Move everything from /var/adm to /var/log

[unleashed/lotheac.git] / usr / src / cmd / svc / startd / graph.c

/*
 * CDDL HEADER START
 *
 * The contents of this file are subject to the terms of the
 * Common Development and Distribution License (the "License").
 * You may not use this file except in compliance with the License.
 *
 * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
 * or http://www.opensolaris.org/os/licensing.
 * See the License for the specific language governing permissions
 * and limitations under the License.
 *
 * When distributing Covered Code, include this CDDL HEADER in each
 * file and include the License file at usr/src/OPENSOLARIS.LICENSE.
 * If applicable, add the following below this CDDL HEADER, with the
 * fields enclosed by brackets "[]" replaced with your own identifying
 * information: Portions Copyright [yyyy] [name of copyright owner]
 *
 * CDDL HEADER END
 */

/*
 * Copyright (c) 2004, 2010, Oracle and/or its affiliates. All rights reserved.
 * Copyright (c) 2015, Syneto S.R.L. All rights reserved.
 * Copyright 2016 Toomas Soome <tsoome@me.com>
 * Copyright 2016 RackTop Systems.
 */

/*
 * graph.c - master restarter graph engine
 *
 *   The graph engine keeps a dependency graph of all service instances on the
 *   system, as recorded in the repository.  It decides when services should
 *   be brought up or down based on service states and dependencies and sends
 *   commands to restarters to effect any changes.  It also executes
 *   administrator commands sent by svcadm via the repository.
 *
 *   The graph is stored in uu_list_t *dgraph and its vertices are
 *   graph_vertex_t's, each of which has a name and an integer id unique to
 *   its name (see dict.c).  A vertex's type attribute designates the type
 *   of object it represents: GVT_INST for service instances, GVT_SVC for
 *   service objects (since service instances may depend on another service,
 *   rather than service instance), GVT_FILE for files (which services may
 *   depend on), and GVT_GROUP for dependencies on multiple objects.  GVT_GROUP
 *   vertices are necessary because dependency lists may have particular
 *   grouping types (require any, require all, optional, or exclude) and
 *   event-propagation characteristics.
 *
 *   The initial graph is built by libscf_populate_graph() invoking
 *   dgraph_add_instance() for each instance in the repository.  The function
 *   adds a GVT_SVC vertex for the service if one does not already exist, adds
 *   a GVT_INST vertex named by the FMRI of the instance, and sets up the edges.
 *   The resulting web of vertices & edges associated with an instance's vertex
 *   includes
 *
 *     - an edge from the GVT_SVC vertex for the instance's service
 *
 *     - an edge to the GVT_INST vertex of the instance's resarter, if its
 *       restarter is not svc.startd
 *
 *     - edges from other GVT_INST vertices if the instance is a restarter
 *
 *     - for each dependency property group in the instance's "running"
 *       snapshot, an edge to a GVT_GROUP vertex named by the FMRI of the
 *       instance and the name of the property group
 *
 *     - for each value of the "entities" property in each dependency property
 *       group, an edge from the corresponding GVT_GROUP vertex to a
 *       GVT_INST, GVT_SVC, or GVT_FILE vertex
 *
 *     - edges from GVT_GROUP vertices for each dependent instance
 *
 *   After the edges are set up the vertex's GV_CONFIGURED flag is set.  If
 *   there are problems, or if a service is mentioned in a dependency but does
 *   not exist in the repository, the GV_CONFIGURED flag will be clear.
 *
 *   The graph and all of its vertices are protected by the dgraph_lock mutex.
 *   See restarter.c for more information.
 *
 *   The properties of an instance fall into two classes: immediate and
 *   snapshotted.  Immediate properties should have an immediate effect when
 *   changed.  Snapshotted properties should be read from a snapshot, so they
 *   only change when the snapshot changes.  The immediate properties used by
 *   the graph engine are general/enabled, general/restarter, and the properties
 *   in the restarter_actions property group.  Since they are immediate, they
 *   are not read out of a snapshot.  The snapshotted properties used by the
 *   graph engine are those in the property groups with type "dependency" and
 *   are read out of the "running" snapshot.  The "running" snapshot is created
 *   by the the graph engine as soon as possible, and it is updated, along with
 *   in-core copies of the data (dependency information for the graph engine) on
 *   receipt of the refresh command from svcadm.  In addition, the graph engine
 *   updates the "start" snapshot from the "running" snapshot whenever a service
 *   comes online.
 *
 *   When a DISABLE event is requested by the administrator, svc.startd shutdown
 *   the dependents first before shutting down the requested service.
 *   In graph_enable_by_vertex, we create a subtree that contains the dependent
 *   vertices by marking those vertices with the GV_TOOFFLINE flag. And we mark
 *   the vertex to disable with the GV_TODISABLE flag. Once the tree is created,
 *   we send the _ADMIN_DISABLE event to the leaves. The leaves will then
 *   transition from STATE_ONLINE/STATE_DEGRADED to STATE_OFFLINE/STATE_MAINT.
 *   In gt_enter_offline and gt_enter_maint if the vertex was in a subtree then
 *   we clear the GV_TOOFFLINE flag and walk the dependencies to offline the new
 *   exposed leaves. We do the same until we reach the last leaf (the one with
 *   the GV_TODISABLE flag). If the vertex to disable is also part of a larger
 *   subtree (eg. multiple DISABLE events on vertices in the same subtree) then
 *   once the first vertex is disabled (GV_TODISABLE flag is removed), we
 *   continue to propagate the offline event to the vertex's dependencies.
 *
 *
 * SMF state transition notifications
 *
 *   When an instance of a service managed by SMF changes state, svc.startd may
 *   publish a GPEC sysevent. All transitions to or from maintenance, a
 *   transition cause by a hardware error will generate an event.
 *   Other transitions will generate an event if there exist notification
 *   parameter for that transition. Notification parameters are stored in the
 *   SMF repository for the service/instance they refer to. System-wide
 *   notification parameters are stored in the global instance.
 *   svc.startd can be told to send events for all SMF state transitions despite
 *   of notification parameters by setting options/info_events_all to true in
 *   restarter:default
 *
 *   The set of transitions that generate events is cached in the
 *   dgraph_vertex_t gv_stn_tset for service/instance and in the global
 *   stn_global for the system-wide set. They are re-read when instances are
 *   refreshed.
 *
 *   The GPEC events published by svc.startd are consumed by fmd(8). After
 *   processing these events, fmd(8) publishes the processed events to
 *   notification agents. The notification agents read the notification
 *   parameters from the SMF repository through libscf(3LIB) interfaces and send
 *   the notification, or not, based on those parameters.
 *
 *   Subscription and publishing to the GPEC channels is done with the
 *   libfmevent(3LIB) wrappers fmev_[r]publish_*() and
 *   fmev_shdl_(un)subscribe().
 *
 */

#include <sys/uadmin.h>
#include <sys/wait.h>

#include <assert.h>
#include <errno.h>
#include <fcntl.h>
#include <fm/libfmevent.h>
#include <libscf.h>
#include <libscf_priv.h>
#include <librestart.h>
#include <libuutil.h>
#include <locale.h>
#include <poll.h>
#include <pthread.h>
#include <signal.h>
#include <stddef.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <strings.h>
#include <sys/statvfs.h>
#include <sys/uadmin.h>
#include <zone.h>
#if defined(__x86)
#include <libbe.h>
#endif  /* __x86 */

#include "startd.h"
#include "protocol.h"


#define MILESTONE_NONE  ((graph_vertex_t *)1)

#define CONSOLE_LOGIN_FMRI      "svc:/system/console-login:default"
#define FS_MINIMAL_FMRI         "svc:/system/filesystem/minimal:default"

#define VERTEX_REMOVED  0       /* vertex has been freed  */
#define VERTEX_INUSE    1       /* vertex is still in use */

#define IS_ENABLED(v) ((v)->gv_flags & (GV_ENABLED | GV_ENBLD_NOOVR))

/*
 * stn_global holds the tset for the system wide notification parameters.
 * It is updated on refresh of svc:/system/svc/global:default
 *
 * There are two assumptions that relax the need for a mutex:
 *     1. 32-bit value assignments are atomic
 *     2. Its value is consumed only in one point at
 *     dgraph_state_transition_notify(). There are no test and set races.
 *
 *     If either assumption is broken, we'll need a mutex to synchronize
 *     access to stn_global
 */
int32_t stn_global;
/*
 * info_events_all holds a flag to override notification parameters and send
 * Information events for all state transitions.
 * same about the need of a mutex here.
 */
int info_events_all;

/*
 * Services in these states are not considered 'down' by the
 * milestone/shutdown code.
 */
#define up_state(state) ((state) == RESTARTER_STATE_ONLINE || \
        (state) == RESTARTER_STATE_DEGRADED || \
        (state) == RESTARTER_STATE_OFFLINE)

#define is_depgrp_bypassed(v) ((v->gv_type == GVT_GROUP) && \
        ((v->gv_depgroup == DEPGRP_EXCLUDE_ALL) || \
        (v->gv_restart < RERR_RESTART)))

#define is_inst_bypassed(v) ((v->gv_type == GVT_INST) && \
        ((v->gv_flags & GV_TODISABLE) || \
        (v->gv_flags & GV_TOOFFLINE)))

static uu_list_pool_t *graph_edge_pool, *graph_vertex_pool;
static uu_list_t *dgraph;
static pthread_mutex_t dgraph_lock;

/*
 * milestone indicates the current subgraph.  When NULL, it is the entire
 * graph.  When MILESTONE_NONE, it is the empty graph.  Otherwise, it is all
 * services on which the target vertex depends.
 */
static graph_vertex_t *milestone = NULL;
static boolean_t initial_milestone_set = B_FALSE;
static pthread_cond_t initial_milestone_cv = PTHREAD_COND_INITIALIZER;

/* protected by dgraph_lock */
static boolean_t sulogin_thread_running = B_FALSE;
static boolean_t sulogin_running = B_FALSE;
static boolean_t console_login_ready = B_FALSE;

/* Number of services to come down to complete milestone transition. */
static uint_t non_subgraph_svcs;

/*
 * These variables indicate what should be done when we reach the milestone
 * target milestone, i.e., when non_subgraph_svcs == 0.  They are acted upon in
 * dgraph_set_instance_state().
 */
static int halting = -1;
static boolean_t go_single_user_mode = B_FALSE;
static boolean_t go_to_level1 = B_FALSE;

/*
 * Tracks when we started halting.
 */
static time_t halting_time = 0;

/*
 * This tracks the legacy runlevel to ensure we signal init and manage
 * utmpx entries correctly.
 */
static char current_runlevel = '\0';

/* Number of single user threads currently running */
static pthread_mutex_t single_user_thread_lock;
static int single_user_thread_count = 0;

/* Statistics for dependency cycle-checking */
static u_longlong_t dep_inserts = 0;
static u_longlong_t dep_cycle_ns = 0;
static u_longlong_t dep_insert_ns = 0;


static const char * const emsg_invalid_restarter =
        "Transitioning %s to maintenance, restarter FMRI %s is invalid "
        "(see 'svcs -xv' for details).\n";
static const char * const console_login_fmri = CONSOLE_LOGIN_FMRI;
static const char * const single_user_fmri = SCF_MILESTONE_SINGLE_USER;
static const char * const multi_user_fmri = SCF_MILESTONE_MULTI_USER;
static const char * const multi_user_svr_fmri = SCF_MILESTONE_MULTI_USER_SERVER;


/*
 * These services define the system being "up".  If none of them can come
 * online, then we will run sulogin on the console.  Note that the install ones
 * are for the miniroot and when installing CDs after the first.  can_come_up()
 * does the decision making, and an sulogin_thread() runs sulogin, which can be
 * started by dgraph_set_instance_state() or single_user_thread().
 *
 * NOTE: can_come_up() relies on SCF_MILESTONE_SINGLE_USER being the first
 * entry, which is only used when booting_to_single_user (boot -s) is set.
 * This is because when doing a "boot -s", sulogin is started from specials.c
 * after milestone/single-user comes online, for backwards compatibility.
 * In this case, SCF_MILESTONE_SINGLE_USER needs to be part of up_svcs
 * to ensure sulogin will be spawned if milestone/single-user cannot be reached.
 */
static const char * const up_svcs[] = {
        SCF_MILESTONE_SINGLE_USER,
        CONSOLE_LOGIN_FMRI,
        "svc:/system/install-setup:default",
        "svc:/system/install:default",
        NULL
};

/* This array must have an element for each non-NULL element of up_svcs[]. */
static graph_vertex_t *up_svcs_p[] = { NULL, NULL, NULL, NULL };

/* These are for seed repository magic.  See can_come_up(). */
static const char * const manifest_import = SCF_INSTANCE_MI;
static graph_vertex_t *manifest_import_p = NULL;


static char target_milestone_as_runlevel(void);
static void graph_runlevel_changed(char rl, int online);
static int dgraph_set_milestone(const char *, scf_handle_t *, boolean_t);
static boolean_t should_be_in_subgraph(graph_vertex_t *v);
static int mark_subtree(graph_edge_t *, void *);
static boolean_t insubtree_dependents_down(graph_vertex_t *);

/*
 * graph_vertex_compare()
 *      This function can compare either int *id or * graph_vertex_t *gv
 *      values, as the vertex id is always the first element of a
 *      graph_vertex structure.
 */
/* ARGSUSED */
static int
graph_vertex_compare(const void *lc_arg, const void *rc_arg, void *private)
{
        int lc_id = ((const graph_vertex_t *)lc_arg)->gv_id;
        int rc_id = *(int *)rc_arg;

        if (lc_id > rc_id)
                return (1);
        if (lc_id < rc_id)
                return (-1);
        return (0);
}

void
graph_init()
{
        graph_edge_pool = startd_list_pool_create("graph_edges",
            sizeof (graph_edge_t), offsetof(graph_edge_t, ge_link), NULL,
            UU_LIST_POOL_DEBUG);
        assert(graph_edge_pool != NULL);

        graph_vertex_pool = startd_list_pool_create("graph_vertices",
            sizeof (graph_vertex_t), offsetof(graph_vertex_t, gv_link),
            graph_vertex_compare, UU_LIST_POOL_DEBUG);
        assert(graph_vertex_pool != NULL);

        (void) pthread_mutex_init(&dgraph_lock, &mutex_attrs);
        (void) pthread_mutex_init(&single_user_thread_lock, &mutex_attrs);
        dgraph = startd_list_create(graph_vertex_pool, NULL, UU_LIST_SORTED);
        assert(dgraph != NULL);

        if (!st->st_initial)
                current_runlevel = utmpx_get_runlevel();

        log_framework(LOG_DEBUG, "Initialized graph\n");
}

static graph_vertex_t *
vertex_get_by_name(const char *name)
{
        int id;

        assert(MUTEX_HELD(&dgraph_lock));

        id = dict_lookup_byname(name);
        if (id == -1)
                return (NULL);

        return (uu_list_find(dgraph, &id, NULL, NULL));
}

static graph_vertex_t *
vertex_get_by_id(int id)
{
        assert(MUTEX_HELD(&dgraph_lock));

        if (id == -1)
                return (NULL);

        return (uu_list_find(dgraph, &id, NULL, NULL));
}

/*
 * Creates a new vertex with the given name, adds it to the graph, and returns
 * a pointer to it.  The graph lock must be held by this thread on entry.
 */
static graph_vertex_t *
graph_add_vertex(const char *name)
{
        int id;
        graph_vertex_t *v;
        void *p;
        uu_list_index_t idx;

        assert(MUTEX_HELD(&dgraph_lock));

        id = dict_insert(name);

        v = startd_zalloc(sizeof (*v));

        v->gv_id = id;

        v->gv_name = startd_alloc(strlen(name) + 1);
        (void) strcpy(v->gv_name, name);

        v->gv_dependencies = startd_list_create(graph_edge_pool, v, 0);
        v->gv_dependents = startd_list_create(graph_edge_pool, v, 0);

        p = uu_list_find(dgraph, &id, NULL, &idx);
        assert(p == NULL);

        uu_list_node_init(v, &v->gv_link, graph_vertex_pool);
        uu_list_insert(dgraph, v, idx);

        return (v);
}

/*
 * Removes v from the graph and frees it.  The graph should be locked by this
 * thread, and v should have no edges associated with it.
 */
static void
graph_remove_vertex(graph_vertex_t *v)
{
        assert(MUTEX_HELD(&dgraph_lock));

        assert(uu_list_numnodes(v->gv_dependencies) == 0);
        assert(uu_list_numnodes(v->gv_dependents) == 0);
        assert(v->gv_refs == 0);

        startd_free(v->gv_name, strlen(v->gv_name) + 1);
        uu_list_destroy(v->gv_dependencies);
        uu_list_destroy(v->gv_dependents);
        uu_list_remove(dgraph, v);

        startd_free(v, sizeof (graph_vertex_t));
}

static void
graph_add_edge(graph_vertex_t *fv, graph_vertex_t *tv)
{
        graph_edge_t *e, *re;
        int r;

        assert(MUTEX_HELD(&dgraph_lock));

        e = startd_alloc(sizeof (graph_edge_t));
        re = startd_alloc(sizeof (graph_edge_t));

        e->ge_parent = fv;
        e->ge_vertex = tv;

        re->ge_parent = tv;
        re->ge_vertex = fv;

        uu_list_node_init(e, &e->ge_link, graph_edge_pool);
        r = uu_list_insert_before(fv->gv_dependencies, NULL, e);
        assert(r == 0);

        uu_list_node_init(re, &re->ge_link, graph_edge_pool);
        r = uu_list_insert_before(tv->gv_dependents, NULL, re);
        assert(r == 0);
}

static void
graph_remove_edge(graph_vertex_t *v, graph_vertex_t *dv)
{
        graph_edge_t *e;

        for (e = uu_list_first(v->gv_dependencies);
            e != NULL;
            e = uu_list_next(v->gv_dependencies, e)) {
                if (e->ge_vertex == dv) {
                        uu_list_remove(v->gv_dependencies, e);
                        startd_free(e, sizeof (graph_edge_t));
                        break;
                }
        }

        for (e = uu_list_first(dv->gv_dependents);
            e != NULL;
            e = uu_list_next(dv->gv_dependents, e)) {
                if (e->ge_vertex == v) {
                        uu_list_remove(dv->gv_dependents, e);
                        startd_free(e, sizeof (graph_edge_t));
                        break;
                }
        }
}

static void
remove_inst_vertex(graph_vertex_t *v)
{
        graph_edge_t *e;
        graph_vertex_t *sv;
        int i;

        assert(MUTEX_HELD(&dgraph_lock));
        assert(uu_list_numnodes(v->gv_dependents) == 1);
        assert(uu_list_numnodes(v->gv_dependencies) == 0);
        assert(v->gv_refs == 0);
        assert((v->gv_flags & GV_CONFIGURED) == 0);

        e = uu_list_first(v->gv_dependents);
        sv = e->ge_vertex;
        graph_remove_edge(sv, v);

        for (i = 0; up_svcs[i] != NULL; ++i) {
                if (up_svcs_p[i] == v)
                        up_svcs_p[i] = NULL;
        }

        if (manifest_import_p == v)
                manifest_import_p = NULL;

        graph_remove_vertex(v);

        if (uu_list_numnodes(sv->gv_dependencies) == 0 &&
            uu_list_numnodes(sv->gv_dependents) == 0 &&
            sv->gv_refs == 0)
                graph_remove_vertex(sv);
}

static void
graph_walk_dependents(graph_vertex_t *v, void (*func)(graph_vertex_t *, void *),
    void *arg)
{
        graph_edge_t *e;

        for (e = uu_list_first(v->gv_dependents);
            e != NULL;
            e = uu_list_next(v->gv_dependents, e))
                func(e->ge_vertex, arg);
}

static void
graph_walk_dependencies(graph_vertex_t *v,
    void (*func)(graph_vertex_t *, void *), void *arg)
{
        graph_edge_t *e;

        assert(MUTEX_HELD(&dgraph_lock));

        for (e = uu_list_first(v->gv_dependencies);
            e != NULL;
            e = uu_list_next(v->gv_dependencies, e)) {

                func(e->ge_vertex, arg);
        }
}

/*
 * Generic graph walking function.
 *
 * Given a vertex, this function will walk either dependencies
 * (WALK_DEPENDENCIES) or dependents (WALK_DEPENDENTS) of a vertex recursively
 * for the entire graph.  It will avoid cycles and never visit the same vertex
 * twice.
 *
 * We avoid traversing exclusion dependencies, because they are allowed to
 * create cycles in the graph.  When propagating satisfiability, there is no
 * need to walk exclusion dependencies because exclude_all_satisfied() doesn't
 * test for satisfiability.
 *
 * The walker takes two callbacks.  The first is called before examining the
 * dependents of each vertex.  The second is called on each vertex after
 * examining its dependents.  This allows is_path_to() to construct a path only
 * after the target vertex has been found.
 */
typedef enum {
        WALK_DEPENDENTS,
        WALK_DEPENDENCIES
} graph_walk_dir_t;

typedef int (*graph_walk_cb_t)(graph_vertex_t *, void *);

typedef struct graph_walk_info {
        graph_walk_dir_t        gi_dir;
        uchar_t                 *gi_visited;    /* vertex bitmap */
        int                     (*gi_pre)(graph_vertex_t *, void *);
        void                    (*gi_post)(graph_vertex_t *, void *);
        void                    *gi_arg;        /* callback arg */
        int                     gi_ret;         /* return value */
} graph_walk_info_t;

static int
graph_walk_recurse(graph_edge_t *e, graph_walk_info_t *gip)
{
        uu_list_t *list;
        int r;
        graph_vertex_t *v = e->ge_vertex;
        int i;
        uint_t b;

        i = v->gv_id / 8;
        b = 1 << (v->gv_id % 8);

        /*
         * Check to see if we've visited this vertex already.
         */
        if (gip->gi_visited[i] & b)
                return (UU_WALK_NEXT);

        gip->gi_visited[i] |= b;

        /*
         * Don't follow exclusions.
         */
        if (v->gv_type == GVT_GROUP && v->gv_depgroup == DEPGRP_EXCLUDE_ALL)
                return (UU_WALK_NEXT);

        /*
         * Call pre-visit callback.  If this doesn't terminate the walk,
         * continue search.
         */
        if ((gip->gi_ret = gip->gi_pre(v, gip->gi_arg)) == UU_WALK_NEXT) {
                /*
                 * Recurse using appropriate list.
                 */
                if (gip->gi_dir == WALK_DEPENDENTS)
                        list = v->gv_dependents;
                else
                        list = v->gv_dependencies;

                r = uu_list_walk(list, (uu_walk_fn_t *)graph_walk_recurse,
                    gip, 0);
                assert(r == 0);
        }

        /*
         * Callbacks must return either UU_WALK_NEXT or UU_WALK_DONE.
         */
        assert(gip->gi_ret == UU_WALK_NEXT || gip->gi_ret == UU_WALK_DONE);

        /*
         * If given a post-callback, call the function for every vertex.
         */
        if (gip->gi_post != NULL)
                (void) gip->gi_post(v, gip->gi_arg);

        /*
         * Preserve the callback's return value.  If the callback returns
         * UU_WALK_DONE, then we propagate that to the caller in order to
         * terminate the walk.
         */
        return (gip->gi_ret);
}

static void
graph_walk(graph_vertex_t *v, graph_walk_dir_t dir,
    int (*pre)(graph_vertex_t *, void *),
    void (*post)(graph_vertex_t *, void *), void *arg)
{
        graph_walk_info_t gi;
        graph_edge_t fake;
        size_t sz = dictionary->dict_new_id / 8 + 1;

        gi.gi_visited = startd_zalloc(sz);
        gi.gi_pre = pre;
        gi.gi_post = post;
        gi.gi_arg = arg;
        gi.gi_dir = dir;
        gi.gi_ret = 0;

        /*
         * Fake up an edge for the first iteration
         */
        fake.ge_vertex = v;
        (void) graph_walk_recurse(&fake, &gi);

        startd_free(gi.gi_visited, sz);
}

typedef struct child_search {
        int     id;             /* id of vertex to look for */
        uint_t  depth;          /* recursion depth */
        /*
         * While the vertex is not found, path is NULL.  After the search, if
         * the vertex was found then path should point to a -1-terminated
         * array of vertex id's which constitute the path to the vertex.
         */
        int     *path;
} child_search_t;

static int
child_pre(graph_vertex_t *v, void *arg)
{
        child_search_t *cs = arg;

        cs->depth++;

        if (v->gv_id == cs->id) {
                cs->path = startd_alloc((cs->depth + 1) * sizeof (int));
                cs->path[cs->depth] = -1;
                return (UU_WALK_DONE);
        }

        return (UU_WALK_NEXT);
}

static void
child_post(graph_vertex_t *v, void *arg)
{
        child_search_t *cs = arg;

        cs->depth--;

        if (cs->path != NULL)
                cs->path[cs->depth] = v->gv_id;
}

/*
 * Look for a path from from to to.  If one exists, returns a pointer to
 * a NULL-terminated array of pointers to the vertices along the path.  If
 * there is no path, returns NULL.
 */
static int *
is_path_to(graph_vertex_t *from, graph_vertex_t *to)
{
        child_search_t cs;

        cs.id = to->gv_id;
        cs.depth = 0;
        cs.path = NULL;

        graph_walk(from, WALK_DEPENDENCIES, child_pre, child_post, &cs);

        return (cs.path);
}

/*
 * Given an array of int's as returned by is_path_to, allocates a string of
 * their names joined by newlines.  Returns the size of the allocated buffer
 * in *sz and frees path.
 */
static void
path_to_str(int *path, char **cpp, size_t *sz)
{
        int i;
        graph_vertex_t *v;
        size_t allocd, new_allocd;
        char *new, *name;

        assert(MUTEX_HELD(&dgraph_lock));
        assert(path[0] != -1);

        allocd = 1;
        *cpp = startd_alloc(1);
        (*cpp)[0] = '\0';

        for (i = 0; path[i] != -1; ++i) {
                name = NULL;

                v = vertex_get_by_id(path[i]);

                if (v == NULL)
                        name = "<deleted>";
                else if (v->gv_type == GVT_INST || v->gv_type == GVT_SVC)
                        name = v->gv_name;

                if (name != NULL) {
                        new_allocd = allocd + strlen(name) + 1;
                        new = startd_alloc(new_allocd);
                        (void) strcpy(new, *cpp);
                        (void) strcat(new, name);
                        (void) strcat(new, "\n");

