2 This file is part of systemd.
4 Copyright 2013 Lennart Poettering
6 systemd is free software; you can redistribute it and/or modify it
7 under the terms of the GNU Lesser General Public License as published by
8 the Free Software Foundation; either version 2.1 of the License, or
9 (at your option) any later version.
11 systemd is distributed in the hope that it will be useful, but
12 WITHOUT ANY WARRANTY; without even the implied warranty of
13 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
14 Lesser General Public License for more details.
16 You should have received a copy of the GNU Lesser General Public License
17 along with systemd; If not, see <http://www.gnu.org/licenses/>.
20 #ifdef HAVE_VALGRIND_MEMCHECK_H
21 #include <valgrind/memcheck.h>
27 #include <sys/prctl.h>
29 /* When we include libgen.h because we need dirname() we immediately
30 * undefine basename() since libgen.h defines it as a macro to the POSIX
31 * version which is really broken. We prefer GNU basename(). */
35 #include "alloc-util.h"
36 #include "bus-bloom.h"
37 #include "bus-internal.h"
38 #include "bus-kernel.h"
39 #include "bus-label.h"
40 #include "bus-message.h"
42 #include "capability-util.h"
45 #include "format-util.h"
46 #include "memfd-util.h"
47 #include "parse-util.h"
48 #include "stdio-util.h"
49 #include "string-util.h"
51 #include "user-util.h"
54 #define UNIQUE_NAME_MAX (3+DECIMAL_STR_MAX(uint64_t))
56 int bus_kernel_parse_unique_name(const char *s, uint64_t *id) {
62 if (!startswith(s, ":1."))
65 r = safe_atou64(s + 3, id);
72 static void append_payload_vec(struct kdbus_item **d, const void *p, size_t sz) {
78 /* Note that p can be NULL, which encodes a region full of
79 * zeroes, which is useful to optimize certain padding
82 (*d)->size = offsetof(struct kdbus_item, vec) + sizeof(struct kdbus_vec);
83 (*d)->type = KDBUS_ITEM_PAYLOAD_VEC;
84 (*d)->vec.address = PTR_TO_UINT64(p);
87 *d = (struct kdbus_item *) ((uint8_t*) *d + (*d)->size);
90 static void append_payload_memfd(struct kdbus_item **d, int memfd, size_t start, size_t sz) {
96 (*d)->size = offsetof(struct kdbus_item, memfd) + sizeof(struct kdbus_memfd);
97 (*d)->type = KDBUS_ITEM_PAYLOAD_MEMFD;
98 (*d)->memfd.fd = memfd;
99 (*d)->memfd.start = start;
100 (*d)->memfd.size = sz;
102 *d = (struct kdbus_item *) ((uint8_t*) *d + (*d)->size);
105 static void append_destination(struct kdbus_item **d, const char *s, size_t length) {
111 (*d)->size = offsetof(struct kdbus_item, str) + length + 1;
112 (*d)->type = KDBUS_ITEM_DST_NAME;
113 memcpy((*d)->str, s, length + 1);
115 *d = (struct kdbus_item *) ((uint8_t*) *d + (*d)->size);
118 static struct kdbus_bloom_filter *append_bloom(struct kdbus_item **d, size_t length) {
119 struct kdbus_item *i;
125 i->size = offsetof(struct kdbus_item, bloom_filter) +
126 offsetof(struct kdbus_bloom_filter, data) +
128 i->type = KDBUS_ITEM_BLOOM_FILTER;
