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author | CrÃstian Deives <cristiandeives@gmail.com> | 2010-03-07 01:55:12 -0300 |
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committer | Andrew Tridgell <tridge@samba.org> | 2010-03-12 16:31:20 +1100 |
commit | 6e20906f420be591894925a38504735d4e220c52 (patch) | |
tree | c5ef2bdeb8a8cda62bf842547261ae2b09571cc5 /source4 | |
parent | b70df94f620eb6c30ddfc98212012df270750412 (diff) | |
download | samba-6e20906f420be591894925a38504735d4e220c52.tar.gz samba-6e20906f420be591894925a38504735d4e220c52.tar.bz2 samba-6e20906f420be591894925a38504735d4e220c52.zip |
spanning tree computation
calculate the spanning tree for the intersite connection. this patch is in
accord with the section [MS-ADTS] 7.2.2.3.4.4.
Diffstat (limited to 'source4')
-rw-r--r-- | source4/dsdb/kcc/kcc_topology.c | 1692 |
1 files changed, 1692 insertions, 0 deletions
diff --git a/source4/dsdb/kcc/kcc_topology.c b/source4/dsdb/kcc/kcc_topology.c index 50a1fee49b..ea303b9076 100644 --- a/source4/dsdb/kcc/kcc_topology.c +++ b/source4/dsdb/kcc/kcc_topology.c @@ -27,10 +27,16 @@ #define FLAG_CR_NTDS_DOMAIN 0x00000002 +#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 NTDSTRANSPORT_OPT_BRIDGES_REQUIRED 0x00000002 +#define DS_BEHAVIOR_WIN2008 3 + /** replication parameters of a graph edge */ struct kcctpl_repl_info { uint32_t cost; @@ -130,6 +136,160 @@ struct message_list { }; /** + * 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, @@ -193,6 +353,22 @@ static struct kcctpl_multi_edge *kcctpl_find_edge_by_vertex_guid(struct kcctpl_g } /** + * 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; +} + +/** * get the Transports DN * (CN=Inter-Site Transports,CN=Sites,CN=Configuration,DC=<domain>). */ @@ -248,6 +424,44 @@ static struct ldb_message *kcctpl_local_site(struct ldb_context *ldb, 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. */ @@ -747,6 +961,324 @@ static NTSTATUS kcctpl_setup_graph(struct ldb_context *ldb, TALLOC_CTX *mem_ctx, } /** + * 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 ldb_context *ldb, + 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; + uint32_t i; + bool rodc; + 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(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_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 = samdb_schema_dn(ldb); + 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(ldb, 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(ldb, 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"); + + rodc = samdb_rodc(ldb); + + 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; + uint32_t j; + 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 = 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, ldb, &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 (rodc && true && behavior_version < DS_BEHAVIOR_WIN2008) { + continue; + } + + ret = ldb_search(ldb, 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(ldb, 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 ldb_context *ldb, @@ -758,6 +1290,21 @@ static NTSTATUS kcctpl_get_bridgehead_dc(struct ldb_context *ldb, bool detect_failed_dcs, struct ldb_message **_dsa) { + struct message_list dsa_list; + NTSTATUS status; + + status = kcctpl_get_all_bridgehead_dcs(ldb, 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; } @@ -974,3 +1521,1148 @@ static NTSTATUS kcctpl_color_vertices(struct ldb_context *ldb, 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 ldb_context *ldb, + 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(ldb); + NT_STATUS_HAVE_NO_MEMORY(tmp_ctx); + + 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_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 ldb_context *ldb, + 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(ldb, 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; +} |