                        startd_free(*cpp, allocd);

                        *cpp = new;
                        allocd = new_allocd;
                }
        }

        startd_free(path, sizeof (int) * (i + 1));

        *sz = allocd;
}


/*
 * This function along with run_sulogin() implements an exclusion relationship
 * between system/console-login and sulogin.  run_sulogin() will fail if
 * system/console-login is online, and the graph engine should call
 * graph_clogin_start() to bring system/console-login online, which defers the
 * start if sulogin is running.
 */
static void
graph_clogin_start(graph_vertex_t *v)
{
        assert(MUTEX_HELD(&dgraph_lock));

        if (sulogin_running)
                console_login_ready = B_TRUE;
        else
                vertex_send_event(v, RESTARTER_EVENT_TYPE_START);
}

static void
graph_su_start(graph_vertex_t *v)
{
        /*
         * /etc/inittab used to have the initial /sbin/rcS as a 'sysinit'
         * entry with a runlevel of 'S', before jumping to the final
         * target runlevel (as set in initdefault).  We mimic that legacy
         * behavior here.
         */
        utmpx_set_runlevel('S', '0', B_FALSE);
        vertex_send_event(v, RESTARTER_EVENT_TYPE_START);
}

static void
graph_post_su_online(void)
{
        graph_runlevel_changed('S', 1);
}

static void
graph_post_su_disable(void)
{
        graph_runlevel_changed('S', 0);
}

static void
graph_post_mu_online(void)
{
        graph_runlevel_changed('2', 1);
}

static void
graph_post_mu_disable(void)
{
        graph_runlevel_changed('2', 0);
}

static void
graph_post_mus_online(void)
{
        graph_runlevel_changed('3', 1);
}

static void
graph_post_mus_disable(void)
{
        graph_runlevel_changed('3', 0);
}

static struct special_vertex_info {
        const char      *name;
        void            (*start_f)(graph_vertex_t *);
        void            (*post_online_f)(void);
        void            (*post_disable_f)(void);
} special_vertices[] = {
        { CONSOLE_LOGIN_FMRI, graph_clogin_start, NULL, NULL },
        { SCF_MILESTONE_SINGLE_USER, graph_su_start,
            graph_post_su_online, graph_post_su_disable },
        { SCF_MILESTONE_MULTI_USER, NULL,
            graph_post_mu_online, graph_post_mu_disable },
        { SCF_MILESTONE_MULTI_USER_SERVER, NULL,
            graph_post_mus_online, graph_post_mus_disable },
        { NULL },
};


void
vertex_send_event(graph_vertex_t *v, restarter_event_type_t e)
{
        switch (e) {
        case RESTARTER_EVENT_TYPE_ADD_INSTANCE:
                assert(v->gv_state == RESTARTER_STATE_UNINIT);

                MUTEX_LOCK(&st->st_load_lock);
                st->st_load_instances++;
                MUTEX_UNLOCK(&st->st_load_lock);
                break;

        case RESTARTER_EVENT_TYPE_ENABLE:
                log_framework(LOG_DEBUG, "Enabling %s.\n", v->gv_name);
                assert(v->gv_state == RESTARTER_STATE_UNINIT ||
                    v->gv_state == RESTARTER_STATE_DISABLED ||
                    v->gv_state == RESTARTER_STATE_MAINT);
                break;

        case RESTARTER_EVENT_TYPE_DISABLE:
        case RESTARTER_EVENT_TYPE_ADMIN_DISABLE:
                log_framework(LOG_DEBUG, "Disabling %s.\n", v->gv_name);
                assert(v->gv_state != RESTARTER_STATE_DISABLED);
                break;

        case RESTARTER_EVENT_TYPE_STOP_RESET:
        case RESTARTER_EVENT_TYPE_STOP:
                log_framework(LOG_DEBUG, "Stopping %s.\n", v->gv_name);
                assert(v->gv_state == RESTARTER_STATE_DEGRADED ||
                    v->gv_state == RESTARTER_STATE_ONLINE);
                break;

        case RESTARTER_EVENT_TYPE_START:
                log_framework(LOG_DEBUG, "Starting %s.\n", v->gv_name);
                assert(v->gv_state == RESTARTER_STATE_OFFLINE);
                break;

        case RESTARTER_EVENT_TYPE_REMOVE_INSTANCE:
        case RESTARTER_EVENT_TYPE_ADMIN_DEGRADED:
        case RESTARTER_EVENT_TYPE_ADMIN_REFRESH:
        case RESTARTER_EVENT_TYPE_ADMIN_RESTART:
        case RESTARTER_EVENT_TYPE_ADMIN_MAINT_OFF:
        case RESTARTER_EVENT_TYPE_ADMIN_MAINT_ON:
        case RESTARTER_EVENT_TYPE_ADMIN_MAINT_ON_IMMEDIATE:
        case RESTARTER_EVENT_TYPE_DEPENDENCY_CYCLE:
        case RESTARTER_EVENT_TYPE_INVALID_DEPENDENCY:
                break;

        default:
#ifndef NDEBUG
                uu_warn("%s:%d: Bad event %d.\n", __FILE__, __LINE__, e);
#endif
                abort();
        }

        restarter_protocol_send_event(v->gv_name, v->gv_restarter_channel, e,
            v->gv_reason);
}

static void
graph_unset_restarter(graph_vertex_t *v)
{
        assert(MUTEX_HELD(&dgraph_lock));
        assert(v->gv_flags & GV_CONFIGURED);

        vertex_send_event(v, RESTARTER_EVENT_TYPE_REMOVE_INSTANCE);

        if (v->gv_restarter_id != -1) {
                graph_vertex_t *rv;

                rv = vertex_get_by_id(v->gv_restarter_id);
                graph_remove_edge(v, rv);
        }

        v->gv_restarter_id = -1;
        v->gv_restarter_channel = NULL;
}

/*
 * Return VERTEX_REMOVED when the vertex passed in argument is deleted from the
 * dgraph otherwise return VERTEX_INUSE.
 */
static int
free_if_unrefed(graph_vertex_t *v)
{
        assert(MUTEX_HELD(&dgraph_lock));

        if (v->gv_refs > 0)
                return (VERTEX_INUSE);

        if (v->gv_type == GVT_SVC &&
            uu_list_numnodes(v->gv_dependents) == 0 &&
            uu_list_numnodes(v->gv_dependencies) == 0) {
                graph_remove_vertex(v);
                return (VERTEX_REMOVED);
        } else if (v->gv_type == GVT_INST &&
            (v->gv_flags & GV_CONFIGURED) == 0 &&
            uu_list_numnodes(v->gv_dependents) == 1 &&
            uu_list_numnodes(v->gv_dependencies) == 0) {
                remove_inst_vertex(v);
                return (VERTEX_REMOVED);
        }

        return (VERTEX_INUSE);
}

static void
delete_depgroup(graph_vertex_t *v)
{
        graph_edge_t *e;
        graph_vertex_t *dv;

        assert(MUTEX_HELD(&dgraph_lock));
        assert(v->gv_type == GVT_GROUP);
        assert(uu_list_numnodes(v->gv_dependents) == 0);

        while ((e = uu_list_first(v->gv_dependencies)) != NULL) {
                dv = e->ge_vertex;

                graph_remove_edge(v, dv);

                switch (dv->gv_type) {
                case GVT_INST:          /* instance dependency */
                case GVT_SVC:           /* service dependency */
                        (void) free_if_unrefed(dv);
                        break;

                case GVT_FILE:          /* file dependency */
                        assert(uu_list_numnodes(dv->gv_dependencies) == 0);
                        if (uu_list_numnodes(dv->gv_dependents) == 0)
                                graph_remove_vertex(dv);
                        break;

                default:
#ifndef NDEBUG
                        uu_warn("%s:%d: Unexpected node type %d", __FILE__,
                            __LINE__, dv->gv_type);
#endif
                        abort();
                }
        }

        graph_remove_vertex(v);
}

static int
delete_instance_deps_cb(graph_edge_t *e, void **ptrs)
{
        graph_vertex_t *v = ptrs[0];
        boolean_t delete_restarter_dep = (boolean_t)ptrs[1];
        graph_vertex_t *dv;

        dv = e->ge_vertex;

        /*
         * We have four possibilities here:
         *   - GVT_INST: restarter
         *   - GVT_GROUP - GVT_INST: instance dependency
         *   - GVT_GROUP - GVT_SVC - GV_INST: service dependency
         *   - GVT_GROUP - GVT_FILE: file dependency
         */
        switch (dv->gv_type) {
        case GVT_INST:  /* restarter */
                assert(dv->gv_id == v->gv_restarter_id);
                if (delete_restarter_dep)
                        graph_remove_edge(v, dv);
                break;

        case GVT_GROUP: /* pg dependency */
                graph_remove_edge(v, dv);
                delete_depgroup(dv);
                break;

        case GVT_FILE:
                /* These are currently not direct dependencies */

        default:
#ifndef NDEBUG
                uu_warn("%s:%d: Bad vertex type %d.\n", __FILE__, __LINE__,
                    dv->gv_type);
#endif
                abort();
        }

        return (UU_WALK_NEXT);
}

static void
delete_instance_dependencies(graph_vertex_t *v, boolean_t delete_restarter_dep)
{
        void *ptrs[2];
        int r;

        assert(MUTEX_HELD(&dgraph_lock));
        assert(v->gv_type == GVT_INST);

        ptrs[0] = v;
        ptrs[1] = (void *)delete_restarter_dep;

        r = uu_list_walk(v->gv_dependencies,
            (uu_walk_fn_t *)delete_instance_deps_cb, &ptrs, UU_WALK_ROBUST);
        assert(r == 0);
}

/*
 * int graph_insert_vertex_unconfigured()
 *   Insert a vertex without sending any restarter events. If the vertex
 *   already exists or creation is successful, return a pointer to it in *vp.
 *
 *   If type is not GVT_GROUP, dt can remain unset.
 *
 *   Returns 0, EEXIST, or EINVAL if the arguments are invalid (i.e., fmri
 *   doesn't agree with type, or type doesn't agree with dt).
 */
static int
graph_insert_vertex_unconfigured(const char *fmri, gv_type_t type,
    depgroup_type_t dt, restarter_error_t rt, graph_vertex_t **vp)
{
        int r;
        int i;

        assert(MUTEX_HELD(&dgraph_lock));

        switch (type) {
        case GVT_SVC:
        case GVT_INST:
                if (strncmp(fmri, "svc:", sizeof ("svc:") - 1) != 0)
                        return (EINVAL);
                break;

        case GVT_FILE:
                if (strncmp(fmri, "file:", sizeof ("file:") - 1) != 0)
                        return (EINVAL);
                break;

        case GVT_GROUP:
                if (dt <= 0 || rt < 0)
                        return (EINVAL);
                break;

        default:
#ifndef NDEBUG
                uu_warn("%s:%d: Unknown type %d.\n", __FILE__, __LINE__, type);
#endif
                abort();
        }

        *vp = vertex_get_by_name(fmri);
        if (*vp != NULL)
                return (EEXIST);

        *vp = graph_add_vertex(fmri);

        (*vp)->gv_type = type;
        (*vp)->gv_depgroup = dt;
        (*vp)->gv_restart = rt;

        (*vp)->gv_flags = 0;
        (*vp)->gv_state = RESTARTER_STATE_NONE;

        for (i = 0; special_vertices[i].name != NULL; ++i) {
                if (strcmp(fmri, special_vertices[i].name) == 0) {
                        (*vp)->gv_start_f = special_vertices[i].start_f;
                        (*vp)->gv_post_online_f =
                            special_vertices[i].post_online_f;
                        (*vp)->gv_post_disable_f =
                            special_vertices[i].post_disable_f;
                        break;
                }
        }

        (*vp)->gv_restarter_id = -1;
        (*vp)->gv_restarter_channel = 0;

        if (type == GVT_INST) {
                char *sfmri;
                graph_vertex_t *sv;

                sfmri = inst_fmri_to_svc_fmri(fmri);
                sv = vertex_get_by_name(sfmri);
                if (sv == NULL) {
                        r = graph_insert_vertex_unconfigured(sfmri, GVT_SVC, 0,
                            0, &sv);
                        assert(r == 0);
                }
                startd_free(sfmri, max_scf_fmri_size);

                graph_add_edge(sv, *vp);
        }

        /*
         * If this vertex is in the subgraph, mark it as so, for both
         * GVT_INST and GVT_SERVICE verteces.
         * A GVT_SERVICE vertex can only be in the subgraph if another instance
         * depends on it, in which case it's already been added to the graph
         * and marked as in the subgraph (by refresh_vertex()).  If a
         * GVT_SERVICE vertex was freshly added (by the code above), it means
         * that it has no dependents, and cannot be in the subgraph.
         * Regardless of this, we still check that gv_flags includes
         * GV_INSUBGRAPH in the event that future behavior causes the above
         * code to add a GVT_SERVICE vertex which should be in the subgraph.
         */

        (*vp)->gv_flags |= (should_be_in_subgraph(*vp)? GV_INSUBGRAPH : 0);

        return (0);
}

/*
 * Returns 0 on success or ELOOP if the dependency would create a cycle.
 */
static int
graph_insert_dependency(graph_vertex_t *fv, graph_vertex_t *tv, int **pathp)
{
        hrtime_t now;

        assert(MUTEX_HELD(&dgraph_lock));

        /* cycle detection */
        now = gethrtime();

        /* Don't follow exclusions. */
        if (!(fv->gv_type == GVT_GROUP &&
            fv->gv_depgroup == DEPGRP_EXCLUDE_ALL)) {
                *pathp = is_path_to(tv, fv);
                if (*pathp)
                        return (ELOOP);
        }

        dep_cycle_ns += gethrtime() - now;
        ++dep_inserts;
        now = gethrtime();

        graph_add_edge(fv, tv);

        dep_insert_ns += gethrtime() - now;

        /* Check if the dependency adds the "to" vertex to the subgraph */
        tv->gv_flags |= (should_be_in_subgraph(tv) ? GV_INSUBGRAPH : 0);

        return (0);
}

static int
inst_running(graph_vertex_t *v)
{
        assert(v->gv_type == GVT_INST);

        if (v->gv_state == RESTARTER_STATE_ONLINE ||
            v->gv_state == RESTARTER_STATE_DEGRADED)
                return (1);

        return (0);
}

/*
 * The dependency evaluation functions return
 *   1 - dependency satisfied
 *   0 - dependency unsatisfied
 *   -1 - dependency unsatisfiable (without administrator intervention)
 *
 * The functions also take a boolean satbility argument.  When true, the
 * functions may recurse in order to determine satisfiability.
 */
static int require_any_satisfied(graph_vertex_t *, boolean_t);
static int dependency_satisfied(graph_vertex_t *, boolean_t);

/*
 * A require_all dependency is unsatisfied if any elements are unsatisfied.  It
 * is unsatisfiable if any elements are unsatisfiable.
 */
static int
require_all_satisfied(graph_vertex_t *groupv, boolean_t satbility)
{
        graph_edge_t *edge;
        int i;
        boolean_t any_unsatisfied;

        if (uu_list_numnodes(groupv->gv_dependencies) == 0)
                return (1);

        any_unsatisfied = B_FALSE;

        for (edge = uu_list_first(groupv->gv_dependencies);
            edge != NULL;
            edge = uu_list_next(groupv->gv_dependencies, edge)) {
                i = dependency_satisfied(edge->ge_vertex, satbility);
                if (i == 1)
                        continue;

                log_framework2(LOG_DEBUG, DEBUG_DEPENDENCIES,
                    "require_all(%s): %s is unsatisfi%s.\n", groupv->gv_name,
                    edge->ge_vertex->gv_name, i == 0 ? "ed" : "able");

                if (!satbility)
                        return (0);

                if (i == -1)
                        return (-1);

                any_unsatisfied = B_TRUE;
        }

        return (any_unsatisfied ? 0 : 1);
}

/*
 * A require_any dependency is satisfied if any element is satisfied.  It is
 * satisfiable if any element is satisfiable.
 */
static int
require_any_satisfied(graph_vertex_t *groupv, boolean_t satbility)
{
        graph_edge_t *edge;
        int s;
        boolean_t satisfiable;

        if (uu_list_numnodes(groupv->gv_dependencies) == 0)
                return (1);

        satisfiable = B_FALSE;

        for (edge = uu_list_first(groupv->gv_dependencies);
            edge != NULL;
            edge = uu_list_next(groupv->gv_dependencies, edge)) {
                s = dependency_satisfied(edge->ge_vertex, satbility);

                if (s == 1)
                        return (1);

                log_framework2(LOG_DEBUG, DEBUG_DEPENDENCIES,
                    "require_any(%s): %s is unsatisfi%s.\n",
                    groupv->gv_name, edge->ge_vertex->gv_name,
                    s == 0 ? "ed" : "able");

                if (satbility && s == 0)
                        satisfiable = B_TRUE;
        }

        return ((!satbility || satisfiable) ? 0 : -1);
}

/*
 * An optional_all dependency only considers elements which are configured,
 * enabled, and not in maintenance.  If any are unsatisfied, then the dependency
 * is unsatisfied.
 *
 * Offline dependencies which are waiting for a dependency to come online are
 * unsatisfied.  Offline dependences which cannot possibly come online
 * (unsatisfiable) are always considered satisfied.
 */
static int
optional_all_satisfied(graph_vertex_t *groupv, boolean_t satbility)
{
        graph_edge_t *edge;
        graph_vertex_t *v;
        boolean_t any_qualified;
        boolean_t any_unsatisfied;
        int i;

        any_qualified = B_FALSE;
        any_unsatisfied = B_FALSE;

        for (edge = uu_list_first(groupv->gv_dependencies);
            edge != NULL;
            edge = uu_list_next(groupv->gv_dependencies, edge)) {
                v = edge->ge_vertex;

                switch (v->gv_type) {
                case GVT_INST:
                        /* Skip missing instances */
                        if ((v->gv_flags & GV_CONFIGURED) == 0)
                                continue;

                        if (v->gv_state == RESTARTER_STATE_MAINT)
                                continue;

                        any_qualified = B_TRUE;
                        if (v->gv_state == RESTARTER_STATE_OFFLINE ||
                            v->gv_state == RESTARTER_STATE_DISABLED) {
                                /*
                                 * For offline/disabled dependencies,
                                 * treat unsatisfiable as satisfied.
                                 */
                                i = dependency_satisfied(v, B_TRUE);
                                if (i == -1)
                                        i = 1;
                        } else {
                                i = dependency_satisfied(v, satbility);
                        }
                        break;

                case GVT_FILE:
                        any_qualified = B_TRUE;
                        i = dependency_satisfied(v, satbility);

                        break;

                case GVT_SVC: {
                        any_qualified = B_TRUE;
                        i = optional_all_satisfied(v, satbility);

                        break;
                }

                case GVT_GROUP:
                default:
#ifndef NDEBUG
                        uu_warn("%s:%d: Unexpected vertex type %d.\n", __FILE__,
                            __LINE__, v->gv_type);
#endif
                        abort();
                }

                if (i == 1)
                        continue;

                log_framework2(LOG_DEBUG, DEBUG_DEPENDENCIES,
                    "optional_all(%s): %s is unsatisfi%s.\n", groupv->gv_name,
                    v->gv_name, i == 0 ? "ed" : "able");

                if (!satbility)
                        return (0);
                if (i == -1)
                        return (-1);
                any_unsatisfied = B_TRUE;
        }

        if (!any_qualified)
                return (1);

        return (any_unsatisfied ? 0 : 1);
}

/*
 * An exclude_all dependency is unsatisfied if any non-service element is
 * satisfied or any service instance which is configured, enabled, and not in
 * maintenance is satisfied.  Usually when unsatisfied, it is also
 * unsatisfiable.
 */
#define LOG_EXCLUDE(u, v)                                               \
        log_framework2(LOG_DEBUG, DEBUG_DEPENDENCIES,                   \
            "exclude_all(%s): %s is satisfied.\n",                      \
            (u)->gv_name, (v)->gv_name)

/* ARGSUSED */
static int
exclude_all_satisfied(graph_vertex_t *groupv, boolean_t satbility)
{
        graph_edge_t *edge, *e2;
        graph_vertex_t *v, *v2;

        for (edge = uu_list_first(groupv->gv_dependencies);
            edge != NULL;
            edge = uu_list_next(groupv->gv_dependencies, edge)) {
                v = edge->ge_vertex;

                switch (v->gv_type) {
                case GVT_INST:
                        if ((v->gv_flags & GV_CONFIGURED) == 0)
                                continue;

                        switch (v->gv_state) {
                        case RESTARTER_STATE_ONLINE:
                        case RESTARTER_STATE_DEGRADED:
                                LOG_EXCLUDE(groupv, v);
                                return (v->gv_flags & GV_ENABLED ? -1 : 0);

                        case RESTARTER_STATE_OFFLINE:
                        case RESTARTER_STATE_UNINIT:
                                LOG_EXCLUDE(groupv, v);
                                return (0);

                        case RESTARTER_STATE_DISABLED:
                        case RESTARTER_STATE_MAINT:
                                continue;

                        default:
#ifndef NDEBUG
                                uu_warn("%s:%d: Unexpected vertex state %d.\n",
                                    __FILE__, __LINE__, v->gv_state);
#endif
                                abort();
                        }
                        /* NOTREACHED */

                case GVT_SVC:
                        break;

                case GVT_FILE:
                        if (!file_ready(v))
                                continue;
                        LOG_EXCLUDE(groupv, v);
                        return (-1);

                case GVT_GROUP:
                default:
#ifndef NDEBUG
                        uu_warn("%s:%d: Unexpected vertex type %d.\n", __FILE__,
                            __LINE__, v->gv_type);
#endif
                        abort();
                }

                /* v represents a service */
                if (uu_list_numnodes(v->gv_dependencies) == 0)
                        continue;

                for (e2 = uu_list_first(v->gv_dependencies);
                    e2 != NULL;
                    e2 = uu_list_next(v->gv_dependencies, e2)) {
                        v2 = e2->ge_vertex;
                        assert(v2->gv_type == GVT_INST);

                        if ((v2->gv_flags & GV_CONFIGURED) == 0)
                                continue;

                        switch (v2->gv_state) {
                        case RESTARTER_STATE_ONLINE:
                        case RESTARTER_STATE_DEGRADED:
                                LOG_EXCLUDE(groupv, v2);
                                return (v2->gv_flags & GV_ENABLED ? -1 : 0);

                        case RESTARTER_STATE_OFFLINE:
                        case RESTARTER_STATE_UNINIT:
                                LOG_EXCLUDE(groupv, v2);
                                return (0);

                        case RESTARTER_STATE_DISABLED:
                        case RESTARTER_STATE_MAINT:
                                continue;

                        default:
#ifndef NDEBUG
                                uu_warn("%s:%d: Unexpected vertex type %d.\n",
                                    __FILE__, __LINE__, v2->gv_type);
#endif
                                abort();
                        }
                }
        }

        return (1);
}

/*
 * int instance_satisfied()
 *   Determine if all the dependencies are satisfied for the supplied instance
 *   vertex. Return 1 if they are, 0 if they aren't, and -1 if they won't be
 *   without administrator intervention.
 */
static int
instance_satisfied(graph_vertex_t *v, boolean_t satbility)
{
        assert(v->gv_type == GVT_INST);
        assert(!inst_running(v));

        return (require_all_satisfied(v, satbility));
}

/*
 * Decide whether v can satisfy a dependency.  v can either be a child of
 * a group vertex, or of an instance vertex.
 */
static int
dependency_satisfied(graph_vertex_t *v, boolean_t satbility)
{
        switch (v->gv_type) {
        case GVT_INST:
                if ((v->gv_flags & GV_CONFIGURED) == 0) {
                        if (v->gv_flags & GV_DEATHROW) {
                                /*
                                 * A dependency on an instance with GV_DEATHROW
                                 * flag is always considered as satisfied.
                                 */
                                return (1);
                        }
                        return (-1);
                }

                /*
                 * Vertices may be transitioning so we try to figure out if
                 * the end state is likely to satisfy the dependency instead
                 * of assuming the dependency is unsatisfied/unsatisfiable.
                 *
                 * Support for optional_all dependencies depends on us getting
                 * this right because unsatisfiable dependencies are treated
                 * as being satisfied.
                 */
                switch (v->gv_state) {
                case RESTARTER_STATE_ONLINE:
                case RESTARTER_STATE_DEGRADED:
                        if (v->gv_flags & GV_TODISABLE)
                                return (-1);
                        if (v->gv_flags & GV_TOOFFLINE)
                                return (0);
                        return (1);

                case RESTARTER_STATE_OFFLINE:
                        if (!satbility || v->gv_flags & GV_TODISABLE)
                                return (satbility ? -1 : 0);
                        return (instance_satisfied(v, satbility) != -1 ?
                            0 : -1);

                case RESTARTER_STATE_DISABLED:
                        if (!satbility || !(v->gv_flags & GV_ENABLED))
                                return (satbility ? -1 : 0);
                        return (instance_satisfied(v, satbility) != -1 ?
                            0 : -1);

                case RESTARTER_STATE_MAINT:
                        return (-1);

                case RESTARTER_STATE_UNINIT:
                        return (0);

                default:
#ifndef NDEBUG
                        uu_warn("%s:%d: Unexpected vertex state %d.\n",
                            __FILE__, __LINE__, v->gv_state);
#endif
                        abort();
                        /* NOTREACHED */
                }

        case GVT_SVC:
                if (uu_list_numnodes(v->gv_dependencies) == 0)
                        return (-1);
                return (require_any_satisfied(v, satbility));

        case GVT_FILE:
                /* i.e., we assume files will not be automatically generated */
                return (file_ready(v) ? 1 : -1);

        case GVT_GROUP:
                break;

        default:
#ifndef NDEBUG
                uu_warn("%s:%d: Unexpected node type %d.\n", __FILE__, __LINE__,
                    v->gv_type);
#endif
                abort();
                /* NOTREACHED */
        }

        switch (v->gv_depgroup) {
        case DEPGRP_REQUIRE_ANY:
                return (require_any_satisfied(v, satbility));

        case DEPGRP_REQUIRE_ALL:
                return (require_all_satisfied(v, satbility));

        case DEPGRP_OPTIONAL_ALL:
                return (optional_all_satisfied(v, satbility));

        case DEPGRP_EXCLUDE_ALL:
                return (exclude_all_satisfied(v, satbility));

        default:
#ifndef NDEBUG
                uu_warn("%s:%d: Unknown dependency grouping %d.\n", __FILE__,
                    __LINE__, v->gv_depgroup);
#endif
                abort();
        }
}

void
graph_start_if_satisfied(graph_vertex_t *v)
{
        if (v->gv_state == RESTARTER_STATE_OFFLINE &&
            instance_satisfied(v, B_FALSE) == 1) {
                if (v->gv_start_f == NULL)
                        vertex_send_event(v, RESTARTER_EVENT_TYPE_START);
                else
                        v->gv_start_f(v);
        }
}