130 *d = (struct kdbus_item *) ((uint8_t*) i + i->size);
132 return &i->bloom_filter;
135 static void append_fds(struct kdbus_item **d, const int fds[], unsigned n_fds) {
141 (*d)->size = offsetof(struct kdbus_item, fds) + sizeof(int) * n_fds;
142 (*d)->type = KDBUS_ITEM_FDS;
143 memcpy((*d)->fds, fds, sizeof(int) * n_fds);
145 *d = (struct kdbus_item *) ((uint8_t*) *d + (*d)->size);
148 static void add_bloom_arg(void *data, size_t size, unsigned n_hash, unsigned i, const char *t) {
149 char buf[sizeof("arg")-1 + 2 + sizeof("-slash-prefix")];
157 e = stpcpy(buf, "arg");
159 *(e++) = '0' + (char) i;
161 *(e++) = '0' + (char) (i / 10);
162 *(e++) = '0' + (char) (i % 10);
166 bloom_add_pair(data, size, n_hash, buf, t);
168 strcpy(e, "-dot-prefix");
169 bloom_add_prefixes(data, size, n_hash, buf, t, '.');
170 strcpy(e, "-slash-prefix");
171 bloom_add_prefixes(data, size, n_hash, buf, t, '/');
174 static void add_bloom_arg_has(void *data, size_t size, unsigned n_hash, unsigned i, const char *t) {
175 char buf[sizeof("arg")-1 + 2 + sizeof("-has")];
183 e = stpcpy(buf, "arg");
185 *(e++) = '0' + (char) i;
187 *(e++) = '0' + (char) (i / 10);
188 *(e++) = '0' + (char) (i % 10);
192 bloom_add_pair(data, size, n_hash, buf, t);
195 static int bus_message_setup_bloom(sd_bus_message *m, struct kdbus_bloom_filter *bloom) {
204 memzero(data, m->bus->bloom_size);
205 bloom->generation = 0;
207 bloom_add_pair(data, m->bus->bloom_size, m->bus->bloom_n_hash, "message-type", bus_message_type_to_string(m->header->type));
210 bloom_add_pair(data, m->bus->bloom_size, m->bus->bloom_n_hash, "interface", m->interface);
212 bloom_add_pair(data, m->bus->bloom_size, m->bus->bloom_n_hash, "member", m->member);
214 bloom_add_pair(data, m->bus->bloom_size, m->bus->bloom_n_hash, "path", m->path);
215 bloom_add_pair(data, m->bus->bloom_size, m->bus->bloom_n_hash, "path-slash-prefix", m->path);
216 bloom_add_prefixes(data, m->bus->bloom_size, m->bus->bloom_n_hash, "path-slash-prefix", m->path, '/');
219 r = sd_bus_message_rewind(m, true);
223 for (i = 0; i < 64; i++) {
224 const char *t, *contents;
227 r = sd_bus_message_peek_type(m, &type, &contents);
231 if (IN_SET(type, SD_BUS_TYPE_STRING, SD_BUS_TYPE_OBJECT_PATH, SD_BUS_TYPE_SIGNATURE)) {
233 /* The bloom filter includes simple strings of any kind */
234 r = sd_bus_message_read_basic(m, type, &t);
238 add_bloom_arg(data, m->bus->bloom_size, m->bus->bloom_n_hash, i, t);
241 if (type == SD_BUS_TYPE_ARRAY && STR_IN_SET(contents, "s", "o", "g")) {
243 /* As well as array of simple strings of any kinds */
244 r = sd_bus_message_enter_container(m, type, contents);
248 while ((r = sd_bus_message_read_basic(m, contents[0], &t)) > 0)
249 add_bloom_arg_has(data, m->bus->bloom_size, m->bus->bloom_n_hash, i, t);
253 r = sd_bus_message_exit_container(m);
258 /* Stop adding to bloom filter as soon as we
259 * run into the first argument we cannot add
