if ( rc != LDAP_SUCCESS || match != 0 ) return 1; } } else { /* no dnattr match, check if this is a self clause */ if ( ! bdn->a_self ) return 1; /* this is a self clause, check if the target is an * attribute. */ if ( val == NULL ) return 1; /* target is attribute, check if the attribute value * is the op dn. */ rc = value_match( &match, bdn->a_at, bdn->a_at->ad_type->sat_equality, 0, val, &bv, &text ); /* on match error or no match, fail the ACL clause */ if ( rc != LDAP_SUCCESS || match != 0 ) return 1; } return 0; } /* * slap_acl_mask - modifies mask based upon the given acl and the * requested access to entry e, attribute attr, value val. if val * is null, access to the whole attribute is assumed (all values). * * returns 0 access NOT allowed * 1 access allowed */ static slap_control_t slap_acl_mask( AccessControl *a, AccessControl *prev, slap_mask_t *mask, Operation *op, Entry *e, AttributeDescription *desc, struct berval *val, AclRegexMatches *matches, int count, AccessControlState *state, slap_access_t access ) { int i; Access *b; #ifdef LDAP_DEBUG char accessmaskbuf[ACCESSMASK_MAXLEN]; #endif /* DEBUG */ const char *attr; #ifdef SLAP_DYNACL slap_mask_t a2pmask = ACL_ACCESS2PRIV( access ); #endif /* SLAP_DYNACL */ assert( a != NULL ); assert( mask != NULL ); assert( desc != NULL ); attr = desc->ad_cname.bv_val; assert( attr != NULL ); Debug( LDAP_DEBUG_ACL, "=> acl_mask: access to entry \"%s\", attr \"%s\" requested\n", e->e_dn, attr, 0 ); Debug( LDAP_DEBUG_ACL, "=> acl_mask: to %s by \"%s\", (%s) \n", val ? "value" : "all values", op->o_ndn.bv_val ? op->o_ndn.bv_val : "", accessmask2str( *mask, accessmaskbuf, 1 ) ); b = a->acl_access; i = 1; for ( ; b != NULL; b = b->a_next, i++ ) { slap_mask_t oldmask, modmask; ACL_INVALIDATE( modmask ); /* check for the "self" modifier in the field */ if ( b->a_dn.a_self ) { const char *dummy; int rc, match = 0; ACL_RECORD_VALUE_STATE; /* must have DN syntax */ if ( desc->ad_type->sat_syntax != slap_schema.si_syn_distinguishedName && !is_at_syntax( desc->ad_type, SLAPD_NAMEUID_SYNTAX )) continue; /* check if the target is an attribute. */ if ( val == NULL ) continue; /* a DN must be present */ if ( BER_BVISEMPTY( &op->o_ndn ) ) { continue; } /* target is attribute, check if the attribute value * is the op dn. */ rc = value_match( &match, desc, desc->ad_type->sat_equality, 0, val, &op->o_ndn, &dummy ); /* on match error or no match, fail the ACL clause */ if ( rc != LDAP_SUCCESS || match != 0 ) continue; } /* AND clauses */ if ( !BER_BVISEMPTY( &b->a_dn_pat ) ) { Debug( LDAP_DEBUG_ACL, "<= check a_dn_pat: %s\n", b->a_dn_pat.bv_val, 0, 0); /* * if access applies to the entry itself, and the * user is bound as somebody in the same namespace as * the entry, OR the given dn matches the dn pattern */ /* * NOTE: styles "anonymous", "users" and "self" * have been moved to enum slap_style_t, whose * value is set in a_dn_style; however, the string * is maintained in a_dn_pat. */ if ( acl_mask_dn( op, e, val, a, matches, &b->a_dn, &op->o_ndn ) ) { continue; } } if ( !BER_BVISEMPTY( &b->a_realdn_pat ) ) { struct berval ndn; Debug( LDAP_DEBUG_ACL, "<= check a_realdn_pat: %s\n", b->a_realdn_pat.bv_val, 0, 0); /* * if access applies to the entry itself, and the * user is bound as somebody in the same namespace as * the entry, OR the given dn matches the dn pattern */ /* * NOTE: styles "anonymous", "users" and "self" * have been moved to enum slap_style_t, whose * value is set in a_dn_style; however, the string * is maintained in a_dn_pat. */ if ( op->o_conn && !BER_BVISNULL( &op->o_conn->c_ndn ) ) { ndn = op->o_conn->c_ndn; } else { ndn = op->o_ndn; } if ( acl_mask_dn( op, e, val, a, matches, &b->a_realdn, &ndn ) ) { continue; } } if ( !BER_BVISEMPTY( &b->a_sockurl_pat ) ) { if ( ! op->o_conn->c_listener ) { continue; } Debug( LDAP_DEBUG_ACL, "<= check a_sockurl_pat: %s\n", b->a_sockurl_pat.bv_val, 0, 0 ); if ( !ber_bvccmp( &b->a_sockurl_pat, '*' ) ) { if ( b->a_sockurl_style == ACL_STYLE_REGEX) { if ( !regex_matches( &b->a_sockurl_pat, op->o_conn->c_listener_url.bv_val, &e->e_nname, val, matches ) ) { continue; } } else if ( b->a_sockurl_style == ACL_STYLE_EXPAND ) { struct berval bv; char buf[ACL_BUF_SIZE]; bv.bv_len = sizeof( buf ) - 1; bv.bv_val = buf; if ( acl_string_expand( &bv, &b->a_sockurl_pat, &e->e_nname, val, matches ) ) { continue; } if ( ber_bvstrcasecmp( &bv, &op->o_conn->c_listener_url ) != 0 ) { continue; } } else { if ( ber_bvstrcasecmp( &b->a_sockurl_pat, &op->o_conn->c_listener_url ) != 0 ) { continue; } } } } if ( !BER_BVISEMPTY( &b->a_domain_pat ) ) { if ( !op->o_conn->c_peer_domain.bv_val ) { continue; } Debug( LDAP_DEBUG_ACL, "<= check a_domain_pat: %s\n", b->a_domain_pat.bv_val, 0, 0 ); if ( !ber_bvccmp( &b->a_domain_pat, '*' ) ) { if ( b->a_domain_style == ACL_STYLE_REGEX) { if ( !regex_matches( &b->a_domain_pat, op->o_conn->c_peer_domain.bv_val, &e->e_nname, val, matches ) ) { continue; } } else { char buf[ACL_BUF_SIZE]; struct berval cmp = op->o_conn->c_peer_domain; struct berval pat = b->a_domain_pat; if ( b->a_domain_expand ) { struct berval bv; bv.bv_len = sizeof(buf) - 1; bv.bv_val = buf; if ( acl_string_expand(&bv, &b->a_domain_pat, &e->e_nname, val, matches) ) { continue; } pat = bv; } if ( b->a_domain_style == ACL_STYLE_SUBTREE ) { int offset = cmp.bv_len - pat.bv_len; if ( offset < 0 ) { continue; } if ( offset == 1 || ( offset > 1 && cmp.bv_val[ offset - 1 ] != '.' ) ) { continue; } /* trim the domain */ cmp.bv_val = &cmp.bv_val[ offset ]; cmp.bv_len -= offset; } if ( ber_bvstrcasecmp( &pat, &cmp ) != 0 ) { continue; } } } } if ( !BER_BVISEMPTY( &b->a_peername_pat ) ) { if ( !op->o_conn->c_peer_name.bv_val ) { continue; } Debug( LDAP_DEBUG_ACL, "<= check a_peername_path: %s\n", b->a_peername_pat.bv_val, 0, 0 ); if ( !ber_bvccmp( &b->a_peername_pat, '*' ) ) { if ( b->a_peername_style == ACL_STYLE_REGEX ) { if ( !regex_matches( &b->a_peername_pat, op->o_conn->c_peer_name.bv_val, &e->e_nname, val, matches ) ) { continue; } } else { /* try exact match */ if ( b->a_peername_style == ACL_STYLE_BASE ) { if ( ber_bvstrcasecmp( &b->a_peername_pat, &op->o_conn->c_peer_name ) != 0 ) { continue; } } else if ( b->a_peername_style == ACL_STYLE_EXPAND ) { struct berval bv; char buf[ACL_BUF_SIZE]; bv.bv_len = sizeof( buf ) - 1; bv.bv_val = buf; if ( acl_string_expand( &bv, &b->a_peername_pat, &e->e_nname, val, matches ) ) { continue; } if ( ber_bvstrcasecmp( &bv, &op->o_conn->c_peer_name ) != 0 ) { continue; } /* extract IP and try exact match */ } else if ( b->a_peername_style == ACL_STYLE_IP ) { char *port; char buf[STRLENOF("255.255.255.255") + 1]; struct berval ip; unsigned long addr; int port_number = -1; if ( strncasecmp( op->o_conn->c_peer_name.bv_val, acl_bv_ip_eq.bv_val, acl_bv_ip_eq.bv_len ) != 0 ) continue; ip.bv_val = op->o_conn->c_peer_name.bv_val + acl_bv_ip_eq.bv_len; ip.bv_len = op->o_conn->c_peer_name.bv_len - acl_bv_ip_eq.bv_len; port = strrchr( ip.bv_val, ':' ); if ( port ) { ip.bv_len = port - ip.bv_val; ++port; if ( lutil_atoi( &port_number, port ) != 0 ) continue; } /* the port check can be anticipated here */ if ( b->a_peername_port != -1 && port_number != b->a_peername_port ) continue; /* address longer than expected? */ if ( ip.bv_len >= sizeof(buf) ) continue; AC_MEMCPY( buf, ip.bv_val, ip.bv_len ); buf[ ip.bv_len ] = '\0'; addr = inet_addr( buf ); /* unable to convert? */ if ( addr == (unsigned long)(-1) ) continue; if ( (addr & b->a_peername_mask) != b->a_peername_addr ) continue; #ifdef LDAP_PF_INET6 /* extract IPv6 and try exact match */ } else if ( b->a_peername_style == ACL_STYLE_IPV6 ) { char *port; char buf[STRLENOF("FFFF:FFFF:FFFF:FFFF:FFFF:FFFF:FFFF:FFFF") + 1]; struct berval ip; struct in6_addr addr; int port_number = -1; if ( strncasecmp( op->o_conn->c_peer_name.bv_val, acl_bv_ipv6_eq.bv_val, acl_bv_ipv6_eq.bv_len ) != 0 ) continue; ip.bv_val = op->o_conn->c_peer_name.bv_val + acl_bv_ipv6_eq.bv_len; ip.bv_len = op->o_conn->c_peer_name.bv_len - acl_bv_ipv6_eq.bv_len; port = strrchr( ip.bv_val, ']' ); if ( port ) { ip.bv_len = port - ip.bv_val; ++port; if ( port[0] == ':' && lutil_atoi( &port_number, ++port ) != 0 ) continue; } /* the port check can be anticipated here */ if ( b->a_peername_port != -1 && port_number != b->a_peername_port ) continue; /* address longer than