/*
 * propagate_satbility()
 *
 * This function is used when the given vertex changes state in such a way that
 * one of its dependents may become unsatisfiable.  This happens when an
 * instance transitions between offline -> online, or from !running ->
 * maintenance, as well as when an instance is removed from the graph.
 *
 * We have to walk all the dependents, since optional_all dependencies several
 * levels up could become (un)satisfied, instead of unsatisfiable.  For example,
 *
 *      +-----+  optional_all  +-----+  require_all  +-----+
 *      |  A  |--------------->|  B  |-------------->|  C  |
 *      +-----+                +-----+               +-----+
 *
 *                                              offline -> maintenance
 *
 * If C goes into maintenance, it's not enough simply to check B.  Because A has
 * an optional dependency, what was previously an unsatisfiable situation is now
 * satisfied (B will never come online, even though its state hasn't changed).
 *
 * Note that it's not necessary to continue examining dependents after reaching
 * an optional_all dependency.  It's not possible for an optional_all dependency
 * to change satisfiability without also coming online, in which case we get a
 * start event and propagation continues naturally.  However, it does no harm to
 * continue propagating satisfiability (as it is a relatively rare event), and
 * keeps the walker code simple and generic.
 */
/*ARGSUSED*/
static int
satbility_cb(graph_vertex_t *v, void *arg)
{
        if (is_inst_bypassed(v))
                return (UU_WALK_NEXT);

        if (v->gv_type == GVT_INST)
                graph_start_if_satisfied(v);

        return (UU_WALK_NEXT);
}

static void
propagate_satbility(graph_vertex_t *v)
{
        graph_walk(v, WALK_DEPENDENTS, satbility_cb, NULL, NULL);
}

static void propagate_stop(graph_vertex_t *, void *);

/*
 * propagate_start()
 *
 * This function is used to propagate a start event to the dependents of the
 * given vertex.  Any dependents that are offline but have their dependencies
 * satisfied are started.  Any dependents that are online and have restart_on
 * set to "restart" or "refresh" are restarted because their dependencies have
 * just changed.  This only happens with optional_all dependencies.
 */
static void
propagate_start(graph_vertex_t *v, void *arg)
{
        restarter_error_t err = (restarter_error_t)arg;

        if (is_inst_bypassed(v))
                return;

        switch (v->gv_type) {
        case GVT_INST:
                /* Restarter */
                if (inst_running(v)) {
                        if (err == RERR_RESTART || err == RERR_REFRESH) {
                                vertex_send_event(v,
                                    RESTARTER_EVENT_TYPE_STOP_RESET);
                        }
                } else {
                        graph_start_if_satisfied(v);
                }
                break;

        case GVT_GROUP:
                if (v->gv_depgroup == DEPGRP_EXCLUDE_ALL) {
                        graph_walk_dependents(v, propagate_stop,
                            (void *)RERR_RESTART);
                        break;
                }
                err = v->gv_restart;
                /* FALLTHROUGH */

        case GVT_SVC:
                graph_walk_dependents(v, propagate_start, (void *)err);
                break;

        case GVT_FILE:
#ifndef NDEBUG
                uu_warn("%s:%d: propagate_start() encountered GVT_FILE.\n",
                    __FILE__, __LINE__);
#endif
                abort();
                /* NOTREACHED */

        default:
#ifndef NDEBUG
                uu_warn("%s:%d: Unknown vertex type %d.\n", __FILE__, __LINE__,
                    v->gv_type);
#endif
                abort();
        }
}

/*
 * propagate_stop()
 *
 * This function is used to propagate a stop event to the dependents of the
 * given vertex.  Any dependents that are online (or in degraded state) with
 * the restart_on property set to "restart" or "refresh" will be stopped as
 * their dependencies have just changed, propagate_start() will start them
 * again once their dependencies have been re-satisfied.
 */
static void
propagate_stop(graph_vertex_t *v, void *arg)
{
        restarter_error_t err = (restarter_error_t)arg;

        if (is_inst_bypassed(v))
                return;

        switch (v->gv_type) {
        case GVT_INST:
                /* Restarter */
                if (err > RERR_NONE && inst_running(v)) {
                        if (err == RERR_RESTART || err == RERR_REFRESH) {
                                vertex_send_event(v,
                                    RESTARTER_EVENT_TYPE_STOP_RESET);
                        } else {
                                vertex_send_event(v, RESTARTER_EVENT_TYPE_STOP);
                        }
                }
                break;

        case GVT_SVC:
                graph_walk_dependents(v, propagate_stop, arg);
                break;

        case GVT_FILE:
#ifndef NDEBUG
                uu_warn("%s:%d: propagate_stop() encountered GVT_FILE.\n",
                    __FILE__, __LINE__);
#endif
                abort();
                /* NOTREACHED */

        case GVT_GROUP:
                if (v->gv_depgroup == DEPGRP_EXCLUDE_ALL) {
                        graph_walk_dependents(v, propagate_start,
                            (void *)RERR_NONE);
                        break;
                }

                if (err == RERR_NONE || err > v->gv_restart)
                        break;

                graph_walk_dependents(v, propagate_stop, arg);
                break;

        default:
#ifndef NDEBUG
                uu_warn("%s:%d: Unknown vertex type %d.\n", __FILE__, __LINE__,
                    v->gv_type);
#endif
                abort();
        }
}

void
offline_vertex(graph_vertex_t *v)
{
        scf_handle_t *h = libscf_handle_create_bound_loop();
        scf_instance_t *scf_inst = safe_scf_instance_create(h);
        scf_propertygroup_t *pg = safe_scf_pg_create(h);
        restarter_instance_state_t state, next_state;
        int r;

        assert(v->gv_type == GVT_INST);

        if (scf_inst == NULL)
                bad_error("safe_scf_instance_create", scf_error());
        if (pg == NULL)
                bad_error("safe_scf_pg_create", scf_error());

        /* if the vertex is already going offline, return */
rep_retry:
        if (scf_handle_decode_fmri(h, v->gv_name, NULL, NULL, scf_inst, NULL,
            NULL, SCF_DECODE_FMRI_EXACT) != 0) {
                switch (scf_error()) {
                case SCF_ERROR_CONNECTION_BROKEN:
                        libscf_handle_rebind(h);
                        goto rep_retry;

                case SCF_ERROR_NOT_FOUND:
                        scf_pg_destroy(pg);
                        scf_instance_destroy(scf_inst);
                        (void) scf_handle_unbind(h);
                        scf_handle_destroy(h);
                        return;
                }
                uu_die("Can't decode FMRI %s: %s\n", v->gv_name,
                    scf_strerror(scf_error()));
        }

        r = scf_instance_get_pg(scf_inst, SCF_PG_RESTARTER, pg);
        if (r != 0) {
                switch (scf_error()) {
                case SCF_ERROR_CONNECTION_BROKEN:
                        libscf_handle_rebind(h);
                        goto rep_retry;

                case SCF_ERROR_NOT_SET:
                case SCF_ERROR_NOT_FOUND:
                        scf_pg_destroy(pg);
                        scf_instance_destroy(scf_inst);
                        (void) scf_handle_unbind(h);
                        scf_handle_destroy(h);
                        return;

                default:
                        bad_error("scf_instance_get_pg", scf_error());
                }
        } else {
                r = libscf_read_states(pg, &state, &next_state);
                if (r == 0 && (next_state == RESTARTER_STATE_OFFLINE ||
                    next_state == RESTARTER_STATE_DISABLED)) {
                        log_framework(LOG_DEBUG,
                            "%s: instance is already going down.\n",
                            v->gv_name);
                        scf_pg_destroy(pg);
                        scf_instance_destroy(scf_inst);
                        (void) scf_handle_unbind(h);
                        scf_handle_destroy(h);
                        return;
                }
        }

        scf_pg_destroy(pg);
        scf_instance_destroy(scf_inst);
        (void) scf_handle_unbind(h);
        scf_handle_destroy(h);

        vertex_send_event(v, RESTARTER_EVENT_TYPE_STOP_RESET);
}

/*
 * void graph_enable_by_vertex()
 *   If admin is non-zero, this is an administrative request for change
 *   of the enabled property.  Thus, send the ADMIN_DISABLE rather than
 *   a plain DISABLE restarter event.
 */
void
graph_enable_by_vertex(graph_vertex_t *vertex, int enable, int admin)
{
        graph_vertex_t *v;
        int r;

        assert(MUTEX_HELD(&dgraph_lock));
        assert((vertex->gv_flags & GV_CONFIGURED));

        vertex->gv_flags = (vertex->gv_flags & ~GV_ENABLED) |
            (enable ? GV_ENABLED : 0);

        if (enable) {
                if (vertex->gv_state != RESTARTER_STATE_OFFLINE &&
                    vertex->gv_state != RESTARTER_STATE_DEGRADED &&
                    vertex->gv_state != RESTARTER_STATE_ONLINE) {
                        /*
                         * In case the vertex was notified to go down,
                         * but now can return online, clear the _TOOFFLINE
                         * and _TODISABLE flags.
                         */
                        vertex->gv_flags &= ~GV_TOOFFLINE;
                        vertex->gv_flags &= ~GV_TODISABLE;

                        vertex_send_event(vertex, RESTARTER_EVENT_TYPE_ENABLE);
                }

                /*
                 * Wait for state update from restarter before sending _START or
                 * _STOP.
                 */

                return;
        }

        if (vertex->gv_state == RESTARTER_STATE_DISABLED)
                return;

        if (!admin) {
                vertex_send_event(vertex, RESTARTER_EVENT_TYPE_DISABLE);

                /*
                 * Wait for state update from restarter before sending _START or
                 * _STOP.
                 */

                return;
        }

        /*
         * If it is a DISABLE event requested by the administrator then we are
         * offlining the dependents first.
         */

        /*
         * Set GV_TOOFFLINE for the services we are offlining. We cannot
         * clear the GV_TOOFFLINE bits from all the services because
         * other DISABLE events might be handled at the same time.
         */
        vertex->gv_flags |= GV_TOOFFLINE;

        /* remember which vertex to disable... */
        vertex->gv_flags |= GV_TODISABLE;

        log_framework(LOG_DEBUG, "Marking in-subtree vertices before "
            "disabling %s.\n", vertex->gv_name);

        /* set GV_TOOFFLINE for its dependents */
        r = uu_list_walk(vertex->gv_dependents, (uu_walk_fn_t *)mark_subtree,
            NULL, 0);
        assert(r == 0);

        /* disable the instance now if there is nothing else to offline */
        if (insubtree_dependents_down(vertex) == B_TRUE) {
                vertex_send_event(vertex, RESTARTER_EVENT_TYPE_ADMIN_DISABLE);
                return;
        }

        /*
         * This loop is similar to the one used for the graph reversal shutdown
         * and could be improved in term of performance for the subtree reversal
         * disable case.
         */
        for (v = uu_list_first(dgraph); v != NULL;
            v = uu_list_next(dgraph, v)) {
                /* skip the vertex we are disabling for now */
                if (v == vertex)
                        continue;

                if (v->gv_type != GVT_INST ||
                    (v->gv_flags & GV_CONFIGURED) == 0 ||
                    (v->gv_flags & GV_ENABLED) == 0 ||
                    (v->gv_flags & GV_TOOFFLINE) == 0)
                        continue;

                if ((v->gv_state != RESTARTER_STATE_ONLINE) &&
                    (v->gv_state != RESTARTER_STATE_DEGRADED)) {
                        /* continue if there is nothing to offline */
                        continue;
                }

                /*
                 * Instances which are up need to come down before we're
                 * done, but we can only offline the leaves here. An
                 * instance is a leaf when all its dependents are down.
                 */
                if (insubtree_dependents_down(v) == B_TRUE) {
                        log_framework(LOG_DEBUG, "Offlining in-subtree "
                            "instance %s for %s.\n",
                            v->gv_name, vertex->gv_name);
                        offline_vertex(v);
                }
        }
}

static int configure_vertex(graph_vertex_t *, scf_instance_t *);

/*
 * Set the restarter for v to fmri_arg.  That is, make sure a vertex for
 * fmri_arg exists, make v depend on it, and send _ADD_INSTANCE for v.  If
 * v is already configured and fmri_arg indicates the current restarter, do
 * nothing.  If v is configured and fmri_arg is a new restarter, delete v's
 * dependency on the restarter, send _REMOVE_INSTANCE for v, and set the new
 * restarter.  Returns 0 on success, EINVAL if the FMRI is invalid,
 * ECONNABORTED if the repository connection is broken, and ELOOP
 * if the dependency would create a cycle.  In the last case, *pathp will
 * point to a -1-terminated array of ids which compose the path from v to
 * restarter_fmri.
 */
int
graph_change_restarter(graph_vertex_t *v, const char *fmri_arg, scf_handle_t *h,
    int **pathp)
{
        char *restarter_fmri = NULL;
        graph_vertex_t *rv;
        int err;
        int id;

        assert(MUTEX_HELD(&dgraph_lock));

        if (fmri_arg[0] != '\0') {
                err = fmri_canonify(fmri_arg, &restarter_fmri, B_TRUE);
                if (err != 0) {
                        assert(err == EINVAL);
                        return (err);
                }
        }

        if (restarter_fmri == NULL ||
            strcmp(restarter_fmri, SCF_SERVICE_STARTD) == 0) {
                if (v->gv_flags & GV_CONFIGURED) {
                        if (v->gv_restarter_id == -1) {
                                if (restarter_fmri != NULL)
                                        startd_free(restarter_fmri,
                                            max_scf_fmri_size);
                                return (0);
                        }

                        graph_unset_restarter(v);
                }

                /* Master restarter, nothing to do. */
                v->gv_restarter_id = -1;
                v->gv_restarter_channel = NULL;
                vertex_send_event(v, RESTARTER_EVENT_TYPE_ADD_INSTANCE);
                return (0);
        }

        if (v->gv_flags & GV_CONFIGURED) {
                id = dict_lookup_byname(restarter_fmri);
                if (id != -1 && v->gv_restarter_id == id) {
                        startd_free(restarter_fmri, max_scf_fmri_size);
                        return (0);
                }

                graph_unset_restarter(v);
        }

        err = graph_insert_vertex_unconfigured(restarter_fmri, GVT_INST, 0,
            RERR_NONE, &rv);
        startd_free(restarter_fmri, max_scf_fmri_size);
        assert(err == 0 || err == EEXIST);

        if (rv->gv_delegate_initialized == 0) {
                if ((rv->gv_delegate_channel = restarter_protocol_init_delegate(
                    rv->gv_name)) == NULL)
                        return (EINVAL);
                rv->gv_delegate_initialized = 1;
        }
        v->gv_restarter_id = rv->gv_id;
        v->gv_restarter_channel = rv->gv_delegate_channel;

        err = graph_insert_dependency(v, rv, pathp);
        if (err != 0) {
                assert(err == ELOOP);
                return (ELOOP);
        }

        vertex_send_event(v, RESTARTER_EVENT_TYPE_ADD_INSTANCE);

        if (!(rv->gv_flags & GV_CONFIGURED)) {
                scf_instance_t *inst;

                err = libscf_fmri_get_instance(h, rv->gv_name, &inst);
                switch (err) {
                case 0:
                        err = configure_vertex(rv, inst);
                        scf_instance_destroy(inst);
                        switch (err) {
                        case 0:
                        case ECANCELED:
                                break;

                        case ECONNABORTED:
                                return (ECONNABORTED);

                        default:
                                bad_error("configure_vertex", err);
                        }
                        break;

                case ECONNABORTED:
                        return (ECONNABORTED);

                case ENOENT:
                        break;

                case ENOTSUP:
                        /*
                         * The fmri doesn't specify an instance - translate
                         * to EINVAL.
                         */
                        return (EINVAL);

                case EINVAL:
                default:
                        bad_error("libscf_fmri_get_instance", err);
                }
        }

        return (0);
}


/*
 * Add all of the instances of the service named by fmri to the graph.
 * Returns
 *   0 - success
 *   ENOENT - service indicated by fmri does not exist
 *
 * In both cases *reboundp will be B_TRUE if the handle was rebound, or B_FALSE
 * otherwise.
 */
static int
add_service(const char *fmri, scf_handle_t *h, boolean_t *reboundp)
{
        scf_service_t *svc;
        scf_instance_t *inst;
        scf_iter_t *iter;
        char *inst_fmri;
        int ret, r;

        *reboundp = B_FALSE;

        svc = safe_scf_service_create(h);
        inst = safe_scf_instance_create(h);
        iter = safe_scf_iter_create(h);
        inst_fmri = startd_alloc(max_scf_fmri_size);

rebound:
        if (scf_handle_decode_fmri(h, fmri, NULL, svc, NULL, NULL, NULL,
            SCF_DECODE_FMRI_EXACT) != 0) {
                switch (scf_error()) {
                case SCF_ERROR_CONNECTION_BROKEN:
                default:
                        libscf_handle_rebind(h);
                        *reboundp = B_TRUE;
                        goto rebound;

                case SCF_ERROR_NOT_FOUND:
                        ret = ENOENT;
                        goto out;

                case SCF_ERROR_INVALID_ARGUMENT:
                case SCF_ERROR_CONSTRAINT_VIOLATED:
                case SCF_ERROR_NOT_BOUND:
                case SCF_ERROR_HANDLE_MISMATCH:
                        bad_error("scf_handle_decode_fmri", scf_error());
                }
        }

        if (scf_iter_service_instances(iter, svc) != 0) {
                switch (scf_error()) {
                case SCF_ERROR_CONNECTION_BROKEN:
                default:
                        libscf_handle_rebind(h);
                        *reboundp = B_TRUE;
                        goto rebound;

                case SCF_ERROR_DELETED:
                        ret = ENOENT;
                        goto out;

                case SCF_ERROR_HANDLE_MISMATCH:
                case SCF_ERROR_NOT_BOUND:
                case SCF_ERROR_NOT_SET:
                        bad_error("scf_iter_service_instances", scf_error());
                }
        }

        for (;;) {
                r = scf_iter_next_instance(iter, inst);
                if (r == 0)
                        break;
                if (r != 1) {
                        switch (scf_error()) {
                        case SCF_ERROR_CONNECTION_BROKEN:
                        default:
                                libscf_handle_rebind(h);
                                *reboundp = B_TRUE;
                                goto rebound;

                        case SCF_ERROR_DELETED:
                                ret = ENOENT;
                                goto out;

                        case SCF_ERROR_HANDLE_MISMATCH:
                        case SCF_ERROR_NOT_BOUND:
                        case SCF_ERROR_NOT_SET:
                        case SCF_ERROR_INVALID_ARGUMENT:
                                bad_error("scf_iter_next_instance",
                                    scf_error());
                        }
                }

                if (scf_instance_to_fmri(inst, inst_fmri, max_scf_fmri_size) <
                    0) {
                        switch (scf_error()) {
                        case SCF_ERROR_CONNECTION_BROKEN:
                                libscf_handle_rebind(h);
                                *reboundp = B_TRUE;
                                goto rebound;

                        case SCF_ERROR_DELETED:
                                continue;

                        case SCF_ERROR_NOT_BOUND:
                        case SCF_ERROR_NOT_SET:
                                bad_error("scf_instance_to_fmri", scf_error());
                        }
                }

                r = dgraph_add_instance(inst_fmri, inst, B_FALSE);
                switch (r) {
                case 0:
                case ECANCELED:
                        break;

                case EEXIST:
                        continue;

                case ECONNABORTED:
                        libscf_handle_rebind(h);
                        *reboundp = B_TRUE;
                        goto rebound;

                case EINVAL:
                default:
                        bad_error("dgraph_add_instance", r);
                }
        }

        ret = 0;

out:
        startd_free(inst_fmri, max_scf_fmri_size);
        scf_iter_destroy(iter);
        scf_instance_destroy(inst);
        scf_service_destroy(svc);
        return (ret);
}

struct depfmri_info {
        graph_vertex_t  *v;             /* GVT_GROUP vertex */
        gv_type_t       type;           /* type of dependency */
        const char      *inst_fmri;     /* FMRI of parental GVT_INST vert. */
        const char      *pg_name;       /* Name of dependency pg */
        scf_handle_t    *h;
        int             err;            /* return error code */
        int             **pathp;        /* return circular dependency path */
};

/*
 * Find or create a vertex for fmri and make info->v depend on it.
 * Returns
 *   0 - success
 *   nonzero - failure
 *
 * On failure, sets info->err to
 *   EINVAL - fmri is invalid
 *            fmri does not match info->type
 *   ELOOP - Adding the dependency creates a circular dependency.  *info->pathp
 *           will point to an array of the ids of the members of the cycle.
 *   ECONNABORTED - repository connection was broken
 *   ECONNRESET - succeeded, but repository connection was reset
 */
static int
process_dependency_fmri(const char *fmri, struct depfmri_info *info)
{
        int err;
        graph_vertex_t *depgroup_v, *v;
        char *fmri_copy, *cfmri;
        size_t fmri_copy_sz;
        const char *scope, *service, *instance, *pg;
        scf_instance_t *inst;
        boolean_t rebound;

        assert(MUTEX_HELD(&dgraph_lock));

        /* Get or create vertex for FMRI */
        depgroup_v = info->v;

        if (strncmp(fmri, "file:", sizeof ("file:") - 1) == 0) {
                if (info->type != GVT_FILE) {
                        log_framework(LOG_NOTICE,
                            "FMRI \"%s\" is not allowed for the \"%s\" "
                            "dependency's type of instance %s.\n", fmri,
                            info->pg_name, info->inst_fmri);
                        return (info->err = EINVAL);
                }

                err = graph_insert_vertex_unconfigured(fmri, info->type, 0,
                    RERR_NONE, &v);
                switch (err) {
                case 0:
                        break;

                case EEXIST:
                        assert(v->gv_type == GVT_FILE);
                        break;

                case EINVAL:            /* prevented above */
                default:
                        bad_error("graph_insert_vertex_unconfigured", err);
                }
        } else {
                if (info->type != GVT_INST) {
                        log_framework(LOG_NOTICE,
                            "FMRI \"%s\" is not allowed for the \"%s\" "
                            "dependency's type of instance %s.\n", fmri,
                            info->pg_name, info->inst_fmri);
                        return (info->err = EINVAL);
                }

                /*
                 * We must canonify fmri & add a vertex for it.
                 */
                fmri_copy_sz = strlen(fmri) + 1;
                fmri_copy = startd_alloc(fmri_copy_sz);
                (void) strcpy(fmri_copy, fmri);

                /* Determine if the FMRI is a property group or instance */
                if (scf_parse_svc_fmri(fmri_copy, &scope, &service,
                    &instance, &pg, NULL) != 0) {
                        startd_free(fmri_copy, fmri_copy_sz);
                        log_framework(LOG_NOTICE,
                            "Dependency \"%s\" of %s has invalid FMRI "
                            "\"%s\".\n", info->pg_name, info->inst_fmri,
                            fmri);
                        return (info->err = EINVAL);
                }

                if (service == NULL || pg != NULL) {
                        startd_free(fmri_copy, fmri_copy_sz);
                        log_framework(LOG_NOTICE,
                            "Dependency \"%s\" of %s does not designate a "
                            "service or instance.\n", info->pg_name,
                            info->inst_fmri);
                        return (info->err = EINVAL);
                }

                if (scope == NULL || strcmp(scope, SCF_SCOPE_LOCAL) == 0) {
                        cfmri = uu_msprintf("svc:/%s%s%s",
                            service, instance ? ":" : "", instance ? instance :
                            "");
                } else {
                        cfmri = uu_msprintf("svc://%s/%s%s%s",
                            scope, service, instance ? ":" : "", instance ?
                            instance : "");
                }

                startd_free(fmri_copy, fmri_copy_sz);

                err = graph_insert_vertex_unconfigured(cfmri, instance ?
                    GVT_INST : GVT_SVC, instance ? 0 : DEPGRP_REQUIRE_ANY,
                    RERR_NONE, &v);
                uu_free(cfmri);
                switch (err) {
                case 0:
                        break;

                case EEXIST:
                        /* Verify v. */
                        if (instance != NULL)
                                assert(v->gv_type == GVT_INST);
                        else
                                assert(v->gv_type == GVT_SVC);
                        break;

                default:
                        bad_error("graph_insert_vertex_unconfigured", err);
                }
        }

        /* Add dependency from depgroup_v to new vertex */
        info->err = graph_insert_dependency(depgroup_v, v, info->pathp);
        switch (info->err) {
        case 0:
                break;

        case ELOOP:
                return (ELOOP);

        default:
                bad_error("graph_insert_dependency", info->err);
        }

        /* This must be after we insert the dependency, to avoid looping. */
        switch (v->gv_type) {
        case GVT_INST:
                if ((v->gv_flags & GV_CONFIGURED) != 0)
                        break;

                inst = safe_scf_instance_create(info->h);

                rebound = B_FALSE;

rebound:
                err = libscf_lookup_instance(v->gv_name, inst);
                switch (err) {
                case 0:
                        err = configure_vertex(v, inst);
                        switch (err) {
                        case 0:
                        case ECANCELED:
                                break;

                        case ECONNABORTED:
                                libscf_handle_rebind(info->h);
                                rebound = B_TRUE;
                                goto rebound;

