/* Unix SMB/CIFS implementation. KCC service Copyright (C) Crístian Deives 2010 This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see . */ #include "includes.h" #include "dsdb/samdb/samdb.h" #include "lib/messaging/irpc.h" #include "librpc/gen_ndr/ndr_misc.h" #include "dsdb/kcc/kcc_service.h" #define FLAG_CR_NTDS_NC 0x00000001 #define FLAG_CR_NTDS_DOMAIN 0x00000002 #define NTDSCONN_OPT_IS_GENERATED 0x00000001 #define NTDSCONN_OPT_TWOWAY_SYNC 0x00000002 #define NTDSCONN_OPT_OVERRIDE_NOTIFY_DEFAULT 0x00000004 #define NTDSCONN_OPT_USE_NOTIFY 0x00000008 #define NTDSCONN_OPT_DISABLE_INTERSITE_COMPRESSION 0x00000010 #define NTDSCONN_OPT_USER_OWNED_SCHEDULE 0x00000020 #define NTDSCONN_OPT_RODC_TOPOLOGY 0x00000040 #define NTDSDSA_OPT_IS_GC 0x00000001 #define NTDSSETTINGS_OPT_IS_TOPL_DETECT_STALE_DISABLED 0x00000008 #define NTDSSETTINGS_OPT_IS_RAND_BH_SELECTION_DISABLED 0x00000100 #define NTDSSETTINGS_OPT_W2K3_BRIDGES_REQUIRED 0x00001000 #define NTDSSITELINK_OPT_USE_NOTIFY 0x00000001 #define NTDSSITELINK_OPT_TWOWAY_SYNC 0x00000002 #define NTDSSITELINK_OPT_DISABLE_COMPRESSION 0x00000004 #define NTDSTRANSPORT_OPT_BRIDGES_REQUIRED 0x00000002 #define DS_BEHAVIOR_WIN2008 3 /** replication parameters of a graph edge */ struct kcctpl_repl_info { uint32_t cost; uint32_t interval; uint32_t options; uint8_t schedule[84]; }; /** color of a vertex */ enum kcctpl_color { RED, BLACK, WHITE }; /** a GUID array list */ struct GUID_list { struct GUID *data; uint32_t count; }; /** a vertex in the site graph */ struct kcctpl_vertex { struct GUID id; struct GUID_list edge_ids; enum kcctpl_color color; struct GUID_list accept_red_red; struct GUID_list accept_black; struct kcctpl_repl_info repl_info; uint32_t dist_to_red; /* Dijkstra data */ struct GUID root_id; bool demoted; /* Kruskal data */ struct GUID component_id; uint32_t component_index; }; /** fully connected subgraph of vertices */ struct kcctpl_multi_edge { struct GUID id; struct GUID_list vertex_ids; struct GUID type; struct kcctpl_repl_info repl_info; bool directed; }; /** set of transitively connected kcc_multi_edge's. all edges within the set * have the same type. */ struct kcctpl_multi_edge_set { struct GUID id; struct GUID_list edge_ids; }; /** a vertices array list */ struct kcctpl_vertex_list { struct kcctpl_vertex *data; uint32_t count; }; /** an edges array list */ struct kcctpl_multi_edge_list { struct kcctpl_multi_edge *data; uint32_t count; }; /** an edge sets array list */ struct kcctpl_multi_edge_set_list { struct kcctpl_multi_edge_set *data; uint32_t count; }; /** a site graph */ struct kcctpl_graph { struct kcctpl_vertex_list vertices; struct kcctpl_multi_edge_list edges; struct kcctpl_multi_edge_set_list edge_sets; }; /** path found in the graph between two non-white vertices */ struct kcctpl_internal_edge { struct GUID v1id; struct GUID v2id; bool red_red; struct kcctpl_repl_info repl_info; struct GUID type; }; /** an internal edges array list */ struct kcctpl_internal_edge_list { struct kcctpl_internal_edge *data; uint32_t count; }; /** an LDB messages array list */ struct message_list { struct ldb_message *data; uint32_t count; }; /** * sort internal edges based on: * - descending red_red, * - ascending repl_info.cost, * - descending available time in repl_info.schedule, * - ascending v1id, * - ascending v2id, * - ascending type. * * this function is used in 'kcctpl_kruskal'. */ static int kcctpl_sort_internal_edges(const void *internal_edge1, const void *internal_edge2) { const struct kcctpl_internal_edge *ie1, *ie2; int cmp_red_red; ie1 = (const struct kcctpl_internal_edge *) internal_edge1; ie2 = (const struct kcctpl_internal_edge *) internal_edge2; cmp_red_red = ie2->red_red - ie1->red_red; if (cmp_red_red == 0) { int cmp_cost = ie1->repl_info.cost - ie2->repl_info.cost; if (cmp_cost == 0) { uint32_t available1, available2, i; int cmp_schedule; available1 = available2 = 0; for (i = 0; i < 84; i++) { if (ie1->repl_info.schedule[i] == 0) { available1++; } if (ie2->repl_info.schedule[i] == 0) { available2++; } } cmp_schedule = available2 - available1; if (cmp_schedule == 0) { int cmp_v1id = GUID_compare(&ie1->v1id, &ie2->v1id); if (cmp_v1id == 0) { int cmp_v2id = GUID_compare(&ie1->v2id, &ie2->v2id); if (cmp_v2id == 0) { return GUID_compare(&ie1->type, &ie2->type); } else { return cmp_v2id; } } else { return cmp_v1id; } } else { return cmp_schedule; } } else { return cmp_cost; } } else { return cmp_red_red; } } /** * sort vertices based on the following criteria: * - ascending color (RED < BLACK), * - ascending repl_info.cost, * - ascending id. * * this function is used in 'kcctpl_process_edge'. */ static int kcctpl_sort_vertices(const void *vertex1, const void *vertex2) { const struct kcctpl_vertex *v1, *v2; int cmp_color; v1 = (const struct kcctpl_vertex *) vertex1; v2 = (const struct kcctpl_vertex *) vertex2; cmp_color = v1->color - v2->color; if (cmp_color == 0) { int cmp_cost = v1->repl_info.cost - v2->repl_info.cost; if (cmp_cost == 0) { return GUID_compare(&v1->id, &v2->id); } else { return cmp_cost; } } else { return cmp_color; } } /** * sort bridgehead elements (nTDSDSA) based on the following criteria: * - GC servers precede non-GC servers * - ascending objectGUID * * this function is used in 'kcctpl_get_all_bridgehead_dcs'. */ static int kcctpl_sort_bridgeheads(const void *bridgehead1, const void *bridgehead2) { const struct ldb_message *bh1, *bh2; uint64_t bh1_opts, bh2_opts, cmp_gc; bh1 = (const struct ldb_message *) bridgehead1; bh2 = (const struct ldb_message *) bridgehead2; bh1_opts = samdb_result_int64(bh1, "options", 0); bh2_opts = samdb_result_int64(bh2, "options", 0); cmp_gc = (bh1_opts & NTDSDSA_OPT_IS_GC) - (bh2_opts & NTDSDSA_OPT_IS_GC); if (cmp_gc == 0) { struct GUID bh1_id, bh2_id; bh1_id = samdb_result_guid(bh1, "objectGUID"); bh2_id = samdb_result_guid(bh2, "objectGUID"); return GUID_compare(&bh1_id, &bh2_id); } else { return cmp_gc; } } /** * sort bridgehead elements (nTDSDSA) in a random order. * * this function is used in 'kcctpl_get_all_bridgehead_dcs'. */ static void kcctpl_shuffle_bridgeheads(struct message_list bridgeheads) { uint32_t i; srandom(time(NULL)); for (i = bridgeheads.count; i > 1; i--) { uint32_t r; struct ldb_message tmp; r = random() % i; tmp = bridgeheads.data[i - 1]; bridgeheads.data[i - 1] = bridgeheads.data[r]; bridgeheads.data[r] = tmp; } } /** * find a graph vertex based on its GUID. */ static struct kcctpl_vertex *kcctpl_find_vertex_by_guid(struct kcctpl_graph *graph, struct GUID guid) { uint32_t i; for (i = 0; i < graph->vertices.count; i++) { if (GUID_equal(&graph->vertices.data[i].id, &guid)) { return &graph->vertices.data[i]; } } return NULL; } /** * find a graph edge based on its GUID. */ static struct kcctpl_multi_edge *kcctpl_find_edge_by_guid(struct kcctpl_graph *graph, struct GUID guid) { uint32_t i; for (i = 0; i < graph->edges.count; i++) { if (GUID_equal(&graph->edges.data[i].id, &guid)) { return &graph->edges.data[i]; } } return NULL; } /** * find a graph edge that contains a vertex with the specified GUID. the first * occurrence will be returned. */ static struct kcctpl_multi_edge *kcctpl_find_edge_by_vertex_guid(struct kcctpl_graph *graph, struct GUID guid) { uint32_t i; for (i = 0; i < graph->edges.count; i++) { struct kcctpl_multi_edge *edge; uint32_t j; edge = &graph->edges.data[i]; for (j = 0; j < edge->vertex_ids.count; j++) { struct GUID vertex_guid = edge->vertex_ids.data[j]; struct GUID *p = &guid; if (GUID_equal(&vertex_guid, p)) { return edge; } } } return NULL; } /** * search for an occurrence of a GUID inside a list of GUIDs. */ static bool kcctpl_guid_list_contains(struct GUID_list list, struct GUID guid) { uint32_t i; for (i = 0; i < list.count; i++) { if (GUID_equal(&list.data[i], &guid)) { return true; } } return false; } /** * search for an occurrence of an ldb_message inside a list of ldb_messages, * based on the ldb_message's DN. */ static bool kcctpl_message_list_contains_dn(struct message_list list, struct ldb_dn *dn) { uint32_t i; for (i = 0; i < list.count; i++) { struct ldb_message *message = &list.data[i]; if (ldb_dn_compare(message->dn, dn) == 0) { return true; } } return false; } /** * get the Transports DN * (CN=Inter-Site Transports,CN=Sites,CN=Configuration,DC=). */ static struct ldb_dn *kcctpl_transports_dn(struct ldb_context *ldb, TALLOC_CTX *mem_ctx) { struct ldb_dn *sites_dn; bool ok; sites_dn = samdb_sites_dn(ldb, mem_ctx); if (!sites_dn) { return NULL; } ok = ldb_dn_add_child_fmt(sites_dn, "CN=Inter-Site Transports"); if (!ok) { talloc_free(sites_dn); return NULL; } return sites_dn; } /** * get the domain local site object. */ static struct ldb_message *kcctpl_local_site(struct ldb_context *ldb, TALLOC_CTX *mem_ctx) { int ret; TALLOC_CTX *tmp_ctx; struct ldb_dn *sites_dn; struct ldb_result *res; const char * const attrs[] = { "objectGUID", "options", NULL }; tmp_ctx = talloc_new(ldb); sites_dn = samdb_sites_dn(ldb, tmp_ctx); if (!sites_dn) { talloc_free(tmp_ctx); return NULL; } ret = ldb_search(ldb, tmp_ctx, &res, sites_dn, LDB_SCOPE_SUBTREE, attrs, "objectClass=site"); if (ret != LDB_SUCCESS || res->count == 0) { talloc_free(tmp_ctx); return NULL; } talloc_steal(mem_ctx, res); talloc_free(tmp_ctx); return res->msgs[0]; } /* * compare two internal edges for equality. every field of the structure will be * compared. */ static bool kcctpl_internal_edge_equal(struct kcctpl_internal_edge *edge1, struct kcctpl_internal_edge *edge2) { if (!edge1 || !edge2) { return false; } if (!GUID_equal(&edge1->v1id, &edge2->v1id)) { return false; } if (!GUID_equal(&edge1->v2id, &edge2->v2id)) { return false; } if (edge1->red_red != edge2->red_red) { return false; } if (edge1->repl_info.cost != edge2->repl_info.cost || edge1->repl_info.interval != edge2->repl_info.interval || edge1->repl_info.options != edge2->repl_info.options || memcmp(&edge1->repl_info.schedule, &edge2->repl_info.schedule, 84) != 0) { return false; } if (!GUID_equal(&edge1->type, &edge2->type)) { return false; } return true; } /** * create a kcctpl_graph instance. */ static NTSTATUS kcctpl_create_graph(TALLOC_CTX *mem_ctx, struct GUID_list guids, struct kcctpl_graph **_graph) { struct kcctpl_graph *graph; uint32_t i; graph = talloc_zero(mem_ctx, struct kcctpl_graph); NT_STATUS_HAVE_NO_MEMORY(graph); graph->vertices.count = guids.count; graph->vertices.data = talloc_zero_array(graph, struct