expected? */ if ( ip.bv_len >= sizeof(buf) ) continue; AC_MEMCPY( buf, ip.bv_val, ip.bv_len ); buf[ ip.bv_len ] = '\0'; if ( inet_pton( AF_INET6, buf, &addr ) != 1 ) continue; /* check mask */ if ( !slap_addr6_mask( &addr, &b->a_peername_mask6, &b->a_peername_addr6 ) ) continue; #endif /* LDAP_PF_INET6 */ #ifdef LDAP_PF_LOCAL /* extract path and try exact match */ } else if ( b->a_peername_style == ACL_STYLE_PATH ) { struct berval path; if ( strncmp( op->o_conn->c_peer_name.bv_val, acl_bv_path_eq.bv_val, acl_bv_path_eq.bv_len ) != 0 ) continue; path.bv_val = op->o_conn->c_peer_name.bv_val + acl_bv_path_eq.bv_len; path.bv_len = op->o_conn->c_peer_name.bv_len - acl_bv_path_eq.bv_len; if ( ber_bvcmp( &b->a_peername_pat, &path ) != 0 ) continue; #endif /* LDAP_PF_LOCAL */ /* exact match (very unlikely...) */ } else if ( ber_bvcmp( &op->o_conn->c_peer_name, &b->a_peername_pat ) != 0 ) { continue; } } } } if ( !BER_BVISEMPTY( &b->a_sockname_pat ) ) { if ( BER_BVISNULL( &op->o_conn->c_sock_name ) ) { continue; } Debug( LDAP_DEBUG_ACL, "<= check a_sockname_path: %s\n", b->a_sockname_pat.bv_val, 0, 0 ); if ( !ber_bvccmp( &b->a_sockname_pat, '*' ) ) { if ( b->a_sockname_style == ACL_STYLE_REGEX) { if ( !regex_matches( &b->a_sockname_pat, op->o_conn->c_sock_name.bv_val, &e->e_nname, val, matches ) ) { continue; } } else if ( b->a_sockname_style == ACL_STYLE_EXPAND ) { struct berval bv; char buf[ACL_BUF_SIZE]; bv.bv_len = sizeof( buf ) - 1; bv.bv_val = buf; if ( acl_string_expand( &bv, &b->a_sockname_pat, &e->e_nname, val, matches ) ) { continue; } if ( ber_bvstrcasecmp( &bv, &op->o_conn->c_sock_name ) != 0 ) { continue; } } else { if ( ber_bvstrcasecmp( &b->a_sockname_pat, &op->o_conn->c_sock_name ) != 0 ) { continue; } } } } if ( b->a_dn_at != NULL ) { if ( acl_mask_dnattr( op, e, val, a, count, state, mask, &b->a_dn, &op->o_ndn ) ) { continue; } } if ( b->a_realdn_at != NULL ) { struct berval ndn; if ( op->o_conn && !BER_BVISNULL( &op->o_conn->c_ndn ) ) { ndn = op->o_conn->c_ndn; } else { ndn = op->o_ndn; } if ( acl_mask_dnattr( op, e, val, a, count, state, mask, &b->a_realdn, &ndn ) ) { continue; } } if ( !BER_BVISEMPTY( &b->a_group_pat ) ) { struct berval bv; struct berval ndn = BER_BVNULL; int rc; if ( op->o_ndn.bv_len == 0 ) { continue; } Debug( LDAP_DEBUG_ACL, "<= check a_group_pat: %s\n", b->a_group_pat.bv_val, 0, 0 ); /* b->a_group is an unexpanded entry name, expanded it should be an * entry with objectclass group* and we test to see if odn is one of * the values in the attribute group */ /* see if asker is listed in dnattr */ if ( b->a_group_style == ACL_STYLE_EXPAND ) { char buf[ACL_BUF_SIZE]; AclRegexMatches tmp_matches, *tmp_matchesp = &tmp_matches; regmatch_t *tmp_data; MATCHES_MEMSET( &tmp_matches ); tmp_data = &tmp_matches.dn_data[0]; bv.bv_len = sizeof(buf) - 1; bv.bv_val = buf; rc = 0; if ( a->acl_attrval_style == ACL_STYLE_REGEX ) tmp_matchesp = matches; else switch ( a->acl_dn_style ) { case ACL_STYLE_REGEX: if ( !BER_BVISNULL( &a->acl_dn_pat ) ) { tmp_matchesp = matches; break; } /* FALLTHRU: applies also to ACL_STYLE_REGEX when pattern is "*" */ case ACL_STYLE_BASE: tmp_data[0].rm_so = 0; tmp_data[0].rm_eo = e->e_nname.bv_len; tmp_matches.dn_count = 1; break; case ACL_STYLE_ONE: case ACL_STYLE_SUBTREE: case ACL_STYLE_CHILDREN: tmp_data[0].rm_so = 0; tmp_data[0].rm_eo = e->e_nname.bv_len; tmp_data[1].rm_so = e->e_nname.bv_len - a->acl_dn_pat.bv_len; tmp_data[1].rm_eo = e->e_nname.bv_len; tmp_matches.dn_count = 2; break; default: /* error */ rc = 1; break; } if ( rc ) { continue; } if ( acl_string_expand( &bv, &b->a_group_pat, &e->e_nname, val, tmp_matchesp ) ) { continue; } if ( dnNormalize( 0, NULL, NULL, &bv, &ndn, op->o_tmpmemctx ) != LDAP_SUCCESS ) { /* did not expand to a valid dn */ continue; } bv = ndn; } else { bv = b->a_group_pat; } rc = backend_group( op, e, &bv, &op->o_ndn, b->a_group_oc, b->a_group_at ); if ( ndn.bv_val ) { slap_sl_free( ndn.bv_val, op->o_tmpmemctx ); } if ( rc != 0 ) { continue; } } if ( !BER_BVISEMPTY( &b->a_set_pat ) ) { struct berval bv; char buf[ACL_BUF_SIZE]; Debug( LDAP_DEBUG_ACL, "<= check a_set_pat: %s\n", b->a_set_pat.bv_val, 0, 