                        default:
                                bad_error("configure_vertex", err);
                        }
                        break;

                case ENOENT:
                        break;

                case ECONNABORTED:
                        libscf_handle_rebind(info->h);
                        rebound = B_TRUE;
                        goto rebound;

                case EINVAL:
                case ENOTSUP:
                default:
                        bad_error("libscf_fmri_get_instance", err);
                }

                scf_instance_destroy(inst);

                if (rebound)
                        return (info->err = ECONNRESET);
                break;

        case GVT_SVC:
                (void) add_service(v->gv_name, info->h, &rebound);
                if (rebound)
                        return (info->err = ECONNRESET);
        }

        return (0);
}

struct deppg_info {
        graph_vertex_t  *v;             /* GVT_INST vertex */
        int             err;            /* return error */
        int             **pathp;        /* return circular dependency path */
};

/*
 * Make info->v depend on a new GVT_GROUP node for this property group,
 * and then call process_dependency_fmri() for the values of the entity
 * property.  Return 0 on success, or if something goes wrong return nonzero
 * and set info->err to ECONNABORTED, EINVAL, or the error code returned by
 * process_dependency_fmri().
 */
static int
process_dependency_pg(scf_propertygroup_t *pg, struct deppg_info *info)
{
        scf_handle_t *h;
        depgroup_type_t deptype;
        restarter_error_t rerr;
        struct depfmri_info linfo;
        char *fmri, *pg_name;
        size_t fmri_sz;
        graph_vertex_t *depgrp;
        scf_property_t *prop;
        int err;
        int empty;
        scf_error_t scferr;
        ssize_t len;

        assert(MUTEX_HELD(&dgraph_lock));

        h = scf_pg_handle(pg);

        pg_name = startd_alloc(max_scf_name_size);

        len = scf_pg_get_name(pg, pg_name, max_scf_name_size);
        if (len < 0) {
                startd_free(pg_name, max_scf_name_size);
                switch (scf_error()) {
                case SCF_ERROR_CONNECTION_BROKEN:
                default:
                        return (info->err = ECONNABORTED);

                case SCF_ERROR_DELETED:
                        return (info->err = 0);

                case SCF_ERROR_NOT_SET:
                        bad_error("scf_pg_get_name", scf_error());
                }
        }

        /*
         * Skip over empty dependency groups.  Since dependency property
         * groups are updated atomically, they are either empty or
         * fully populated.
         */
        empty = depgroup_empty(h, pg);
        if (empty < 0) {
                log_error(LOG_INFO,
                    "Error reading dependency group \"%s\" of %s: %s\n",
                    pg_name, info->v->gv_name, scf_strerror(scf_error()));
                startd_free(pg_name, max_scf_name_size);
                return (info->err = EINVAL);

        } else if (empty == 1) {
                log_framework(LOG_DEBUG,
                    "Ignoring empty dependency group \"%s\" of %s\n",
                    pg_name, info->v->gv_name);
                startd_free(pg_name, max_scf_name_size);
                return (info->err = 0);
        }

        fmri_sz = strlen(info->v->gv_name) + 1 + len + 1;
        fmri = startd_alloc(fmri_sz);

        (void) snprintf(fmri, fmri_sz, "%s>%s", info->v->gv_name,
            pg_name);

        /* Validate the pg before modifying the graph */
        deptype = depgroup_read_grouping(h, pg);
        if (deptype == DEPGRP_UNSUPPORTED) {
                log_error(LOG_INFO,
                    "Dependency \"%s\" of %s has an unknown grouping value.\n",
                    pg_name, info->v->gv_name);
                startd_free(fmri, fmri_sz);
                startd_free(pg_name, max_scf_name_size);
                return (info->err = EINVAL);
        }

        rerr = depgroup_read_restart(h, pg);
        if (rerr == RERR_UNSUPPORTED) {
                log_error(LOG_INFO,
                    "Dependency \"%s\" of %s has an unknown restart_on value."
                    "\n", pg_name, info->v->gv_name);
                startd_free(fmri, fmri_sz);
                startd_free(pg_name, max_scf_name_size);
                return (info->err = EINVAL);
        }

        prop = safe_scf_property_create(h);

        if (scf_pg_get_property(pg, SCF_PROPERTY_ENTITIES, prop) != 0) {
                scferr = scf_error();
                scf_property_destroy(prop);
                if (scferr == SCF_ERROR_DELETED) {
                        startd_free(fmri, fmri_sz);
                        startd_free(pg_name, max_scf_name_size);
                        return (info->err = 0);
                } else if (scferr != SCF_ERROR_NOT_FOUND) {
                        startd_free(fmri, fmri_sz);
                        startd_free(pg_name, max_scf_name_size);
                        return (info->err = ECONNABORTED);
                }

                log_error(LOG_INFO,
                    "Dependency \"%s\" of %s is missing a \"%s\" property.\n",
                    pg_name, info->v->gv_name, SCF_PROPERTY_ENTITIES);

                startd_free(fmri, fmri_sz);
                startd_free(pg_name, max_scf_name_size);

                return (info->err = EINVAL);
        }

        /* Create depgroup vertex for pg */
        err = graph_insert_vertex_unconfigured(fmri, GVT_GROUP, deptype,
            rerr, &depgrp);
        assert(err == 0);
        startd_free(fmri, fmri_sz);

        /* Add dependency from inst vertex to new vertex */
        err = graph_insert_dependency(info->v, depgrp, info->pathp);
        /* ELOOP can't happen because this should be a new vertex */
        assert(err == 0);

        linfo.v = depgrp;
        linfo.type = depgroup_read_scheme(h, pg);
        linfo.inst_fmri = info->v->gv_name;
        linfo.pg_name = pg_name;
        linfo.h = h;
        linfo.err = 0;
        linfo.pathp = info->pathp;
        err = walk_property_astrings(prop, (callback_t)process_dependency_fmri,
            &linfo);

        scf_property_destroy(prop);
        startd_free(pg_name, max_scf_name_size);

        switch (err) {
        case 0:
        case EINTR:
                return (info->err = linfo.err);

        case ECONNABORTED:
        case EINVAL:
                return (info->err = err);

        case ECANCELED:
                return (info->err = 0);

        case ECONNRESET:
                return (info->err = ECONNABORTED);

        default:
                bad_error("walk_property_astrings", err);
                /* NOTREACHED */
        }
}

/*
 * Build the dependency info for v from the repository.  Returns 0 on success,
 * ECONNABORTED on repository disconnection, EINVAL if the repository
 * configuration is invalid, and ELOOP if a dependency would cause a cycle.
 * In the last case, *pathp will point to a -1-terminated array of ids which
 * constitute the rest of the dependency cycle.
 */
static int
set_dependencies(graph_vertex_t *v, scf_instance_t *inst, int **pathp)
{
        struct deppg_info info;
        int err;
        uint_t old_configured;

        assert(MUTEX_HELD(&dgraph_lock));

        /*
         * Mark the vertex as configured during dependency insertion to avoid
         * dependency cycles (which can appear in the graph if one of the
         * vertices is an exclusion-group).
         */
        old_configured = v->gv_flags & GV_CONFIGURED;
        v->gv_flags |= GV_CONFIGURED;

        info.err = 0;
        info.v = v;
        info.pathp = pathp;

        err = walk_dependency_pgs(inst, (callback_t)process_dependency_pg,
            &info);

        if (!old_configured)
                v->gv_flags &= ~GV_CONFIGURED;

        switch (err) {
        case 0:
        case EINTR:
                return (info.err);

        case ECONNABORTED:
                return (ECONNABORTED);

        case ECANCELED:
                /* Should get delete event, so return 0. */
                return (0);

        default:
                bad_error("walk_dependency_pgs", err);
                /* NOTREACHED */
        }
}


static void
handle_cycle(const char *fmri, int *path)
{
        const char *cp;
        size_t sz;

        assert(MUTEX_HELD(&dgraph_lock));

        path_to_str(path, (char **)&cp, &sz);

        log_error(LOG_ERR, "Transitioning %s to maintenance "
            "because it completes a dependency cycle (see svcs -xv for "
            "details):\n%s", fmri ? fmri : "?", cp);

        startd_free((void *)cp, sz);
}

/*
 * Increment the vertex's reference count to prevent the vertex removal
 * from the dgraph.
 */
static void
vertex_ref(graph_vertex_t *v)
{
        assert(MUTEX_HELD(&dgraph_lock));

        v->gv_refs++;
}

/*
 * Decrement the vertex's reference count and remove the vertex from
 * the dgraph when possible.
 *
 * Return VERTEX_REMOVED when the vertex has been removed otherwise
 * return VERTEX_INUSE.
 */
static int
vertex_unref(graph_vertex_t *v)
{
        assert(MUTEX_HELD(&dgraph_lock));
        assert(v->gv_refs > 0);

        v->gv_refs--;

        return (free_if_unrefed(v));
}

/*
 * When run on the dependencies of a vertex, populates list with
 * graph_edge_t's which point to the service vertices or the instance
 * vertices (no GVT_GROUP nodes) on which the vertex depends.
 *
 * Increment the vertex's reference count once the vertex is inserted
 * in the list. The vertex won't be able to be deleted from the dgraph
 * while it is referenced.
 */
static int
append_svcs_or_insts(graph_edge_t *e, uu_list_t *list)
{
        graph_vertex_t *v = e->ge_vertex;
        graph_edge_t *new;
        int r;

        switch (v->gv_type) {
        case GVT_INST:
        case GVT_SVC:
                break;

        case GVT_GROUP:
                r = uu_list_walk(v->gv_dependencies,
                    (uu_walk_fn_t *)append_svcs_or_insts, list, 0);
                assert(r == 0);
                return (UU_WALK_NEXT);

        case GVT_FILE:
                return (UU_WALK_NEXT);

        default:
#ifndef NDEBUG
                uu_warn("%s:%d: Unexpected vertex type %d.\n", __FILE__,
                    __LINE__, v->gv_type);
#endif
                abort();
        }

        new = startd_alloc(sizeof (*new));
        new->ge_vertex = v;
        uu_list_node_init(new, &new->ge_link, graph_edge_pool);
        r = uu_list_insert_before(list, NULL, new);
        assert(r == 0);

        /*
         * Because we are inserting the vertex in a list, we don't want
         * the vertex to be freed while the list is in use. In order to
         * achieve that, increment the vertex's reference count.
         */
        vertex_ref(v);

        return (UU_WALK_NEXT);
}

static boolean_t
should_be_in_subgraph(graph_vertex_t *v)
{
        graph_edge_t *e;

        if (v == milestone)
                return (B_TRUE);

        /*
         * v is in the subgraph if any of its dependents are in the subgraph.
         * Except for EXCLUDE_ALL dependents.  And OPTIONAL dependents only
         * count if we're enabled.
         */
        for (e = uu_list_first(v->gv_dependents);
            e != NULL;
            e = uu_list_next(v->gv_dependents, e)) {
                graph_vertex_t *dv = e->ge_vertex;

                if (!(dv->gv_flags & GV_INSUBGRAPH))
                        continue;

                /*
                 * Don't include instances that are optional and disabled.
                 */
                if (v->gv_type == GVT_INST && dv->gv_type == GVT_SVC) {

                        int in = 0;
                        graph_edge_t *ee;

                        for (ee = uu_list_first(dv->gv_dependents);
                            ee != NULL;
                            ee = uu_list_next(dv->gv_dependents, ee)) {

                                graph_vertex_t *ddv = e->ge_vertex;

                                if (ddv->gv_type == GVT_GROUP &&
                                    ddv->gv_depgroup == DEPGRP_EXCLUDE_ALL)
                                        continue;

                                if (ddv->gv_type == GVT_GROUP &&
                                    ddv->gv_depgroup == DEPGRP_OPTIONAL_ALL &&
                                    !(v->gv_flags & GV_ENBLD_NOOVR))
                                        continue;

                                in = 1;
                        }
                        if (!in)
                                continue;
                }
                if (v->gv_type == GVT_INST &&
                    dv->gv_type == GVT_GROUP &&
                    dv->gv_depgroup == DEPGRP_OPTIONAL_ALL &&
                    !(v->gv_flags & GV_ENBLD_NOOVR))
                        continue;

                /* Don't include excluded services and instances */
                if (dv->gv_type == GVT_GROUP &&
                    dv->gv_depgroup == DEPGRP_EXCLUDE_ALL)
                        continue;

                return (B_TRUE);
        }

        return (B_FALSE);
}

/*
 * Ensures that GV_INSUBGRAPH is set properly for v and its descendents.  If
 * any bits change, manipulate the repository appropriately.  Returns 0 or
 * ECONNABORTED.
 */
static int
eval_subgraph(graph_vertex_t *v, scf_handle_t *h)
{
        boolean_t old = (v->gv_flags & GV_INSUBGRAPH) != 0;
        boolean_t new;
        graph_edge_t *e;
        scf_instance_t *inst;
        int ret = 0, r;

        assert(milestone != NULL && milestone != MILESTONE_NONE);

        new = should_be_in_subgraph(v);

        if (new == old)
                return (0);

        log_framework(LOG_DEBUG, new ? "Adding %s to the subgraph.\n" :
            "Removing %s from the subgraph.\n", v->gv_name);

        v->gv_flags = (v->gv_flags & ~GV_INSUBGRAPH) |
            (new ? GV_INSUBGRAPH : 0);

        if (v->gv_type == GVT_INST && (v->gv_flags & GV_CONFIGURED)) {
                int err;

get_inst:
                err = libscf_fmri_get_instance(h, v->gv_name, &inst);
                if (err != 0) {
                        switch (err) {
                        case ECONNABORTED:
                                libscf_handle_rebind(h);
                                ret = ECONNABORTED;
                                goto get_inst;

                        case ENOENT:
                                break;

                        case EINVAL:
                        case ENOTSUP:
                        default:
                                bad_error("libscf_fmri_get_instance", err);
                        }
                } else {
                        const char *f;

                        if (new) {
                                err = libscf_delete_enable_ovr(inst);
                                f = "libscf_delete_enable_ovr";
                        } else {
                                err = libscf_set_enable_ovr(inst, 0);
                                f = "libscf_set_enable_ovr";
                        }
                        scf_instance_destroy(inst);
                        switch (err) {
                        case 0:
                        case ECANCELED:
                                break;

                        case ECONNABORTED:
                                libscf_handle_rebind(h);
                                /*
                                 * We must continue so the graph is updated,
                                 * but we must return ECONNABORTED so any
                                 * libscf state held by any callers is reset.
                                 */
                                ret = ECONNABORTED;
                                goto get_inst;

                        case EROFS:
                        case EPERM:
                                log_error(LOG_WARNING,
                                    "Could not set %s/%s for %s: %s.\n",
                                    SCF_PG_GENERAL_OVR, SCF_PROPERTY_ENABLED,
                                    v->gv_name, strerror(err));
                                break;

                        default:
                                bad_error(f, err);
                        }
                }
        }

        for (e = uu_list_first(v->gv_dependencies);
            e != NULL;
            e = uu_list_next(v->gv_dependencies, e)) {
                r = eval_subgraph(e->ge_vertex, h);
                if (r != 0) {
                        assert(r == ECONNABORTED);
                        ret = ECONNABORTED;
                }
        }

        return (ret);
}

/*
 * Delete the (property group) dependencies of v & create new ones based on
 * inst.  If doing so would create a cycle, log a message and put the instance
 * into maintenance.  Update GV_INSUBGRAPH flags as necessary.  Returns 0 or
 * ECONNABORTED.
 */
int
refresh_vertex(graph_vertex_t *v, scf_instance_t *inst)
{
        int err;
        int *path;
        char *fmri;
        int r;
        scf_handle_t *h = scf_instance_handle(inst);
        uu_list_t *old_deps;
        int ret = 0;
        graph_edge_t *e;
        graph_vertex_t *vv;

        assert(MUTEX_HELD(&dgraph_lock));
        assert(v->gv_type == GVT_INST);

        log_framework(LOG_DEBUG, "Graph engine: Refreshing %s.\n", v->gv_name);

        if (milestone > MILESTONE_NONE) {
                /*
                 * In case some of v's dependencies are being deleted we must
                 * make a list of them now for GV_INSUBGRAPH-flag evaluation
                 * after the new dependencies are in place.
                 */
                old_deps = startd_list_create(graph_edge_pool, NULL, 0);

                err = uu_list_walk(v->gv_dependencies,
                    (uu_walk_fn_t *)append_svcs_or_insts, old_deps, 0);
                assert(err == 0);
        }

        delete_instance_dependencies(v, B_FALSE);

        err = set_dependencies(v, inst, &path);
        switch (err) {
        case 0:
                break;

        case ECONNABORTED:
                ret = err;
                goto out;

        case EINVAL:
        case ELOOP:
                r = libscf_instance_get_fmri(inst, &fmri);
                switch (r) {
                case 0:
                        break;

                case ECONNABORTED:
                        ret = ECONNABORTED;
                        goto out;

                case ECANCELED:
                        ret = 0;
                        goto out;

                default:
                        bad_error("libscf_instance_get_fmri", r);
                }

                if (err == EINVAL) {
                        log_error(LOG_ERR, "Transitioning %s "
                            "to maintenance due to misconfiguration.\n",
                            fmri ? fmri : "?");
                        vertex_send_event(v,
                            RESTARTER_EVENT_TYPE_INVALID_DEPENDENCY);
                } else {
                        handle_cycle(fmri, path);
                        vertex_send_event(v,
                            RESTARTER_EVENT_TYPE_DEPENDENCY_CYCLE);
                }
                startd_free(fmri, max_scf_fmri_size);
                ret = 0;
                goto out;

        default:
                bad_error("set_dependencies", err);
        }

        if (milestone > MILESTONE_NONE) {
                boolean_t aborted = B_FALSE;

                for (e = uu_list_first(old_deps);
                    e != NULL;
                    e = uu_list_next(old_deps, e)) {
                        vv = e->ge_vertex;

                        if (vertex_unref(vv) == VERTEX_INUSE &&
                            eval_subgraph(vv, h) == ECONNABORTED)
                                aborted = B_TRUE;
                }

                for (e = uu_list_first(v->gv_dependencies);
                    e != NULL;
                    e = uu_list_next(v->gv_dependencies, e)) {
                        if (eval_subgraph(e->ge_vertex, h) ==
                            ECONNABORTED)
                                aborted = B_TRUE;
                }

                if (aborted) {
                        ret = ECONNABORTED;
                        goto out;
                }
        }

        graph_start_if_satisfied(v);

        ret = 0;

out:
        if (milestone > MILESTONE_NONE) {
                void *cookie = NULL;

                while ((e = uu_list_teardown(old_deps, &cookie)) != NULL)
                        startd_free(e, sizeof (*e));

                uu_list_destroy(old_deps);
        }

        return (ret);
}

/*
 * Set up v according to inst.  That is, make sure it depends on its
 * restarter and set up its dependencies.  Send the ADD_INSTANCE command to
 * the restarter, and send ENABLE or DISABLE as appropriate.
 *
 * Returns 0 on success, ECONNABORTED on repository disconnection, or
 * ECANCELED if inst is deleted.
 */
static int
configure_vertex(graph_vertex_t *v, scf_instance_t *inst)
{
        scf_handle_t *h;
        scf_propertygroup_t *pg;
        scf_snapshot_t *snap;
        char *restarter_fmri = startd_alloc(max_scf_value_size);
        int enabled, enabled_ovr;
        int err;
        int *path;
        int deathrow;
        int32_t tset;

        restarter_fmri[0] = '\0';

        assert(MUTEX_HELD(&dgraph_lock));
        assert(v->gv_type == GVT_INST);
        assert((v->gv_flags & GV_CONFIGURED) == 0);

        /* GV_INSUBGRAPH should already be set properly. */
        assert(should_be_in_subgraph(v) ==
            ((v->gv_flags & GV_INSUBGRAPH) != 0));

        /*
         * If the instance fmri is in the deathrow list then set the
         * GV_DEATHROW flag on the vertex and create and set to true the
         * SCF_PROPERTY_DEATHROW boolean property in the non-persistent
         * repository for this instance fmri.
         */
        if ((v->gv_flags & GV_DEATHROW) ||
            (is_fmri_in_deathrow(v->gv_name) == B_TRUE)) {
                if ((v->gv_flags & GV_DEATHROW) == 0) {
                        /*
                         * Set flag GV_DEATHROW, create and set to true
                         * the SCF_PROPERTY_DEATHROW property in the
                         * non-persistent repository for this instance fmri.
                         */
                        v->gv_flags |= GV_DEATHROW;

                        switch (err = libscf_set_deathrow(inst, 1)) {
                        case 0:
                                break;

                        case ECONNABORTED:
                        case ECANCELED:
                                startd_free(restarter_fmri, max_scf_value_size);
                                return (err);

                        case EROFS:
                                log_error(LOG_WARNING, "Could not set %s/%s "
                                    "for deathrow %s: %s.\n",
                                    SCF_PG_DEATHROW, SCF_PROPERTY_DEATHROW,
                                    v->gv_name, strerror(err));
                                break;

                        case EPERM:
                                uu_die("Permission denied.\n");
                                /* NOTREACHED */

                        default:
                                bad_error("libscf_set_deathrow", err);
                        }
                        log_framework(LOG_DEBUG, "Deathrow, graph set %s.\n",
                            v->gv_name);
                }
                startd_free(restarter_fmri, max_scf_value_size);
                return (0);
        }

        h = scf_instance_handle(inst);

        /*
         * Using a temporary deathrow boolean property, set through
         * libscf_set_deathrow(), only for fmris on deathrow, is necessary
         * because deathrow_fini() may already have been called, and in case
         * of a refresh, GV_DEATHROW may need to be set again.
         * libscf_get_deathrow() sets deathrow to 1 only if this instance
         * has a temporary boolean property named 'deathrow' valued true
         * in a property group 'deathrow', -1 or 0 in all other cases.
         */
        err = libscf_get_deathrow(h, inst, &deathrow);
        switch (err) {
        case 0:
                break;

        case ECONNABORTED:
        case ECANCELED:
                startd_free(restarter_fmri, max_scf_value_size);
                return (err);

        default:
                bad_error("libscf_get_deathrow", err);
        }

        if (deathrow == 1) {
                v->gv_flags |= GV_DEATHROW;
                startd_free(restarter_fmri, max_scf_value_size);
                return (0);
        }

        log_framework(LOG_DEBUG, "Graph adding %s.\n", v->gv_name);

        /*
         * If the instance does not have a restarter property group,
         * initialize its state to uninitialized/none, in case the restarter
         * is not enabled.
         */
        pg = safe_scf_pg_create(h);

        if (scf_instance_get_pg(inst, SCF_PG_RESTARTER, pg) != 0) {
                instance_data_t idata;
                uint_t count = 0, msecs = ALLOC_DELAY;

                switch (scf_error()) {
                case SCF_ERROR_NOT_FOUND:
                        break;

                case SCF_ERROR_CONNECTION_BROKEN:
                default:
                        scf_pg_destroy(pg);
                        startd_free(restarter_fmri, max_scf_value_size);
                        return (ECONNABORTED);

                case SCF_ERROR_DELETED:
                        scf_pg_destroy(pg);
                        startd_free(restarter_fmri, max_scf_value_size);
                        return (ECANCELED);

                case SCF_ERROR_NOT_SET:
                        bad_error("scf_instance_get_pg", scf_error());
                }

                switch (err = libscf_instance_get_fmri(inst,
                    (char **)&idata.i_fmri)) {
                case 0:
                        break;

                case ECONNABORTED:
                case ECANCELED:
                        scf_pg_destroy(pg);
                        startd_free(restarter_fmri, max_scf_value_size);
                        return (err);

                default:
                        bad_error("libscf_instance_get_fmri", err);
                }

                idata.i_state = RESTARTER_STATE_NONE;
                idata.i_next_state = RESTARTER_STATE_NONE;

init_state:
                switch (err = _restarter_commit_states(h, &idata,
                    RESTARTER_STATE_UNINIT, RESTARTER_STATE_NONE,
                    restarter_get_str_short(restarter_str_insert_in_graph))) {
                case 0:
                        break;

                case ENOMEM:
                        ++count;
                        if (count < ALLOC_RETRY) {
                                (void) poll(NULL, 0, msecs);
                                msecs *= ALLOC_DELAY_MULT;
                                goto init_state;
                        }

                        uu_die("Insufficient memory.\n");
                        /* NOTREACHED */

                case ECONNABORTED:
                        startd_free((void *)idata.i_fmri, max_scf_fmri_size);
                        scf_pg_destroy(pg);
                        startd_free(restarter_fmri, max_scf_value_size);
                        return (ECONNABORTED);

                case ENOENT:
                        startd_free((void *)idata.i_fmri, max_scf_fmri_size);
                        scf_pg_destroy(pg);
                        startd_free(restarter_fmri, max_scf_value_size);
                        return (ECANCELED);

                case EPERM:
                case EACCES:
                case EROFS:
                        log_error(LOG_NOTICE, "Could not initialize state for "
                            "%s: %s.\n", idata.i_fmri, strerror(err));
                        break;

                case EINVAL:
                default:
                        bad_error("_restarter_commit_states", err);
                }

                startd_free((void *)idata.i_fmri, max_scf_fmri_size);
        }

        scf_pg_destroy(pg);

        if (milestone != NULL) {
                /*
                 * Make sure the enable-override is set properly before we
                 * read whether we should be enabled.
                 */
                if (milestone == MILESTONE_NONE ||
                    !(v->gv_flags & GV_INSUBGRAPH)) {
                        /*
                         * This might seem unjustified after the milestone
                         * transition has completed (non_subgraph_svcs == 0),
                         * but it's important because when we boot to
                         * a milestone, we set the milestone before populating
                         * the graph, and all of the new non-subgraph services
                         * need to be disabled here.
                         */
                        switch (err = libscf_set_enable_ovr(inst, 0)) {
                        case 0:
                                break;

                        case ECONNABORTED:
                        case ECANCELED:
                                startd_free(restarter_fmri, max_scf_value_size);
                                return (err);

                        case EROFS:
                                log_error(LOG_WARNING,
                                    "Could not set %s/%s for %s: %s.\n",
                                    SCF_PG_GENERAL_OVR, SCF_PROPERTY_ENABLED,
                                    v->gv_name, strerror(err));
                                break;

                        case EPERM:
                                uu_die("Permission denied.\n");
                                /* NOTREACHED */

                        default:
                                bad_error("libscf_set_enable_ovr", err);
                        }
                } else {
                        assert(v->gv_flags & GV_INSUBGRAPH);
                        switch (err = libscf_delete_enable_ovr(inst)) {
                        case 0:
                                break;