kcctpl_vertex, guids.count); NT_STATUS_HAVE_NO_MEMORY_AND_FREE(graph->vertices.data, graph); TYPESAFE_QSORT(guids.data, guids.count, GUID_compare); for (i = 0; i < guids.count; i++) { graph->vertices.data[i].id = guids.data[i]; } *_graph = graph; return NT_STATUS_OK; } /** * create a kcctpl_multi_edge instance. */ static NTSTATUS kcctpl_create_edge(struct ldb_context *ldb, TALLOC_CTX *mem_ctx, struct GUID type, struct ldb_message *site_link, struct kcctpl_multi_edge **_edge) { struct kcctpl_multi_edge *edge; TALLOC_CTX *tmp_ctx; struct ldb_dn *sites_dn; struct ldb_result *res; const char * const attrs[] = { "siteList", NULL }; int ret; struct ldb_message_element *el; unsigned int i; struct ldb_val val; tmp_ctx = talloc_new(mem_ctx); NT_STATUS_HAVE_NO_MEMORY(tmp_ctx); edge = talloc_zero(tmp_ctx, struct kcctpl_multi_edge); NT_STATUS_HAVE_NO_MEMORY_AND_FREE(edge, tmp_ctx); edge->id = samdb_result_guid(site_link, "objectGUID"); sites_dn = samdb_sites_dn(ldb, tmp_ctx); if (!sites_dn) { DEBUG(1, (__location__ ": failed to find our own Sites DN\n")); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } ret = ldb_search(ldb, tmp_ctx, &res, sites_dn, LDB_SCOPE_SUBTREE, attrs, "objectGUID=%s", GUID_string(tmp_ctx, &edge->id)); if (ret != LDB_SUCCESS) { DEBUG(1, (__location__ ": failed to find siteLink object %s: " "%s\n", GUID_string(tmp_ctx, &edge->id), ldb_strerror(ret))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } if (res->count == 0) { DEBUG(1, (__location__ ": failed to find siteLink object %s\n", GUID_string(tmp_ctx, &edge->id))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } el = ldb_msg_find_element(res->msgs[0], "siteList"); if (!el) { DEBUG(1, (__location__ ": failed to find siteList attribute of " "object %s\n", ldb_dn_get_linearized(res->msgs[0]->dn))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } edge->vertex_ids.data = talloc_array(edge, struct GUID, el->num_values); NT_STATUS_HAVE_NO_MEMORY_AND_FREE(edge->vertex_ids.data, tmp_ctx); edge->vertex_ids.count = el->num_values; for (i = 0; i < el->num_values; i++) { struct ldb_dn *dn; struct GUID guid; val = el->values[i]; dn = ldb_dn_from_ldb_val(tmp_ctx, ldb, &val); if (!dn) { DEBUG(1, (__location__ ": failed to read a DN from " "siteList attribute of %s\n", ldb_dn_get_linearized(res->msgs[0]->dn))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } ret = dsdb_find_guid_by_dn(ldb, dn, &guid); if (ret != LDB_SUCCESS) { DEBUG(1, (__location__ ": failed to find objectGUID " "for object %s: %s\n", ldb_dn_get_linearized(dn), ldb_strerror(ret))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } edge->vertex_ids.data[i] = guid; } edge->repl_info.cost = samdb_result_int64(site_link, "cost", 0); edge->repl_info.options = samdb_result_int64(site_link, "options", 0); edge->repl_info.interval = samdb_result_int64(site_link, "replInterval", 0); /* TODO: edge->repl_info.schedule = site_link!schedule */ edge->type = type; edge->directed = false; *_edge = talloc_steal(mem_ctx, edge); talloc_free(tmp_ctx); return NT_STATUS_OK; } /** * create a kcctpl_multi_edge_set instance containing edges for all siteLink * objects. */ static NTSTATUS kcctpl_create_auto_edge_set(struct kcctpl_graph *graph, struct GUID type, struct ldb_result *res_site_link, struct kcctpl_multi_edge_set **_set) { struct kcctpl_multi_edge_set *set; TALLOC_CTX *tmp_ctx; uint32_t i; tmp_ctx = talloc_new(graph); NT_STATUS_HAVE_NO_MEMORY(tmp_ctx); set = talloc_zero(tmp_ctx, struct kcctpl_multi_edge_set); NT_STATUS_HAVE_NO_MEMORY_AND_FREE(set, tmp_ctx); for (i = 0; i < res_site_link->count; i++) { struct GUID site_link_guid; struct kcctpl_multi_edge *edge; site_link_guid = samdb_result_guid(res_site_link->msgs[i], "objectGUID"); edge = kcctpl_find_edge_by_guid(graph, site_link_guid); if (!edge) { DEBUG(1, (__location__ ": failed to find a graph edge " "with ID=%s\n", GUID_string(tmp_ctx, &site_link_guid))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } if (GUID_equal(&edge->type, &type)) { struct GUID *new_data; new_data = talloc_realloc(set, set->edge_ids.data, struct GUID, set->edge_ids.count + 1); NT_STATUS_HAVE_NO_MEMORY_AND_FREE(new_data, tmp_ctx); new_data[set->edge_ids.count] = site_link_guid; set->edge_ids.data = new_data; set->edge_ids.count++; } } *_set = talloc_steal(graph, set); return NT_STATUS_OK; } /** * create a kcctpl_multi_edge_set instance. */ static NTSTATUS kcctpl_create_edge_set(struct ldb_context *ldb, struct kcctpl_graph *graph, struct GUID type, struct ldb_message *bridge, struct kcctpl_multi_edge_set **_set) { struct kcctpl_multi_edge_set *set; TALLOC_CTX *tmp_ctx; struct ldb_message_element *el; unsigned int i; tmp_ctx = talloc_new(ldb); NT_STATUS_HAVE_NO_MEMORY(tmp_ctx); set = talloc_zero(tmp_ctx, struct kcctpl_multi_edge_set); NT_STATUS_HAVE_NO_MEMORY_AND_FREE(set, tmp_ctx); set->id = samdb_result_guid(bridge, "objectGUID"); el = ldb_msg_find_element(bridge, "siteLinkList"); if (!el) { DEBUG(1, (__location__ ": failed to find siteLinkList " "attribute of object %s\n", ldb_dn_get_linearized(bridge->dn))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } for (i = 0; i < el->num_values; i++) { struct ldb_val val; struct ldb_dn *dn; struct GUID site_link_guid; int ret; struct kcctpl_multi_edge *edge; val = el->values[i]; dn = ldb_dn_from_ldb_val(tmp_ctx, ldb, &val); if (!dn) { DEBUG(1, (__location__ ": failed to read a DN from " "siteList attribute of %s\n", ldb_dn_get_linearized(bridge->dn))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } ret = dsdb_find_guid_by_dn(ldb, dn, &site_link_guid); if (ret != LDB_SUCCESS) { DEBUG(1, (__location__ ": failed to find objectGUID " "for object %s: %s\n", ldb_dn_get_linearized(dn), ldb_strerror(ret))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } edge = kcctpl_find_edge_by_guid(graph, site_link_guid); if (!edge) { DEBUG(1, (__location__ ": failed to find a graph edge " "with ID=%s\n", GUID_string(tmp_ctx, &site_link_guid))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } if (GUID_equal(&edge->type, &type)) { struct GUID *new_data; new_data = talloc_realloc(set, set->edge_ids.data, struct GUID, set->edge_ids.count + 1); NT_STATUS_HAVE_NO_MEMORY_AND_FREE(new_data, tmp_ctx); new_data[set->edge_ids.count] = site_link_guid; set->edge_ids.data = new_data; set->edge_ids.count++; } } *_set = talloc_steal(graph, set); talloc_free(tmp_ctx); return NT_STATUS_OK; } /** * set up a kcctpl_graph, populated with a kcctpl_vertex for each site object, a * kcctpl_multi_edge for each siteLink object, and a kcctpl_multi_edge_set for * each siteLinkBridge object (or implied siteLinkBridge). */ static NTSTATUS kcctpl_setup_graph(struct ldb_context *ldb, TALLOC_CTX *mem_ctx, struct kcctpl_graph **_graph) { struct kcctpl_graph *graph; struct ldb_dn *sites_dn, *transports_dn; TALLOC_CTX *tmp_ctx; struct ldb_result *res; const char * const transport_attrs[] = { "objectGUID", NULL }; const char * const site_attrs[] = { "objectGUID", "options", NULL }; const char * const attrs[] = { "objectGUID", "cost", "options", "replInterval", "schedule", NULL }; const char * const site_link_bridge_attrs[] = { "objectGUID", "siteLinkList", NULL }; int ret; struct GUID_list vertex_ids; unsigned int i; NTSTATUS status; struct ldb_message *site; uint64_t site_opts; tmp_ctx = talloc_new(mem_ctx); NT_STATUS_HAVE_NO_MEMORY(tmp_ctx); sites_dn = samdb_sites_dn(ldb, tmp_ctx); if (!sites_dn) { DEBUG(1, (__location__ ": failed to find our own Sites DN\n")); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } ret = ldb_search(ldb, tmp_ctx, &res, sites_dn, LDB_SCOPE_SUBTREE, site_attrs, "objectClass=site"); if (ret != LDB_SUCCESS) { DEBUG(1, (__location__ ": failed to find site objects under " "%s: %s\n", ldb_dn_get_linearized(sites_dn), ldb_strerror(ret))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } ZERO_STRUCT(vertex_ids); for (i = 0; i < res->count; i++) { struct GUID guid, *new_data; guid = samdb_result_guid(res->msgs[i], "objectGUID"); new_data = talloc_realloc(tmp_ctx, vertex_ids.data, struct GUID, vertex_ids.count + 1); NT_STATUS_HAVE_NO_MEMORY_AND_FREE(new_data, tmp_ctx); new_data[vertex_ids.count] = guid; vertex_ids.data = new_data; vertex_ids.count++; } status = kcctpl_create_graph(tmp_ctx, vertex_ids, &graph); if (NT_STATUS_IS_ERR(status)) { DEBUG(1, (__location__ ": failed to create graph: %s\n", nt_errstr(status))); talloc_free(tmp_ctx); return status; } site = kcctpl_local_site(ldb, tmp_ctx); if (!site) { DEBUG(1, (__location__ ": failed to find our own local DC's " "site\n")); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } site_opts = samdb_result_int64(site, "options", 0); transports_dn = kcctpl_transports_dn(ldb, tmp_ctx); if (!transports_dn) { DEBUG(1, (__location__ ": failed to find our own Inter-Site " "Transports DN\n")); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } ret = ldb_search(ldb, tmp_ctx, &res, transports_dn, LDB_SCOPE_ONELEVEL, transport_attrs, "objectClass=interSiteTransport"); if (ret != LDB_SUCCESS) { DEBUG(1, (__location__ ": failed to find interSiteTransport " "objects under %s: %s\n", ldb_dn_get_linearized(transports_dn), ldb_strerror(ret))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } for (i = 0; i < res->count; i++) { struct ldb_message *transport; struct ldb_result *res_site_link; struct GUID transport_guid; unsigned int j; uint64_t transport_opts; transport = res->msgs[i]; ret = ldb_search(ldb, tmp_ctx, &res_site_link, transport->dn, LDB_SCOPE_SUBTREE, attrs, "objectClass=siteLink"); if (ret != LDB_SUCCESS) { DEBUG(1, (__location__ ": failed to find siteLink " "objects under %s: %s\n", ldb_dn_get_linearized(transport->dn), ldb_strerror(ret))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } transport_guid = samdb_result_guid(transport, "objectGUID"); for (j = 0; j < res_site_link->count; j++) { struct kcctpl_multi_edge *edge, *new_data; status = kcctpl_create_edge(ldb, graph, transport_guid, res_site_link->msgs[j], &edge); if (NT_STATUS_IS_ERR(status)) { DEBUG(1, (__location__ ": failed to create " "edge: %s\n", nt_errstr(status))); talloc_free(tmp_ctx); return status; } new_data = talloc_realloc(graph, graph->edges.data, struct kcctpl_multi_edge, graph->edges.count + 1); NT_STATUS_HAVE_NO_MEMORY_AND_FREE(new_data, tmp_ctx); new_data[graph->edges.count] = *edge; graph->edges.data = new_data; graph->edges.count++; } transport_opts = samdb_result_int64(transport, "options", 0); if (!