0 ); if ( b->a_set_style == ACL_STYLE_EXPAND ) { AclRegexMatches tmp_matches, *tmp_matchesp = &tmp_matches; int rc = 0; regmatch_t *tmp_data; MATCHES_MEMSET( &tmp_matches ); tmp_data = &tmp_matches.dn_data[0]; bv.bv_len = sizeof( buf ) - 1; bv.bv_val = buf; rc = 0; if ( a->acl_attrval_style == ACL_STYLE_REGEX ) tmp_matchesp = matches; else switch ( a->acl_dn_style ) { case ACL_STYLE_REGEX: if ( !BER_BVISNULL( &a->acl_dn_pat ) ) { tmp_matchesp = matches; break; } /* FALLTHRU: applies also to ACL_STYLE_REGEX when pattern is "*" */ case ACL_STYLE_BASE: tmp_data[0].rm_so = 0; tmp_data[0].rm_eo = e->e_nname.bv_len; tmp_matches.dn_count = 1; break; case ACL_STYLE_ONE: case ACL_STYLE_SUBTREE: case ACL_STYLE_CHILDREN: tmp_data[0].rm_so = 0; tmp_data[0].rm_eo = e->e_nname.bv_len; tmp_data[1].rm_so = e->e_nname.bv_len - a->acl_dn_pat.bv_len; tmp_data[1].rm_eo = e->e_nname.bv_len; tmp_matches.dn_count = 2; break; default: /* error */ rc = 1; break; } if ( rc ) { continue; } if ( acl_string_expand( &bv, &b->a_set_pat, &e->e_nname, val, tmp_matchesp ) ) { continue; } } else { bv = b->a_set_pat; } if ( acl_match_set( &bv, op, e, NULL ) == 0 ) { continue; } } if ( b->a_authz.sai_ssf ) { Debug( LDAP_DEBUG_ACL, "<= check a_authz.sai_ssf: ACL %u > OP %u\n", b->a_authz.sai_ssf, op->o_ssf, 0 ); if ( b->a_authz.sai_ssf > op->o_ssf ) { continue; } } if ( b->a_authz.sai_transport_ssf ) { Debug( LDAP_DEBUG_ACL, "<= check a_authz.sai_transport_ssf: ACL %u > OP %u\n", b->a_authz.sai_transport_ssf, op->o_transport_ssf, 0 ); if ( b->a_authz.sai_transport_ssf > op->o_transport_ssf ) { continue; } } if ( b->a_authz.sai_tls_ssf ) { Debug( LDAP_DEBUG_ACL, "<= check a_authz.sai_tls_ssf: ACL %u > OP %u\n", b->a_authz.sai_tls_ssf, op->o_tls_ssf, 0 ); if ( b->a_authz.sai_tls_ssf > op->o_tls_ssf ) { continue; } } if ( b->a_authz.sai_sasl_ssf ) { Debug( LDAP_DEBUG_ACL, "<= check a_authz.sai_sasl_ssf: ACL %u > OP %u\n", b->a_authz.sai_sasl_ssf, op->o_sasl_ssf, 0 ); if ( b->a_authz.sai_sasl_ssf > op->o_sasl_ssf ) { continue; } } #ifdef SLAP_DYNACL if ( b->a_dynacl ) { slap_dynacl_t *da; slap_access_t tgrant, tdeny; Debug( LDAP_DEBUG_ACL, "<= check a_dynacl\n", 0, 0, 0 ); /* this case works different from the others above. * since dynamic ACL's themselves give permissions, we need * to first check b->a_access_mask, the ACL's access level. */ /* first check if the right being requested * is allowed by the ACL clause. */ if ( ! ACL_PRIV_ISSET( b->a_access_mask, a2pmask ) ) { continue; } /* start out with nothing granted, nothing denied */ ACL_INVALIDATE(tgrant); ACL_INVALIDATE(tdeny); for ( da = b->a_dynacl; da; da = da->da_next ) { slap_access_t grant, deny; ACL_INVALIDATE(grant); ACL_INVALIDATE(deny); Debug( LDAP_DEBUG_ACL, " <= check a_dynacl: %s\n", da->da_name, 0, 0 ); /* * XXXmanu Only DN matches are supplied * sending attribute values matches require * an API update */ (void)da->da_mask( da->da_private, op, e, desc, val, matches->dn_count, matches->dn_data, &grant, &deny ); tgrant |= grant; tdeny |= deny; } /* remove anything that the ACL clause does not allow */ tgrant &= b->a_access_mask & ACL_PRIV_MASK; tdeny &= ACL_PRIV_MASK; /* see if we have anything to contribute */ if( ACL_IS_INVALID(tgrant) && ACL_IS_INVALID(tdeny) ) { continue; } /* this could be improved by changing slap_acl_mask so that it can deal with * by clauses that return grant/deny pairs. Right now, it does either * additive or subtractive rights, but not both at the same time. So, * we need to combine the grant/deny pair into a single rights mask in * a smart way: if either grant or deny is "empty", then we use the * opposite as is, otherwise we remove any denied rights from the grant * rights mask and construct an additive mask. */ if (ACL_IS_INVALID(tdeny)) { modmask = tgrant | ACL_PRIV_ADDITIVE; } else if (ACL_IS_INVALID(tgrant)) { modmask = tdeny | ACL_PRIV_SUBSTRACTIVE; } else { modmask = (tgrant & ~tdeny) | ACL_PRIV_ADDITIVE; } } else #endif /* SLAP_DYNACL */ { modmask = b->a_access_mask; } Debug( LDAP_DEBUG_ACL, "<= acl_mask: [%d] applying %s (%s)\n", i, accessmask2str( modmask, accessmaskbuf, 1 ), b->a_type == ACL_CONTINUE ? "continue" : b->a_type == ACL_BREAK ? "break" : "stop" ); /* save old mask */ oldmask = *mask; if( ACL_IS_ADDITIVE(modmask) ) { /* add privs */ ACL_PRIV_SET( *mask, modmask ); /* cleanup */ ACL_PRIV_CLR( *mask, ~ACL_PRIV_MASK ); } else if( ACL_IS_SUBTRACTIVE(modmask) ) { /* substract privs */ ACL_PRIV_CLR( *mask, modmask ); /* cleanup */ ACL_PRIV_CLR( *mask, ~ACL_PRIV_MASK ); } else { /* assign privs */ *mask = modmask; } Debug( LDAP_DEBUG_ACL, "<= acl_mask: [%d] mask: %s\n", i, accessmask2str(*mask, accessmaskbuf, 1), 0 ); if( b->a_type == ACL_CONTINUE ) { continue; } else if ( b->a_type == ACL_BREAK ) { return ACL_BREAK; } else { return ACL_STOP; } } /* implicit "by * none" clause */ ACL_INIT(*mask); Debug( LDAP_DEBUG_ACL, "<= acl_mask: no more clauses, returning %s (stop)\n", accessmask2str(*mask, accessmaskbuf, 1), 0, 0 ); return ACL_STOP; } /* * acl_check_modlist - check access control on the given entry to see if * it allows the given modifications by the user associated with op. * returns 1 if mods allowed ok * 0 mods not allowed */ int acl_check_modlist( Operation *op, Entry *e, Modifications *mlist ) { struct berval *bv; AccessControlState state = ACL_STATE_INIT; Backend *be; int be_null = 0; int ret = 1; /* default is access allowed */ be = op->o_bd; if ( be == NULL ) { be = LDAP_STAILQ_FIRST(&backendDB); be_null = 1; op->o_bd = be; } assert( be != NULL ); /* If ADD attribute checking is not enabled, just allow it */ if ( op->o_tag == LDAP_REQ_ADD && !SLAP_DBACL_ADD( be )) return 1; /* short circuit root database access */ if ( be_isroot( op ) ) { Debug( LDAP_DEBUG_ACL, "<= acl_access_allowed: granted to database root\n", 0, 0, 0 ); goto done; } /* use backend default access if no backend acls */ if( op->o_bd != NULL && op->o_bd->be_acl == NULL && frontendDB->be_acl == NULL ) { Debug( LDAP_DEBUG_ACL, "=> access_allowed: backend default %s access %s to \"%s\"\n", access2str( ACL_WRITE ), op->o_bd->be_dfltaccess >= ACL_WRITE ? "granted" : "denied", op->o_dn.bv_val ); ret = (op->o_bd->be_dfltaccess >= ACL_WRITE); goto done; } for ( ; mlist != NULL; mlist = mlist->sml_next ) { /* * Internal mods are ignored by ACL_WRITE checking */ if ( mlist->sml_flags & SLAP_MOD_INTERNAL ) { Debug( LDAP_DEBUG_ACL, "acl: internal mod %s:" " modify access granted\n", mlist->sml_desc->ad_cname.bv_val, 0, 0 ); continue; } /* * no-user-modification operational attributes are ignored * by ACL_WRITE checking as any found here are not provided * by the user */ if ( is_at_no_user_mod( mlist->sml_desc->ad_type ) && ! ( mlist->sml_flags & SLAP_MOD_MANAGING ) ) { Debug( LDAP_DEBUG_ACL, "acl: no-user-mod %s:" " modify access granted\n", mlist->sml_desc->ad_cname.bv_val, 0, 0 ); continue; } switch ( mlist->sml_op ) { case LDAP_MOD_REPLACE: case LDAP_MOD_INCREMENT: /* * We must check both permission to delete the whole * attribute and permission to add the specific attributes. * This prevents abuse from selfwriters. */ if ( ! access_allowed( op, e, mlist->sml_desc, NULL, ( mlist->sml_flags & SLAP_MOD_MANAGING ) ? ACL_MANAGE : ACL_WDEL, &state ) ) { ret = 0; goto done; } if ( mlist->sml_values == NULL ) break; /* fall thru to check value to add */ case LDAP_MOD_ADD: case SLAP_MOD_ADD_IF_NOT_PRESENT: assert( mlist->sml_values != NULL ); if ( mlist->sml_op == SLAP_MOD_ADD_IF_NOT_PRESENT && attr_find( e->e_attrs, mlist->sml_desc ) ) { break; } for ( bv = mlist->sml_nvalues ? mlist->sml_nvalues : mlist->sml_values; bv->bv_val != NULL; bv++ ) { if ( ! access_allowed( op, e, mlist->sml_desc, bv, ( mlist->sml_flags & SLAP_MOD_MANAGING ) ? ACL_MANAGE : ACL_WADD, &state ) ) { ret = 0; goto done; } } break; case LDAP_MOD_DELETE: case SLAP_MOD_SOFTDEL: if ( mlist->sml_values == NULL ) { if ( ! access_allowed( op, e, mlist->sml_desc, NULL, ( mlist->sml_flags & SLAP_MOD_MANAGING ) ? ACL_MANAGE : ACL_WDEL, &state ) ) { ret = 0; goto done; } break; } for ( bv = mlist->sml_nvalues ? mlist->sml_nvalues : mlist->sml_values; bv->bv_val != NULL; bv++ ) { if ( ! access_allowed( op, e, mlist->sml_desc, bv, ( mlist->sml_flags & SLAP_MOD_MANAGING ) ? ACL_MANAGE : ACL_WDEL, &state ) ) { ret = 0; goto done; } } break; case SLAP_MOD_SOFTADD: /* allow adding attribute via modrdn thru */ break; default: assert( 0 ); /* not reached */ ret = 0; break; } } done: if (be_null) op->o_bd = NULL; return( ret ); } int acl_get_part( struct berval *list, int ix, char sep, struct berval *bv ) { int len; char *p; if ( bv ) { BER_BVZERO( bv ); } len = list->bv_len; p = list->bv_val; while ( len >= 0 && --ix >= 0 ) { while ( --len >= 0 && *p++ != sep ) ; } while ( len >= 0 && *p == ' ' ) { len--; p++; } if ( len < 0 ) { return -1; } if ( !bv ) { return 0; } bv->bv_val = p; while ( --len >= 0 && *p != sep ) { bv->bv_len++; p++; } while ( bv->bv_len > 0 && *--p == ' ' ) { bv->bv_len--; } return bv->bv_len; } typedef struct acl_set_gather_t { SetCookie *cookie; BerVarray bvals; } acl_set_gather_t; static int acl_set_cb_gather( Operation *op, SlapReply *rs ) { acl_set_gather_t *p = (acl_set_gather_t *)op->o_callback->sc_private; if ( rs->sr_type == REP_SEARCH ) { BerValue bvals[ 2 ]; BerVarray bvalsp = NULL; int j; for ( j = 0; !BER_BVISNULL( &rs->sr_attrs[ j ].an_name ); j++ ) { AttributeDescription *desc = rs->sr_attrs[ j ].an_desc; if ( desc == NULL ) { continue; } if ( desc == slap_schema.si_ad_entryDN ) { bvalsp = bvals; bvals[ 0 ] = rs->sr_entry->e_nname; BER_BVZERO( &bvals[ 1 ] ); } else { Attribute *a; a = attr_find( rs->sr_entry->e_attrs, desc ); if ( a != NULL ) { bvalsp = a->a_nvals; } } if ( bvalsp ) { p->bvals = slap_set_join( p->cookie, p->bvals, ( '|' | SLAP_SET_RREF ), bvalsp ); } } } else { switch ( rs->sr_type ) { case REP_SEARCHREF: case REP_INTERMEDIATE: /* ignore */ break; default: assert( rs->sr_type == REP_RESULT ); break; } } return 0; } BerVarray acl_set_gather( SetCookie *cookie, struct berval *name, AttributeDescription *desc ) { AclSetCookie *cp = (AclSetCookie *)cookie; int rc = 0; LDAPURLDesc *ludp = NULL; Operation op2 = { 0 }; SlapReply rs = {REP_RESULT}; AttributeName anlist[ 2 ], *anlistp = NULL; int nattrs = 0; slap_callback cb = { NULL, acl_set_cb_gather, NULL, NULL }; acl_set_gather_t p = { 0 }; /* this routine needs to return the bervals instead of * plain strings, since syntax is not known. It should * also return the syntax or some "comparison cookie". */ if ( strncasecmp( name->bv_val, "ldap:///", STRLENOF( "ldap:///" ) ) != 0 ) { return acl_set_gather2( cookie, name, desc ); } rc = ldap_url_parse( name->bv_val, &ludp ); if ( rc != LDAP_URL_SUCCESS ) { Debug( LDAP_DEBUG_TRACE, "%s acl_set_gather: unable to parse URL=\"%s\"\n", cp->asc_op->o_log_prefix, name->bv_val, 0 ); rc = LDAP_PROTOCOL_ERROR; goto url_done; } if ( ( ludp->lud_host && ludp->lud_host[0] ) || ludp->lud_exts ) { /* host part must be empty */ /* extensions parts must be empty */ Debug( LDAP_DEBUG_TRACE, "%s acl_set_gather: host/exts must be absent in URL=\"%s\"\n", cp->asc_op->o_log_prefix, name->bv_val, 0 ); rc = LDAP_PROTOCOL_ERROR; goto url_done; } /* Grab the searchbase and see if an appropriate database can be found */ ber_str2bv( ludp->lud_dn, 0, 0, &op2.o_req_dn ); rc = dnNormalize( 0, NULL, NULL, &op2.o_req_dn, &op2.o_req_ndn, cp->asc_op->o_tmpmemctx ); BER_BVZERO( &op2.o_req_dn ); if ( rc != LDAP_SUCCESS ) { Debug( LDAP_DEBUG_TRACE, "%s acl_set_gather: DN=\"%s\" normalize failed\n", cp->asc_op->o_log_prefix, ludp->lud_dn, 0 ); goto url_done; } op2.o_bd = select_backend( &op2.o_req_ndn, 1 ); if ( ( op2.o_bd == NULL ) || ( op2.o_bd->be_search == NULL ) ) { Debug( LDAP_DEBUG_TRACE, "%s acl_set_gather: no database could be selected for DN=\"%s\"\n", cp->asc_op->o_log_prefix, op2.o_req_ndn.bv_val, 0 ); rc = LDAP_NO_SUCH_OBJECT; goto url_done; } /* Grab the filter */ if ( ludp->lud_filter ) { ber_str2bv_x( ludp->lud_filter, 0, 0, &op2.ors_filterstr, cp->asc_op->o_tmpmemctx ); op2.ors_filter = str2filter_x( cp->asc_op, op2.ors_filterstr.bv_val ); if ( op2.ors_filter == NULL ) { Debug( LDAP_DEBUG_TRACE, "%s acl_set_gather: unable to parse filter=\"%s\"\n", cp->asc_op->o_log_prefix, op2.ors_filterstr.bv_val, 0 ); rc = LDAP_PROTOCOL_ERROR; goto url_done; } } else { op2.ors_filterstr = *slap_filterstr_objectClass_pres; op2.ors_filter = (Filter *)slap_filter_objectClass_pres; } /* Grab the scope */ op2.ors_scope = ludp->lud_scope; /* Grap