                        case ECONNABORTED:
                        case ECANCELED:
                                startd_free(restarter_fmri, max_scf_value_size);
                                return (err);

                        case EPERM:
                                uu_die("Permission denied.\n");
                                /* NOTREACHED */

                        default:
                                bad_error("libscf_delete_enable_ovr", err);
                        }
                }
        }

        err = libscf_get_basic_instance_data(h, inst, v->gv_name, &enabled,
            &enabled_ovr, &restarter_fmri);
        switch (err) {
        case 0:
                break;

        case ECONNABORTED:
        case ECANCELED:
                startd_free(restarter_fmri, max_scf_value_size);
                return (err);

        case ENOENT:
                log_framework(LOG_DEBUG,
                    "Ignoring %s because it has no general property group.\n",
                    v->gv_name);
                startd_free(restarter_fmri, max_scf_value_size);
                return (0);

        default:
                bad_error("libscf_get_basic_instance_data", err);
        }

        if ((tset = libscf_get_stn_tset(inst)) == -1) {
                log_framework(LOG_WARNING,
                    "Failed to get notification parameters for %s: %s\n",
                    v->gv_name, scf_strerror(scf_error()));
                v->gv_stn_tset = 0;
        } else {
                v->gv_stn_tset = tset;
        }
        if (strcmp(v->gv_name, SCF_INSTANCE_GLOBAL) == 0)
                stn_global = v->gv_stn_tset;

        if (enabled == -1) {
                startd_free(restarter_fmri, max_scf_value_size);
                return (0);
        }

        v->gv_flags = (v->gv_flags & ~GV_ENBLD_NOOVR) |
            (enabled ? GV_ENBLD_NOOVR : 0);

        if (enabled_ovr != -1)
                enabled = enabled_ovr;

        v->gv_state = RESTARTER_STATE_UNINIT;

        snap = libscf_get_or_make_running_snapshot(inst, v->gv_name, B_TRUE);
        scf_snapshot_destroy(snap);

        /* Set up the restarter. (Sends _ADD_INSTANCE on success.) */
        err = graph_change_restarter(v, restarter_fmri, h, &path);
        if (err != 0) {
                instance_data_t idata;
                uint_t count = 0, msecs = ALLOC_DELAY;
                restarter_str_t reason;

                if (err == ECONNABORTED) {
                        startd_free(restarter_fmri, max_scf_value_size);
                        return (err);
                }

                assert(err == EINVAL || err == ELOOP);

                if (err == EINVAL) {
                        log_framework(LOG_ERR, emsg_invalid_restarter,
                            v->gv_name, restarter_fmri);
                        reason = restarter_str_invalid_restarter;
                } else {
                        handle_cycle(v->gv_name, path);
                        reason = restarter_str_dependency_cycle;
                }

                startd_free(restarter_fmri, max_scf_value_size);

                /*
                 * We didn't register the instance with the restarter, so we
                 * must set maintenance mode ourselves.
                 */
                err = libscf_instance_get_fmri(inst, (char **)&idata.i_fmri);
                if (err != 0) {
                        assert(err == ECONNABORTED || err == ECANCELED);
                        return (err);
                }

                idata.i_state = RESTARTER_STATE_NONE;
                idata.i_next_state = RESTARTER_STATE_NONE;

set_maint:
                switch (err = _restarter_commit_states(h, &idata,
                    RESTARTER_STATE_MAINT, RESTARTER_STATE_NONE,
                    restarter_get_str_short(reason))) {
                case 0:
                        break;

                case ENOMEM:
                        ++count;
                        if (count < ALLOC_RETRY) {
                                (void) poll(NULL, 0, msecs);
                                msecs *= ALLOC_DELAY_MULT;
                                goto set_maint;
                        }

                        uu_die("Insufficient memory.\n");
                        /* NOTREACHED */

                case ECONNABORTED:
                        startd_free((void *)idata.i_fmri, max_scf_fmri_size);
                        return (ECONNABORTED);

                case ENOENT:
                        startd_free((void *)idata.i_fmri, max_scf_fmri_size);
                        return (ECANCELED);

                case EPERM:
                case EACCES:
                case EROFS:
                        log_error(LOG_NOTICE, "Could not initialize state for "
                            "%s: %s.\n", idata.i_fmri, strerror(err));
                        break;

                case EINVAL:
                default:
                        bad_error("_restarter_commit_states", err);
                }

                startd_free((void *)idata.i_fmri, max_scf_fmri_size);

                v->gv_state = RESTARTER_STATE_MAINT;

                goto out;
        }
        startd_free(restarter_fmri, max_scf_value_size);

        /* Add all the other dependencies. */
        err = refresh_vertex(v, inst);
        if (err != 0) {
                assert(err == ECONNABORTED);
                return (err);
        }

out:
        v->gv_flags |= GV_CONFIGURED;

        graph_enable_by_vertex(v, enabled, 0);

        return (0);
}


static void
kill_user_procs(void)
{
        (void) fputs("svc.startd: Killing user processes.\n", stdout);

        /*
         * Despite its name, killall's role is to get select user processes--
         * basically those representing terminal-based logins-- to die.  Victims
         * are located by killall in the utmp database.  Since these are most
         * often shell based logins, and many shells mask SIGTERM (but are
         * responsive to SIGHUP) we first HUP and then shortly thereafter
         * kill -9.
         */
        (void) fork_with_timeout("/usr/sbin/killall HUP", 1, 5);
        (void) fork_with_timeout("/usr/sbin/killall KILL", 1, 5);

        /*
         * Note the selection of user id's 0, 1 and 15, subsequently
         * inverted by -v.  15 is reserved for dladmd.  Yes, this is a
         * kludge-- a better policy is needed.
         *
         * Note that fork_with_timeout will only wait out the 1 second
         * "grace time" if pkill actually returns 0.  So if there are
         * no matches, this will run to completion much more quickly.
         */
        (void) fork_with_timeout("/usr/bin/pkill -TERM -v -u 0,1,15", 1, 5);
        (void) fork_with_timeout("/usr/bin/pkill -KILL -v -u 0,1,15", 1, 5);
}

static void
do_uadmin(void)
{
        const char * const resetting = "/etc/svc/volatile/resetting";
        int fd;
        struct statvfs vfs;
        time_t now;
        struct tm nowtm;
        char down_buf[256], time_buf[256];
        uintptr_t mdep;
#if defined(__x86)
        char *fbarg = NULL;
#endif  /* __x86 */

        mdep = (uintptr_t)NULL;
        fd = creat(resetting, 0777);
        if (fd >= 0)
                startd_close(fd);
        else
                uu_warn("Could not create \"%s\"", resetting);

        /* Kill dhcpagent if we're not using nfs for root */
        if ((statvfs("/", &vfs) == 0) &&
            (strncmp(vfs.f_basetype, "nfs", sizeof ("nfs") - 1) != 0))
                fork_with_timeout("/usr/bin/pkill -x -u 0 dhcpagent", 0, 5);

        /*
         * Call sync(2) now, before we kill off user processes.  This takes
         * advantage of the several seconds of pause we have before the
         * killalls are done.  Time we can make good use of to get pages
         * moving out to disk.
         *
         * Inside non-global zones, we don't bother, and it's better not to
         * anyway, since sync(2) can have system-wide impact.
         */
        if (getzoneid() == 0)
                sync();

        kill_user_procs();

        /*
         * Note that this must come after the killing of user procs, since
         * killall relies on utmpx, and this command affects the contents of
         * said file.
         */
        if (access("/usr/lib/acct/closewtmp", X_OK) == 0)
                fork_with_timeout("/usr/lib/acct/closewtmp", 0, 5);

        /*
         * For patches which may be installed as the system is shutting
         * down, we need to ensure, one more time, that the boot archive
         * really is up to date.
         */
        if (getzoneid() == 0 && access("/usr/sbin/bootadm", X_OK) == 0)
                fork_with_timeout("/usr/sbin/bootadm -a update_all", 0, 3600);

        /*
         * Right now, fast reboot is supported only on i386.
         * scf_is_fastboot_default() should take care of it.
         * If somehow we got there on unsupported platform -
         * print warning and fall back to regular reboot.
         */
        if (halting == AD_FASTREBOOT) {
#if defined(__x86)
                if (be_get_boot_args(&fbarg, BE_ENTRY_DEFAULT) == 0) {
                        mdep = (uintptr_t)fbarg;
                } else {
                        /*
                         * Failed to read BE info, fall back to normal reboot
                         */
                        halting = AD_BOOT;
                        uu_warn("Failed to get fast reboot arguments.\n"
                            "Falling back to regular reboot.\n");
                }
#else   /* __x86 */
                halting = AD_BOOT;
                uu_warn("Fast reboot configured, but not supported by "
                    "this ISA\n");
#endif  /* __x86 */
        }

        fork_with_timeout("/sbin/umountall -l", 0, 5);
        fork_with_timeout("/sbin/umount /tmp /var/log /var/run /var "
            ">/dev/null 2>&1", 0, 5);

        /*
         * Try to get to consistency for whatever UFS filesystems are left.
         * This is pretty expensive, so we save it for the end in the hopes of
         * minimizing what it must do.  The other option would be to start in
         * parallel with the killall's, but lockfs tends to throw out much more
         * than is needed, and so subsequent commands (like umountall) take a
         * long time to get going again.
         *
         * Inside of zones, we don't bother, since we're not about to terminate
         * the whole OS instance.
         *
         * On systems using only ZFS, this call to lockfs -fa is a no-op.
         */
        if (getzoneid() == 0) {
                if (access("/usr/sbin/lockfs", X_OK) == 0)
                        fork_with_timeout("/usr/sbin/lockfs -fa", 0, 30);

                sync(); /* once more, with feeling */
        }

        fork_with_timeout("/sbin/umount /usr >/dev/null 2>&1", 0, 5);

        /*
         * Construct and emit the last words from userland:
         * "<timestamp> The system is down.  Shutdown took <N> seconds."
         *
         * Normally we'd use syslog, but with /var and other things
         * potentially gone, try to minimize the external dependencies.
         */
        now = time(NULL);
        (void) localtime_r(&now, &nowtm);

        if (strftime(down_buf, sizeof (down_buf),
            "%b %e %T The system is down.", &nowtm) == 0) {
                (void) strlcpy(down_buf, "The system is down.",
                    sizeof (down_buf));
        }

        if (halting_time != 0 && halting_time <= now) {
                (void) snprintf(time_buf, sizeof (time_buf),
                    "  Shutdown took %lu seconds.", now - halting_time);
        } else {
                time_buf[0] = '\0';
        }
        (void) printf("%s%s\n", down_buf, time_buf);

        (void) uadmin(A_SHUTDOWN, halting, mdep);
        uu_warn("uadmin() failed");

#if defined(__x86)
        if (halting == AD_FASTREBOOT)
                free(fbarg);
#endif  /* __x86 */

        if (remove(resetting) != 0 && errno != ENOENT)
                uu_warn("Could not remove \"%s\"", resetting);
}

/*
 * If any of the up_svcs[] are online or satisfiable, return true.  If they are
 * all missing, disabled, in maintenance, or unsatisfiable, return false.
 */
boolean_t
can_come_up(void)
{
        int i;

        assert(MUTEX_HELD(&dgraph_lock));

        /*
         * If we are booting to single user (boot -s),
         * SCF_MILESTONE_SINGLE_USER is needed to come up because startd
         * spawns sulogin after single-user is online (see specials.c).
         */
        i = (booting_to_single_user ? 0 : 1);

        for (; up_svcs[i] != NULL; ++i) {
                if (up_svcs_p[i] == NULL) {
                        up_svcs_p[i] = vertex_get_by_name(up_svcs[i]);

                        if (up_svcs_p[i] == NULL)
                                continue;
                }

                /*
                 * Ignore unconfigured services (the ones that have been
                 * mentioned in a dependency from other services, but do
                 * not exist in the repository).  Services which exist
                 * in the repository but don't have general/enabled
                 * property will be also ignored.
                 */
                if (!(up_svcs_p[i]->gv_flags & GV_CONFIGURED))
                        continue;

                switch (up_svcs_p[i]->gv_state) {
                case RESTARTER_STATE_ONLINE:
                case RESTARTER_STATE_DEGRADED:
                        /*
                         * Deactivate verbose boot once a login service has been
                         * reached.
                         */
                        st->st_log_login_reached = 1;
                        /*FALLTHROUGH*/
                case RESTARTER_STATE_UNINIT:
                        return (B_TRUE);

                case RESTARTER_STATE_OFFLINE:
                        if (instance_satisfied(up_svcs_p[i], B_TRUE) != -1)
                                return (B_TRUE);
                        log_framework(LOG_DEBUG,
                            "can_come_up(): %s is unsatisfiable.\n",
                            up_svcs_p[i]->gv_name);
                        continue;

                case RESTARTER_STATE_DISABLED:
                case RESTARTER_STATE_MAINT:
                        log_framework(LOG_DEBUG,
                            "can_come_up(): %s is in state %s.\n",
                            up_svcs_p[i]->gv_name,
                            instance_state_str[up_svcs_p[i]->gv_state]);
                        continue;

                default:
#ifndef NDEBUG
                        uu_warn("%s:%d: Unexpected vertex state %d.\n",
                            __FILE__, __LINE__, up_svcs_p[i]->gv_state);
#endif
                        abort();
                }
        }

        /*
         * In the seed repository, console-login is unsatisfiable because
         * services are missing.  To behave correctly in that case we don't want
         * to return false until manifest-import is online.
         */

        if (manifest_import_p == NULL) {
                manifest_import_p = vertex_get_by_name(manifest_import);

                if (manifest_import_p == NULL)
                        return (B_FALSE);
        }

        switch (manifest_import_p->gv_state) {
        case RESTARTER_STATE_ONLINE:
        case RESTARTER_STATE_DEGRADED:
        case RESTARTER_STATE_DISABLED:
        case RESTARTER_STATE_MAINT:
                break;

        case RESTARTER_STATE_OFFLINE:
                if (instance_satisfied(manifest_import_p, B_TRUE) == -1)
                        break;
                /* FALLTHROUGH */

        case RESTARTER_STATE_UNINIT:
                return (B_TRUE);
        }

        return (B_FALSE);
}

/*
 * Runs sulogin.  Returns
 *   0 - success
 *   EALREADY - sulogin is already running
 *   EBUSY - console-login is running
 */
static int
run_sulogin(const char *msg)
{
        graph_vertex_t *v;

        assert(MUTEX_HELD(&dgraph_lock));

        if (sulogin_running)
                return (EALREADY);

        v = vertex_get_by_name(console_login_fmri);
        if (v != NULL && inst_running(v))
                return (EBUSY);

        sulogin_running = B_TRUE;

        MUTEX_UNLOCK(&dgraph_lock);

        fork_sulogin(B_FALSE, msg);

        MUTEX_LOCK(&dgraph_lock);

        sulogin_running = B_FALSE;

        if (console_login_ready) {
                v = vertex_get_by_name(console_login_fmri);

                if (v != NULL && v->gv_state == RESTARTER_STATE_OFFLINE) {
                        if (v->gv_start_f == NULL)
                                vertex_send_event(v,
                                    RESTARTER_EVENT_TYPE_START);
                        else
                                v->gv_start_f(v);
                }

                console_login_ready = B_FALSE;
        }

        return (0);
}

/*
 * The sulogin thread runs sulogin while can_come_up() is false.  run_sulogin()
 * keeps sulogin from stepping on console-login's toes.
 */
/* ARGSUSED */
static void *
sulogin_thread(void *unused)
{
        MUTEX_LOCK(&dgraph_lock);

        assert(sulogin_thread_running);

        do {
                (void) run_sulogin("Console login service(s) cannot run\n");
        } while (!can_come_up());

        sulogin_thread_running = B_FALSE;
        MUTEX_UNLOCK(&dgraph_lock);

        return (NULL);
}

/* ARGSUSED */
void *
single_user_thread(void *unused)
{
        uint_t left;
        scf_handle_t *h;
        scf_instance_t *inst;
        scf_property_t *prop;
        scf_value_t *val;
        const char *msg;
        char *buf;
        int r;

        MUTEX_LOCK(&single_user_thread_lock);
        single_user_thread_count++;

        if (!booting_to_single_user)
                kill_user_procs();

        if (go_single_user_mode || booting_to_single_user) {
                msg = "SINGLE USER MODE\n";
        } else {
                assert(go_to_level1);

                fork_rc_script('1', "start", B_TRUE);

                uu_warn("The system is ready for administration.\n");

                msg = "";
        }

        MUTEX_UNLOCK(&single_user_thread_lock);

        for (;;) {
                MUTEX_LOCK(&dgraph_lock);
                r = run_sulogin(msg);
                MUTEX_UNLOCK(&dgraph_lock);
                if (r == 0)
                        break;

                assert(r == EALREADY || r == EBUSY);

                left = 3;
                while (left > 0)
                        left = sleep(left);
        }

        MUTEX_LOCK(&single_user_thread_lock);

        /*
         * If another single user thread has started, let it finish changing
         * the run level.
         */
        if (single_user_thread_count > 1) {
                single_user_thread_count--;
                MUTEX_UNLOCK(&single_user_thread_lock);
                return (NULL);
        }

        h = libscf_handle_create_bound_loop();
        inst = scf_instance_create(h);
        prop = safe_scf_property_create(h);
        val = safe_scf_value_create(h);
        buf = startd_alloc(max_scf_fmri_size);

lookup:
        if (scf_handle_decode_fmri(h, SCF_SERVICE_STARTD, NULL, NULL, inst,
            NULL, NULL, SCF_DECODE_FMRI_EXACT) != 0) {
                switch (scf_error()) {
                case SCF_ERROR_NOT_FOUND:
                        r = libscf_create_self(h);
                        if (r == 0)
                                goto lookup;
                        assert(r == ECONNABORTED);
                        /* FALLTHROUGH */

                case SCF_ERROR_CONNECTION_BROKEN:
                        libscf_handle_rebind(h);
                        goto lookup;

                case SCF_ERROR_INVALID_ARGUMENT:
                case SCF_ERROR_CONSTRAINT_VIOLATED:
                case SCF_ERROR_NOT_BOUND:
                case SCF_ERROR_HANDLE_MISMATCH:
                default:
                        bad_error("scf_handle_decode_fmri", scf_error());
                }
        }

        MUTEX_LOCK(&dgraph_lock);

        r = scf_instance_delete_prop(inst, SCF_PG_OPTIONS_OVR,
            SCF_PROPERTY_MILESTONE);
        switch (r) {
        case 0:
        case ECANCELED:
                break;

        case ECONNABORTED:
                MUTEX_UNLOCK(&dgraph_lock);
                libscf_handle_rebind(h);
                goto lookup;

        case EPERM:
        case EACCES:
        case EROFS:
                log_error(LOG_WARNING, "Could not clear temporary milestone: "
                    "%s.\n", strerror(r));
                break;

        default:
                bad_error("scf_instance_delete_prop", r);
        }

        MUTEX_UNLOCK(&dgraph_lock);

        r = libscf_get_milestone(inst, prop, val, buf, max_scf_fmri_size);
        switch (r) {
        case ECANCELED:
        case ENOENT:
        case EINVAL:
                (void) strcpy(buf, "all");
                /* FALLTHROUGH */

        case 0:
                uu_warn("Returning to milestone %s.\n", buf);
                break;

        case ECONNABORTED:
                libscf_handle_rebind(h);
                goto lookup;

        default:
                bad_error("libscf_get_milestone", r);
        }

        r = dgraph_set_milestone(buf, h, B_FALSE);
        switch (r) {
        case 0:
        case ECONNRESET:
        case EALREADY:
        case EINVAL:
        case ENOENT:
                break;

        default:
                bad_error("dgraph_set_milestone", r);
        }

        /*
         * See graph_runlevel_changed().
         */
        MUTEX_LOCK(&dgraph_lock);
        utmpx_set_runlevel(target_milestone_as_runlevel(), 'S', B_TRUE);
        MUTEX_UNLOCK(&dgraph_lock);

        startd_free(buf, max_scf_fmri_size);
        scf_value_destroy(val);
        scf_property_destroy(prop);
        scf_instance_destroy(inst);
        scf_handle_destroy(h);

        /*
         * We'll give ourselves 3 seconds to respond to all of the enablings
         * that setting the milestone should have created before checking
         * whether to run sulogin.
         */
        left = 3;
        while (left > 0)
                left = sleep(left);

        MUTEX_LOCK(&dgraph_lock);
        /*
         * Clearing these variables will allow the sulogin thread to run.  We
         * check here in case there aren't any more state updates anytime soon.
         */
        go_to_level1 = go_single_user_mode = booting_to_single_user = B_FALSE;
        if (!sulogin_thread_running && !can_come_up()) {
                (void) startd_thread_create(sulogin_thread, NULL);
                sulogin_thread_running = B_TRUE;
        }
        MUTEX_UNLOCK(&dgraph_lock);
        single_user_thread_count--;
        MUTEX_UNLOCK(&single_user_thread_lock);
        return (NULL);
}


/*
 * Dependency graph operations API.  These are handle-independent thread-safe
 * graph manipulation functions which are the entry points for the event
 * threads below.
 */

/*
 * If a configured vertex exists for inst_fmri, return EEXIST.  If no vertex
 * exists for inst_fmri, add one.  Then fetch the restarter from inst, make
 * this vertex dependent on it, and send _ADD_INSTANCE to the restarter.
 * Fetch whether the instance should be enabled from inst and send _ENABLE or
 * _DISABLE as appropriate.  Finally rummage through inst's dependency
 * property groups and add vertices and edges as appropriate.  If anything
 * goes wrong after sending _ADD_INSTANCE, send _ADMIN_MAINT_ON to put the
 * instance in maintenance.  Don't send _START or _STOP until we get a state
 * update in case we're being restarted and the service is already running.
 *
 * To support booting to a milestone, we must also make sure all dependencies
 * encountered are configured, if they exist in the repository.
 *
 * Returns 0 on success, ECONNABORTED on repository disconnection, EINVAL if
 * inst_fmri is an invalid (or not canonical) FMRI, ECANCELED if inst is
 * deleted, or EEXIST if a configured vertex for inst_fmri already exists.
 */
int
dgraph_add_instance(const char *inst_fmri, scf_instance_t *inst,
    boolean_t lock_graph)
{
        graph_vertex_t *v;
        int err;

        if (strcmp(inst_fmri, SCF_SERVICE_STARTD) == 0)
                return (0);

        /* Check for a vertex for inst_fmri. */
        if (lock_graph) {
                MUTEX_LOCK(&dgraph_lock);
        } else {
                assert(MUTEX_HELD(&dgraph_lock));
        }

        v = vertex_get_by_name(inst_fmri);

        if (v != NULL) {
                assert(v->gv_type == GVT_INST);

                if (v->gv_flags & GV_CONFIGURED) {
                        if (lock_graph)
                                MUTEX_UNLOCK(&dgraph_lock);
                        return (EEXIST);
                }
        } else {
                /* Add the vertex. */
                err = graph_insert_vertex_unconfigured(inst_fmri, GVT_INST, 0,
                    RERR_NONE, &v);
                if (err != 0) {
                        assert(err == EINVAL);
                        if (lock_graph)
                                MUTEX_UNLOCK(&dgraph_lock);
                        return (EINVAL);
                }
        }

        err = configure_vertex(v, inst);

        if (lock_graph)
                MUTEX_UNLOCK(&dgraph_lock);

        return (err);
}

/*
 * Locate the vertex for this property group's instance.  If it doesn't exist
 * or is unconfigured, call dgraph_add_instance() & return.  Otherwise fetch
 * the restarter for the instance, and if it has changed, send
 * _REMOVE_INSTANCE to the old restarter, remove the dependency, make sure the
 * new restarter has a vertex, add a new dependency, and send _ADD_INSTANCE to
 * the new restarter.  Then fetch whether the instance should be enabled, and
 * if it is different from what we had, or if we changed the restarter, send
 * the appropriate _ENABLE or _DISABLE command.
 *
 * Returns 0 on success, ENOTSUP if the pg's parent is not an instance,
 * ECONNABORTED on repository disconnection, ECANCELED if the instance is
 * deleted, or -1 if the instance's general property group is deleted or if
 * its enabled property is misconfigured.
 */
static int
dgraph_update_general(scf_propertygroup_t *pg)
{
        scf_handle_t *h;
        scf_instance_t *inst;
        char *fmri;
        char *restarter_fmri;
        graph_vertex_t *v;
        int err;
        int enabled, enabled_ovr;
        int oldflags;

        /* Find the vertex for this service */
        h = scf_pg_handle(pg);

        inst = safe_scf_instance_create(h);

        if (scf_pg_get_parent_instance(pg, inst) != 0) {
                switch (scf_error()) {
                case SCF_ERROR_CONSTRAINT_VIOLATED:
                        return (ENOTSUP);

                case SCF_ERROR_CONNECTION_BROKEN:
                default:
                        return (ECONNABORTED);

                case SCF_ERROR_DELETED:
                        return (0);

                case SCF_ERROR_NOT_SET:
                        bad_error("scf_pg_get_parent_instance", scf_error());
                }
        }

        err = libscf_instance_get_fmri(inst, &fmri);
        switch (err) {
        case 0:
                break;

        case ECONNABORTED:
                scf_instance_destroy(inst);
                return (ECONNABORTED);

        case ECANCELED:
                scf_instance_destroy(inst);
                return (0);

        default:
                bad_error("libscf_instance_get_fmri", err);
        }

        log_framework(LOG_DEBUG,
            "Graph engine: Reloading general properties for %s.\n", fmri);

        MUTEX_LOCK(&dgraph_lock);

        v = vertex_get_by_name(fmri);
        if (v == NULL || !(v->gv_flags & GV_CONFIGURED)) {
                /* Will get the up-to-date properties. */
                MUTEX_UNLOCK(&dgraph_lock);
                err = dgraph_add_instance(fmri, inst, B_TRUE);
                startd_free(fmri, max_scf_fmri_size);
                scf_instance_destroy(inst);
                return (err == ECANCELED ? 0 : err);
        }