(transport_opts & NTDSTRANSPORT_OPT_BRIDGES_REQUIRED) && !(site_opts & NTDSSETTINGS_OPT_W2K3_BRIDGES_REQUIRED)) { struct kcctpl_multi_edge_set *edge_set, *new_data; status = kcctpl_create_auto_edge_set(graph, transport_guid, res_site_link, &edge_set); if (NT_STATUS_IS_ERR(status)) { DEBUG(1, (__location__ ": failed to create " "edge set: %s\n", nt_errstr(status))); talloc_free(tmp_ctx); return status; } new_data = talloc_realloc(graph, graph->edge_sets.data, struct kcctpl_multi_edge_set, graph->edge_sets.count + 1); NT_STATUS_HAVE_NO_MEMORY_AND_FREE(new_data, tmp_ctx); new_data[graph->edge_sets.count] = *edge_set; graph->edge_sets.data = new_data; graph->edge_sets.count++; } else { ret = ldb_search(ldb, tmp_ctx, &res_site_link, transport->dn, LDB_SCOPE_SUBTREE, site_link_bridge_attrs, "objectClass=siteLinkBridge"); if (ret != LDB_SUCCESS) { DEBUG(1, (__location__ ": failed to find " "siteLinkBridge objects under %s: " "%s\n", ldb_dn_get_linearized(transport->dn), ldb_strerror(ret))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } for (j = 0; j < res_site_link->count; j++) { struct ldb_message *bridge; struct kcctpl_multi_edge_set *edge_set, *new_data; bridge = res_site_link->msgs[j]; status = kcctpl_create_edge_set(ldb, graph, transport_guid, bridge, &edge_set); if (NT_STATUS_IS_ERR(status)) { DEBUG(1, (__location__ ": failed to " "create edge set: %s\n", nt_errstr(status))); talloc_free(tmp_ctx); return status; } new_data = talloc_realloc(graph, graph->edge_sets.data, struct kcctpl_multi_edge_set, graph->edge_sets.count + 1); NT_STATUS_HAVE_NO_MEMORY_AND_FREE(new_data, tmp_ctx); new_data[graph->edge_sets.count] = *edge_set; graph->edge_sets.data = new_data; graph->edge_sets.count++; } } } *_graph = talloc_steal(mem_ctx, graph); talloc_free(tmp_ctx); return NT_STATUS_OK; } /** * determine whether a given DC is known to be in a failed state. */ static NTSTATUS kcctpl_bridgehead_dc_failed(struct ldb_context *ldb, struct GUID guid, bool detect_failed_dcs, bool *_failed) { TALLOC_CTX *tmp_ctx; struct ldb_dn *settings_dn; struct ldb_result *res; const char * const attrs[] = { "options", NULL }; int ret; struct ldb_message *settings; uint64_t settings_opts; bool failed; tmp_ctx = talloc_new(ldb); NT_STATUS_HAVE_NO_MEMORY(tmp_ctx); settings_dn = samdb_ntds_settings_dn(ldb); if (!settings_dn) { DEBUG(1, (__location__ ": failed to find our own NTDS Settings " "DN\n")); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } ret = ldb_search(ldb, tmp_ctx, &res, settings_dn, LDB_SCOPE_BASE, attrs, "objectClass=nTDSSiteSettings"); if (ret != LDB_SUCCESS) { DEBUG(1, (__location__ ": failed to find site settings object " "%s: %s\n", ldb_dn_get_linearized(settings_dn), ldb_strerror(ret))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } if (res->count == 0) { DEBUG(1, ("failed to find site settings object %s\n", ldb_dn_get_linearized(settings_dn))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } settings = res->msgs[0]; settings_opts = samdb_result_int64(settings, "options", 0); if (settings_opts & NTDSSETTINGS_OPT_IS_TOPL_DETECT_STALE_DISABLED) { failed = false; } else if (true) { /* TODO: how to get kCCFailedLinks and kCCFailedConnections? */ failed = true; } else { failed = detect_failed_dcs; } *_failed = failed; talloc_free(tmp_ctx); return NT_STATUS_OK; } /** * get all bridgehead DCs satisfying the given criteria. */ static NTSTATUS kcctpl_get_all_bridgehead_dcs(struct kccsrv_service *service, TALLOC_CTX *mem_ctx, struct GUID site_guid, struct ldb_message *cross_ref, struct ldb_message *transport, bool partial_replica_okay, bool detect_failed_dcs, struct message_list *_bridgeheads) { struct message_list bridgeheads, all_dcs_in_site; TALLOC_CTX *tmp_ctx; struct ldb_result *res; struct ldb_dn *sites_dn, *schemas_dn; const char * const attrs[] = { "options", NULL }; int ret; struct ldb_message *site, *schema; const char * const dc_attrs[] = { "objectGUID", "options", NULL }; struct ldb_message_element *el; unsigned int i; const char *transport_name, *transport_address_attr; uint64_t site_opts; ZERO_STRUCT(bridgeheads); tmp_ctx = talloc_new(mem_ctx); NT_STATUS_HAVE_NO_MEMORY(tmp_ctx); sites_dn = samdb_sites_dn(service->samdb, tmp_ctx); if (!sites_dn) { DEBUG(1, (__location__ ": failed to find our own Sites DN\n")); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } ret = ldb_search(service->samdb, tmp_ctx, &res, sites_dn, LDB_SCOPE_ONELEVEL, attrs, "(&(objectClass=site)(objectGUID=%s))", GUID_string(tmp_ctx, &site_guid)); if (ret != LDB_SUCCESS) { DEBUG(1, (__location__ ": failed to find site object %s: %s\n", GUID_string(tmp_ctx, &site_guid), ldb_strerror(ret))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } if (res->count == 0) { DEBUG(1, (__location__ ": failed to find site object %s\n", GUID_string(tmp_ctx, &site_guid))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } site = res->msgs[0]; schemas_dn = ldb_get_schema_basedn(service->samdb); if (!schemas_dn) { DEBUG(1, (__location__ ": failed to find our own Schemas DN\n")); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } ret = ldb_search(service->samdb, tmp_ctx, &res, schemas_dn, LDB_SCOPE_SUBTREE, NULL, "(&(lDAPDisplayName=nTDSDSA)(objectClass=classSchema))"); if (ret != LDB_SUCCESS) { DEBUG(1, (__location__ ": failed to find classSchema object :" "%s\n", ldb_strerror(ret))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } if (res->count == 0) { DEBUG(1, (__location__ ": failed to find classSchema " "object\n")); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } schema = res->msgs[0]; ZERO_STRUCT(all_dcs_in_site); ret = ldb_search(service->samdb, tmp_ctx, &res, site->dn, LDB_SCOPE_SUBTREE, dc_attrs, "objectCategory=%s", ldb_dn_get_linearized(schema->dn)); if (ret != LDB_SUCCESS) { DEBUG(1, (__location__ ": failed to find DCs objects :%s\n", ldb_strerror(ret))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } el = ldb_msg_find_element(transport, "bridgeheadServerListBL"); transport_name = samdb_result_string(transport, "name", NULL); if (!transport_name) { DEBUG(1, (__location__ ": failed to find name attribute of " "object %s\n", ldb_dn_get_linearized(transport->dn))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } transport_address_attr = samdb_result_string(transport, "transportAddressAttribute", NULL); if (!transport_address_attr) { DEBUG(1, (__location__ ": failed to find " "transportAddressAttribute attribute of object %s\n", ldb_dn_get_linearized(transport->dn))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } site_opts = samdb_result_int64(site, "options", 0); for (i = 0; i < res->count; i++) { struct ldb_message *dc, *new_data; struct ldb_dn *parent_dn; uint64_t behavior_version; const char *dc_transport_address; struct ldb_result *parent_res; const char *parent_attrs[] = { transport_address_attr, NULL }; NTSTATUS status; struct GUID dc_guid; bool failed; dc = res->msgs[i]; parent_dn = ldb_dn_get_parent(tmp_ctx, dc->dn); if (!parent_dn) { DEBUG(1, (__location__ ": failed to get parent DN of " "%s\n", ldb_dn_get_linearized(dc->dn))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } if (el && (el->num_values >= 1)) { bool contains; unsigned int j; contains = false; for (j = 0; j < el->num_values; j++) { struct ldb_val val; struct ldb_dn *dn; val = el->values[j]; dn = ldb_dn_from_ldb_val(tmp_ctx, service->samdb, &val); if (!dn) { DEBUG(1, (__location__ ": failed to read a DN " "from bridgeheadServerListBL " "attribute of %s\n", ldb_dn_get_linearized(transport->dn))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } if (ldb_dn_compare(dn, parent_dn) == 0) { contains = true; break; } } if (!contains) { continue; } } /* TODO: if dc is in the same site as the local DC */ if (true) { /* TODO: if a replica of cr!nCName is not in the set of * NC replicas that "should be present" on 'dc' */ /* TODO: a partial replica of the NC "should be present" */ if (true || (true && !partial_replica_okay)) { continue; } } else { /* TODO: if an NC replica of cr!nCName is not in the set * of NC replicas that "are present" on 'dc' */ /* TODO: a partial replica of the NC "is present" */ if (true || (true && !partial_replica_okay)) { continue; } } behavior_version = samdb_result_int64(dc, "msDS-Behavior-Version", 0); /* TODO: cr!nCName corresponds to default NC */ if (service->am_rodc && true && behavior_version < DS_BEHAVIOR_WIN2008) { continue; } ret = ldb_search(service->samdb, tmp_ctx, &parent_res, parent_dn, LDB_SCOPE_BASE, parent_attrs , NULL); dc_transport_address = samdb_result_string(parent_res->msgs[0], transport_address_attr, NULL); if (strncmp(transport_name, "IP", 2) != 0 && dc_transport_address == NULL) { continue; } dc_guid = samdb_result_guid(dc, "objectGUID"); status = kcctpl_bridgehead_dc_failed(service->samdb, dc_guid, detect_failed_dcs, &failed); if (NT_STATUS_IS_ERR(status)) { DEBUG(1, (__location__ ": failed to check if " "bridgehead DC has failed: %s\n", nt_errstr(status))); talloc_free(tmp_ctx); return status; } if (failed) { continue; } new_data = talloc_realloc(tmp_ctx, bridgeheads.data, struct ldb_message, bridgeheads.count + 1); NT_STATUS_HAVE_NO_MEMORY_AND_FREE(new_data, tmp_ctx); new_data[bridgeheads.count + 1] = *dc; bridgeheads.data = new_data; bridgeheads.count++; } if (site_opts & NTDSSETTINGS_OPT_IS_RAND_BH_SELECTION_DISABLED) { qsort(bridgeheads.data, bridgeheads.count, sizeof(struct ldb_message), kcctpl_sort_bridgeheads); } else { kcctpl_shuffle_bridgeheads(bridgeheads); } talloc_steal(mem_ctx, bridgeheads.data); *_bridgeheads = bridgeheads; talloc_free(tmp_ctx); return NT_STATUS_OK; } /** * get a bridgehead DC. */ static NTSTATUS kcctpl_get_bridgehead_dc(struct kccsrv_service *service, TALLOC_CTX *mem_ctx, struct GUID site_guid, struct ldb_message *cross_ref, struct ldb_message *transport, bool partial_replica_okay, bool detect_failed_dcs, struct ldb_message **_dsa) { struct message_list dsa_list; NTSTATUS status; status = kcctpl_get_all_bridgehead_dcs(service, mem_ctx, site_guid, cross_ref, transport, partial_replica_okay, detect_failed_dcs, &dsa_list); if (NT_STATUS_IS_ERR(status)) { DEBUG(1, (__location__ ": failed to get all bridgehead DCs: " "%s\n", nt_errstr(status))); return status; } *_dsa = (dsa_list.count == 0) ? NULL : &dsa_list.data[0]; return NT_STATUS_OK; } /* * color each vertex to indicate which kinds of NC replicas it contains. */ static NTSTATUS kcctpl_color_vertices(struct