267 static int bus_message_setup_kmsg(sd_bus *b, sd_bus_message *m) {
268 struct bus_body_part *part;
269 struct kdbus_item *d;
270 const char *destination;
271 bool well_known = false;
281 /* We put this together only once, if this message is reused
282 * we reuse the earlier-built version */
286 destination = m->destination ?: m->destination_ptr;
289 r = bus_kernel_parse_unique_name(destination, &dst_id);
295 /* verify_destination_id will usually be 0, which makes the kernel
296 * driver only look at the provided well-known name. Otherwise,
297 * the kernel will make sure the provided destination id matches
298 * the owner of the provided well-known-name, and fail if they
299 * differ. Currently, this is only needed for bus-proxyd. */
300 dst_id = m->verify_destination_id;
303 dst_id = KDBUS_DST_ID_BROADCAST;
305 sz = offsetof(struct kdbus_msg, items);
307 /* Add in fixed header, fields header and payload */
308 sz += (1 + m->n_body_parts) * ALIGN8(offsetof(struct kdbus_item, vec) +
309 MAX(sizeof(struct kdbus_vec),
310 sizeof(struct kdbus_memfd)));
312 /* Add space for bloom filter */
313 sz += ALIGN8(offsetof(struct kdbus_item, bloom_filter) +
314 offsetof(struct kdbus_bloom_filter, data) +
317 /* Add in well-known destination header */
319 dl = strlen(destination);
320 sz += ALIGN8(offsetof(struct kdbus_item, str) + dl + 1);
323 /* Add space for unix fds */
325 sz += ALIGN8(offsetof(struct kdbus_item, fds) + sizeof(int)*m->n_fds);
327 m->kdbus = memalign(8, sz);
333 m->free_kdbus = true;
334 memzero(m->kdbus, sz);
337 ((m->header->flags & BUS_MESSAGE_NO_REPLY_EXPECTED) ? 0 : KDBUS_MSG_EXPECT_REPLY) |
338 ((m->header->flags & BUS_MESSAGE_NO_AUTO_START) ? KDBUS_MSG_NO_AUTO_START : 0) |
339 ((m->header->type == SD_BUS_MESSAGE_SIGNAL) ? KDBUS_MSG_SIGNAL : 0);
341 m->kdbus->dst_id = dst_id;
342 m->kdbus->payload_type = KDBUS_PAYLOAD_DBUS;
343 m->kdbus->cookie = m->header->dbus2.cookie;
344 m->kdbus->priority = m->priority;
346 if (m->header->flags & BUS_MESSAGE_NO_REPLY_EXPECTED)
347 m->kdbus->cookie_reply = m->reply_cookie;
351 assert_se(clock_gettime(CLOCK_MONOTONIC_COARSE, &now) == 0);
352 m->kdbus->timeout_ns = now.tv_sec * NSEC_PER_SEC + now.tv_nsec +
353 m->timeout * NSEC_PER_USEC;
359 append_destination(&d, destination, dl);
361 append_payload_vec(&d, m->header, BUS_MESSAGE_BODY_BEGIN(m));
363 MESSAGE_FOREACH_PART(part, i, m) {
365 /* If this is padding then simply send a
366 * vector with a NULL data pointer which the
367 * kernel will just pass through. This is the
368 * most efficient way to encode zeroes */
370 append_payload_vec(&d, NULL, part->size);
374 if (part->memfd >= 0 && part->sealed && destination) {
375 /* Try to send a memfd, if the part is
376 * sealed and this is not a broadcast. Since we can only */
378 append_payload_memfd(&d, part->memfd, part->memfd_offset, part->size);
382 /* Otherwise, let's send a vector to the actual data.