        /* Read enabled & restarter from repository. */
        restarter_fmri = startd_alloc(max_scf_value_size);
        err = libscf_get_basic_instance_data(h, inst, v->gv_name, &enabled,
            &enabled_ovr, &restarter_fmri);
        if (err != 0 || enabled == -1) {
                MUTEX_UNLOCK(&dgraph_lock);
                scf_instance_destroy(inst);
                startd_free(fmri, max_scf_fmri_size);

                switch (err) {
                case ENOENT:
                case 0:
                        startd_free(restarter_fmri, max_scf_value_size);
                        return (-1);

                case ECONNABORTED:
                case ECANCELED:
                        startd_free(restarter_fmri, max_scf_value_size);
                        return (err);

                default:
                        bad_error("libscf_get_basic_instance_data", err);
                }
        }

        oldflags = v->gv_flags;
        v->gv_flags = (v->gv_flags & ~GV_ENBLD_NOOVR) |
            (enabled ? GV_ENBLD_NOOVR : 0);

        if (enabled_ovr != -1)
                enabled = enabled_ovr;

        /*
         * If GV_ENBLD_NOOVR has changed, then we need to re-evaluate the
         * subgraph.
         */
        if (milestone > MILESTONE_NONE && v->gv_flags != oldflags)
                (void) eval_subgraph(v, h);

        scf_instance_destroy(inst);

        /* Ignore restarter change for now. */

        startd_free(restarter_fmri, max_scf_value_size);
        startd_free(fmri, max_scf_fmri_size);

        /*
         * Always send _ENABLE or _DISABLE.  We could avoid this if the
         * restarter didn't change and the enabled value didn't change, but
         * that's not easy to check and improbable anyway, so we'll just do
         * this.
         */
        graph_enable_by_vertex(v, enabled, 1);

        MUTEX_UNLOCK(&dgraph_lock);

        return (0);
}

/*
 * Delete all of the property group dependencies of v, update inst's running
 * snapshot, and add the dependencies in the new snapshot.  If any of the new
 * dependencies would create a cycle, send _ADMIN_MAINT_ON.  Otherwise
 * reevaluate v's dependencies, send _START or _STOP as appropriate, and do
 * the same for v's dependents.
 *
 * Returns
 *   0 - success
 *   ECONNABORTED - repository connection broken
 *   ECANCELED - inst was deleted
 *   EINVAL - inst is invalid (e.g., missing general/enabled)
 *   -1 - libscf_snapshots_refresh() failed
 */
static int
dgraph_refresh_instance(graph_vertex_t *v, scf_instance_t *inst)
{
        int r;
        int enabled;
        int32_t tset;

        assert(MUTEX_HELD(&dgraph_lock));
        assert(v->gv_type == GVT_INST);

        /* Only refresh services with valid general/enabled properties. */
        r = libscf_get_basic_instance_data(scf_instance_handle(inst), inst,
            v->gv_name, &enabled, NULL, NULL);
        switch (r) {
        case 0:
                break;

        case ECONNABORTED:
        case ECANCELED:
                return (r);

        case ENOENT:
                log_framework(LOG_DEBUG,
                    "Ignoring %s because it has no general property group.\n",
                    v->gv_name);
                return (EINVAL);

        default:
                bad_error("libscf_get_basic_instance_data", r);
        }

        if ((tset = libscf_get_stn_tset(inst)) == -1) {
                log_framework(LOG_WARNING,
                    "Failed to get notification parameters for %s: %s\n",
                    v->gv_name, scf_strerror(scf_error()));
                tset = 0;
        }
        v->gv_stn_tset = tset;
        if (strcmp(v->gv_name, SCF_INSTANCE_GLOBAL) == 0)
                stn_global = tset;

        if (enabled == -1)
                return (EINVAL);

        r = libscf_snapshots_refresh(inst, v->gv_name);
        if (r != 0) {
                if (r != -1)
                        bad_error("libscf_snapshots_refresh", r);

                /* error logged */
                return (r);
        }

        r = refresh_vertex(v, inst);
        if (r != 0 && r != ECONNABORTED)
                bad_error("refresh_vertex", r);
        return (r);
}

/*
 * Returns true only if none of this service's dependents are 'up' -- online
 * or degraded (offline is considered down in this situation). This function
 * is somehow similar to is_nonsubgraph_leaf() but works on subtrees.
 */
static boolean_t
insubtree_dependents_down(graph_vertex_t *v)
{
        graph_vertex_t *vv;
        graph_edge_t *e;

        assert(MUTEX_HELD(&dgraph_lock));

        for (e = uu_list_first(v->gv_dependents); e != NULL;
            e = uu_list_next(v->gv_dependents, e)) {
                vv = e->ge_vertex;
                if (vv->gv_type == GVT_INST) {
                        if ((vv->gv_flags & GV_CONFIGURED) == 0)
                                continue;

                        if ((vv->gv_flags & GV_TOOFFLINE) == 0)
                                continue;

                        if ((vv->gv_state == RESTARTER_STATE_ONLINE) ||
                            (vv->gv_state == RESTARTER_STATE_DEGRADED))
                                return (B_FALSE);
                } else {
                        /*
                         * Skip all excluded dependents and decide whether
                         * to offline the service based on the restart_on
                         * attribute.
                         */
                        if (is_depgrp_bypassed(vv))
                                continue;

                        /*
                         * For dependency groups or service vertices, keep
                         * traversing to see if instances are running.
                         */
                        if (insubtree_dependents_down(vv) == B_FALSE)
                                return (B_FALSE);
                }
        }

        return (B_TRUE);
}

/*
 * Returns true only if none of this service's dependents are 'up' -- online,
 * degraded, or offline.
 */
static int
is_nonsubgraph_leaf(graph_vertex_t *v)
{
        graph_vertex_t *vv;
        graph_edge_t *e;

        assert(MUTEX_HELD(&dgraph_lock));

        for (e = uu_list_first(v->gv_dependents);
            e != NULL;
            e = uu_list_next(v->gv_dependents, e)) {

                vv = e->ge_vertex;
                if (vv->gv_type == GVT_INST) {
                        if ((vv->gv_flags & GV_CONFIGURED) == 0)
                                continue;

                        if (vv->gv_flags & GV_INSUBGRAPH)
                                continue;

                        if (up_state(vv->gv_state))
                                return (0);
                } else {
                        /*
                         * For dependency group or service vertices, keep
                         * traversing to see if instances are running.
                         *
                         * We should skip exclude_all dependencies otherwise
                         * the vertex will never be considered as a leaf
                         * if the dependent is offline. The main reason for
                         * this is that disable_nonsubgraph_leaves() skips
                         * exclusion dependencies.
                         */
                        if (vv->gv_type == GVT_GROUP &&
                            vv->gv_depgroup == DEPGRP_EXCLUDE_ALL)
                                continue;

                        if (!is_nonsubgraph_leaf(vv))
                                return (0);
                }
        }

        return (1);
}

/*
 * Disable v temporarily.  Attempt to do this by setting its enabled override
 * property in the repository.  If that fails, send a _DISABLE command.
 * Returns 0 on success and ECONNABORTED if the repository connection is
 * broken.
 */
static int
disable_service_temporarily(graph_vertex_t *v, scf_handle_t *h)
{
        const char * const emsg = "Could not temporarily disable %s because "
            "%s.  Will stop service anyways.  Repository status for the "
            "service may be inaccurate.\n";
        const char * const emsg_cbroken =
            "the repository connection was broken";

        scf_instance_t *inst;
        int r;

        inst = scf_instance_create(h);
        if (inst == NULL) {
                char buf[100];

                (void) snprintf(buf, sizeof (buf),
                    "scf_instance_create() failed (%s)",
                    scf_strerror(scf_error()));
                log_error(LOG_WARNING, emsg, v->gv_name, buf);

                graph_enable_by_vertex(v, 0, 0);
                return (0);
        }

        r = scf_handle_decode_fmri(h, v->gv_name, NULL, NULL, inst,
            NULL, NULL, SCF_DECODE_FMRI_EXACT);
        if (r != 0) {
                switch (scf_error()) {
                case SCF_ERROR_CONNECTION_BROKEN:
                        log_error(LOG_WARNING, emsg, v->gv_name, emsg_cbroken);
                        graph_enable_by_vertex(v, 0, 0);
                        return (ECONNABORTED);

                case SCF_ERROR_NOT_FOUND:
                        return (0);

                case SCF_ERROR_HANDLE_MISMATCH:
                case SCF_ERROR_INVALID_ARGUMENT:
                case SCF_ERROR_CONSTRAINT_VIOLATED:
                case SCF_ERROR_NOT_BOUND:
                default:
                        bad_error("scf_handle_decode_fmri",
                            scf_error());
                }
        }

        r = libscf_set_enable_ovr(inst, 0);
        switch (r) {
        case 0:
                scf_instance_destroy(inst);
                return (0);

        case ECANCELED:
                scf_instance_destroy(inst);
                return (0);

        case ECONNABORTED:
                log_error(LOG_WARNING, emsg, v->gv_name, emsg_cbroken);
                graph_enable_by_vertex(v, 0, 0);
                return (ECONNABORTED);

        case EPERM:
                log_error(LOG_WARNING, emsg, v->gv_name,
                    "the repository denied permission");
                graph_enable_by_vertex(v, 0, 0);
                return (0);

        case EROFS:
                log_error(LOG_WARNING, emsg, v->gv_name,
                    "the repository is read-only");
                graph_enable_by_vertex(v, 0, 0);
                return (0);

        default:
                bad_error("libscf_set_enable_ovr", r);
                /* NOTREACHED */
        }
}

/*
 * Of the transitive instance dependencies of v, offline those which are
 * in the subtree and which are leaves (i.e., have no dependents which are
 * "up").
 */
void
offline_subtree_leaves(graph_vertex_t *v, void *arg)
{
        assert(MUTEX_HELD(&dgraph_lock));

        /* If v isn't an instance, recurse on its dependencies. */
        if (v->gv_type != GVT_INST) {
                graph_walk_dependencies(v, offline_subtree_leaves, arg);
                return;
        }

        /*
         * If v is not in the subtree, so should all of its dependencies,
         * so do nothing.
         */
        if ((v->gv_flags & GV_TOOFFLINE) == 0)
                return;

        /* If v isn't a leaf because it's already down, recurse. */
        if (!up_state(v->gv_state)) {
                graph_walk_dependencies(v, offline_subtree_leaves, arg);
                return;
        }

        /* if v is a leaf, offline it or disable it if it's the last one */
        if (insubtree_dependents_down(v) == B_TRUE) {
                if (v->gv_flags & GV_TODISABLE)
                        vertex_send_event(v,
                            RESTARTER_EVENT_TYPE_ADMIN_DISABLE);
                else
                        offline_vertex(v);
        }
}

void
graph_offline_subtree_leaves(graph_vertex_t *v, void *h)
{
        graph_walk_dependencies(v, offline_subtree_leaves, (void *)h);
}


/*
 * Of the transitive instance dependencies of v, disable those which are not
 * in the subgraph and which are leaves (i.e., have no dependents which are
 * "up").
 */
static void
disable_nonsubgraph_leaves(graph_vertex_t *v, void *arg)
{
        assert(MUTEX_HELD(&dgraph_lock));

        /*
         * We must skip exclusion dependencies because they are allowed to
         * complete dependency cycles.  This is correct because A's exclusion
         * dependency on B doesn't bear on the order in which they should be
         * stopped.  Indeed, the exclusion dependency should guarantee that
         * they are never online at the same time.
         */
        if (v->gv_type == GVT_GROUP && v->gv_depgroup == DEPGRP_EXCLUDE_ALL)
                return;

        /* If v isn't an instance, recurse on its dependencies. */
        if (v->gv_type != GVT_INST)
                goto recurse;

        if ((v->gv_flags & GV_CONFIGURED) == 0)
                /*
                 * Unconfigured instances should have no dependencies, but in
                 * case they ever get them,
                 */
                goto recurse;

        /*
         * If v is in the subgraph, so should all of its dependencies, so do
         * nothing.
         */
        if (v->gv_flags & GV_INSUBGRAPH)
                return;

        /* If v isn't a leaf because it's already down, recurse. */
        if (!up_state(v->gv_state))
                goto recurse;

        /* If v is disabled but not down yet, be patient. */
        if ((v->gv_flags & GV_ENABLED) == 0)
                return;

        /* If v is a leaf, disable it. */
        if (is_nonsubgraph_leaf(v))
                (void) disable_service_temporarily(v, (scf_handle_t *)arg);

        return;

recurse:
        graph_walk_dependencies(v, disable_nonsubgraph_leaves, arg);
}

static int
stn_restarter_state(restarter_instance_state_t rstate)
{
        static const struct statemap {
                restarter_instance_state_t restarter_state;
                int scf_state;
        } map[] = {
                { RESTARTER_STATE_UNINIT, SCF_STATE_UNINIT },
                { RESTARTER_STATE_MAINT, SCF_STATE_MAINT },
                { RESTARTER_STATE_OFFLINE, SCF_STATE_OFFLINE },
                { RESTARTER_STATE_DISABLED, SCF_STATE_DISABLED },
                { RESTARTER_STATE_ONLINE, SCF_STATE_ONLINE },
                { RESTARTER_STATE_DEGRADED, SCF_STATE_DEGRADED }
        };

        int i;

        for (i = 0; i < sizeof (map) / sizeof (map[0]); i++) {
                if (rstate == map[i].restarter_state)
                        return (map[i].scf_state);
        }

        return (-1);
}

/*
 * State transition counters
 * Not incremented atomically - indicative only
 */
static uint64_t stev_ct_maint;
static uint64_t stev_ct_hwerr;
static uint64_t stev_ct_service;
static uint64_t stev_ct_global;
static uint64_t stev_ct_noprefs;
static uint64_t stev_ct_from_uninit;
static uint64_t stev_ct_bad_state;
static uint64_t stev_ct_ovr_prefs;

static void
dgraph_state_transition_notify(graph_vertex_t *v,
    restarter_instance_state_t old_state, restarter_str_t reason)
{
        restarter_instance_state_t new_state = v->gv_state;
        int stn_transition, maint;
        int from, to;
        nvlist_t *attr;
        fmev_pri_t pri = FMEV_LOPRI;
        int raise = 0;

        if ((from = stn_restarter_state(old_state)) == -1 ||
            (to = stn_restarter_state(new_state)) == -1) {
                stev_ct_bad_state++;
                return;
        }

        stn_transition = from << 16 | to;

        maint = (to == SCF_STATE_MAINT || from == SCF_STATE_MAINT);

        if (maint) {
                /*
                 * All transitions to/from maintenance state must raise
                 * an event.
                 */
                raise++;
                pri = FMEV_HIPRI;
                stev_ct_maint++;
        } else if (reason == restarter_str_ct_ev_hwerr) {
                /*
                 * All transitions caused by hardware fault must raise
                 * an event
                 */
                raise++;
                pri = FMEV_HIPRI;
                stev_ct_hwerr++;
        } else if (stn_transition & v->gv_stn_tset) {
                /*
                 * Specifically enabled event.
                 */
                raise++;
                stev_ct_service++;
        } else if (from == SCF_STATE_UNINIT) {
                /*
                 * Only raise these if specifically selected above.
                 */
                stev_ct_from_uninit++;
        } else if (stn_transition & stn_global &&
            (IS_ENABLED(v) == 1 || to == SCF_STATE_DISABLED)) {
                raise++;
                stev_ct_global++;
        } else {
                stev_ct_noprefs++;
        }

        if (info_events_all) {
                stev_ct_ovr_prefs++;
                raise++;
        }
        if (!raise)
                return;

        if (nvlist_alloc(&attr, NV_UNIQUE_NAME, 0) != 0 ||
            nvlist_add_string(attr, "fmri", v->gv_name) != 0 ||
            nvlist_add_uint32(attr, "reason-version",
            restarter_str_version()) || nvlist_add_string(attr, "reason-short",
            restarter_get_str_short(reason)) != 0 ||
            nvlist_add_string(attr, "reason-long",
            restarter_get_str_long(reason)) != 0 ||
            nvlist_add_int32(attr, "transition", stn_transition) != 0) {
                log_framework(LOG_WARNING,
                    "FMEV: %s could not create nvlist for transition "
                    "event: %s\n", v->gv_name, strerror(errno));
                nvlist_free(attr);
                return;
        }

        if (fmev_rspublish_nvl(FMEV_RULESET_SMF, "state-transition",
            instance_state_str[new_state], pri, attr) != FMEV_SUCCESS) {
                log_framework(LOG_DEBUG,
                    "FMEV: %s failed to publish transition event: %s\n",
                    v->gv_name, fmev_strerror(fmev_errno));
                nvlist_free(attr);
        }
}

/*
 * Find the vertex for inst_name.  If it doesn't exist, return ENOENT.
 * Otherwise set its state to state.  If the instance has entered a state
 * which requires automatic action, take it (Uninitialized: do
 * dgraph_refresh_instance() without the snapshot update.  Disabled: if the
 * instance should be enabled, send _ENABLE.  Offline: if the instance should
 * be disabled, send _DISABLE, and if its dependencies are satisfied, send
 * _START.  Online, Degraded: if the instance wasn't running, update its start
 * snapshot.  Maintenance: no action.)
 *
 * Also fails with ECONNABORTED, or EINVAL if state is invalid.
 */
static int
dgraph_set_instance_state(scf_handle_t *h, const char *inst_name,
    protocol_states_t *states)
{
        graph_vertex_t *v;
        int err = 0;
        restarter_instance_state_t old_state;
        restarter_instance_state_t state = states->ps_state;
        restarter_error_t serr = states->ps_err;

        MUTEX_LOCK(&dgraph_lock);

        v = vertex_get_by_name(inst_name);
        if (v == NULL) {
                MUTEX_UNLOCK(&dgraph_lock);
                return (ENOENT);
        }

        assert(v->gv_type == GVT_INST);

        switch (state) {
        case RESTARTER_STATE_UNINIT:
        case RESTARTER_STATE_DISABLED:
        case RESTARTER_STATE_OFFLINE:
        case RESTARTER_STATE_ONLINE:
        case RESTARTER_STATE_DEGRADED:
        case RESTARTER_STATE_MAINT:
                break;

        default:
                MUTEX_UNLOCK(&dgraph_lock);
                return (EINVAL);
        }

        log_framework(LOG_DEBUG, "Graph noting %s %s -> %s.\n", v->gv_name,
            instance_state_str[v->gv_state], instance_state_str[state]);

        old_state = v->gv_state;
        v->gv_state = state;

        v->gv_reason = states->ps_reason;
        err = gt_transition(h, v, serr, old_state);
        if (err == 0 && v->gv_state != old_state) {
                dgraph_state_transition_notify(v, old_state, states->ps_reason);
        }

        MUTEX_UNLOCK(&dgraph_lock);
        return (err);
}

/*
 * Handle state changes during milestone shutdown.  See
 * dgraph_set_milestone().  If the repository connection is broken,
 * ECONNABORTED will be returned, though a _DISABLE command will be sent for
 * the vertex anyway.
 */
int
vertex_subgraph_dependencies_shutdown(scf_handle_t *h, graph_vertex_t *v,
    restarter_instance_state_t old_state)
{
        int was_up, now_up;
        int ret = 0;

        assert(v->gv_type == GVT_INST);

        /* Don't care if we're not going to a milestone. */
        if (milestone == NULL)
                return (0);

        /* Don't care if we already finished coming down. */
        if (non_subgraph_svcs == 0)
                return (0);

        /* Don't care if the service is in the subgraph. */
        if (v->gv_flags & GV_INSUBGRAPH)
                return (0);

        /*
         * Update non_subgraph_svcs.  It is the number of non-subgraph
         * services which are in online, degraded, or offline.
         */

        was_up = up_state(old_state);
        now_up = up_state(v->gv_state);

        if (!was_up && now_up) {
                ++non_subgraph_svcs;
        } else if (was_up && !now_up) {
                --non_subgraph_svcs;

                if (non_subgraph_svcs == 0) {
                        if (halting != -1) {
                                do_uadmin();
                        } else if (go_single_user_mode || go_to_level1) {
                                (void) startd_thread_create(single_user_thread,
                                    NULL);
                        }
                        return (0);
                }
        }

        /* If this service is a leaf, it should be disabled. */
        if ((v->gv_flags & GV_ENABLED) && is_nonsubgraph_leaf(v)) {
                int r;

                r = disable_service_temporarily(v, h);
                switch (r) {
                case 0:
                        break;

                case ECONNABORTED:
                        ret = ECONNABORTED;
                        break;

                default:
                        bad_error("disable_service_temporarily", r);
                }
        }

        /*
         * If the service just came down, propagate the disable to the newly
         * exposed leaves.
         */
        if (was_up && !now_up)
                graph_walk_dependencies(v, disable_nonsubgraph_leaves,
                    (void *)h);

        return (ret);
}

/*
 * Decide whether to start up an sulogin thread after a service is
 * finished changing state.  Only need to do the full can_come_up()
 * evaluation if an instance is changing state, we're not halfway through
 * loading the thread, and we aren't shutting down or going to the single
 * user milestone.
 */
void
graph_transition_sulogin(restarter_instance_state_t state,
    restarter_instance_state_t old_state)
{
        assert(MUTEX_HELD(&dgraph_lock));

        if (state != old_state && st->st_load_complete &&
            !go_single_user_mode && !go_to_level1 &&
            halting == -1) {
                if (!sulogin_thread_running && !can_come_up()) {
                        (void) startd_thread_create(sulogin_thread, NULL);
                        sulogin_thread_running = B_TRUE;
                }
        }
}

/*
 * Propagate a start, stop event, or a satisfiability event.
 *
 * PROPAGATE_START and PROPAGATE_STOP simply propagate the transition event
 * to direct dependents.  PROPAGATE_SAT propagates a start then walks the
 * full dependent graph to check for newly satisfied nodes.  This is
 * necessary for cases when non-direct dependents may be effected but direct
 * dependents may not (e.g. for optional_all evaluations, see the
 * propagate_satbility() comments).
 *
 * PROPAGATE_SAT should be used whenever a non-running service moves into
 * a state which can satisfy optional dependencies, like disabled or
 * maintenance.
 */
void
graph_transition_propagate(graph_vertex_t *v, propagate_event_t type,
    restarter_error_t rerr)
{
        if (type == PROPAGATE_STOP) {
                graph_walk_dependents(v, propagate_stop, (void *)rerr);
        } else if (type == PROPAGATE_START || type == PROPAGATE_SAT) {
                graph_walk_dependents(v, propagate_start, (void *)RERR_NONE);

                if (type == PROPAGATE_SAT)
                        propagate_satbility(v);
        } else {
#ifndef NDEBUG
                uu_warn("%s:%d: Unexpected type value %d.\n",  __FILE__,
                    __LINE__, type);
#endif
                abort();
        }
}

/*
 * If a vertex for fmri exists and it is enabled, send _DISABLE to the
 * restarter.  If it is running, send _STOP.  Send _REMOVE_INSTANCE.  Delete
 * all property group dependencies, and the dependency on the restarter,
 * disposing of vertices as appropriate.  If other vertices depend on this
 * one, mark it unconfigured and return.  Otherwise remove the vertex.  Always
 * returns 0.
 */
static int
dgraph_remove_instance(const char *fmri, scf_handle_t *h)
{
        graph_vertex_t *v;
        graph_edge_t *e;
        uu_list_t *old_deps;
        int err;

        log_framework(LOG_DEBUG, "Graph engine: Removing %s.\n", fmri);

        MUTEX_LOCK(&dgraph_lock);

        v = vertex_get_by_name(fmri);
        if (v == NULL) {
                MUTEX_UNLOCK(&dgraph_lock);
                return (0);
        }

        /* Send restarter delete event. */
        if (v->gv_flags & GV_CONFIGURED)
                graph_unset_restarter(v);

        if (milestone > MILESTONE_NONE) {
                /*
                 * Make a list of v's current dependencies so we can
                 * reevaluate their GV_INSUBGRAPH flags after the dependencies
                 * are removed.
                 */
                old_deps = startd_list_create(graph_edge_pool, NULL, 0);

                err = uu_list_walk(v->gv_dependencies,
                    (uu_walk_fn_t *)append_svcs_or_insts, old_deps, 0);
                assert(err == 0);
        }

        delete_instance_dependencies(v, B_TRUE);

        /*
         * Deleting an instance can both satisfy and unsatisfy dependencies,
         * depending on their type.  First propagate the stop as a RERR_RESTART
         * event -- deletion isn't a fault, just a normal stop.  This gives
         * dependent services the chance to do a clean shutdown.  Then, mark
         * the service as unconfigured and propagate the start event for the
         * optional_all dependencies that might have become satisfied.
         */
        graph_walk_dependents(v, propagate_stop, (void *)RERR_RESTART);

        v->gv_flags &= ~GV_CONFIGURED;
        v->gv_flags &= ~GV_DEATHROW;

        graph_walk_dependents(v, propagate_start, (void *)RERR_NONE);
        propagate_satbility(v);

        /*
         * If there are no (non-service) dependents, the vertex can be
         * completely removed.
         */
        if (v != milestone && v->gv_refs == 0 &&
            uu_list_numnodes(v->gv_dependents) == 1)
                remove_inst_vertex(v);

        if (milestone > MILESTONE_NONE) {
                void *cookie = NULL;

                while ((e = uu_list_teardown(old_deps, &cookie)) != NULL) {
                        v = e->ge_vertex;

                        if (vertex_unref(v) == VERTEX_INUSE)
                                while (eval_subgraph(v, h) == ECONNABORTED)
                                        libscf_handle_rebind(h);

                        startd_free(e, sizeof (*e));
                }

                uu_list_destroy(old_deps);
        }

        MUTEX_UNLOCK(&dgraph_lock);

        return (0);
}

/*
 * Return the eventual (maybe current) milestone in the form of a
 * legacy runlevel.
 */
static char
target_milestone_as_runlevel()
{
        assert(MUTEX_HELD(&dgraph_lock));

        if (milestone == NULL)
                return ('3');
        else if (milestone == MILESTONE_NONE)
                return ('0');

        if (strcmp(milestone->gv_name, multi_user_fmri) == 0)
                return ('2');
        else if (strcmp(milestone->gv_name, single_user_fmri) == 0)
                return ('S');
        else if (strcmp(milestone->gv_name, multi_user_svr_fmri) == 0)
                return ('3');