the attributes */ if ( ludp->lud_attrs ) { int i; for ( ; ludp->lud_attrs[ nattrs ]; nattrs++ ) ; anlistp = slap_sl_calloc( sizeof( AttributeName ), nattrs + 2, cp->asc_op->o_tmpmemctx ); for ( i = 0, nattrs = 0; ludp->lud_attrs[ i ]; i++ ) { struct berval name; AttributeDescription *desc = NULL; const char *text = NULL; ber_str2bv( ludp->lud_attrs[ i ], 0, 0, &name ); rc = slap_bv2ad( &name, &desc, &text ); if ( rc == LDAP_SUCCESS ) { anlistp[ nattrs ].an_name = name; anlistp[ nattrs ].an_desc = desc; nattrs++; } } } else { anlistp = anlist; } anlistp[ nattrs ].an_name = desc->ad_cname; anlistp[ nattrs ].an_desc = desc; BER_BVZERO( &anlistp[ nattrs + 1 ].an_name ); p.cookie = cookie; op2.o_hdr = cp->asc_op->o_hdr; op2.o_tag = LDAP_REQ_SEARCH; op2.o_ndn = op2.o_bd->be_rootndn; op2.o_callback = &cb; slap_op_time( &op2.o_time, &op2.o_tincr ); op2.o_do_not_cache = 1; op2.o_is_auth_check = 0; ber_dupbv_x( &op2.o_req_dn, &op2.o_req_ndn, cp->asc_op->o_tmpmemctx ); op2.ors_slimit = SLAP_NO_LIMIT; op2.ors_tlimit = SLAP_NO_LIMIT; op2.ors_attrs = anlistp; op2.ors_attrsonly = 0; op2.o_private = cp->asc_op->o_private; op2.o_extra = cp->asc_op->o_extra; cb.sc_private = &p; rc = op2.o_bd->be_search( &op2, &rs ); if ( rc != 0 ) { goto url_done; } url_done:; if ( op2.ors_filter && op2.ors_filter != slap_filter_objectClass_pres ) { filter_free_x( cp->asc_op, op2.ors_filter, 1 ); } if ( !BER_BVISNULL( &op2.o_req_ndn ) ) { slap_sl_free( op2.o_req_ndn.bv_val, cp->asc_op->o_tmpmemctx ); } if ( !BER_BVISNULL( &op2.o_req_dn ) ) { slap_sl_free( op2.o_req_dn.bv_val, cp->asc_op->o_tmpmemctx ); } if ( ludp ) { ldap_free_urldesc( ludp ); } if ( anlistp && anlistp != anlist ) { slap_sl_free( anlistp, cp->asc_op->o_tmpmemctx ); } return p.bvals; } BerVarray acl_set_gather2( SetCookie *cookie, struct berval *name, AttributeDescription *desc ) { AclSetCookie *cp = (AclSetCookie *)cookie; BerVarray bvals = NULL; struct berval ndn; int rc = 0; /* this routine needs to return the bervals instead of * plain strings, since syntax is not known. It should * also return the syntax or some "comparison cookie". */ rc = dnNormalize( 0, NULL, NULL, name, &ndn, cp->asc_op->o_tmpmemctx ); if ( rc == LDAP_SUCCESS ) { if ( desc == slap_schema.si_ad_entryDN ) { bvals = (BerVarray)slap_sl_malloc( sizeof( BerValue ) * 2, cp->asc_op->o_tmpmemctx ); bvals[ 0 ] = ndn; BER_BVZERO( &bvals[ 1 ] ); BER_BVZERO( &ndn ); } else { backend_attribute( cp->asc_op, cp->asc_e, &ndn, desc, &bvals, ACL_NONE ); } if ( !BER_BVISNULL( &ndn ) ) { slap_sl_free( ndn.bv_val, cp->asc_op->o_tmpmemctx ); } } return bvals; } int acl_match_set ( struct berval *subj, Operation *op, Entry *e, struct berval *default_set_attribute ) { struct berval set = BER_BVNULL; int rc = 0; AclSetCookie cookie; if ( default_set_attribute == NULL ) { set = *subj; } else { struct berval subjdn, ndn = BER_BVNULL; struct berval setat; BerVarray bvals = NULL; const char *text; AttributeDescription *desc = NULL; /* format of string is "entry/setAttrName" */ if ( acl_get_part( subj, 0, '/', &subjdn ) < 0 ) { return 0; } if ( acl_get_part( subj, 1, '/', &setat ) < 0 ) { setat = *default_set_attribute; } /* * NOTE: dnNormalize honors the ber_len field * as the length of the dn to be normalized */ if ( slap_bv2ad( &setat, &desc, &text ) == LDAP_SUCCESS ) { if ( dnNormalize( 0, NULL, NULL, &subjdn, &ndn, op->o_tmpmemctx ) == LDAP_SUCCESS ) { backend_attribute( op, e, &ndn, desc, &bvals, ACL_NONE ); if ( bvals != NULL && !BER_BVISNULL( &bvals[0] ) ) { int i; set = bvals[0]; BER_BVZERO( &bvals[0] ); for ( i = 1; !BER_BVISNULL( &bvals[i] ); i++ ) /* count */ ; bvals[0].bv_val = bvals[i-1].bv_val; BER_BVZERO( &bvals[i-1] ); } ber_bvarray_free_x( bvals, op->o_tmpmemctx ); slap_sl_free( ndn.bv_val, op->o_tmpmemctx ); } } } if ( !BER_BVISNULL( &set ) ) { cookie.asc_op = op; cookie.asc_e = e; rc = ( slap_set_filter( acl_set_gather, (SetCookie *)&cookie, &set, &op->o_ndn, &e->e_nname, NULL ) > 0 ); if ( set.bv_val != subj->bv_val ) { slap_sl_free( set.bv_val, op->o_tmpmemctx ); } } return(rc); } #ifdef SLAP_DYNACL /* * dynamic ACL infrastructure */ static slap_dynacl_t *da_list = NULL; int