kccsrv_service *service, struct kcctpl_graph *graph, struct ldb_message *cross_ref, bool detect_failed_dcs, bool *_found_failed_dcs) { TALLOC_CTX *tmp_ctx; struct ldb_dn *sites_dn; bool found_failed_dcs, partial_replica_okay; uint32_t i; struct ldb_message *site; struct ldb_result *res; int ret, cr_flags; struct GUID site_guid; struct kcctpl_vertex *site_vertex; found_failed_dcs = false; tmp_ctx = talloc_new(service); NT_STATUS_HAVE_NO_MEMORY(tmp_ctx); sites_dn = samdb_sites_dn(service->samdb, tmp_ctx); if (!sites_dn) { DEBUG(1, (__location__ ": failed to find our own Sites DN\n")); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } for (i = 0; i < graph->vertices.count; i++) { struct kcctpl_vertex *vertex; struct ldb_dn *nc_name; /* TODO: set 'attrs' with its corresponding values */ const char * const attrs[] = { NULL }; vertex = &graph->vertices.data[i]; ret = ldb_search(service->samdb, tmp_ctx, &res, sites_dn, LDB_SCOPE_SUBTREE, attrs, "objectGUID=%s", GUID_string(tmp_ctx, &vertex->id)); if (ret != LDB_SUCCESS) { DEBUG(1, (__location__ ": failed to find site object " "%s: %s\n", GUID_string(tmp_ctx, &vertex->id), ldb_strerror(ret))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } if (res->count == 0) { DEBUG(1, (__location__ ": failed to find site object " "%s\n", GUID_string(tmp_ctx, &vertex->id))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } site = res->msgs[0]; nc_name = samdb_result_dn(service->samdb, tmp_ctx, cross_ref, "nCName", NULL); if (!nc_name) { DEBUG(1, (__location__ ": failed to find nCName " "attribute of object %s\n", ldb_dn_get_linearized(cross_ref->dn))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } if (true) { /* TODO: site contains 1+ DCs with full replicas of 'nc_name' */ vertex->color = RED; } else if (true) { /* TODO: site contains 1+ partial replicas of 'nc_name' */ vertex->color = BLACK; } else { vertex->color = WHITE; } } site = kcctpl_local_site(service->samdb, tmp_ctx); if (!site) { DEBUG(1, (__location__ ": failed to find our own local DC's " "site\n")); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } site_guid = samdb_result_guid(site, "objectGUID"); site_vertex = kcctpl_find_vertex_by_guid(graph, site_guid); if (!site_vertex) { DEBUG(1, (__location__ ": failed to find a vertex edge with " "GUID=%s\n", GUID_string(tmp_ctx, &site_guid))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } partial_replica_okay = (site_vertex->color == BLACK); cr_flags = samdb_result_int64(cross_ref, "systemFlags", 0); for (i = 0; i < graph->vertices.count; i++) { struct kcctpl_vertex *vertex; struct ldb_dn *transports_dn; const char * const attrs[] = { "objectGUID", "name", "transportAddressAttribute", NULL }; unsigned int j; vertex = &graph->vertices.data[i]; transports_dn = kcctpl_transports_dn(service->samdb, tmp_ctx); if (!transports_dn) { DEBUG(1, (__location__ ": failed to find our own " "Inter-Site Transports DN\n")); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } ret = ldb_search(service->samdb, tmp_ctx, &res, transports_dn, LDB_SCOPE_ONELEVEL, attrs, "objectClass=interSiteTransport"); if (ret != LDB_SUCCESS) { DEBUG(1, (__location__ ": failed to find " "interSiteTransport objects under %s: %s\n", ldb_dn_get_linearized(transports_dn), ldb_strerror(ret))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } for (j = 0; j < res->count; j++) { struct ldb_message *transport, *bridgehead; const char *transport_name; struct GUID transport_guid, *new_data; NTSTATUS status; transport = res->msgs[j]; transport_name = samdb_result_string(transport, "name", NULL); if (!transport_name) { DEBUG(1, (__location__ ": failed to find name " "attribute of object %s\n", ldb_dn_get_linearized(transport->dn))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } transport_guid = samdb_result_guid(transport, "objectGUID"); if (site_vertex->color == RED && strncmp(transport_name, "IP", 2) != 0 && (cr_flags & FLAG_CR_NTDS_DOMAIN)) { continue; } if (!kcctpl_find_edge_by_vertex_guid(graph, vertex->id)) { continue; } status = kcctpl_get_bridgehead_dc(service, tmp_ctx, site_vertex->id, cross_ref, transport, partial_replica_okay, detect_failed_dcs, &bridgehead); if (NT_STATUS_IS_ERR(status)) { DEBUG(1, (__location__ ": failed to get a " "bridgehead DC: %s\n", nt_errstr(status))); talloc_free(tmp_ctx); return status; } if (!bridgehead) { found_failed_dcs = true; continue; } new_data = talloc_realloc(vertex, vertex->accept_red_red.data, struct GUID, vertex->accept_red_red.count + 1); NT_STATUS_HAVE_NO_MEMORY_AND_FREE(new_data, tmp_ctx); new_data[vertex->accept_red_red.count + 1] = transport_guid; vertex->accept_red_red.data = new_data; vertex->accept_red_red.count++; new_data = talloc_realloc(vertex, vertex->accept_black.data, struct GUID, vertex->accept_black.count + 1); NT_STATUS_HAVE_NO_MEMORY_AND_FREE(new_data, tmp_ctx); new_data[vertex->accept_black.count + 1] = transport_guid; vertex->accept_black.data = new_data; vertex->accept_black.count++; } } *_found_failed_dcs = found_failed_dcs; talloc_free(tmp_ctx); return NT_STATUS_OK; } /** * setup the fields of the vertices that are relevant to Phase I (Dijkstra's * Algorithm). for each vertex, set up its cost, root vertex and component. this * defines the shortest-path forest structures. */ static void kcctpl_setup_vertices(struct kcctpl_graph *graph) { uint32_t i; for (i = 0; i < graph->vertices.count; i++) { struct kcctpl_vertex *vertex = &graph->vertices.data[i]; if (vertex->color == WHITE) { vertex->repl_info.cost = UINT32_MAX; vertex->root_id = vertex->component_id = GUID_zero(); } else { vertex->repl_info.cost = 0; vertex->root_id = vertex->component_id = vertex->id; } vertex->repl_info.interval = 0; vertex->repl_info.options = 0xFFFFFFFF; ZERO_STRUCT(vertex->repl_info.schedule); vertex->demoted = false; } } /** * demote one vertex if necessary. */ static void kcctpl_check_demote_one_vertex(struct kcctpl_vertex *vertex, struct GUID type) { if (vertex->color == WHITE) { return; } if (!kcctpl_guid_list_contains(vertex->accept_black, type) && !kcctpl_guid_list_contains(vertex->accept_red_red, type)) { vertex->repl_info.cost = UINT32_MAX; vertex->root_id = GUID_zero(); vertex->demoted = true; } } /** * clear the demoted state of a vertex. */ static void kcctpl_undemote_one_vertex(struct kcctpl_vertex *vertex) { if (vertex->color == WHITE) { return; } vertex->repl_info.cost = 0; vertex->root_id = vertex->id; vertex->demoted = false; } /** * returns the id of the component containing 'vertex' by traversing the up-tree * implied by the component pointers. */ static struct GUID kcctpl_get_component_id(struct kcctpl_graph *graph, struct kcctpl_vertex *vertex) { struct kcctpl_vertex *u; struct GUID root; u = vertex; while (!GUID_equal(&u->component_id, &u->id)) { u = kcctpl_find_vertex_by_guid(graph, u->component_id); } root = u->id; u = vertex; while (!GUID_equal(&u->component_id, &u->id)) { struct kcctpl_vertex *w; w = kcctpl_find_vertex_by_guid(graph, u->component_id); u->component_id = root; u = w; } return root; } /** * copy all spanning tree edges from 'output_edges' that contain the vertex for * DCs in the local DC's site. */ static NTSTATUS kcctpl_copy_output_edges(struct kccsrv_service *service, TALLOC_CTX *mem_ctx, struct kcctpl_graph *graph, struct kcctpl_multi_edge_list output_edges, struct kcctpl_multi_edge_list *_copy) { struct kcctpl_multi_edge_list copy; TALLOC_CTX *tmp_ctx; struct ldb_message *site; struct GUID site_guid; uint32_t i; ZERO_STRUCT(copy); tmp_ctx = talloc_new(service); NT_STATUS_HAVE_NO_MEMORY(tmp_ctx); site = kcctpl_local_site(service->samdb, tmp_ctx); if (!site) { DEBUG(1, (__location__ ": failed to find our own local DC's " "site\n")); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } site_guid = samdb_result_guid(site, "objectGUID"); for (i = 0; i < output_edges.count; i++) { struct kcctpl_multi_edge *edge; struct kcctpl_vertex *vertex1, *vertex2; edge = &output_edges.data[i]; vertex1 = kcctpl_find_vertex_by_guid(graph, edge->vertex_ids.data[0]); if (!vertex1) { DEBUG(1, (__location__ ": failed to find vertex %s\n", GUID_string(tmp_ctx, &edge->vertex_ids.data[0]))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } vertex2 = kcctpl_find_vertex_by_guid(graph, edge->vertex_ids.data[1]); if (!vertex2) { DEBUG(1, (__location__ ": failed to find vertex %s\n", GUID_string(tmp_ctx, &edge->vertex_ids.data[1]))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } if (GUID_equal(&vertex1->id, &site_guid) || GUID_equal(&vertex2->id, &site_guid)) { struct kcctpl_multi_edge *new_data; if ((vertex1->color == BLACK || vertex2->color == BLACK) && vertex1->dist_to_red != UINT32_MAX) { edge->directed = true; if (vertex2->dist_to_red < vertex1->dist_to_red) { struct GUID tmp; tmp = edge->vertex_ids.data[0]; edge->vertex_ids.data[0] = edge->vertex_ids.data[1]; edge->vertex_ids.data[1] = tmp; } } new_data = talloc_realloc(tmp_ctx, copy.data, struct kcctpl_multi_edge, copy.count + 1); NT_STATUS_HAVE_NO_MEMORY_AND_FREE(new_data, tmp_ctx); new_data[copy.count + 1] = *edge; copy.data = new_data; copy.count++; } } talloc_steal(mem_ctx, copy.data); *_copy = copy; return NT_STATUS_OK; } /** * build the initial sequence for use with Dijkstra's algorithm. it will contain * the red and black vertices as root vertices, unless these vertices accept no * edges of the current 'type', or unless black vertices are not being * including. */ static NTSTATUS kcctpl_setup_dijkstra(TALLOC_CTX *mem_ctx, struct kcctpl_graph *graph, struct GUID type, bool include_black, struct kcctpl_vertex_list *_vertices) { struct kcctpl_vertex_list vertices; uint32_t i; kcctpl_setup_vertices(graph); ZERO_STRUCT(vertices); for (i = 0; i < graph->vertices.count; i++) { struct kcctpl_vertex *vertex = &graph->vertices.data[i]; if (vertex->color == WHITE) { continue; } if ((vertex->color == BLACK && !include_black) || !kcctpl_guid_list_contains(vertex->accept_black, type) || !kcctpl_guid_list_contains(vertex->accept_red_red, type)) { vertex->repl_info.cost = UINT32_MAX; vertex->root_id = GUID_zero(); vertex->demoted = true; } else { struct kcctpl_vertex *new_data; new_data = talloc_realloc(mem_ctx, vertices.data, struct kcctpl_vertex, vertices.count + 1); NT_STATUS_HAVE_NO_MEMORY(new_data); new_data[vertices.count] = *vertex; vertices.data = new_data; vertices.count++; } } *_vertices = vertices; return NT_STATUS_OK; } /** * merge schedules, replication intervals, options and costs. */ static bool kcctpl_combine_repl_info(struct kcctpl_graph *graph, struct kcctpl_repl_info *ria, struct kcctpl_repl_info *rib, struct kcctpl_repl_info *ric) { uint8_t schedule[84]; bool is_available; uint32_t i; int32_t ric_cost; is_available = false; for (i = 0; i < 84; i++) { schedule[i] = ria->schedule[i] & rib->schedule[i]; if (schedule[i] == 1) { is_available = true; } } if (!is_available) { return false; } ric_cost = ria->cost + rib->cost; ric->cost = (ric_cost < 0) ? UINT32_MAX : ric_cost; ric->interval = MAX(ria->interval, rib->interval); ric->options = ria->options & rib->options; memcpy(&ric->schedule, &schedule, 84); return true; } /** * helper function for Dijkstra's algorithm. a new path has been found from a * root vertex to vertex 'vertex2'. this path is ('vertex1->root, ..., vertex1, * vertex2'). 