#ifndef NDEBUG
        (void) fprintf(stderr, "%s:%d: Unknown milestone name \"%s\".\n",
            __FILE__, __LINE__, milestone->gv_name);
#endif
        abort();
        /* NOTREACHED */
}

static struct {
        char    rl;
        int     sig;
} init_sigs[] = {
        { 'S', SIGBUS },
        { '0', SIGINT },
        { '1', SIGQUIT },
        { '2', SIGILL },
        { '3', SIGTRAP },
        { '4', SIGIOT },
        { '5', SIGEMT },
        { '6', SIGFPE },
        { 0, 0 }
};

static void
signal_init(char rl)
{
        pid_t init_pid;
        int i;

        assert(MUTEX_HELD(&dgraph_lock));

        if (zone_getattr(getzoneid(), ZONE_ATTR_INITPID, &init_pid,
            sizeof (init_pid)) != sizeof (init_pid)) {
                log_error(LOG_NOTICE, "Could not get pid to signal init.\n");
                return;
        }

        for (i = 0; init_sigs[i].rl != 0; ++i)
                if (init_sigs[i].rl == rl)
                        break;

        if (init_sigs[i].rl != 0) {
                if (kill(init_pid, init_sigs[i].sig) != 0) {
                        switch (errno) {
                        case EPERM:
                        case ESRCH:
                                log_error(LOG_NOTICE, "Could not signal init: "
                                    "%s.\n", strerror(errno));
                                break;

                        case EINVAL:
                        default:
                                bad_error("kill", errno);
                        }
                }
        }
}

/*
 * This is called when one of the major milestones changes state, or when
 * init is signalled and tells us it was told to change runlevel.  We wait
 * to reach the milestone because this allows /etc/inittab entries to retain
 * some boot ordering: historically, entries could place themselves before/after
 * the running of /sbin/rcX scripts but we can no longer make the
 * distinction because the /sbin/rcX scripts no longer exist as punctuation
 * marks in /etc/inittab.
 *
 * Also, we only trigger an update when we reach the eventual target
 * milestone: without this, an /etc/inittab entry marked only for
 * runlevel 2 would be executed for runlevel 3, which is not how
 * /etc/inittab entries work.
 *
 * If we're single user coming online, then we set utmpx to the target
 * runlevel so that legacy scripts can work as expected.
 */
static void
graph_runlevel_changed(char rl, int online)
{
        char trl;

        assert(MUTEX_HELD(&dgraph_lock));

        trl = target_milestone_as_runlevel();

        if (online) {
                if (rl == trl) {
                        current_runlevel = trl;
                        signal_init(trl);
                } else if (rl == 'S') {
                        /*
                         * At boot, set the entry early for the benefit of the
                         * legacy init scripts.
                         */
                        utmpx_set_runlevel(trl, 'S', B_FALSE);
                }
        } else {
                if (rl == '3' && trl == '2') {
                        current_runlevel = trl;
                        signal_init(trl);
                } else if (rl == '2' && trl == 'S') {
                        current_runlevel = trl;
                        signal_init(trl);
                }
        }
}

/*
 * Move to a backwards-compatible runlevel by executing the appropriate
 * /etc/rc?.d/K* scripts and/or setting the milestone.
 *
 * Returns
 *   0 - success
 *   ECONNRESET - success, but handle was reset
 *   ECONNABORTED - repository connection broken
 *   ECANCELED - pg was deleted
 */
static int
dgraph_set_runlevel(scf_propertygroup_t *pg, scf_property_t *prop)
{
        char rl;
        scf_handle_t *h;
        int r;
        const char *ms = NULL;  /* what to commit as options/milestone */
        boolean_t rebound = B_FALSE;
        int mark_rl = 0;

        const char * const stop = "stop";

        r = libscf_extract_runlevel(prop, &rl);
        switch (r) {
        case 0:
                break;

        case ECONNABORTED:
        case ECANCELED:
                return (r);

        case EINVAL:
        case ENOENT:
                log_error(LOG_WARNING, "runlevel property is misconfigured; "
                    "ignoring.\n");
                /* delete the bad property */
                goto nolock_out;

        default:
                bad_error("libscf_extract_runlevel", r);
        }

        switch (rl) {
        case 's':
                rl = 'S';
                /* FALLTHROUGH */

        case 'S':
        case '2':
        case '3':
                /*
                 * These cases cause a milestone change, so
                 * graph_runlevel_changed() will eventually deal with
                 * signalling init.
                 */
                break;

        case '0':
        case '1':
        case '4':
        case '5':
        case '6':
                mark_rl = 1;
                break;

        default:
                log_framework(LOG_NOTICE, "Unknown runlevel '%c'.\n", rl);
                ms = NULL;
                goto nolock_out;
        }

        h = scf_pg_handle(pg);

        MUTEX_LOCK(&dgraph_lock);

        /*
         * Since this triggers no milestone changes, force it by hand.
         */
        if (current_runlevel == '4' && rl == '3')
                mark_rl = 1;

        /*
         * 1. If we are here after an "init X":
         *
         * init X
         *      init/lscf_set_runlevel()
         *              process_pg_event()
         *              dgraph_set_runlevel()
         *
         * then we haven't passed through graph_runlevel_changed() yet,
         * therefore 'current_runlevel' has not changed for sure but 'rl' has.
         * In consequence, if 'rl' is lower than 'current_runlevel', we change
         * the system runlevel and execute the appropriate /etc/rc?.d/K* scripts
         * past this test.
         *
         * 2. On the other hand, if we are here after a "svcadm milestone":
         *
         * svcadm milestone X
         *      dgraph_set_milestone()
         *              handle_graph_update_event()
         *              dgraph_set_instance_state()
         *              graph_post_X_[online|offline]()
         *              graph_runlevel_changed()
         *              signal_init()
         *                      init/lscf_set_runlevel()
         *                              process_pg_event()
         *                              dgraph_set_runlevel()
         *
         * then we already passed through graph_runlevel_changed() (by the way
         * of dgraph_set_milestone()) and 'current_runlevel' may have changed
         * and already be equal to 'rl' so we are going to return immediately
         * from dgraph_set_runlevel() without changing the system runlevel and
         * without executing the /etc/rc?.d/K* scripts.
         */
        if (rl == current_runlevel) {
                ms = NULL;
                goto out;
        }

        log_framework(LOG_DEBUG, "Changing to runlevel '%c'.\n", rl);

        /*
         * Make sure stop rc scripts see the new settings via who -r.
         */
        utmpx_set_runlevel(rl, current_runlevel, B_TRUE);

        /*
         * Some run levels don't have a direct correspondence to any
         * milestones, so we have to signal init directly.
         */
        if (mark_rl) {
                current_runlevel = rl;
                signal_init(rl);
        }

        switch (rl) {
        case 'S':
                uu_warn("The system is coming down for administration.  "
                    "Please wait.\n");
                fork_rc_script(rl, stop, B_FALSE);
                ms = single_user_fmri;
                go_single_user_mode = B_TRUE;
                break;

        case '0':
                halting_time = time(NULL);
                fork_rc_script(rl, stop, B_TRUE);
                halting = AD_HALT;
                goto uadmin;

        case '5':
                halting_time = time(NULL);
                fork_rc_script(rl, stop, B_TRUE);
                halting = AD_POWEROFF;
                goto uadmin;

        case '6':
                halting_time = time(NULL);
                fork_rc_script(rl, stop, B_TRUE);
                if (scf_is_fastboot_default() && getzoneid() == GLOBAL_ZONEID)
                        halting = AD_FASTREBOOT;
                else
                        halting = AD_BOOT;

uadmin:
                uu_warn("The system is coming down.  Please wait.\n");
                ms = "none";

                /*
                 * We can't wait until all services are offline since this
                 * thread is responsible for taking them offline.  Instead we
                 * set halting to the second argument for uadmin() and call
                 * do_uadmin() from dgraph_set_instance_state() when
                 * appropriate.
                 */
                break;

        case '1':
                if (current_runlevel != 'S') {
                        uu_warn("Changing to state 1.\n");
                        fork_rc_script(rl, stop, B_FALSE);
                } else {
                        uu_warn("The system is coming up for administration.  "
                            "Please wait.\n");
                }
                ms = single_user_fmri;
                go_to_level1 = B_TRUE;
                break;

        case '2':
                if (current_runlevel == '3' || current_runlevel == '4')
                        fork_rc_script(rl, stop, B_FALSE);
                ms = multi_user_fmri;
                break;

        case '3':
        case '4':
                ms = "all";
                break;

        default:
#ifndef NDEBUG
                (void) fprintf(stderr, "%s:%d: Uncaught case %d ('%c').\n",
                    __FILE__, __LINE__, rl, rl);
#endif
                abort();
        }

out:
        MUTEX_UNLOCK(&dgraph_lock);

nolock_out:
        switch (r = libscf_clear_runlevel(pg, ms)) {
        case 0:
                break;

        case ECONNABORTED:
                libscf_handle_rebind(h);
                rebound = B_TRUE;
                goto nolock_out;

        case ECANCELED:
                break;

        case EPERM:
        case EACCES:
        case EROFS:
                log_error(LOG_NOTICE, "Could not delete \"%s/%s\" property: "
                    "%s.\n", SCF_PG_OPTIONS, "runlevel", strerror(r));
                break;

        default:
                bad_error("libscf_clear_runlevel", r);
        }

        return (rebound ? ECONNRESET : 0);
}

/*
 * mark_subtree walks the dependents and add the GV_TOOFFLINE flag
 * to the instances that are supposed to go offline during an
 * administrative disable operation.
 */
static int
mark_subtree(graph_edge_t *e, void *arg)
{
        graph_vertex_t *v;
        int r;

        v = e->ge_vertex;

        /* If it's already in the subgraph, skip. */
        if (v->gv_flags & GV_TOOFFLINE)
                return (UU_WALK_NEXT);

        switch (v->gv_type) {
        case GVT_INST:
                /* If the instance is already offline, skip it. */
                if (!inst_running(v))
                        return (UU_WALK_NEXT);

                v->gv_flags |= GV_TOOFFLINE;
                log_framework(LOG_DEBUG, "%s added to subtree\n", v->gv_name);
                break;
        case GVT_GROUP:
                /*
                 * Skip all excluded dependents and decide whether to offline
                 * the service based on the restart_on attribute.
                 */
                if (is_depgrp_bypassed(v))
                        return (UU_WALK_NEXT);
                break;
        }

        r = uu_list_walk(v->gv_dependents, (uu_walk_fn_t *)mark_subtree, arg,
            0);
        assert(r == 0);
        return (UU_WALK_NEXT);
}

static int
mark_subgraph(graph_edge_t *e, void *arg)
{
        graph_vertex_t *v;
        int r;
        int optional = (int)arg;

        v = e->ge_vertex;

        /* If it's already in the subgraph, skip. */
        if (v->gv_flags & GV_INSUBGRAPH)
                return (UU_WALK_NEXT);

        /*
         * Keep track if walk has entered an optional dependency group
         */
        if (v->gv_type == GVT_GROUP && v->gv_depgroup == DEPGRP_OPTIONAL_ALL) {
                optional = 1;
        }
        /*
         * Quit if we are in an optional dependency group and the instance
         * is disabled
         */
        if (optional && (v->gv_type == GVT_INST) &&
            (!(v->gv_flags & GV_ENBLD_NOOVR)))
                return (UU_WALK_NEXT);

        v->gv_flags |= GV_INSUBGRAPH;

        /* Skip all excluded dependencies. */
        if (v->gv_type == GVT_GROUP && v->gv_depgroup == DEPGRP_EXCLUDE_ALL)
                return (UU_WALK_NEXT);

        r = uu_list_walk(v->gv_dependencies, (uu_walk_fn_t *)mark_subgraph,
            (void *)optional, 0);
        assert(r == 0);
        return (UU_WALK_NEXT);
}

/*
 * Bring down all services which are not dependencies of fmri.  The
 * dependencies of fmri (direct & indirect) will constitute the "subgraph",
 * and will have the GV_INSUBGRAPH flag set.  The rest must be brought down,
 * which means the state is "disabled", "maintenance", or "uninitialized".  We
 * could consider "offline" to be down, and refrain from sending start
 * commands for such services, but that's not strictly necessary, so we'll
 * decline to intrude on the state machine.  It would probably confuse users
 * anyway.
 *
 * The services should be brought down in reverse-dependency order, so we
 * can't do it all at once here.  We initiate by override-disabling the leaves
 * of the dependency tree -- those services which are up but have no
 * dependents which are up.  When they come down,
 * vertex_subgraph_dependencies_shutdown() will override-disable the newly
 * exposed leaves.  Perseverance will ensure completion.
 *
 * Sometimes we need to take action when the transition is complete, like
 * start sulogin or halt the system.  To tell when we're done, we initialize
 * non_subgraph_svcs here to be the number of services which need to come
 * down.  As each does, we decrement the counter.  When it hits zero, we take
 * the appropriate action.  See vertex_subgraph_dependencies_shutdown().
 *
 * In case we're coming up, we also remove any enable-overrides for the
 * services which are dependencies of fmri.
 *
 * If norepository is true, the function will not change the repository.
 *
 * The decision to change the system run level in accordance with the milestone
 * is taken in dgraph_set_runlevel().
 *
 * Returns
 *   0 - success
 *   ECONNRESET - success, but handle was rebound
 *   EINVAL - fmri is invalid (error is logged)
 *   EALREADY - the milestone is already set to fmri
 *   ENOENT - a configured vertex does not exist for fmri (an error is logged)
 */
static int
dgraph_set_milestone(const char *fmri, scf_handle_t *h, boolean_t norepository)
{
        const char *cfmri, *fs;
        graph_vertex_t *nm, *v;
        int ret = 0, r;
        scf_instance_t *inst;
        boolean_t isall, isnone, rebound = B_FALSE;

        /* Validate fmri */
        isall = (strcmp(fmri, "all") == 0);
        isnone = (strcmp(fmri, "none") == 0);

        if (!isall && !isnone) {
                if (fmri_canonify(fmri, (char **)&cfmri, B_FALSE) == EINVAL)
                        goto reject;

                if (strcmp(cfmri, single_user_fmri) != 0 &&
                    strcmp(cfmri, multi_user_fmri) != 0 &&
                    strcmp(cfmri, multi_user_svr_fmri) != 0) {
                        startd_free((void *)cfmri, max_scf_fmri_size);
reject:
                        log_framework(LOG_WARNING,
                            "Rejecting request for invalid milestone \"%s\".\n",
                            fmri);
                        return (EINVAL);
                }
        }

        inst = safe_scf_instance_create(h);

        MUTEX_LOCK(&dgraph_lock);

        if (milestone == NULL) {
                if (isall) {
                        log_framework(LOG_DEBUG,
                            "Milestone already set to all.\n");
                        ret = EALREADY;
                        goto out;
                }
        } else if (milestone == MILESTONE_NONE) {
                if (isnone) {
                        log_framework(LOG_DEBUG,
                            "Milestone already set to none.\n");
                        ret = EALREADY;
                        goto out;
                }
        } else {
                if (!isall && !isnone &&
                    strcmp(cfmri, milestone->gv_name) == 0) {
                        log_framework(LOG_DEBUG,
                            "Milestone already set to %s.\n", cfmri);
                        ret = EALREADY;
                        goto out;
                }
        }

        if (!isall && !isnone) {
                nm = vertex_get_by_name(cfmri);
                if (nm == NULL || !(nm->gv_flags & GV_CONFIGURED)) {
                        log_framework(LOG_WARNING, "Cannot set milestone to %s "
                            "because no such service exists.\n", cfmri);
                        ret = ENOENT;
                        goto out;
                }
        }

        log_framework(LOG_DEBUG, "Changing milestone to %s.\n", fmri);

        /*
         * Set milestone, removing the old one if this was the last reference.
         */
        if (milestone > MILESTONE_NONE)
                (void) vertex_unref(milestone);

        if (isall)
                milestone = NULL;
        else if (isnone)
                milestone = MILESTONE_NONE;
        else {
                milestone = nm;
                /* milestone should count as a reference */
                vertex_ref(milestone);
        }

        /* Clear all GV_INSUBGRAPH bits. */
        for (v = uu_list_first(dgraph); v != NULL; v = uu_list_next(dgraph, v))
                v->gv_flags &= ~GV_INSUBGRAPH;

        if (!isall && !isnone) {
                /* Set GV_INSUBGRAPH for milestone & descendents. */
                milestone->gv_flags |= GV_INSUBGRAPH;

                r = uu_list_walk(milestone->gv_dependencies,
                    (uu_walk_fn_t *)mark_subgraph, NULL, 0);
                assert(r == 0);
        }

        /* Un-override services in the subgraph & override-disable the rest. */
        if (norepository)
                goto out;

        non_subgraph_svcs = 0;
        for (v = uu_list_first(dgraph);
            v != NULL;
            v = uu_list_next(dgraph, v)) {
                if (v->gv_type != GVT_INST ||
                    (v->gv_flags & GV_CONFIGURED) == 0)
                        continue;

again:
                r = scf_handle_decode_fmri(h, v->gv_name, NULL, NULL, inst,
                    NULL, NULL, SCF_DECODE_FMRI_EXACT);
                if (r != 0) {
                        switch (scf_error()) {
                        case SCF_ERROR_CONNECTION_BROKEN:
                        default:
                                libscf_handle_rebind(h);
                                rebound = B_TRUE;
                                goto again;

                        case SCF_ERROR_NOT_FOUND:
                                continue;

                        case SCF_ERROR_HANDLE_MISMATCH:
                        case SCF_ERROR_INVALID_ARGUMENT:
                        case SCF_ERROR_CONSTRAINT_VIOLATED:
                        case SCF_ERROR_NOT_BOUND:
                                bad_error("scf_handle_decode_fmri",
                                    scf_error());
                        }
                }

                if (isall || (v->gv_flags & GV_INSUBGRAPH)) {
                        r = libscf_delete_enable_ovr(inst);
                        fs = "libscf_delete_enable_ovr";
                } else {
                        assert(isnone || (v->gv_flags & GV_INSUBGRAPH) == 0);

                        /*
                         * Services which are up need to come down before
                         * we're done, but we can only disable the leaves
                         * here.
                         */

                        if (up_state(v->gv_state))
                                ++non_subgraph_svcs;

                        /* If it's already disabled, don't bother. */
                        if ((v->gv_flags & GV_ENABLED) == 0)
                                continue;

                        if (!is_nonsubgraph_leaf(v))
                                continue;

                        r = libscf_set_enable_ovr(inst, 0);
                        fs = "libscf_set_enable_ovr";
                }
                switch (r) {
                case 0:
                case ECANCELED:
                        break;

                case ECONNABORTED:
                        libscf_handle_rebind(h);
                        rebound = B_TRUE;
                        goto again;

                case EPERM:
                case EROFS:
                        log_error(LOG_WARNING,
                            "Could not set %s/%s for %s: %s.\n",
                            SCF_PG_GENERAL_OVR, SCF_PROPERTY_ENABLED,
                            v->gv_name, strerror(r));
                        break;

                default:
                        bad_error(fs, r);
                }
        }

        if (halting != -1) {
                if (non_subgraph_svcs > 1)
                        uu_warn("%d system services are now being stopped.\n",
                            non_subgraph_svcs);
                else if (non_subgraph_svcs == 1)
                        uu_warn("One system service is now being stopped.\n");
                else if (non_subgraph_svcs == 0)
                        do_uadmin();
        }

        ret = rebound ? ECONNRESET : 0;

out:
        MUTEX_UNLOCK(&dgraph_lock);
        if (!isall && !isnone)
                startd_free((void *)cfmri, max_scf_fmri_size);
        scf_instance_destroy(inst);
        return (ret);
}


/*
 * Returns 0, ECONNABORTED, or EINVAL.
 */
static int
handle_graph_update_event(scf_handle_t *h, graph_protocol_event_t *e)
{
        int r;

        switch (e->gpe_type) {
        case GRAPH_UPDATE_RELOAD_GRAPH:
                log_error(LOG_WARNING,
                    "graph_event: reload graph unimplemented\n");
                break;

        case GRAPH_UPDATE_STATE_CHANGE: {
                protocol_states_t *states = e->gpe_data;

                switch (r = dgraph_set_instance_state(h, e->gpe_inst, states)) {
                case 0:
                case ENOENT:
                        break;

                case ECONNABORTED:
                        return (ECONNABORTED);

                case EINVAL:
                default:
#ifndef NDEBUG
                        (void) fprintf(stderr, "dgraph_set_instance_state() "
                            "failed with unexpected error %d at %s:%d.\n", r,
                            __FILE__, __LINE__);
#endif
                        abort();
                }

                startd_free(states, sizeof (protocol_states_t));
                break;
        }

        default:
                log_error(LOG_WARNING,
                    "graph_event_loop received an unknown event: %d\n",
                    e->gpe_type);
                break;
        }

        return (0);
}

/*
 * graph_event_thread()
 *    Wait for state changes from the restarters.
 */
/*ARGSUSED*/
void *
graph_event_thread(void *unused)
{
        scf_handle_t *h;
        int err;

        h = libscf_handle_create_bound_loop();

        /*CONSTCOND*/
        while (1) {
                graph_protocol_event_t *e;

                MUTEX_LOCK(&gu->gu_lock);

                while (gu->gu_wakeup == 0)
                        (void) pthread_cond_wait(&gu->gu_cv, &gu->gu_lock);

                gu->gu_wakeup = 0;

                while ((e = graph_event_dequeue()) != NULL) {
                        MUTEX_LOCK(&e->gpe_lock);
                        MUTEX_UNLOCK(&gu->gu_lock);

                        while ((err = handle_graph_update_event(h, e)) ==
                            ECONNABORTED)
                                libscf_handle_rebind(h);

                        if (err == 0)
                                graph_event_release(e);
                        else
                                graph_event_requeue(e);

                        MUTEX_LOCK(&gu->gu_lock);
                }

                MUTEX_UNLOCK(&gu->gu_lock);
        }

        /*
         * Unreachable for now -- there's currently no graceful cleanup
         * called on exit().
         */
        MUTEX_UNLOCK(&gu->gu_lock);
        scf_handle_destroy(h);
        return (NULL);
}

static void
set_initial_milestone(scf_handle_t *h)
{
        scf_instance_t *inst;
        char *fmri, *cfmri;
        size_t sz;
        int r;

        inst = safe_scf_instance_create(h);
        fmri = startd_alloc(max_scf_fmri_size);

        /*
         * If -m milestone= was specified, we want to set options_ovr/milestone
         * to it.  Otherwise we want to read what the milestone should be set
         * to.  Either way we need our inst.
         */
get_self:
        if (scf_handle_decode_fmri(h, SCF_SERVICE_STARTD, NULL, NULL, inst,
            NULL, NULL, SCF_DECODE_FMRI_EXACT) != 0) {
                switch (scf_error()) {
                case SCF_ERROR_CONNECTION_BROKEN:
                        libscf_handle_rebind(h);
                        goto get_self;

                case SCF_ERROR_NOT_FOUND:
                        if (st->st_subgraph != NULL &&
                            st->st_subgraph[0] != '\0') {
                                sz = strlcpy(fmri, st->st_subgraph,
                                    max_scf_fmri_size);
                                assert(sz < max_scf_fmri_size);
                        } else {
                                fmri[0] = '\0';
                        }
                        break;

                case SCF_ERROR_INVALID_ARGUMENT:
                case SCF_ERROR_CONSTRAINT_VIOLATED:
                case SCF_ERROR_HANDLE_MISMATCH:
                default:
                        bad_error("scf_handle_decode_fmri", scf_error());
                }
        } else {
                if (st->st_subgraph != NULL && st->st_subgraph[0] != '\0') {
                        scf_propertygroup_t *pg;

                        pg = safe_scf_pg_create(h);

                        sz = strlcpy(fmri, st->st_subgraph, max_scf_fmri_size);
                        assert(sz < max_scf_fmri_size);

                        r = libscf_inst_get_or_add_pg(inst, SCF_PG_OPTIONS_OVR,
                            SCF_PG_OPTIONS_OVR_TYPE, SCF_PG_OPTIONS_OVR_FLAGS,
                            pg);
                        switch (r) {
                        case 0:
                                break;

                        case ECONNABORTED:
                                libscf_handle_rebind(h);
                                goto get_self;

                        case EPERM:
                        case EACCES:
                        case EROFS:
                                log_error(LOG_WARNING, "Could not set %s/%s: "
                                    "%s.\n", SCF_PG_OPTIONS_OVR,
                                    SCF_PROPERTY_MILESTONE, strerror(r));
                                /* FALLTHROUGH */

                        case ECANCELED:
                                sz = strlcpy(fmri, st->st_subgraph,
                                    max_scf_fmri_size);
                                assert(sz < max_scf_fmri_size);
                                break;

                        default:
                                bad_error("libscf_inst_get_or_add_pg", r);
                        }

                        r = libscf_clear_runlevel(pg, fmri);
                        switch (r) {
                        case 0:
                                break;

                        case ECONNABORTED:
                                libscf_handle_rebind(h);
                                goto get_self;

                        case EPERM:
                        case EACCES:
                        case EROFS:
                                log_error(LOG_WARNING, "Could not set %s/%s: "
                                    "%s.\n", SCF_PG_OPTIONS_OVR,
                                    SCF_PROPERTY_MILESTONE, strerror(r));
                                /* FALLTHROUGH */

                        case ECANCELED:
                                sz = strlcpy(fmri, st->st_subgraph,
                                    max_scf_fmri_size);
                                assert(sz < max_scf_fmri_size);
                                break;

                        default:
                                bad_error("libscf_clear_runlevel", r);
                        }

                        scf_pg_destroy(pg);
                } else {
                        scf_property_t *prop;
                        scf_value_t *val;

                        prop = safe_scf_property_create(h);
                        val = safe_scf_value_create(h);

                        r = libscf_get_milestone(inst, prop, val, fmri,
                            max_scf_fmri_size);
                        switch (r) {
                        case 0:
                                break;

                        case ECONNABORTED:
                                libscf_handle_rebind(h);
                                goto get_self;

                        case EINVAL:
                                log_error(LOG_WARNING, "Milestone property is "
                                    "misconfigured.  Defaulting to \"all\".\n");
                                /* FALLTHROUGH */

                        case ECANCELED:
                        case ENOENT:
                                fmri[0] = '\0';
                                break;

                        default:
                                bad_error("libscf_get_milestone", r);
                        }

