/*- * Copyright (c) 2007 Pawel Jakub Dawidek * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHORS AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHORS OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #include __FBSDID("$FreeBSD$"); #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* OSD (Object Specific Data) */ /* * Lock key: * (m) osd_module_lock * (o) osd_object_lock * (l) osd_list_lock */ struct osd_master { struct sx osd_module_lock; struct rmlock osd_object_lock; struct mtx osd_list_lock; LIST_HEAD(, osd) osd_list; /* (l) */ osd_destructor_t *osd_destructors; /* (o) */ osd_method_t *osd_methods; /* (m) */ u_int osd_ntslots; /* (m) */ const u_int osd_nmethods; }; static MALLOC_DEFINE(M_OSD, "osd", "Object Specific Data"); static int osd_debug = 0; SYSCTL_INT(_debug, OID_AUTO, osd, CTLFLAG_RWTUN, &osd_debug, 0, "OSD debug level"); #define OSD_DEBUG(...) do { \ if (osd_debug) { \ printf("OSD (%s:%u): ", __func__, __LINE__); \ printf(__VA_ARGS__); \ printf("\n"); \ } \ } while (0) static void do_osd_del(u_int type, struct osd *osd, u_int slot, int list_locked); /* * List of objects with OSD. */ struct osd_master osdm[OSD_LAST + 1] = { [OSD_JAIL] = { .osd_nmethods = PR_MAXMETHOD }, }; static void osd_default_destructor(void *value __unused) { /* Do nothing. */ } int osd_register(u_int type, osd_destructor_t destructor, osd_method_t *methods) { void *newptr; u_int i, m; KASSERT(type >= OSD_FIRST && type <= OSD_LAST, ("Invalid type.")); /* * If no destructor is given, use default one. We need to use some * destructor, because NULL destructor means unused slot. */ if (destructor == NULL) destructor = osd_default_destructor; sx_xlock(&osdm[type].osd_module_lock); /* * First, we try to find unused slot. */ for (i = 0; i < osdm[type].osd_ntslots; i++) { if (osdm[type].osd_destructors[i] == NULL) { OSD_DEBUG("Unused slot found (type=%u, slot=%u).", type, i); break; } } /* * If no unused slot was found, allocate one. */ if (i == osdm[type].osd_ntslots) { osdm[type].osd_ntslots++; if (osdm[type].osd_nmethods != 0) osdm[type].osd_methods = realloc(osdm[type].osd_methods, sizeof(osd_method_t) * osdm[type].osd_ntslots * osdm[type].osd_nmethods, M_OSD, M_WAITOK); newptr = malloc(sizeof(osd_destructor_t) * osdm[type].osd_ntslots, M_OSD, M_WAITOK); rm_wlock(&osdm[type].osd_object_lock); bcopy(osdm[type].osd_destructors, newptr, sizeof(osd_destructor_t) * i); free(osdm[type].osd_destructors, M_OSD); osdm[type].osd_destructors = newptr; rm_wunlock(&osdm[type].osd_object_lock); OSD_DEBUG("New slot allocated (type=%u, slot=%u).", type, i + 1); } osdm[type].osd_destructors[i] = destructor; if (osdm[type].osd_nmethods != 0) { for (m = 0; m < osdm[type].osd_nmethods; m++) osdm[type].osd_methods[i * osdm[type].osd_nmethods + m] = methods != NULL ? methods[m] : NULL; } sx_xunlock(&osdm[type].osd_module_lock); return (i + 1); } void osd_deregister(u_int type, u_int slot) { struct osd *osd, *tosd; KASSERT(type >= OSD_FIRST && type <= OSD_LAST, ("Invalid type.")); KASSERT(slot > 0, ("Invalid slot.")); KASSERT(osdm[type].osd_destructors[slot - 1] != NULL, ("Unused slot.")); sx_xlock(&osdm[type].osd_module_lock); rm_wlock(&osdm[type].osd_object_lock); /* * Free all OSD for the given slot. */ mtx_lock(&osdm[type].osd_list_lock); LIST_FOREACH_SAFE(osd, &osdm[type].osd_list, osd_next, tosd) do_osd_del(type, osd, slot, 1); mtx_unlock(&osdm[type].osd_list_lock); /* * Set destructor to NULL to free the slot. */ osdm[type].osd_destructors[slot - 1] = NULL; if (slot == osdm[type].osd_ntslots) { osdm[type].osd_ntslots--; osdm[type].osd_destructors = realloc(osdm[type].osd_destructors, sizeof(osd_destructor_t) * osdm[type].osd_ntslots, M_OSD, M_NOWAIT | M_ZERO); if (osdm[type].osd_nmethods != 0) osdm[type].osd_methods = realloc(osdm[type].osd_methods, sizeof(osd_method_t) * osdm[type].osd_ntslots * osdm[type].osd_nmethods, M_OSD, M_NOWAIT | M_ZERO); /* * We always reallocate to smaller size, so we assume it will * always succeed. */ KASSERT(osdm[type].osd_destructors != NULL && (osdm[type].osd_nmethods == 0 || osdm[type].osd_methods != NULL), ("realloc() failed")); OSD_DEBUG("Deregistration of the last slot (type=%u, slot=%u).", type, slot); } else { OSD_DEBUG("Slot deregistration (type=%u, slot=%u).", type, slot); } rm_wunlock(&osdm[type].osd_object_lock); sx_xunlock(&osdm[type].osd_module_lock); } int osd_set(u_int type, struct osd *osd, u_int slot, void *value) { return (osd_set_reserved(type, osd, slot, NULL, value)); } void * osd_reserve(u_int slot) { KASSERT(slot > 0, ("Invalid slot.")); OSD_DEBUG("Reserving slot array (slot=%u).", slot); return (malloc(sizeof(void *) * slot, M_OSD, M_WAITOK | M_ZERO)); } int osd_set_reserved(u_int type, struct osd *osd, u_int slot, void *rsv, void *value) { struct rm_priotracker tracker; KASSERT(type >= OSD_FIRST && type <= OSD_LAST, ("Invalid type.")); KASSERT(slot > 0, ("Invalid slot.")); KASSERT(osdm[type].osd_destructors[slot - 1] != NULL, ("Unused slot.")); rm_rlock(&osdm[type].osd_object_lock, &tracker); if (slot > osd->osd_nslots) { void *newptr; if (value == NULL) { OSD_DEBUG( "Not allocating null slot (type=%u, slot=%u).", type, slot); rm_runlock(&osdm[type].osd_object_lock, &tracker); if (rsv) osd_free_reserved(rsv); return (0); } /* * Too few slots allocated here, so we need to extend or create * the array. */ if (rsv) { /* * Use the reserve passed in (assumed to be * the right size). */ newptr = rsv; if (osd->osd_nslots != 0) { memcpy(newptr, osd->osd_slots, sizeof(void *) * osd->osd_nslots); free(osd->osd_slots, M_OSD); } } else { newptr = realloc(osd->osd_slots, sizeof(void *) * slot, M_OSD, M_NOWAIT | M_ZERO); if (newptr == NULL) { rm_runlock(&osdm[type].osd_object_lock, &tracker); return (ENOMEM); } } if (osd->osd_nslots == 0) { /* * First OSD for this object, so we need to put it * onto the list. */ mtx_lock(&osdm[type].osd_list_lock); LIST_INSERT_HEAD(&osdm[type].osd_list, osd, osd_next); mtx_unlock(&osdm[type].osd_list_lock); OSD_DEBUG("Setting first slot (type=%u).", type); } else OSD_DEBUG("Growing slots array (type=%u).", type); osd->osd_slots = newptr; osd->osd_nslots = slot; } else if (rsv) osd_free_reserved(rsv); OSD_DEBUG("Setting slot value (type=%u, slot=%u, value=%p).", type, slot, value); osd->osd_slots[slot - 1] = value; rm_runlock(&osdm[type].osd_object_lock, &tracker); return (0); } void osd_free_reserved(void *rsv) { OSD_DEBUG("Discarding reserved slot array."); free(rsv, M_OSD); } void * osd_get(u_int type, struct osd *osd, u_int slot) { struct rm_priotracker tracker; void *value; KASSERT(type >= OSD_FIRST && type <= OSD_LAST, ("Invalid type.")); KASSERT(slot > 0, ("Invalid slot.")); KASSERT(osdm[type].osd_destructors[slot - 1] != NULL, ("Unused slot.")); rm_rlock(&osdm[type].osd_object_lock, &tracker); if (slot > osd->osd_nslots) { value = NULL; OSD_DEBUG("Slot doesn't exist (type=%u, slot=%u).", type, slot); } else { value = osd->osd_slots[slot - 1]; OSD_DEBUG("Returning