383 * For that, we need to map it first. */
384 r = bus_body_part_map(part);
388 append_payload_vec(&d, part->data, part->size);
391 if (m->header->type == SD_BUS_MESSAGE_SIGNAL) {
392 struct kdbus_bloom_filter *bloom;
394 bloom = append_bloom(&d, m->bus->bloom_size);
395 r = bus_message_setup_bloom(m, bloom);
401 append_fds(&d, m->fds, m->n_fds);
403 m->kdbus->size = (uint8_t*) d - (uint8_t*) m->kdbus;
404 assert(m->kdbus->size <= sz);
413 static void unset_memfds(struct sd_bus_message *m) {
414 struct bus_body_part *part;
419 /* Make sure the memfds are not freed twice */
420 MESSAGE_FOREACH_PART(part, i, m)
421 if (part->memfd >= 0)
425 static void message_set_timestamp(sd_bus *bus, sd_bus_message *m, const struct kdbus_timestamp *ts) {
432 if (!(bus->attach_flags & KDBUS_ATTACH_TIMESTAMP))
435 m->realtime = ts->realtime_ns / NSEC_PER_USEC;
436 m->monotonic = ts->monotonic_ns / NSEC_PER_USEC;
437 m->seqnum = ts->seqnum;
440 static int bus_kernel_make_message(sd_bus *bus, struct kdbus_msg *k) {
441 sd_bus_message *m = NULL;
442 struct kdbus_item *d;
444 _cleanup_free_ int *fds = NULL;
445 struct bus_header *header = NULL;
447 size_t header_size = 0, footer_size = 0;
448 size_t n_bytes = 0, idx = 0;
449 const char *destination = NULL, *seclabel = NULL;
450 bool last_was_memfd = false;
455 assert(k->payload_type == KDBUS_PAYLOAD_DBUS);
457 KDBUS_ITEM_FOREACH(d, k, items) {
460 l = d->size - offsetof(struct kdbus_item, data);
464 case KDBUS_ITEM_PAYLOAD_OFF:
466 header = (struct bus_header*)((uint8_t*) k + d->vec.offset);
467 header_size = d->vec.size;
470 footer = (uint8_t*) k + d->vec.offset;
471 footer_size = d->vec.size;
473 n_bytes += d->vec.size;
474 last_was_memfd = false;
477 case KDBUS_ITEM_PAYLOAD_MEMFD:
478 if (!header) /* memfd cannot be first part */
481 n_bytes += d->memfd.size;
482 last_was_memfd = true;
485 case KDBUS_ITEM_FDS: {
490 f = realloc(fds, sizeof(int) * (n_fds + j));
495 memcpy(fds + n_fds, d->fds, sizeof(int) * j);
500 case KDBUS_ITEM_SECLABEL:
506 if (last_was_memfd) /* memfd cannot be last part */
512 if (header_size < sizeof(struct bus_header))
515 /* on kdbus we only speak native endian gvariant, never dbus1
516 * marshalling or reverse endian */
517 if (header->version != 2 ||
518 header->endian != BUS_NATIVE_ENDIAN)
521 r = bus_message_from_header(
531 /* The well-known names list is different from the other
532 credentials. If we asked for it, but nothing is there, this
533 means that the list of well-known names is simply empty, not
534 that we lack any data */
536 m->creds.mask |= (SD_BUS_CREDS_UNIQUE_NAME|SD_BUS_CREDS_WELL_KNOWN_NAMES) & bus->creds_mask;
538 KDBUS_ITEM_FOREACH(d, k, items) {
541 l = d->size - offsetof(struct kdbus_item, data);
545 case KDBUS_ITEM_PAYLOAD_OFF: {
548 begin_body = BUS_MESSAGE_BODY_BEGIN(m);
550 if (idx + d->vec.size > begin_body) {
551 struct bus_body_part *part;
553 /* Contains body material */