                        scf_value_destroy(val);
                        scf_property_destroy(prop);
                }
        }

        if (fmri[0] == '\0' || strcmp(fmri, "all") == 0)
                goto out;

        if (strcmp(fmri, "none") != 0) {
retry:
                if (scf_handle_decode_fmri(h, fmri, NULL, NULL, inst, NULL,
                    NULL, SCF_DECODE_FMRI_EXACT) != 0) {
                        switch (scf_error()) {
                        case SCF_ERROR_INVALID_ARGUMENT:
                                log_error(LOG_WARNING,
                                    "Requested milestone \"%s\" is invalid.  "
                                    "Reverting to \"all\".\n", fmri);
                                goto out;

                        case SCF_ERROR_CONSTRAINT_VIOLATED:
                                log_error(LOG_WARNING, "Requested milestone "
                                    "\"%s\" does not specify an instance.  "
                                    "Reverting to \"all\".\n", fmri);
                                goto out;

                        case SCF_ERROR_CONNECTION_BROKEN:
                                libscf_handle_rebind(h);
                                goto retry;

                        case SCF_ERROR_NOT_FOUND:
                                log_error(LOG_WARNING, "Requested milestone "
                                    "\"%s\" not in repository.  Reverting to "
                                    "\"all\".\n", fmri);
                                goto out;

                        case SCF_ERROR_HANDLE_MISMATCH:
                        default:
                                bad_error("scf_handle_decode_fmri",
                                    scf_error());
                        }
                }

                r = fmri_canonify(fmri, &cfmri, B_FALSE);
                assert(r == 0);

                r = dgraph_add_instance(cfmri, inst, B_TRUE);
                startd_free(cfmri, max_scf_fmri_size);
                switch (r) {
                case 0:
                        break;

                case ECONNABORTED:
                        goto retry;

                case EINVAL:
                        log_error(LOG_WARNING,
                            "Requested milestone \"%s\" is invalid.  "
                            "Reverting to \"all\".\n", fmri);
                        goto out;

                case ECANCELED:
                        log_error(LOG_WARNING,
                            "Requested milestone \"%s\" not "
                            "in repository.  Reverting to \"all\".\n",
                            fmri);
                        goto out;

                case EEXIST:
                default:
                        bad_error("dgraph_add_instance", r);
                }
        }

        log_console(LOG_INFO, "Booting to milestone \"%s\".\n", fmri);

        r = dgraph_set_milestone(fmri, h, B_FALSE);
        switch (r) {
        case 0:
        case ECONNRESET:
        case EALREADY:
                break;

        case EINVAL:
        case ENOENT:
        default:
                bad_error("dgraph_set_milestone", r);
        }

out:
        startd_free(fmri, max_scf_fmri_size);
        scf_instance_destroy(inst);
}

void
set_restart_milestone(scf_handle_t *h)
{
        scf_instance_t *inst;
        scf_property_t *prop;
        scf_value_t *val;
        char *fmri;
        int r;

        inst = safe_scf_instance_create(h);

get_self:
        if (scf_handle_decode_fmri(h, SCF_SERVICE_STARTD, NULL, NULL,
            inst, NULL, NULL, SCF_DECODE_FMRI_EXACT) != 0) {
                switch (scf_error()) {
                case SCF_ERROR_CONNECTION_BROKEN:
                        libscf_handle_rebind(h);
                        goto get_self;

                case SCF_ERROR_NOT_FOUND:
                        break;

                case SCF_ERROR_INVALID_ARGUMENT:
                case SCF_ERROR_CONSTRAINT_VIOLATED:
                case SCF_ERROR_HANDLE_MISMATCH:
                default:
                        bad_error("scf_handle_decode_fmri", scf_error());
                }

                scf_instance_destroy(inst);
                return;
        }

        prop = safe_scf_property_create(h);
        val = safe_scf_value_create(h);
        fmri = startd_alloc(max_scf_fmri_size);

        r = libscf_get_milestone(inst, prop, val, fmri, max_scf_fmri_size);
        switch (r) {
        case 0:
                break;

        case ECONNABORTED:
                libscf_handle_rebind(h);
                goto get_self;

        case ECANCELED:
        case ENOENT:
        case EINVAL:
                goto out;

        default:
                bad_error("libscf_get_milestone", r);
        }

        r = dgraph_set_milestone(fmri, h, B_TRUE);
        switch (r) {
        case 0:
        case ECONNRESET:
        case EALREADY:
        case EINVAL:
        case ENOENT:
                break;

        default:
                bad_error("dgraph_set_milestone", r);
        }

out:
        startd_free(fmri, max_scf_fmri_size);
        scf_value_destroy(val);
        scf_property_destroy(prop);
        scf_instance_destroy(inst);
}

/*
 * void *graph_thread(void *)
 *
 * Graph management thread.
 */
/*ARGSUSED*/
void *
graph_thread(void *arg)
{
        scf_handle_t *h;
        int err;

        h = libscf_handle_create_bound_loop();

        if (st->st_initial)
                set_initial_milestone(h);

        MUTEX_LOCK(&dgraph_lock);
        initial_milestone_set = B_TRUE;
        err = pthread_cond_broadcast(&initial_milestone_cv);
        assert(err == 0);
        MUTEX_UNLOCK(&dgraph_lock);

        libscf_populate_graph(h);

        if (!st->st_initial)
                set_restart_milestone(h);

        MUTEX_LOCK(&st->st_load_lock);
        st->st_load_complete = 1;
        (void) pthread_cond_broadcast(&st->st_load_cv);
        MUTEX_UNLOCK(&st->st_load_lock);

        MUTEX_LOCK(&dgraph_lock);
        /*
         * Now that we've set st_load_complete we need to check can_come_up()
         * since if we booted to a milestone, then there won't be any more
         * state updates.
         */
        if (!go_single_user_mode && !go_to_level1 &&
            halting == -1) {
                if (!sulogin_thread_running && !can_come_up()) {
                        (void) startd_thread_create(sulogin_thread, NULL);
                        sulogin_thread_running = B_TRUE;
                }
        }
        MUTEX_UNLOCK(&dgraph_lock);

        (void) pthread_mutex_lock(&gu->gu_freeze_lock);

        /*CONSTCOND*/
        while (1) {
                (void) pthread_cond_wait(&gu->gu_freeze_cv,
                    &gu->gu_freeze_lock);
        }

        /*
         * Unreachable for now -- there's currently no graceful cleanup
         * called on exit().
         */
        (void) pthread_mutex_unlock(&gu->gu_freeze_lock);
        scf_handle_destroy(h);

        return (NULL);
}


/*
 * int next_action()
 *   Given an array of timestamps 'a' with 'num' elements, find the
 *   lowest non-zero timestamp and return its index. If there are no
 *   non-zero elements, return -1.
 */
static int
next_action(hrtime_t *a, int num)
{
        hrtime_t t = 0;
        int i = 0, smallest = -1;

        for (i = 0; i < num; i++) {
                if (t == 0) {
                        t = a[i];
                        smallest = i;
                } else if (a[i] != 0 && a[i] < t) {
                        t = a[i];
                        smallest = i;
                }
        }

        if (t == 0)
                return (-1);
        else
                return (smallest);
}

/*
 * void process_actions()
 *   Process actions requested by the administrator. Possibilities include:
 *   refresh, restart, maintenance mode off, maintenance mode on,
 *   maintenance mode immediate, and degraded.
 *
 *   The set of pending actions is represented in the repository as a
 *   per-instance property group, with each action being a single property
 *   in that group.  This property group is converted to an array, with each
 *   action type having an array slot.  The actions in the array at the
 *   time process_actions() is called are acted on in the order of the
 *   timestamp (which is the value stored in the slot).  A value of zero
 *   indicates that there is no pending action of the type associated with
 *   a particular slot.
 *
 *   Sending an action event multiple times before the restarter has a
 *   chance to process that action will force it to be run at the last
 *   timestamp where it appears in the ordering.
 *
 *   Turning maintenance mode on trumps all other actions.
 *
 *   Returns 0 or ECONNABORTED.
 */
static int
process_actions(scf_handle_t *h, scf_propertygroup_t *pg, scf_instance_t *inst)
{
        scf_property_t *prop = NULL;
        scf_value_t *val = NULL;
        scf_type_t type;
        graph_vertex_t *vertex;
        admin_action_t a;
        int i, ret = 0, r;
        hrtime_t action_ts[NACTIONS];
        char *inst_name;

        r = libscf_instance_get_fmri(inst, &inst_name);
        switch (r) {
        case 0:
                break;

        case ECONNABORTED:
                return (ECONNABORTED);

        case ECANCELED:
                return (0);

        default:
                bad_error("libscf_instance_get_fmri", r);
        }

        MUTEX_LOCK(&dgraph_lock);

        vertex = vertex_get_by_name(inst_name);
        if (vertex == NULL) {
                MUTEX_UNLOCK(&dgraph_lock);
                log_framework(LOG_DEBUG, "%s: Can't find graph vertex. "
                    "The instance must have been removed.\n", inst_name);
                startd_free(inst_name, max_scf_fmri_size);
                return (0);
        }

        prop = safe_scf_property_create(h);
        val = safe_scf_value_create(h);

        for (i = 0; i < NACTIONS; i++) {
                if (scf_pg_get_property(pg, admin_actions[i], prop) != 0) {
                        switch (scf_error()) {
                        case SCF_ERROR_CONNECTION_BROKEN:
                        default:
                                ret = ECONNABORTED;
                                goto out;

                        case SCF_ERROR_DELETED:
                                goto out;

                        case SCF_ERROR_NOT_FOUND:
                                action_ts[i] = 0;
                                continue;

                        case SCF_ERROR_HANDLE_MISMATCH:
                        case SCF_ERROR_INVALID_ARGUMENT:
                        case SCF_ERROR_NOT_SET:
                                bad_error("scf_pg_get_property", scf_error());
                        }
                }

                if (scf_property_type(prop, &type) != 0) {
                        switch (scf_error()) {
                        case SCF_ERROR_CONNECTION_BROKEN:
                        default:
                                ret = ECONNABORTED;
                                goto out;

                        case SCF_ERROR_DELETED:
                                action_ts[i] = 0;
                                continue;

                        case SCF_ERROR_NOT_SET:
                                bad_error("scf_property_type", scf_error());
                        }
                }

                if (type != SCF_TYPE_INTEGER) {
                        action_ts[i] = 0;
                        continue;
                }

                if (scf_property_get_value(prop, val) != 0) {
                        switch (scf_error()) {
                        case SCF_ERROR_CONNECTION_BROKEN:
                        default:
                                ret = ECONNABORTED;
                                goto out;

                        case SCF_ERROR_DELETED:
                                goto out;

                        case SCF_ERROR_NOT_FOUND:
                        case SCF_ERROR_CONSTRAINT_VIOLATED:
                                action_ts[i] = 0;
                                continue;

                        case SCF_ERROR_NOT_SET:
                        case SCF_ERROR_PERMISSION_DENIED:
                                bad_error("scf_property_get_value",
                                    scf_error());
                        }
                }

                r = scf_value_get_integer(val, &action_ts[i]);
                assert(r == 0);
        }

        a = ADMIN_EVENT_MAINT_ON_IMMEDIATE;
        if (action_ts[ADMIN_EVENT_MAINT_ON_IMMEDIATE] ||
            action_ts[ADMIN_EVENT_MAINT_ON]) {
                a = action_ts[ADMIN_EVENT_MAINT_ON_IMMEDIATE] ?
                    ADMIN_EVENT_MAINT_ON_IMMEDIATE : ADMIN_EVENT_MAINT_ON;

                vertex_send_event(vertex, admin_events[a]);
                r = libscf_unset_action(h, pg, a, action_ts[a]);
                switch (r) {
                case 0:
                case EACCES:
                        break;

                case ECONNABORTED:
                        ret = ECONNABORTED;
                        goto out;

                case EPERM:
                        uu_die("Insufficient privilege.\n");
                        /* NOTREACHED */

                default:
                        bad_error("libscf_unset_action", r);
                }
        }

        while ((a = next_action(action_ts, NACTIONS)) != -1) {
                log_framework(LOG_DEBUG,
                    "Graph: processing %s action for %s.\n", admin_actions[a],
                    inst_name);

                if (a == ADMIN_EVENT_REFRESH) {
                        r = dgraph_refresh_instance(vertex, inst);
                        switch (r) {
                        case 0:
                        case ECANCELED:
                        case EINVAL:
                        case -1:
                                break;

                        case ECONNABORTED:
                                /* pg & inst are reset now, so just return. */
                                ret = ECONNABORTED;
                                goto out;

                        default:
                                bad_error("dgraph_refresh_instance", r);
                        }
                }

                vertex_send_event(vertex, admin_events[a]);

                r = libscf_unset_action(h, pg, a, action_ts[a]);
                switch (r) {
                case 0:
                case EACCES:
                        break;

                case ECONNABORTED:
                        ret = ECONNABORTED;
                        goto out;

                case EPERM:
                        uu_die("Insufficient privilege.\n");
                        /* NOTREACHED */

                default:
                        bad_error("libscf_unset_action", r);
                }

                action_ts[a] = 0;
        }

out:
        MUTEX_UNLOCK(&dgraph_lock);

        scf_property_destroy(prop);
        scf_value_destroy(val);
        startd_free(inst_name, max_scf_fmri_size);
        return (ret);
}

/*
 * inst and pg_name are scratch space, and are unset on entry.
 * Returns
 *   0 - success
 *   ECONNRESET - success, but repository handle rebound
 *   ECONNABORTED - repository connection broken
 */
static int
process_pg_event(scf_handle_t *h, scf_propertygroup_t *pg, scf_instance_t *inst,
    char *pg_name)
{
        int r;
        scf_property_t *prop;
        scf_value_t *val;
        char *fmri;
        boolean_t rebound = B_FALSE, rebind_inst = B_FALSE;

        if (scf_pg_get_name(pg, pg_name, max_scf_value_size) < 0) {
                switch (scf_error()) {
                case SCF_ERROR_CONNECTION_BROKEN:
                default:
                        return (ECONNABORTED);

                case SCF_ERROR_DELETED:
                        return (0);

                case SCF_ERROR_NOT_SET:
                        bad_error("scf_pg_get_name", scf_error());
                }
        }

        if (strcmp(pg_name, SCF_PG_GENERAL) == 0 ||
            strcmp(pg_name, SCF_PG_GENERAL_OVR) == 0) {
                r = dgraph_update_general(pg);
                switch (r) {
                case 0:
                case ENOTSUP:
                case ECANCELED:
                        return (0);

                case ECONNABORTED:
                        return (ECONNABORTED);

                case -1:
                        /* Error should have been logged. */
                        return (0);

                default:
                        bad_error("dgraph_update_general", r);
                }
        } else if (strcmp(pg_name, SCF_PG_RESTARTER_ACTIONS) == 0) {
                if (scf_pg_get_parent_instance(pg, inst) != 0) {
                        switch (scf_error()) {
                        case SCF_ERROR_CONNECTION_BROKEN:
                                return (ECONNABORTED);

                        case SCF_ERROR_DELETED:
                        case SCF_ERROR_CONSTRAINT_VIOLATED:
                                /* Ignore commands on services. */
                                return (0);

                        case SCF_ERROR_NOT_BOUND:
                        case SCF_ERROR_HANDLE_MISMATCH:
                        case SCF_ERROR_NOT_SET:
                        default:
                                bad_error("scf_pg_get_parent_instance",
                                    scf_error());
                        }
                }

                return (process_actions(h, pg, inst));
        }

        if (strcmp(pg_name, SCF_PG_OPTIONS) != 0 &&
            strcmp(pg_name, SCF_PG_OPTIONS_OVR) != 0)
                return (0);

        /*
         * We only care about the options[_ovr] property groups of our own
         * instance, so get the fmri and compare.  Plus, once we know it's
         * correct, if the repository connection is broken we know exactly what
         * property group we were operating on, and can look it up again.
         */
        if (scf_pg_get_parent_instance(pg, inst) != 0) {
                switch (scf_error()) {
                case SCF_ERROR_CONNECTION_BROKEN:
                        return (ECONNABORTED);

                case SCF_ERROR_DELETED:
                case SCF_ERROR_CONSTRAINT_VIOLATED:
                        return (0);

                case SCF_ERROR_HANDLE_MISMATCH:
                case SCF_ERROR_NOT_BOUND:
                case SCF_ERROR_NOT_SET:
                default:
                        bad_error("scf_pg_get_parent_instance",
                            scf_error());
                }
        }

        switch (r = libscf_instance_get_fmri(inst, &fmri)) {
        case 0:
                break;

        case ECONNABORTED:
                return (ECONNABORTED);

        case ECANCELED:
                return (0);

        default:
                bad_error("libscf_instance_get_fmri", r);
        }

        if (strcmp(fmri, SCF_SERVICE_STARTD) != 0) {
                startd_free(fmri, max_scf_fmri_size);
                return (0);
        }

        /*
         * update the information events flag
         */
        if (strcmp(pg_name, SCF_PG_OPTIONS) == 0)
                info_events_all = libscf_get_info_events_all(pg);

        prop = safe_scf_property_create(h);
        val = safe_scf_value_create(h);

        if (strcmp(pg_name, SCF_PG_OPTIONS_OVR) == 0) {
                /* See if we need to set the runlevel. */
                /* CONSTCOND */
                if (0) {
rebind_pg:
                        libscf_handle_rebind(h);
                        rebound = B_TRUE;

                        r = libscf_lookup_instance(SCF_SERVICE_STARTD, inst);
                        switch (r) {
                        case 0:
                                break;

                        case ECONNABORTED:
                                goto rebind_pg;

                        case ENOENT:
                                goto out;

                        case EINVAL:
                        case ENOTSUP:
                                bad_error("libscf_lookup_instance", r);
                        }

                        if (scf_instance_get_pg(inst, pg_name, pg) != 0) {
                                switch (scf_error()) {
                                case SCF_ERROR_DELETED:
                                case SCF_ERROR_NOT_FOUND:
                                        goto out;

                                case SCF_ERROR_CONNECTION_BROKEN:
                                        goto rebind_pg;

                                case SCF_ERROR_HANDLE_MISMATCH:
                                case SCF_ERROR_NOT_BOUND:
                                case SCF_ERROR_NOT_SET:
                                case SCF_ERROR_INVALID_ARGUMENT:
                                default:
                                        bad_error("scf_instance_get_pg",
                                            scf_error());
                                }
                        }
                }

                if (scf_pg_get_property(pg, "runlevel", prop) == 0) {
                        r = dgraph_set_runlevel(pg, prop);
                        switch (r) {
                        case ECONNRESET:
                                rebound = B_TRUE;
                                rebind_inst = B_TRUE;
                                /* FALLTHROUGH */

                        case 0:
                                break;

                        case ECONNABORTED:
                                goto rebind_pg;

                        case ECANCELED:
                                goto out;

                        default:
                                bad_error("dgraph_set_runlevel", r);
                        }
                } else {
                        switch (scf_error()) {
                        case SCF_ERROR_CONNECTION_BROKEN:
                        default:
                                goto rebind_pg;

                        case SCF_ERROR_DELETED:
                                goto out;

                        case SCF_ERROR_NOT_FOUND:
                                break;

                        case SCF_ERROR_INVALID_ARGUMENT:
                        case SCF_ERROR_HANDLE_MISMATCH:
                        case SCF_ERROR_NOT_BOUND:
                        case SCF_ERROR_NOT_SET:
                                bad_error("scf_pg_get_property", scf_error());
                        }
                }
        }

        if (rebind_inst) {
lookup_inst:
                r = libscf_lookup_instance(SCF_SERVICE_STARTD, inst);
                switch (r) {
                case 0:
                        break;

                case ECONNABORTED:
                        libscf_handle_rebind(h);
                        rebound = B_TRUE;
                        goto lookup_inst;

                case ENOENT:
                        goto out;

                case EINVAL:
                case ENOTSUP:
                        bad_error("libscf_lookup_instance", r);
                }
        }

        r = libscf_get_milestone(inst, prop, val, fmri, max_scf_fmri_size);
        switch (r) {
        case 0:
                break;

        case ECONNABORTED:
                libscf_handle_rebind(h);
                rebound = B_TRUE;
                goto lookup_inst;

        case EINVAL:
                log_error(LOG_NOTICE,
                    "%s/%s property of %s is misconfigured.\n", pg_name,
                    SCF_PROPERTY_MILESTONE, SCF_SERVICE_STARTD);
                /* FALLTHROUGH */

        case ECANCELED:
        case ENOENT:
                (void) strcpy(fmri, "all");
                break;

        default:
                bad_error("libscf_get_milestone", r);
        }

        r = dgraph_set_milestone(fmri, h, B_FALSE);
        switch (r) {
        case 0:
        case ECONNRESET:
        case EALREADY:
                break;

        case EINVAL:
                log_error(LOG_WARNING, "Milestone %s is invalid.\n", fmri);
                break;

        case ENOENT:
                log_error(LOG_WARNING, "Milestone %s does not exist.\n", fmri);
                break;

        default:
                bad_error("dgraph_set_milestone", r);
        }

out:
        startd_free(fmri, max_scf_fmri_size);
        scf_value_destroy(val);
        scf_property_destroy(prop);

        return (rebound ? ECONNRESET : 0);
}

/*
 * process_delete() deletes an instance from the dgraph if 'fmri' is an
 * instance fmri or if 'fmri' matches the 'general' property group of an
 * instance (or the 'general/enabled' property).
 *
 * 'fmri' may be overwritten and cannot be trusted on return by the caller.
 */
static void
process_delete(char *fmri, scf_handle_t *h)
{
        char *lfmri, *end_inst_fmri;
        const char *inst_name = NULL;
        const char *pg_name = NULL;
        const char *prop_name = NULL;

        lfmri = safe_strdup(fmri);

        /* Determine if the FMRI is a property group or instance */
        if (scf_parse_svc_fmri(lfmri, NULL, NULL, &inst_name, &pg_name,
            &prop_name) != SCF_SUCCESS) {
                log_error(LOG_WARNING,
                    "Received invalid FMRI \"%s\" from repository server.\n",
                    fmri);
        } else if (inst_name != NULL && pg_name == NULL) {
                (void) dgraph_remove_instance(fmri, h);
        } else if (inst_name != NULL && pg_name != NULL) {
                /*
                 * If we're deleting the 'general' property group or
                 * 'general/enabled' property then the whole instance
                 * must be removed from the dgraph.
                 */
                if (strcmp(pg_name, SCF_PG_GENERAL) != 0) {
                        free(lfmri);
                        return;
                }

                if (prop_name != NULL &&
                    strcmp(prop_name, SCF_PROPERTY_ENABLED) != 0) {
                        free(lfmri);
                        return;
                }

                /*
                 * Because the instance has already been deleted from the
                 * repository, we cannot use any scf_ functions to retrieve
                 * the instance FMRI however we can easily reconstruct it
                 * manually.
                 */
                end_inst_fmri = strstr(fmri, SCF_FMRI_PROPERTYGRP_PREFIX);
                if (end_inst_fmri == NULL)
                        bad_error("process_delete", 0);

                end_inst_fmri[0] = '\0';

                (void) dgraph_remove_instance(fmri, h);
        }

        free(lfmri);
}

/*ARGSUSED*/
void *
repository_event_thread(void *unused)
{
        scf_handle_t *h;
        scf_propertygroup_t *pg;
        scf_instance_t *inst;
        char *fmri = startd_alloc(max_scf_fmri_size);
        char *pg_name = startd_alloc(max_scf_value_size);
        int r;

        h = libscf_handle_create_bound_loop();

        pg = safe_scf_pg_create(h);
        inst = safe_scf_instance_create(h);

retry:
        if (_scf_notify_add_pgtype(h, SCF_GROUP_FRAMEWORK) != SCF_SUCCESS) {
                if (scf_error() == SCF_ERROR_CONNECTION_BROKEN) {
                        libscf_handle_rebind(h);
                } else {
                        log_error(LOG_WARNING,
                            "Couldn't set up repository notification "
                            "for property group type %s: %s\n",
                            SCF_GROUP_FRAMEWORK, scf_strerror(scf_error()));

                        (void) sleep(1);
                }

                goto retry;
        }

        /*CONSTCOND*/
        while (1) {
                ssize_t res;

                /* Note: fmri is only set on delete events. */
                res = _scf_notify_wait(pg, fmri, max_scf_fmri_size);
                if (res < 0) {
                        libscf_handle_rebind(h);
                        goto retry;
                } else if (res == 0) {
                        /*
                         * property group modified.  inst and pg_name are
                         * pre-allocated scratch space.
                         */
                        if (scf_pg_update(pg) < 0) {
                                switch (scf_error()) {
                                case SCF_ERROR_DELETED:
                                        continue;

                                case SCF_ERROR_CONNECTION_BROKEN:
                                        log_error(LOG_WARNING,
                                            "Lost repository event due to "
                                            "disconnection.\n");
                                        libscf_handle_rebind(h);
                                        goto retry;

                                case SCF_ERROR_NOT_BOUND:
                                case SCF_ERROR_NOT_SET:
                                default:
                                        bad_error("scf_pg_update", scf_error());
                                }
                        }

                        r = process_pg_event(h, pg, inst, pg_name);
                        switch (r) {
                        case 0:
                                break;

                        case ECONNABORTED:
                                log_error(LOG_WARNING, "Lost repository event "
                                    "due to disconnection.\n");
                                libscf_handle_rebind(h);
                                /* FALLTHROUGH */

                        case ECONNRESET:
                                goto retry;

                        default:
                                bad_error("process_pg_event", r);
                        }
                } else {
                        /*
                         * Service, instance, or pg deleted.
                         * Don't trust fmri on return.
                         */
                        process_delete(fmri, h);
                }
        }

        /*NOTREACHED*/
        return (NULL);
}

void
graph_engine_start()
{
        int err;

        (void) startd_thread_create(graph_thread, NULL);

        MUTEX_LOCK(&dgraph_lock);
        while (!initial_milestone_set) {
                err = pthread_cond_wait(&initial_milestone_cv, &dgraph_lock);
                assert(err == 0);
        }
        MUTEX_UNLOCK(&dgraph_lock);

        (void) startd_thread_create(repository_event_thread, NULL);
        (void) startd_thread_create(graph_event_thread, NULL);
}