slot value (type=%u, slot=%u, value=%p).", type, slot, value); } rm_runlock(&osdm[type].osd_object_lock, &tracker); return (value); } void osd_del(u_int type, struct osd *osd, u_int slot) { struct rm_priotracker tracker; rm_rlock(&osdm[type].osd_object_lock, &tracker); do_osd_del(type, osd, slot, 0); rm_runlock(&osdm[type].osd_object_lock, &tracker); } static void do_osd_del(u_int type, struct osd *osd, u_int slot, int list_locked) { int i; KASSERT(type >= OSD_FIRST && type <= OSD_LAST, ("Invalid type.")); KASSERT(slot > 0, ("Invalid slot.")); KASSERT(osdm[type].osd_destructors[slot - 1] != NULL, ("Unused slot.")); OSD_DEBUG("Deleting slot (type=%u, slot=%u).", type, slot); if (slot > osd->osd_nslots) { OSD_DEBUG("Slot doesn't exist (type=%u, slot=%u).", type, slot); return; } if (osd->osd_slots[slot - 1] != NULL) { osdm[type].osd_destructors[slot - 1](osd->osd_slots[slot - 1]); osd->osd_slots[slot - 1] = NULL; } for (i = osd->osd_nslots - 1; i >= 0; i--) { if (osd->osd_slots[i] != NULL) { OSD_DEBUG("Slot still has a value (type=%u, slot=%u).", type, i + 1); break; } } if (i == -1) { /* No values left for this object. */ OSD_DEBUG("No more slots left (type=%u).", type); if (!list_locked) mtx_lock(&osdm[type].osd_list_lock); LIST_REMOVE(osd, osd_next); if (!list_locked) mtx_unlock(&osdm[type].osd_list_lock); free(osd->osd_slots, M_OSD); osd->osd_slots = NULL; osd->osd_nslots = 0; } else if (slot == osd->osd_nslots) { /* This was the last slot. */ osd->osd_slots = realloc(osd->osd_slots, sizeof(void *) * (i + 1), M_OSD, M_NOWAIT | M_ZERO); /* * We always reallocate to smaller size, so we assume it will * always succeed. */ KASSERT(osd->osd_slots != NULL, ("realloc() failed")); osd->osd_nslots = i + 1; OSD_DEBUG("Reducing slots array to %u (type=%u).", osd->osd_nslots, type); } } int osd_call(u_int type, u_int method, void *obj, void *data) { osd_method_t methodfun; int error, i; KASSERT(type >= OSD_FIRST && type <= OSD_LAST, ("Invalid type.")); KASSERT(method < osdm[type].osd_nmethods, ("Invalid method.")); /* * Call this method for every slot that defines it, stopping if an * error is encountered. */ error = 0; sx_slock(&osdm[type].osd_module_lock); for (i = 0; i < osdm[type].osd_ntslots; i++) { methodfun = osdm[type].osd_methods[i * osdm[type].osd_nmethods + method]; if (methodfun != NULL && (error = methodfun(obj, data)) != 0) break; } sx_sunlock(&osdm[type].osd_module_lock); return (error); } void osd_exit(u_int type, struct osd *osd) { struct rm_priotracker tracker; u_int i; KASSERT(type >= OSD_FIRST && type <= OSD_LAST, ("Invalid type.")); if (osd->osd_nslots == 0) { KASSERT(osd->osd_slots == NULL, ("Non-null osd_slots.")); /* No OSD attached, just leave. */ return; } rm_rlock(&osdm[type].osd_object_lock, &tracker); for (i = 1; i <= osd->osd_nslots; i++) { if (osdm[type].osd_destructors[i - 1] != NULL) do_osd_del(type, osd, i, 0); else OSD_DEBUG("Unused slot (type=%u, slot=%u).", type, i); } rm_runlock(&osdm[type].osd_object_lock, &tracker); OSD_DEBUG("Object exit (type=%u).", type); } static void osd_init(void *arg __unused) { u_int i; for (i = OSD_FIRST; i <= OSD_LAST; i++) { sx_init(&osdm[i].osd_module_lock, "osd_module"); rm_init(&osdm[i].osd_object_lock, "osd_object"); mtx_init(&osdm[i].osd_list_lock, "osd_list", NULL, MTX_DEF); LIST_INIT(&osdm[i].osd_list); osdm[i].osd_destructors = NULL; osdm[i].osd_ntslots = 0; osdm[i].osd_methods = NULL; } } SYSINIT(osd, SI_SUB_LOCK, SI_ORDER_ANY, osd_init, NULL);