555 part = message_append_part(m);
561 /* A -1 offset is NUL padding. */
562 part->is_zero = d->vec.offset == ~0ULL;
564 if (idx >= begin_body) {
566 part->data = (uint8_t* )k + d->vec.offset;
567 part->size = d->vec.size;
570 part->data = (uint8_t*) k + d->vec.offset + (begin_body - idx);
571 part->size = d->vec.size - (begin_body - idx);
581 case KDBUS_ITEM_PAYLOAD_MEMFD: {
582 struct bus_body_part *part;
584 if (idx < BUS_MESSAGE_BODY_BEGIN(m)) {
589 part = message_append_part(m);
595 part->memfd = d->memfd.fd;
596 part->memfd_offset = d->memfd.start;
597 part->size = d->memfd.size;
600 idx += d->memfd.size;
604 case KDBUS_ITEM_PIDS:
606 /* The PID/TID might be missing, when the data
607 * is faked by a bus proxy and it lacks that
608 * information about the real client (since
609 * SO_PEERCRED is used for that). Also kernel
610 * namespacing might make some of this data
611 * unavailable when untranslatable. */
613 if (d->pids.pid > 0) {
614 m->creds.pid = (pid_t) d->pids.pid;
615 m->creds.mask |= SD_BUS_CREDS_PID & bus->creds_mask;
618 if (d->pids.tid > 0) {
619 m->creds.tid = (pid_t) d->pids.tid;
620 m->creds.mask |= SD_BUS_CREDS_TID & bus->creds_mask;
623 if (d->pids.ppid > 0) {
624 m->creds.ppid = (pid_t) d->pids.ppid;
625 m->creds.mask |= SD_BUS_CREDS_PPID & bus->creds_mask;
626 } else if (d->pids.pid == 1) {
628 m->creds.mask |= SD_BUS_CREDS_PPID & bus->creds_mask;
633 case KDBUS_ITEM_CREDS:
635 /* EUID/SUID/FSUID/EGID/SGID/FSGID might be
636 * missing too (see above). */
638 if ((uid_t) d->creds.uid != UID_INVALID) {
639 m->creds.uid = (uid_t) d->creds.uid;
640 m->creds.mask |= SD_BUS_CREDS_UID & bus->creds_mask;
643 if ((uid_t) d->creds.euid != UID_INVALID) {
644 m->creds.euid = (uid_t) d->creds.euid;
645 m->creds.mask |= SD_BUS_CREDS_EUID & bus->creds_mask;
648 if ((uid_t) d->creds.suid != UID_INVALID) {
649 m->creds.suid = (uid_t) d->creds.suid;
650 m->creds.mask |= SD_BUS_CREDS_SUID & bus->creds_mask;
653 if ((uid_t) d->creds.fsuid != UID_INVALID) {
654 m->creds.fsuid = (uid_t) d->creds.fsuid;
655 m->creds.mask |= SD_BUS_CREDS_FSUID & bus->creds_mask;
658 if ((gid_t) d->creds.gid != GID_INVALID) {
659 m->creds.gid = (gid_t) d->creds.gid;
660 m->creds.mask |= SD_BUS_CREDS_GID & bus->creds_mask;
663 if ((gid_t) d->creds.egid != GID_INVALID) {
664 m->creds.egid = (gid_t) d->creds.egid;
665 m->creds.mask |= SD_BUS_CREDS_EGID & bus->creds_mask;
668 if ((gid_t) d->creds.sgid != GID_INVALID) {
669 m->creds.sgid = (gid_t) d->creds.sgid;
670 m->creds.mask |= SD_BUS_CREDS_SGID & bus->creds_mask;
673 if ((gid_t) d->creds.fsgid != GID_INVALID) {
674 m->creds.fsgid = (gid_t) d->creds.fsgid;
675 m->creds.mask |= SD_BUS_CREDS_FSGID & bus->creds_mask;
680 case KDBUS_ITEM_TIMESTAMP:
681 message_set_timestamp(bus, m, &d->timestamp);
684 case KDBUS_ITEM_PID_COMM:
685 m->creds.comm = d->str;
686 m->creds.mask |= SD_BUS_CREDS_COMM & bus->creds_mask;
689 case KDBUS_ITEM_TID_COMM:
690 m->creds.tid_comm = d->str;