'edge' is the edge connecting 'vertex1' and 'vertex2'. if this new * path is better (in this case cheaper, or has a longer schedule), update * 'vertex2' to use the new path. */ static NTSTATUS kcctpl_try_new_path(TALLOC_CTX *mem_ctx, struct kcctpl_graph *graph, struct kcctpl_vertex_list vertices, struct kcctpl_vertex *vertex1, struct kcctpl_multi_edge *edge, struct kcctpl_vertex *vertex2) { struct kcctpl_repl_info new_repl_info; bool intersect; uint32_t i, new_duration, old_duration; ZERO_STRUCT(new_repl_info); intersect = kcctpl_combine_repl_info(graph, &vertex1->repl_info, &edge->repl_info, &new_repl_info); if (new_repl_info.cost > vertex2->repl_info.cost) { return NT_STATUS_OK; } if (new_repl_info.cost < vertex2->repl_info.cost && !intersect) { return NT_STATUS_OK; } new_duration = old_duration = 0; for (i = 0; i < 84; i++) { if (new_repl_info.schedule[i] == 1) { new_duration++; } if (vertex2->repl_info.schedule[i] == 1) { old_duration++; } } if (new_repl_info.cost < vertex2->repl_info.cost || new_duration > old_duration) { struct kcctpl_vertex *new_data; vertex2->root_id = vertex1->root_id; vertex2->component_id = vertex1->component_id; vertex2->repl_info = new_repl_info; new_data = talloc_realloc(mem_ctx, vertices.data, struct kcctpl_vertex, vertices.count + 1); NT_STATUS_HAVE_NO_MEMORY(new_data); new_data[vertices.count + 1] = *vertex2; vertices.data = new_data; vertices.count++; } return NT_STATUS_OK; } /** * run Dijkstra's algorithm with the red (and possibly black) vertices as the * root vertices, and build up a shortest-path forest. */ static NTSTATUS kcctpl_dijkstra(struct kcctpl_graph *graph, struct GUID type, bool include_black) { TALLOC_CTX *tmp_ctx; struct kcctpl_vertex_list vertices; NTSTATUS status; tmp_ctx = talloc_new(graph); NT_STATUS_HAVE_NO_MEMORY(tmp_ctx); status = kcctpl_setup_dijkstra(tmp_ctx, graph, type, include_black, &vertices); if (NT_STATUS_IS_ERR(status)) { DEBUG(1, (__location__ ": failed to build the initial sequence " "for Dijkstra's algorithm: %s\n", nt_errstr(status))); talloc_free(tmp_ctx); return status; } while (vertices.count > 0) { uint32_t minimum_cost, minimum_index, i; struct kcctpl_vertex *minimum_vertex, *new_data; minimum_cost = UINT32_MAX; minimum_index = -1; minimum_vertex = NULL; for (i = 0; i < vertices.count; i++) { struct kcctpl_vertex *vertex = &vertices.data[i]; if (vertex->repl_info.cost < minimum_cost) { minimum_cost = vertex->repl_info.cost; minimum_vertex = vertex; minimum_index = i; } else if (vertex->repl_info.cost == minimum_cost && GUID_compare(&vertex->id, &minimum_vertex->id) < 0) { minimum_vertex = vertex; minimum_index = i; } } if (minimum_index < vertices.count - 1) { memcpy(&vertices.data[minimum_index + 1], &vertices.data[minimum_index], vertices.count - minimum_index - 1); } new_data = talloc_realloc(tmp_ctx, vertices.data, struct kcctpl_vertex, vertices.count - 1); NT_STATUS_HAVE_NO_MEMORY_AND_FREE(new_data, tmp_ctx); talloc_free(vertices.data); vertices.data = new_data; vertices.count--; for (i = 0; i < graph->edges.count; i++) { struct kcctpl_multi_edge *edge = &graph->edges.data[i]; if (kcctpl_guid_list_contains(minimum_vertex->edge_ids, edge->id)) { uint32_t j; for (j = 0; j < edge->vertex_ids.count; j++) { struct GUID vertex_id; struct kcctpl_vertex *vertex; vertex_id = edge->vertex_ids.data[j]; vertex = kcctpl_find_vertex_by_guid(graph, vertex_id); if (!vertex) { DEBUG(1, (__location__ ": failed to find " "vertex %s\n", GUID_string(tmp_ctx, &vertex_id))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } kcctpl_try_new_path(tmp_ctx, graph, vertices, minimum_vertex, edge, vertex); } } } } talloc_free(tmp_ctx); return NT_STATUS_OK; } /** * add an edge to the list of edges that will be processed with Kruskal's. the * endpoints are in fact the root of the vertices to pass in, so the endpoints * are always colored vertices. */ static NTSTATUS kcctpl_add_int_edge(TALLOC_CTX *mem_ctx, struct kcctpl_graph *graph, struct kcctpl_internal_edge_list internal_edges, struct kcctpl_multi_edge *edge, struct kcctpl_vertex *vertex1, struct kcctpl_vertex *vertex2) { struct kcctpl_vertex *root1, *root2; bool red_red, found; struct kcctpl_repl_info repl_info1, repl_info2; struct kcctpl_internal_edge new_internal_edge, *new_data; uint32_t i; root1 = kcctpl_find_vertex_by_guid(graph, vertex1->root_id); if (!root1) { TALLOC_CTX *tmp_ctx = talloc_new(graph); NT_STATUS_HAVE_NO_MEMORY(tmp_ctx); DEBUG(1, (__location__ ": failed to find vertex %s\n", GUID_string(tmp_ctx, &vertex1->root_id))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } root2 = kcctpl_find_vertex_by_guid(graph, vertex2->root_id); if (!root2) { TALLOC_CTX *tmp_ctx = talloc_new(graph); NT_STATUS_HAVE_NO_MEMORY(tmp_ctx); DEBUG(1, (__location__ ": failed to find vertex %s\n", GUID_string(tmp_ctx, &vertex2->root_id))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } red_red = (root1->color == RED && root2->color == RED); if (red_red) { if (!kcctpl_guid_list_contains(root1->accept_red_red, edge->type) || !kcctpl_guid_list_contains(root2->accept_red_red, edge->type)) { return NT_STATUS_OK; } } else if (!kcctpl_guid_list_contains(root1->accept_black, edge->type) || !kcctpl_guid_list_contains(root2->accept_black, edge->type)) { return NT_STATUS_OK; } if (!kcctpl_combine_repl_info(graph, &vertex1->repl_info, &vertex2->repl_info, &repl_info1) || !kcctpl_combine_repl_info(graph, &repl_info1, &edge->repl_info, &repl_info2)) { return NT_STATUS_OK; } new_internal_edge.v1id = root1->id; new_internal_edge.v2id = root2->id; new_internal_edge.red_red = red_red; new_internal_edge.repl_info = repl_info2; new_internal_edge.type = edge->type; if (GUID_compare(&new_internal_edge.v1id, &new_internal_edge.v2id) > 0) { struct GUID tmp_guid = new_internal_edge.v1id; new_internal_edge.v1id = new_internal_edge.v2id; new_internal_edge.v2id = tmp_guid; } found = false; for (i = 0; i < internal_edges.count; i++) { struct kcctpl_internal_edge *ie = &internal_edges.data[i]; if (kcctpl_internal_edge_equal(ie, &new_internal_edge)) { found = true; } } if (found) { return NT_STATUS_OK; } new_data = talloc_realloc(mem_ctx, internal_edges.data, struct kcctpl_internal_edge, internal_edges.count + 1); NT_STATUS_HAVE_NO_MEMORY(new_data); new_data[internal_edges.count + 1] = new_internal_edge; internal_edges.data = new_data; internal_edges.count++; return NT_STATUS_OK; } /** * after running Dijkstra's algorithm, this function examines a multi-edge and * adds internal edges between every tree connected by this edge. */ static NTSTATUS kcctpl_process_edge(TALLOC_CTX *mem_ctx, struct kcctpl_graph *graph, struct kcctpl_multi_edge *edge, struct kcctpl_internal_edge_list internal_edges) { TALLOC_CTX *tmp_ctx; struct kcctpl_vertex_list vertices; uint32_t i; struct kcctpl_vertex *best_vertex; ZERO_STRUCT(vertices); tmp_ctx = talloc_new(mem_ctx); NT_STATUS_HAVE_NO_MEMORY(tmp_ctx); for (i = 0; i < edge->vertex_ids.count; i++) { struct GUID id; struct kcctpl_vertex *vertex, *new_data; id = edge->vertex_ids.data[i]; vertex = kcctpl_find_vertex_by_guid(graph, id); if (!vertex) { DEBUG(1, (__location__ ": failed to find vertex %s\n", GUID_string(tmp_ctx, &id))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } new_data = talloc_realloc(tmp_ctx, vertices.data, struct kcctpl_vertex, vertices.count + 1); NT_STATUS_HAVE_NO_MEMORY_AND_FREE(new_data, tmp_ctx); new_data[vertices.count] = *vertex; vertices.data = new_data; vertices.count++; } qsort(vertices.data, vertices.count, sizeof(struct kcctpl_vertex), kcctpl_sort_vertices); best_vertex = &vertices.data[0]; for (i = 0; i < edge->vertex_ids.count; i++) { struct GUID id, empty_id = GUID_zero(); struct kcctpl_vertex *vertex = &graph->vertices.data[i]; id = edge->vertex_ids.data[i]; vertex = kcctpl_find_vertex_by_guid(graph, id); if (!vertex) { DEBUG(1, (__location__ ": failed to find vertex %s\n", GUID_string(tmp_ctx, &id))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } if (!GUID_equal(&vertex->component_id, &empty_id) && !GUID_equal(&vertex->root_id, &empty_id)) { continue; } if (!GUID_equal(&best_vertex->component_id, &empty_id) && !GUID_equal(&best_vertex->root_id, &empty_id) && !GUID_equal(&vertex->component_id, &empty_id) && !GUID_equal(&vertex->root_id, &empty_id) && !GUID_equal(&best_vertex->component_id, &vertex->component_id)) { NTSTATUS status; status = kcctpl_add_int_edge(mem_ctx, graph, internal_edges, edge, best_vertex, vertex); if (NT_STATUS_IS_ERR(status)) { DEBUG(1, (__location__ ": failed to add an " "internal edge for %s: %s\n", GUID_string(tmp_ctx, &vertex->id), nt_errstr(status))); talloc_free(tmp_ctx); return status; } } } talloc_free(tmp_ctx); return NT_STATUS_OK; } /** * after running Dijkstra's algorithm to determine the shortest-path forest, * examine all edges in this edge set. find all inter-tree edges, from which to * build the list of 'internal edges', which will later be passed on to * Kruskal's algorithm. */ static NTSTATUS kcctpl_process_edge_set(TALLOC_CTX *mem_ctx, struct kcctpl_graph *graph, struct kcctpl_multi_edge_set *set, struct kcctpl_internal_edge_list internal_edges) { uint32_t i; if (!set) { for (i = 0; i < graph->edges.count; i++) { struct kcctpl_multi_edge *edge; uint32_t j; NTSTATUS status; edge = &graph->edges.data[i]; for (j = 0; j < edge->vertex_ids.count; j++) { struct GUID id; struct kcctpl_vertex *vertex; id = edge->vertex_ids.data[j]; vertex = kcctpl_find_vertex_by_guid(graph, id); if (!vertex) { TALLOC_CTX *tmp_ctx; tmp_ctx = talloc_new(mem_ctx); NT_STATUS_HAVE_NO_MEMORY(tmp_ctx); DEBUG(1, (__location__ ": failed to " "find vertex %s\n", GUID_string(tmp_ctx, &id))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } kcctpl_check_demote_one_vertex(vertex, edge->type); } status = kcctpl_process_edge(mem_ctx, graph, edge, internal_edges); if (NT_STATUS_IS_ERR(status)) { TALLOC_CTX *tmp_ctx = talloc_new(mem_ctx); NT_STATUS_HAVE_NO_MEMORY(tmp_ctx); DEBUG(1, (__location__ ": failed to process " "edge %s: %s\n", GUID_string(tmp_ctx, &edge->id), nt_errstr(status))); talloc_free(tmp_ctx); return status; } for (j = 0; j < edge->vertex_ids.count; j++) { struct GUID id; struct kcctpl_vertex *vertex; id = edge->vertex_ids.data[j]; vertex = kcctpl_find_vertex_by_guid(graph, id); if (!vertex) { TALLOC_CTX *tmp_ctx; tmp_ctx = talloc_new(mem_ctx); NT_STATUS_HAVE_NO_MEMORY(tmp_ctx); DEBUG(1, (__location__ ": failed to " "find vertex %s\n", GUID_string(tmp_ctx, &id))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } kcctpl_undemote_one_vertex(vertex); } } } else { for (i = 0; i < graph->edges.count; i++) { struct kcctpl_multi_edge *edge = &graph->edges.data[i]; if (kcctpl_guid_list_contains(set->edge_ids, edge->id)) { NTSTATUS status; status = kcctpl_process_edge(mem_ctx, graph, edge, internal_edges); if (NT_STATUS_IS_ERR(status)) { TALLOC_CTX *tmp_ctx; tmp_ctx = talloc_new(mem_ctx); NT_STATUS_HAVE_NO_MEMORY(tmp_ctx); DEBUG(1, (__location__ ": failed to " "process edge %s: %s\n", GUID_string(tmp_ctx, &edge->id), nt_errstr(status))); talloc_free(tmp_ctx); return status; } } } } return NT_STATUS_OK; } /** * a new edge, 'internal_edge', has been found for the spanning tree edge. add * this edge to the list of output edges. */ static NTSTATUS kcctpl_add_out_edge(TALLOC_CTX *mem_ctx, struct kcctpl_graph *graph, struct kcctpl_multi_edge_list output_edges, struct kcctpl_internal_edge *internal_edge) { struct kcctpl_vertex *vertex1, *vertex2; TALLOC_CTX *tmp_ctx; struct kcctpl_multi_edge *new_edge, *new_data; struct GUID *new_data_id; tmp_ctx = talloc_new(mem_ctx); NT_STATUS_HAVE_NO_MEMORY(tmp_ctx); vertex1 = kcctpl_find_vertex_by_guid(graph, internal_edge->v1id); if (!vertex1) { DEBUG(1, (__location__ ": failed to find vertex %s\n", GUID_string(tmp_ctx, &internal_edge->v1id))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } vertex2 = kcctpl_find_vertex_by_guid(graph, internal_edge->v2id); if (!vertex2) { DEBUG(1, (__location__ ": failed to find vertex %s\n", GUID_string(tmp_ctx, &internal_edge->v2id))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } new_edge = talloc(tmp_ctx, struct kcctpl_multi_edge); NT_STATUS_HAVE_NO_MEMORY_AND_FREE(new_edge, tmp_ctx); new_edge->id = GUID_random(); /* TODO: what should be new_edge->GUID? */ new_edge->directed = false; new_edge->vertex_ids.data = talloc_array(new_edge, struct GUID, 2); NT_STATUS_HAVE_NO_MEMORY_AND_FREE(new_edge->vertex_ids.data, tmp_ctx); new_edge->vertex_ids.data[0] = vertex1->id; new_edge->vertex_ids.data[1] = vertex2->id; new_edge->vertex_ids.count = 2; new_edge->type = internal_edge->type; new_edge->repl_info = internal_edge->repl_info; new_data = talloc_realloc(tmp_ctx, output_edges.data, struct kcctpl_multi_edge, output_edges.count + 1); NT_STATUS_HAVE_NO_MEMORY_AND_FREE(new_data, tmp_ctx); new_data[output_edges.count + 1] = *new_edge; output_edges.data = new_data; output_edges.count++; new_data_id = talloc_realloc(vertex1, vertex1->edge_ids.data, struct GUID, vertex1->edge_ids.count); NT_STATUS_HAVE_NO_MEMORY_AND_FREE(new_data_id, tmp_ctx); new_data_id[vertex1->edge_ids.count] = new_edge->id; talloc_free(vertex1->edge_ids.data); vertex1->edge_ids.data = new_data_id; vertex1->edge_ids.count++; new_data_id = talloc_realloc(vertex2, vertex2->edge_ids.data, struct GUID, vertex2->edge_ids.count); NT_STATUS_HAVE_NO_MEMORY_AND_FREE(new_data_id, tmp_ctx); new_data_id[vertex2->edge_ids.count] = new_edge->id; talloc_free(vertex2->edge_ids.data); vertex2->edge_ids.data = new_data_id; vertex2->edge_ids.count++; talloc_steal(graph, new_edge); talloc_steal(mem_ctx, output_edges.data); talloc_free(tmp_ctx); return NT_STATUS_OK; } /** * run Kruskal's minimum-cost spanning tree algorithm on the internal edges * (that represent shortest paths in the original graph between colored * vertices). */ static NTSTATUS kcctpl_kruskal(TALLOC_CTX *mem_ctx, struct kcctpl_graph *graph, struct kcctpl_internal_edge_list internal_edges, struct kcctpl_multi_edge_list *_output_edges) { uint32_t i, num_expected_tree_edges, cst_edges; struct kcctpl_multi_edge_list output_edges; num_expected_tree_edges = 0; for (i = 0; i < graph->vertices.count; i++) { struct kcctpl_vertex *vertex = &graph->vertices.data[i]; talloc_free(vertex->edge_ids.data); ZERO_STRUCT(vertex->edge_ids); if (vertex->color == RED || vertex->color == WHITE) { num_expected_tree_edges++; } } qsort(internal_edges.data, internal_edges.count, sizeof(struct kcctpl_internal_edge), kcctpl_sort_internal_edges); cst_edges = 0; ZERO_STRUCT(output_edges); while (internal_edges.count > 0 && cst_edges < num_expected_tree_edges) { struct kcctpl_internal_edge *edge, *new_data; struct kcctpl_vertex *vertex1, *vertex2; struct GUID comp1, comp2; edge = &internal_edges.data[0]; vertex1 = kcctpl_find_vertex_by_guid(graph, edge->v1id); if (!vertex1) { TALLOC_CTX *tmp_ctx = talloc_new(mem_ctx); NT_STATUS_HAVE_NO_MEMORY(tmp_ctx); DEBUG(1, (__location__ ": failed to find vertex %s\n", GUID_string(tmp_ctx, &edge->v1id))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } vertex2 = kcctpl_find_vertex_by_guid(graph, edge->v2id); if (!vertex2) { TALLOC_CTX *tmp_ctx = talloc_new(mem_ctx); NT_STATUS_HAVE_NO_MEMORY(tmp_ctx); DEBUG(1, (__location__ ": failed to find vertex %s\n", GUID_string(tmp_ctx, &edge->v2id))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } comp1 = kcctpl_get_component_id(graph, vertex1); comp2 = kcctpl_get_component_id(graph, vertex2); if (!GUID_equal(&comp1, &comp2)) { NTSTATUS status; struct kcctpl_vertex *vertex; cst_edges++; status = kcctpl_add_out_edge(mem_ctx, graph, output_edges, edge); if (NT_STATUS_IS_ERR(status)) { TALLOC_CTX *tmp_ctx = talloc_new(mem_ctx); NT_STATUS_HAVE_NO_MEMORY(tmp_ctx); DEBUG(1, (__location__ ": failed to add an " "output edge between %s and %s: %s\n", GUID_string(tmp_ctx, &edge->v1id), GUID_string(tmp_ctx, &edge->v2id), nt_errstr(status))); talloc_free(tmp_ctx); return status; } vertex = kcctpl_find_vertex_by_guid(graph, comp1); if (!vertex) { TALLOC_CTX *tmp_ctx = talloc_new(mem_ctx); NT_STATUS_HAVE_NO_MEMORY(tmp_ctx); DEBUG(1, (__location__ ": failed to find " "vertex %s\n", GUID_string(tmp_ctx, &comp1))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } vertex->component_id = comp2; } internal_edges.data = internal_edges.data + 1; new_data = talloc_realloc(mem_ctx, internal_edges.data, struct kcctpl_internal_edge, internal_edges.count - 1); NT_STATUS_HAVE_NO_MEMORY(new_data); talloc_free(internal_edges.data); internal_edges.data = new_data; internal_edges.count--; } *_output_edges = output_edges; return NT_STATUS_OK; } /** * count the number of components. a component is considered to be a bunch of * colored vertices that are connected by the spanning tree. vertices whose * component ID is the same as their vertex ID are the root of the connected * component. */ static uint32_t kcctpl_count_components(struct kcctpl_graph *graph) { uint32_t num_components = 0, i; for (i = 0; i < graph->vertices.count; i++) { struct kcctpl_vertex *vertex; struct GUID component_id; vertex = &graph->vertices.data[i]; if (vertex->color == WHITE) { continue; } component_id = kcctpl_get_component_id(graph, vertex); if (GUID_equal(&component_id, &vertex->id)) { vertex->component_index = num_components; num_components++; } } return num_components; } /** * calculate the spanning tree and return the edges that include the vertex for * the local site. */ static NTSTATUS kcctpl_get_spanning_tree_edges(struct kccsrv_service *service, TALLOC_CTX *mem_ctx, struct kcctpl_graph *graph, uint32_t *_component_count, struct kcctpl_multi_edge_list *_st_edge_list) { TALLOC_CTX *tmp_ctx; struct kcctpl_internal_edge_list internal_edges; uint32_t i, component_count; NTSTATUS status; struct kcctpl_multi_edge_list output_edges, st_edge_list; ZERO_STRUCT(internal_edges); tmp_ctx = talloc_new(mem_ctx); NT_STATUS_HAVE_NO_MEMORY(tmp_ctx); for (i = 0; i < graph->edge_sets.count; i++) { struct kcctpl_multi_edge_set *set; struct GUID edge_type; uint32_t j; set = &graph->edge_sets.data[i]; edge_type = GUID_zero(); for (j = 0; j < graph->vertices.count; j++) { struct kcctpl_vertex *vertex = &graph->vertices.data[j]; talloc_free(vertex->edge_ids.data); ZERO_STRUCT(vertex->edge_ids.data); } for (j = 0; j < set->edge_ids.count; j++) { struct GUID edge_id; struct kcctpl_multi_edge *edge; uint32_t k; edge_id = set->edge_ids.data[j]; edge = kcctpl_find_edge_by_guid(graph, edge_id); if (!edge) { DEBUG(1, (__location__ ": failed to find a " "graph edge with ID=%s\n", GUID_string(tmp_ctx, &edge_id))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } edge_type = edge->type; for (k = 0; k < edge->vertex_ids.count; k++) { struct GUID vertex_id, *new_data; struct kcctpl_vertex *vertex; vertex_id = edge->vertex_ids.data[k]; vertex = kcctpl_find_vertex_by_guid(graph, vertex_id); if (!vertex) { DEBUG(1, (__location__ ": failed to " "find a graph vertex with " "ID=%s\n", GUID_string(tmp_ctx, &edge_id))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } new_data = talloc_realloc(tmp_ctx, vertex->edge_ids.data, struct GUID, vertex->edge_ids.count + 1); NT_STATUS_HAVE_NO_MEMORY_AND_FREE(new_data, tmp_ctx); new_data[vertex->edge_ids.count] = edge->id; vertex->edge_ids.data = new_data; vertex->edge_ids.count++; } } status = kcctpl_dijkstra(graph, edge_type, false); if (NT_STATUS_IS_ERR(status)) { DEBUG(1, (__location__ ": failed to run Dijkstra's " "algorithm: %s\n", nt_errstr(status))); talloc_free(tmp_ctx); return status; } status = kcctpl_process_edge_set(tmp_ctx, graph, set, internal_edges); if (NT_STATUS_IS_ERR(status)) { DEBUG(1, (__location__ ": failed to process edge set " "%s: %s\n", GUID_string(tmp_ctx, &set->id), nt_errstr(status))); talloc_free(tmp_ctx); return status; } status = kcctpl_dijkstra(graph, edge_type, true); if (NT_STATUS_IS_ERR(status)) { DEBUG(1, (__location__ ": failed to run Dijkstra's " "algorithm: %s\n", nt_errstr(status))); talloc_free(tmp_ctx); return status; } status = kcctpl_process_edge_set(tmp_ctx, graph, set, internal_edges); if (NT_STATUS_IS_ERR(status)) { DEBUG(1, (__location__ ": failed to process edge set " "%s: %s\n", GUID_string(tmp_ctx, &set->id), nt_errstr(status))); talloc_free(tmp_ctx); return status; } } kcctpl_setup_vertices(graph); status = kcctpl_process_edge_set(tmp_ctx, graph, NULL, internal_edges); if (NT_STATUS_IS_ERR(status)) { DEBUG(1, (__location__ ": failed to process empty edge set: " "%s\n", nt_errstr(status))); talloc_free(tmp_ctx); return status; } status = kcctpl_kruskal(tmp_ctx, graph, internal_edges, &output_edges); if (NT_STATUS_IS_ERR(status)) { DEBUG(1, (__location__ ": failed to run Kruskal's algorithm: " "%s\n", nt_errstr(status))); talloc_free(tmp_ctx); return status; } for (i = 0; i < graph->vertices.count; i++) { struct kcctpl_vertex *vertex = &graph->vertices.data[i]; if (vertex->color == RED) { vertex->dist_to_red = 0; } else if (true) { /* TODO: if there exists a path from 'vertex' to a RED vertex */ vertex->dist_to_red = -1; /* TODO: the length of the shortest such path */ } else { vertex->dist_to_red = UINT32_MAX; } } component_count = kcctpl_count_components(graph); status = kcctpl_copy_output_edges(service, tmp_ctx, graph, output_edges, &st_edge_list); if (NT_STATUS_IS_ERR(status)) { DEBUG(1, (__location__ ": failed to copy edge list: %s\n", nt_errstr(status))); talloc_free(tmp_ctx); return status; } *_component_count = component_count; talloc_steal(mem_ctx, st_edge_list.data); *_st_edge_list = st_edge_list; talloc_free(tmp_ctx); return NT_STATUS_OK; } /** * creat an nTDSConnection object with the given parameters if one does not * already exist. */ static NTSTATUS kcctpl_create_connection(struct kccsrv_service *service, TALLOC_CTX *mem_ctx, struct ldb_message *cross_ref, struct ldb_message *r_bridgehead, struct ldb_message *transport, struct ldb_message *l_bridgehead, struct kcctpl_repl_info repl_info, uint8_t schedule[84], bool detect_failed_dcs, bool partial_replica_okay, struct GUID_list *_keep_connections) { TALLOC_CTX *tmp_ctx; struct ldb_dn *r_site_dn, *l_site_dn, *servers_dn; bool ok; struct GUID r_site_guid, l_site_guid; int ret; struct message_list r_bridgeheads_all, l_bridgeheads_all, r_bridgeheads_available, l_bridgeheads_available; NTSTATUS status; struct ldb_result *res; const char * const attrs[] = { "objectGUID", "parent", "fromServer", "transportType", "schedule", "options", "enabledConnection", NULL }; unsigned int i, valid_connections; struct GUID_list keep_connections; tmp_ctx = talloc_new(service); NT_STATUS_HAVE_NO_MEMORY(tmp_ctx); r_site_dn = ldb_dn_copy(tmp_ctx, r_bridgehead->dn); NT_STATUS_HAVE_NO_MEMORY_AND_FREE(r_site_dn, tmp_ctx); ok = ldb_dn_remove_child_components(r_site_dn, 3); if (!ok) { talloc_free(tmp_ctx); return NT_STATUS_NO_MEMORY; } ret = dsdb_find_guid_by_dn(service->samdb, r_site_dn, &r_site_guid); if (ret != LDB_SUCCESS) { DEBUG(1, (__location__ ": failed to find objectGUID for object " "%s: %s\n", ldb_dn_get_linearized(r_site_dn), ldb_strerror(ret))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } l_site_dn = ldb_dn_copy(tmp_ctx, l_bridgehead->dn); NT_STATUS_HAVE_NO_MEMORY_AND_FREE(l_site_dn, tmp_ctx); ok = ldb_dn_remove_child_components(l_site_dn, 3); if (!ok) { talloc_free(tmp_ctx); return NT_STATUS_NO_MEMORY; } ret = dsdb_find_guid_by_dn(service->samdb, l_site_dn, &l_site_guid); if (ret != LDB_SUCCESS) { DEBUG(1, (__location__ ": failed to find objectGUID for object " "%s: %s\n", ldb_dn_get_linearized(l_site_dn), ldb_strerror(ret))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } status = kcctpl_get_all_bridgehead_dcs(service, tmp_ctx, r_site_guid, cross_ref, transport, partial_replica_okay, false, &r_bridgeheads_all); if (NT_STATUS_IS_ERR(status)) { DEBUG(1, (__location__ ": failed to get all bridgehead DCs: " "%s\n", nt_errstr(status))); return status; } status = kcctpl_get_all_bridgehead_dcs(service->samdb, tmp_ctx, r_site_guid, cross_ref, transport, partial_replica_okay, detect_failed_dcs, &r_bridgeheads_available); if (NT_STATUS_IS_ERR(status)) { DEBUG(1, (__location__ ": failed to get all bridgehead DCs: " "%s\n", nt_errstr(status))); return status; } status = kcctpl_get_all_bridgehead_dcs(service, tmp_ctx, l_site_guid, cross_ref, transport, partial_replica_okay, false, &l_bridgeheads_all); if (NT_STATUS_IS_ERR(status)) { DEBUG(1, (__location__ ": failed to get all bridgehead DCs: " "%s\n", nt_errstr(status))); return status; } status = kcctpl_get_all_bridgehead_dcs(service, tmp_ctx, l_site_guid, cross_ref, transport, partial_replica_okay, detect_failed_dcs, &l_bridgeheads_available); if (NT_STATUS_IS_ERR(status)) { DEBUG(1, (__location__ ": failed to get all bridgehead DCs: " "%s\n", nt_errstr(status))); return status; } servers_dn = samdb_sites_dn(service->samdb, tmp_ctx); if (!servers_dn) { DEBUG(1, (__location__ ": failed to find our own Sites DN\n")); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } ok = ldb_dn_add_child_fmt(servers_dn, "CN=Servers"); if (!ok) { talloc_free(tmp_ctx); return NT_STATUS_NO_MEMORY; } ret = ldb_search(service->samdb, tmp_ctx, &res, servers_dn, LDB_SCOPE_SUBTREE, attrs, "objectClass=nTDSConnection"); if (ret != LDB_SUCCESS) { DEBUG(1, (__location__ ": failed to find nTDSConnection " "objects: %s\n", ldb_strerror(ret))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } for (i = 0; i < res->count; i++) { struct ldb_message *connection; struct ldb_dn *parent_dn, *from_server; connection = res->msgs[i]; parent_dn = ldb_dn_get_parent(tmp_ctx, connection->dn); if (!parent_dn) { DEBUG(1, (__location__ ": failed to get parent DN of " "%s\n", ldb_dn_get_linearized(connection->dn))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } from_server = samdb_result_dn(service->samdb, tmp_ctx, connection, "fromServer", NULL); if (!from_server) { DEBUG(1, (__location__ ": failed to find fromServer " "attribute of object %s\n", ldb_dn_get_linearized(connection->dn))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } if (kcctpl_message_list_contains_dn(l_bridgeheads_all, parent_dn) && kcctpl_message_list_contains_dn(r_bridgeheads_all, from_server)) { uint64_t conn_opts; /* TODO: initialize conn_schedule from connection */ uint8_t conn_schedule[84]; struct ldb_dn *conn_transport_type; conn_opts = samdb_result_int64(connection, "options", 0); conn_transport_type = samdb_result_dn(service->samdb, tmp_ctx, connection, "transportType", NULL); if (!conn_transport_type) { DEBUG(1, (__location__ ": failed to find " "transportType attribute of object " "%s\n", ldb_dn_get_linearized(connection->dn))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } if ((conn_opts & NTDSCONN_OPT_IS_GENERATED) && !(conn_opts & NTDSCONN_OPT_RODC_TOPOLOGY) && ldb_dn_compare(conn_transport_type, transport->dn) == 0) { if (!(conn_opts & NTDSCONN_OPT_USER_OWNED_SCHEDULE) && memcmp(&conn_schedule, &schedule, 84) != 0) { /* TODO: perform an originating update to set conn!schedule to schedule */ } if ((conn_opts & NTDSCONN_OPT_OVERRIDE_NOTIFY_DEFAULT) && (conn_opts & NTDSCONN_OPT_USE_NOTIFY)) { if (!(repl_info.options & NTDSSITELINK_OPT_USE_NOTIFY)) { /* TODO: perform an originating update to clear bits NTDSCONN_OPT_OVERRIDE_NOTIFY_DEFAULT and NTDSCONN_OPT_USE_NOTIFY in conn!options */ } } else if (repl_info.options & NTDSSITELINK_OPT_USE_NOTIFY) { /* TODO: perform an originating update to set bits NTDSCONN_OPT_OVERRIDE_NOTIFY_DEFAULT and NTDSCONN_OPT_USE_NOTIFY in conn!options */ } if (conn_opts & NTDSCONN_OPT_TWOWAY_SYNC) { if (!(repl_info.options & NTDSSITELINK_OPT_TWOWAY_SYNC)) { /* TODO: perform an originating update to clear bit NTDSCONN_OPT_TWOWAY_SYNC in conn!options. */ } } else if (repl_info.options & NTDSSITELINK_OPT_TWOWAY_SYNC) { /* TODO: perform an originating update to set bit NTDSCONN_OPT_TWOWAY_SYNC in conn!options. */ } if (conn_opts & NTDSCONN_OPT_DISABLE_INTERSITE_COMPRESSION) { if (!(repl_info.options & NTDSSITELINK_OPT_DISABLE_COMPRESSION)) { /* TODO: perform an originating update to clear bit NTDSCONN_OPT_DISABLE_INTERSITE_COMPRESSION in conn!options. */ } } else if (repl_info.options & NTDSSITELINK_OPT_DISABLE_COMPRESSION) { /* TODO: perform an originating update to set bit NTDSCONN_OPT_DISABLE_INTERSITE_COMPRESSION in conn!options. */ } } } } ZERO_STRUCT(keep_connections); valid_connections = 0; for (i = 0; i < res->count; i++) { struct ldb_message *connection; struct ldb_dn *parent_dn, *from_server; connection = res->msgs[i]; parent_dn = ldb_dn_get_parent(tmp_ctx, connection->dn); if (!parent_dn) { DEBUG(1, (__location__ ": failed to get parent DN of " "%s\n", ldb_dn_get_linearized(connection->dn))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } from_server = samdb_result_dn(service->samdb, tmp_ctx, connection, "fromServer", NULL); if (!from_server) { DEBUG(1, (__location__ ": failed to find fromServer " "attribute of object %s\n", ldb_dn_get_linearized(connection->dn))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } if (kcctpl_message_list_contains_dn(l_bridgeheads_all, parent_dn) && kcctpl_message_list_contains_dn(r_bridgeheads_all, from_server)) { uint64_t conn_opts; struct ldb_dn *conn_transport_type; conn_opts = samdb_result_int64(connection, "options", 0); conn_transport_type = samdb_result_dn(service->samdb, tmp_ctx, connection, "transportType", NULL); if (!conn_transport_type) { DEBUG(1, (__location__ ": failed to find " "transportType attribute of object " "%s\n", ldb_dn_get_linearized(connection->dn))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } if ((!(conn_opts & NTDSCONN_OPT_IS_GENERATED) || ldb_dn_compare(conn_transport_type, transport->dn) == 0) && !