slap_dynacl_register( slap_dynacl_t *da ) { slap_dynacl_t *tmp; for ( tmp = da_list; tmp; tmp = tmp->da_next ) { if ( strcasecmp( da->da_name, tmp->da_name ) == 0 ) { break; } } if ( tmp != NULL ) { return -1; } if ( da->da_mask == NULL ) { return -1; } da->da_private = NULL; da->da_next = da_list; da_list = da; return 0; } static slap_dynacl_t * slap_dynacl_next( slap_dynacl_t *da ) { if ( da ) { return da->da_next; } return da_list; } slap_dynacl_t * slap_dynacl_get( const char *name ) { slap_dynacl_t *da; for ( da = slap_dynacl_next( NULL ); da; da = slap_dynacl_next( da ) ) { if ( strcasecmp( da->da_name, name ) == 0 ) { break; } } return da; } #endif /* SLAP_DYNACL */ /* * statically built-in dynamic ACL initialization */ static int (*acl_init_func[])( void ) = { #ifdef SLAP_DYNACL /* TODO: remove when ACI will only be dynamic */ #if SLAPD_ACI_ENABLED == SLAPD_MOD_STATIC dynacl_aci_init, #endif /* SLAPD_ACI_ENABLED */ #endif /* SLAP_DYNACL */ NULL }; int acl_init( void ) { int i, rc; for ( i = 0; acl_init_func[ i ] != NULL; i++ ) { rc = (*(acl_init_func[ i ]))(); if ( rc != 0 ) { return rc; } } return 0; } int acl_string_expand( struct berval *bv, struct berval *pat, struct berval *dn_matches, struct berval *val_matches, AclRegexMatches *matches) { ber_len_t size; char *sp; char *dp; int flag; enum { DN_FLAG, VAL_FLAG } tflag; size = 0; bv->bv_val[0] = '\0'; bv->bv_len--; /* leave space for lone $ */ flag = 0; tflag = DN_FLAG; for ( dp = bv->bv_val, sp = pat->bv_val; size < bv->bv_len && sp < pat->bv_val + pat->bv_len ; sp++ ) { /* did we previously see a $ */ if ( flag ) { if ( flag == 1 && *sp == '$' ) { *dp++ = '$'; size++; flag = 0; tflag = DN_FLAG; } else if ( flag == 2 && *sp == 'v' /*'}'*/) { tflag = VAL_FLAG; } else if ( flag == 2 && *sp == 'd' /*'}'*/) { tflag = DN_FLAG; } else if ( flag == 1 && *sp == '{' /*'}'*/) { flag = 2; } else if ( *sp >= '0' && *sp <= '9' ) { int nm; regmatch_t *m; char *data; int n; int i; int l; n = *sp - '0'; if ( flag == 2 ) { for ( sp++; *sp != '\0' && *sp != /*'{'*/ '}'; sp++ ) { if ( *sp >= '0' && *sp <= '9' ) { n = 10*n + ( *sp - '0' ); } } if ( *sp != /*'{'*/ '}' ) { /* FIXME: error */ return 1; } } switch (tflag) { case DN_FLAG: nm = matches->dn_count; m = matches->dn_data; data = dn_matches ? dn_matches->bv_val : NULL; break; case VAL_FLAG: nm = matches->val_count; m = matches->val_data; data = val_matches ? val_matches->bv_val : NULL; break; default: assert( 0 ); } if ( n >= nm ) { /* FIXME: error */ return 1; } if ( data == NULL ) { /* FIXME: error */ return 1; } *dp = '\0'; i = m[n].rm_so; l = m[n].rm_eo; for ( ; size < bv->bv_len && i < l; size++, i++ ) { *dp++ = data[i]; } *dp = '\0'; flag = 0; tflag = DN_FLAG; } } else { if (*sp == '$') { flag = 1; } else { *dp++ = *sp; size++; } } } if ( flag ) { /* must have ended with a single $ */ *dp++ = '$'; size++; } *dp = '\0'; bv->bv_len = size; Debug( LDAP_DEBUG_ACL, "=> acl_string_expand: pattern: %.*s\n", (int)pat->bv_len, pat->bv_val, 0 ); Debug( LDAP_DEBUG_ACL, "=> acl_string_expand: expanded: %s\n", bv->bv_val, 0, 0 ); return 0; } static int regex_matches( struct berval *pat, /* pattern to expand and match against */ char *str, /* string to match against pattern */ struct berval *dn_matches, /* buffer with $N expansion variables from DN */ struct berval *val_matches, /* buffer with $N expansion variables from val */ AclRegexMatches *matches /* offsets in buffer for $N expansion variables */ ) { regex_t re; char newbuf[ACL_BUF_SIZE]; struct berval bv; int rc; bv.bv_len = sizeof( newbuf ) - 1; bv.bv_val = newbuf; if (str == NULL) { str = ""; }; acl_string_expand( &bv, pat, dn_matches, val_matches, matches ); rc = regcomp( &re, newbuf, REG_EXTENDED|REG_ICASE ); if ( rc ) { char error[ACL_BUF_SIZE]; regerror( rc, &re, error, sizeof( error ) ); Debug( LDAP_DEBUG_TRACE, "compile( \"%s\", \"%s\") failed %s\n", pat->bv_val, str, error ); return( 0 ); } rc = regexec( &re, str, 0, NULL, 0 ); regfree( &re ); Debug( LDAP_DEBUG_TRACE, "=> regex_matches: string: %s\n", str, 0, 0 ); Debug( LDAP_DEBUG_TRACE, "=> regex_matches: rc: %d %s\n", rc, !rc ? "matches" : "no matches", 0 ); return( !rc ); }