691 m->creds.mask |= SD_BUS_CREDS_TID_COMM & bus->creds_mask;
695 m->creds.exe = d->str;
696 m->creds.mask |= SD_BUS_CREDS_EXE & bus->creds_mask;
699 case KDBUS_ITEM_CMDLINE:
700 m->creds.cmdline = d->str;
701 m->creds.cmdline_size = l;
702 m->creds.mask |= SD_BUS_CREDS_CMDLINE & bus->creds_mask;
705 case KDBUS_ITEM_CGROUP:
706 m->creds.cgroup = d->str;
707 m->creds.mask |= (SD_BUS_CREDS_CGROUP|SD_BUS_CREDS_UNIT|SD_BUS_CREDS_USER_UNIT|SD_BUS_CREDS_SLICE|SD_BUS_CREDS_SESSION|SD_BUS_CREDS_OWNER_UID) & bus->creds_mask;
709 r = bus_get_root_path(bus);
713 m->creds.cgroup_root = bus->cgroup_root;
716 case KDBUS_ITEM_AUDIT:
717 m->creds.audit_session_id = (uint32_t) d->audit.sessionid;
718 m->creds.mask |= SD_BUS_CREDS_AUDIT_SESSION_ID & bus->creds_mask;
720 m->creds.audit_login_uid = (uid_t) d->audit.loginuid;
721 m->creds.mask |= SD_BUS_CREDS_AUDIT_LOGIN_UID & bus->creds_mask;
724 case KDBUS_ITEM_CAPS:
725 if (d->caps.last_cap != cap_last_cap() ||
726 d->size - offsetof(struct kdbus_item, caps.caps) < DIV_ROUND_UP(d->caps.last_cap, 32U) * 4 * 4) {
731 m->creds.capability = d->caps.caps;
732 m->creds.mask |= (SD_BUS_CREDS_EFFECTIVE_CAPS|SD_BUS_CREDS_PERMITTED_CAPS|SD_BUS_CREDS_INHERITABLE_CAPS|SD_BUS_CREDS_BOUNDING_CAPS) & bus->creds_mask;
735 case KDBUS_ITEM_DST_NAME:
736 if (!service_name_is_valid(d->str)) {
741 destination = d->str;
744 case KDBUS_ITEM_OWNED_NAME:
745 if (!service_name_is_valid(d->name.name)) {
750 if (bus->creds_mask & SD_BUS_CREDS_WELL_KNOWN_NAMES) {
754 /* We just extend the array here, but
755 * do not allocate the strings inside
756 * of it, instead we just point to our
757 * buffer directly. */
758 n = strv_length(m->creds.well_known_names);
759 wkn = realloc(m->creds.well_known_names, (n + 2) * sizeof(char*));
765 wkn[n] = d->name.name;
767 m->creds.well_known_names = wkn;
769 m->creds.mask |= SD_BUS_CREDS_WELL_KNOWN_NAMES;
773 case KDBUS_ITEM_CONN_DESCRIPTION:
774 m->creds.description = d->str;
775 m->creds.mask |= SD_BUS_CREDS_DESCRIPTION & bus->creds_mask;
778 case KDBUS_ITEM_AUXGROUPS:
780 if (bus->creds_mask & SD_BUS_CREDS_SUPPLEMENTARY_GIDS) {
784 n = (d->size - offsetof(struct kdbus_item, data64)) / sizeof(uint64_t);
791 for (i = 0; i < n; i++)
794 m->creds.supplementary_gids = g;
795 m->creds.n_supplementary_gids = n;
796 m->creds.mask |= SD_BUS_CREDS_SUPPLEMENTARY_GIDS;
802 case KDBUS_ITEM_SECLABEL:
803 case KDBUS_ITEM_BLOOM_FILTER:
807 log_debug("Got unknown field from kernel %llu", d->type);
811 /* If we requested the list of well-known names to be appended
812 * and the sender had none no item for it will be
813 * attached. However, this does *not* mean that the kernel
814 * didn't want to provide this information to us. Hence, let's
815 * explicitly mark this information as available if it was
817 m->creds.mask |= bus->creds_mask & SD_BUS_CREDS_WELL_KNOWN_NAMES;
819 r = bus_message_parse_fields(m);