(conn_opts & NTDSCONN_OPT_RODC_TOPOLOGY)) { struct GUID r_guid, l_guid, conn_guid; bool failed_state_r, failed_state_l; ret = dsdb_find_guid_by_dn(service->samdb, from_server, &r_guid); if (ret != LDB_SUCCESS) { DEBUG(1, (__location__ ": failed to " "find GUID for object %s\n", ldb_dn_get_linearized(from_server))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } ret = dsdb_find_guid_by_dn(service->samdb, parent_dn, &l_guid); if (ret != LDB_SUCCESS) { DEBUG(1, (__location__ ": failed to " "find GUID for object %s\n", ldb_dn_get_linearized(parent_dn))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } status = kcctpl_bridgehead_dc_failed(service->samdb, r_guid, detect_failed_dcs, &failed_state_r); if (NT_STATUS_IS_ERR(status)) { DEBUG(1, (__location__ ": failed to " "check if bridgehead DC has " "failed: %s\n", nt_errstr(status))); talloc_free(tmp_ctx); return status; } status = kcctpl_bridgehead_dc_failed(service->samdb, l_guid, detect_failed_dcs, &failed_state_l); if (NT_STATUS_IS_ERR(status)) { DEBUG(1, (__location__ ": failed to " "check if bridgehead DC has " "failed: %s\n", nt_errstr(status))); talloc_free(tmp_ctx); return status; } if (!failed_state_r && !failed_state_l) { valid_connections++; } conn_guid = samdb_result_guid(connection, "objectGUID"); if (!kcctpl_guid_list_contains(keep_connections, conn_guid)) { struct GUID *new_data; new_data = talloc_realloc(tmp_ctx, keep_connections.data, struct GUID, keep_connections.count + 1); NT_STATUS_HAVE_NO_MEMORY_AND_FREE(new_data, tmp_ctx); new_data[keep_connections.count] = conn_guid; keep_connections.data = new_data; keep_connections.count++; } } } } if (valid_connections == 0) { uint64_t opts = NTDSCONN_OPT_IS_GENERATED; struct GUID new_guid, *new_data; if (repl_info.options & NTDSSITELINK_OPT_USE_NOTIFY) { opts |= NTDSCONN_OPT_OVERRIDE_NOTIFY_DEFAULT; opts |= NTDSCONN_OPT_USE_NOTIFY; } if (repl_info.options & NTDSSITELINK_OPT_TWOWAY_SYNC) { opts |= NTDSCONN_OPT_TWOWAY_SYNC; } if (repl_info.options & NTDSSITELINK_OPT_DISABLE_COMPRESSION) { opts |= NTDSCONN_OPT_DISABLE_INTERSITE_COMPRESSION; } /* perform an originating update to create a new nTDSConnection * object cn that is: * * - child of l_bridgehead * - cn!enabledConnection = true * - cn!options = opts * - cn!transportType = t * - cn!fromServer = r_bridgehead * - cn!schedule = schedule */ /* TODO: what should be the new connection's GUID? */ new_guid = GUID_random(); new_data = talloc_realloc(tmp_ctx, keep_connections.data, struct GUID, keep_connections.count + 1); NT_STATUS_HAVE_NO_MEMORY_AND_FREE(new_data, tmp_ctx); new_data[keep_connections.count] = new_guid; keep_connections.data = new_data; keep_connections.count++; } talloc_steal(mem_ctx, keep_connections.data); *_keep_connections = keep_connections; talloc_free(tmp_ctx); return NT_STATUS_OK; } /** * construct an NC replica graph for the NC identified by the given 'cross_ref', * then create any additional nTDSConnection objects required. */ static NTSTATUS kcctpl_create_connections(struct kccsrv_service *service, TALLOC_CTX *mem_ctx, struct kcctpl_graph *graph, struct ldb_message *cross_ref, bool detect_failed_dcs, struct GUID_list keep_connections, bool *_found_failed_dcs, bool *_connected) { bool connected, found_failed_dcs, partial_replica_okay; NTSTATUS status; struct ldb_message *site; TALLOC_CTX *tmp_ctx; struct GUID site_guid; struct kcctpl_vertex *site_vertex; uint32_t component_count, i; struct kcctpl_multi_edge_list st_edge_list; struct ldb_dn *transports_dn; const char * const attrs[] = { "bridgeheadServerListBL", "name", "transportAddressAttribute", NULL }; int ret; connected = true; status = kcctpl_color_vertices(service, graph, cross_ref, detect_failed_dcs, &found_failed_dcs); if (NT_STATUS_IS_ERR(status)) { DEBUG(1, (__location__ ": failed to color vertices: %s\n", nt_errstr(status))); return status; } tmp_ctx = talloc_new(mem_ctx); NT_STATUS_HAVE_NO_MEMORY(tmp_ctx); site = kcctpl_local_site(service->samdb, tmp_ctx); if (!site) { DEBUG(1, (__location__ ": failed to find our own local DC's " "site\n")); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } site_guid = samdb_result_guid(site, "objectGUID"); site_vertex = kcctpl_find_vertex_by_guid(graph, site_guid); if (!site_vertex) { DEBUG(1, (__location__ ": failed to find vertex %s\n", GUID_string(tmp_ctx, &site_guid))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } if (site_vertex->color == WHITE) { *_found_failed_dcs = found_failed_dcs; *_connected = true; talloc_free(tmp_ctx); return NT_STATUS_OK; } status = kcctpl_get_spanning_tree_edges(service, tmp_ctx, graph, &component_count, &st_edge_list); if (NT_STATUS_IS_ERR(status)) { DEBUG(1, (__location__ ": failed get spanning tree edges: %s\n", nt_errstr(status))); talloc_free(tmp_ctx); return status; } if (component_count > 1) { connected = false; } partial_replica_okay = (site_vertex->color == BLACK); transports_dn = kcctpl_transports_dn(service->samdb, tmp_ctx); if (!transports_dn) { DEBUG(1, (__location__ ": failed to find our own Inter-Site " "Transports DN\n")); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } for (i = 0; i < st_edge_list.count; i++) { struct kcctpl_multi_edge *edge; struct GUID other_site_id; struct kcctpl_vertex *other_site_vertex; struct ldb_result *res; struct ldb_message *transport, *r_bridgehead, *l_bridgehead; uint8_t schedule[84]; uint32_t first_available, j, interval; edge = &st_edge_list.data[i]; if (edge->directed && !GUID_equal(&edge->vertex_ids.data[1], &site_vertex->id)) { continue; } if (GUID_equal(&edge->vertex_ids.data[0], &site_vertex->id)) { other_site_id = edge->vertex_ids.data[1]; } else { other_site_id = edge->vertex_ids.data[0]; } other_site_vertex = kcctpl_find_vertex_by_guid(graph, other_site_id); if (!other_site_vertex) { DEBUG(1, (__location__ ": failed to find vertex %s\n", GUID_string(tmp_ctx, &other_site_id))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } ret = ldb_search(service->samdb, tmp_ctx, &res, transports_dn, LDB_SCOPE_ONELEVEL, attrs, "(&(objectClass=interSiteTransport)" "(objectGUID=%s))", GUID_string(tmp_ctx, &edge->type)); if (ret != LDB_SUCCESS) { DEBUG(1, (__location__ ": failed to find " "interSiteTransport object %s: %s\n", GUID_string(tmp_ctx, &edge->type), ldb_strerror(ret))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } if (res->count == 0) { DEBUG(1, (__location__ ": failed to find " "interSiteTransport object %s\n", GUID_string(tmp_ctx, &edge->type))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } transport = res->msgs[0]; status = kcctpl_get_bridgehead_dc(service, tmp_ctx, other_site_vertex->id, cross_ref, transport, partial_replica_okay, detect_failed_dcs, &r_bridgehead); if (NT_STATUS_IS_ERR(status)) { DEBUG(1, (__location__ ": failed to get a bridgehead " "DC: %s\n", nt_errstr(status))); talloc_free(tmp_ctx); return status; } if (service->am_rodc) { /* TODO: l_bridgehad = nTDSDSA of local DC */ } else { status = kcctpl_get_bridgehead_dc(service, tmp_ctx, site_vertex->id, cross_ref, transport, partial_replica_okay, detect_failed_dcs, &l_bridgehead); if (NT_STATUS_IS_ERR(status)) { DEBUG(1, (__location__ ": failed to get a " "bridgehead DC: %s\n", nt_errstr(status))); talloc_free(tmp_ctx); return status; } } ZERO_ARRAY(schedule); first_available = 84; interval = edge->repl_info.interval / 15; for (j = 0; j < 84; j++) { if (edge->repl_info.schedule[j] == 1) { first_available = j; break; } } for (j = first_available; j < 84; j += interval) { schedule[j] = 1; } status = kcctpl_create_connection(service, mem_ctx, cross_ref, r_bridgehead, transport, l_bridgehead, edge->repl_info, schedule, detect_failed_dcs, partial_replica_okay, &keep_connections); if (NT_STATUS_IS_ERR(status)) { DEBUG(1, (__location__ ": failed to create a " "connection: %s\n", nt_errstr(status))); talloc_free(tmp_ctx); return status; } } *_found_failed_dcs = found_failed_dcs; *_connected = connected; talloc_free(tmp_ctx); return NT_STATUS_OK; } /** * computes an NC replica graph for each NC replica that "should be present" on * the local DC or "is present" on any DC in the same site as the local DC. for * each edge directed to an NC replica on such a DC from an NC replica on a DC * in another site, the KCC creates and nTDSConnection object to imply that edge * if one does not already exist. */ static NTSTATUS kcctpl_create_intersite_connections(struct kccsrv_service *service, TALLOC_CTX *mem_ctx, struct GUID_list *_keep_connections, bool *_all_connected) { struct GUID_list keep_connections; bool all_connected; TALLOC_CTX *tmp_ctx; struct ldb_dn *partitions_dn; struct ldb_result *res; const char * const attrs[] = { "enabled", "systemFlags", "nCName", NULL }; int ret; unsigned int i; all_connected = true; ZERO_STRUCT(keep_connections); tmp_ctx = talloc_new(mem_ctx); NT_STATUS_HAVE_NO_MEMORY(tmp_ctx); partitions_dn = samdb_partitions_dn(service->samdb, tmp_ctx); NT_STATUS_HAVE_NO_MEMORY_AND_FREE(partitions_dn, tmp_ctx); ret = ldb_search(service->samdb, tmp_ctx, &res, partitions_dn, LDB_SCOPE_ONELEVEL, attrs, "objectClass=crossRef"); if (ret != LDB_SUCCESS) { DEBUG(1, (__location__ ": failed to find crossRef objects: " "%s\n", ldb_strerror(ret))); talloc_free(tmp_ctx); return NT_STATUS_INTERNAL_DB_CORRUPTION; } for (i = 0; i < res->count; i++) { struct ldb_message *cross_ref; unsigned int cr_enabled; int64_t cr_flags; struct kcctpl_graph *graph; bool found_failed_dc, connected; NTSTATUS status; cross_ref = res->msgs[i]; cr_enabled = samdb_result_uint(cross_ref, "enabled", -1); cr_flags = samdb_result_int64(cross_ref, "systemFlags", 0); if ((cr_enabled == 0) || !(cr_flags & FLAG_CR_NTDS_NC)) { continue; } status = kcctpl_setup_graph(service->samdb, tmp_ctx, &graph); if (NT_STATUS_IS_ERR(status)) { DEBUG(1, (__location__ ": failed to create a graph: " "%s\n", nt_errstr(status))); talloc_free(tmp_ctx); return status; } status = kcctpl_create_connections(service, mem_ctx, graph, cross_ref, true, keep_connections, &found_failed_dc, &connected); if (NT_STATUS_IS_ERR(status)) { DEBUG(1, (__location__ ": failed to create " "connections: %s\n", nt_errstr(status))); talloc_free(tmp_ctx); return status; } if (!connected) { all_connected = false; if (found_failed_dc) { status = kcctpl_create_connections(service, mem_ctx, graph, cross_ref, true, keep_connections, &found_failed_dc, &connected); if (NT_STATUS_IS_ERR(status)) { DEBUG(1, (__location__ ": failed to " "create connections: %s\n", nt_errstr(status))); talloc_free(tmp_ctx); return status; } } } } *_keep_connections = keep_connections; *_all_connected = all_connected; talloc_free(tmp_ctx); return NT_STATUS_OK; } NTSTATUS kcctpl_test(struct kccsrv_service *service) { NTSTATUS status; TALLOC_CTX *tmp_ctx = talloc_new(service); struct GUID_list keep; bool all_connected; DEBUG(2, ("Testing kcctpl_create_intersite_connections\n")); status = kcctpl_create_intersite_connections(service, tmp_ctx, &keep, &all_connected); DEBUG(4, ("%s\n", nt_errstr(status))); if (NT_STATUS_IS_OK(status)) { uint32_t i; DEBUG(4, ("all_connected=%d, %d GUIDs returned\n", all_connected, keep.count)); for (i = 0; i < keep.count; i++) { DEBUG(4, ("GUID %d: %s\n", i + 1, GUID_string(tmp_ctx, &keep.data[i]))); } } talloc_free(tmp_ctx); return status; }