823 /* Refuse messages if kdbus and dbus1 cookie doesn't match up */
824 if ((uint64_t) m->header->dbus2.cookie != k->cookie) {
829 /* Refuse messages where the reply flag doesn't match up */
830 if (!(m->header->flags & BUS_MESSAGE_NO_REPLY_EXPECTED) != !!(k->flags & KDBUS_MSG_EXPECT_REPLY)) {
835 /* Refuse reply messages where the reply cookie doesn't match up */
836 if ((m->header->flags & BUS_MESSAGE_NO_REPLY_EXPECTED) && m->reply_cookie != k->cookie_reply) {
841 /* Refuse messages where the autostart flag doesn't match up */
842 if (!(m->header->flags & BUS_MESSAGE_NO_AUTO_START) != !(k->flags & KDBUS_MSG_NO_AUTO_START)) {
847 /* Override information from the user header with data from the kernel */
848 if (k->src_id == KDBUS_SRC_ID_KERNEL)
849 bus_message_set_sender_driver(bus, m);
851 xsprintf(m->sender_buffer, ":1.%llu", k->src_id);
852 m->sender = m->creds.unique_name = m->sender_buffer;
856 m->destination = destination;
857 else if (k->dst_id == KDBUS_DST_ID_BROADCAST)
858 m->destination = NULL;
859 else if (k->dst_id == KDBUS_DST_ID_NAME)
860 m->destination = bus->unique_name; /* fill in unique name if the well-known name is missing */
862 xsprintf(m->destination_buffer, ":1.%llu", k->dst_id);
863 m->destination = m->destination_buffer;
866 /* We take possession of the kmsg struct now */
868 m->release_kdbus = true;
872 bus->rqueue[bus->rqueue_size++] = m;
878 sd_bus_message_unref(m);
883 int bus_kernel_take_fd(sd_bus *b) {
884 struct kdbus_bloom_parameter *bloom = NULL;
885 struct kdbus_item *items, *item;
886 struct kdbus_cmd_hello *hello;
887 _cleanup_free_ char *g = NULL;
889 size_t l = 0, m = 0, sz;
899 if (b->description) {
900 g = bus_label_escape(b->description);
908 /* If no name is explicitly set, we'll include a hint
909 * indicating the library implementation, a hint which
910 * kind of bus this is and the thread name */
912 assert_se(prctl(PR_GET_NAME, (unsigned long) pr) >= 0);
915 name = b->is_system ? "sd-system" :
916 b->is_user ? "sd-user" : "sd";
918 _cleanup_free_ char *e = NULL;
920 e = bus_label_escape(pr);
924 g = strappend(b->is_system ? "sd-system-" :
925 b->is_user ? "sd-user-" : "sd-",
933 b->description = bus_label_unescape(name);
940 sz = ALIGN8(offsetof(struct kdbus_cmd_hello, items)) +
941 ALIGN8(offsetof(struct kdbus_item, str) + m + 1);
943 if (b->fake_creds_valid)
944 sz += ALIGN8(offsetof(struct kdbus_item, creds) + sizeof(struct kdbus_creds));
946 if (b->fake_pids_valid)
947 sz += ALIGN8(offsetof(struct kdbus_item, pids) + sizeof(struct kdbus_pids));
950 l = strlen(b->fake_label);
951 sz += ALIGN8(offsetof(struct kdbus_item, str) + l + 1);
954 hello = alloca0_align(sz, 8);
956 hello->flags = b->hello_flags;
957 hello->attach_flags_send = _KDBUS_ATTACH_ANY;
958 hello->attach_flags_recv = b->attach_flags;
959 hello->pool_size = KDBUS_POOL_SIZE;
963 item->size = offsetof(struct kdbus_item, str) + m + 1;
964 item->type = KDBUS_ITEM_CONN_DESCRIPTION;
965 memcpy(item->str, name, m + 1);
966 item = KDBUS_ITEM_NEXT(item);
968 if (b->fake_creds_valid) {
969 item->size = offsetof(struct kdbus_item, creds) + sizeof(struct kdbus_creds);
970 item->type = KDBUS_ITEM_CREDS;
971 item->creds = b->fake_creds;
973 item = KDBUS_ITEM_NEXT(item);
976 if (b->fake_pids_valid) {
977 item->size = offsetof(struct kdbus_item, pids) + sizeof(struct kdbus_pids);
978 item->type = KDBUS_ITEM_PIDS;
979 item->pids = b->fake_pids;
981 item = KDBUS_ITEM_NEXT(item);
985 item->size = offsetof(struct kdbus_item, str) + l + 1;
986 item->type = KDBUS_ITEM_SECLABEL;
987 memcpy(item->str, b->fake_label, l+1);
990 r = ioctl(b->input_fd, KDBUS_CMD_HELLO, hello);
993 /* If the ioctl is not supported we assume that the
994 * API version changed in a major incompatible way,
995 * let's indicate an API incompatibility in this
997 return -ESOCKTNOSUPPORT;
1002 if (!b->kdbus_buffer) {
1003 b->kdbus_buffer = mmap(NULL, KDBUS_POOL_SIZE, PROT_READ, MAP_SHARED, b->input_fd, 0);
1004 if (b->kdbus_buffer == MAP_FAILED) {
1005 b->kdbus_buffer = NULL;
1011 /* The higher 32bit of the bus_flags fields are considered
1012 * 'incompatible flags'. Refuse them all for now. */
1013 if (hello->bus_flags > 0xFFFFFFFFULL) {
1014 r = -ESOCKTNOSUPPORT;
1018 /* extract bloom parameters from items */
1019 items = (void*)((uint8_t*)b->kdbus_buffer + hello->offset);
1020 KDBUS_FOREACH(item, items, hello->items_size) {
1021 switch (item->type) {
1022 case KDBUS_ITEM_BLOOM_PARAMETER:
1023 bloom = &item->bloom_parameter;
1028 if (!bloom || !bloom_validate_parameters((size_t) bloom->size, (unsigned) bloom->n_hash)) {
1033 b->bloom_size = (size_t) bloom->size;
1034 b->bloom_n_hash = (unsigned) bloom->n_hash;
1036 if (asprintf(&b->unique_name, ":1.%llu", hello->id) < 0) {
1041 b->unique_id = hello->id;
1043 b->is_kernel = true;
1044 b->bus_client = true;
1045 b->can_fds = !!(hello->flags & KDBUS_HELLO_ACCEPT_FD);
1046 b->message_version = 2;
1047 b->message_endian = BUS_NATIVE_ENDIAN;
1049 /* the kernel told us the UUID of the underlying bus */
1050 memcpy(b->server_id.bytes, hello->id128, sizeof(b->server_id.bytes));
1052 /* free returned items */
1053 (void) bus_kernel_cmd_free(b, hello->offset);
1054 return bus_start_running(b);
1057 (void) bus_kernel_cmd_free(b, hello->offset);
1061 int bus_kernel_connect(sd_bus *b) {
1063 assert(b->input_fd < 0);
1064 assert(b->output_fd < 0);
1070 b->input_fd = open(b->kernel, O_RDWR|O_NOCTTY|O_CLOEXEC);
1071 if (b->input_fd < 0)
1074 b->output_fd = b->input_fd;
1076 return bus_kernel_take_fd(b);
1079 int bus_kernel_cmd_free(sd_bus *bus, uint64_t offset) {
1080 struct kdbus_cmd_free cmd = {
1081 .size = sizeof(cmd),
1087 assert(bus->is_kernel);
1089 r = ioctl(bus->input_fd, KDBUS_CMD_FREE, &cmd);
1096 static void close_kdbus_msg(sd_bus *bus, struct kdbus_msg *k) {
1097 struct kdbus_item *d;
1102 KDBUS_ITEM_FOREACH(d, k, items) {
1103 if (d->type == KDBUS_ITEM_FDS)
1104 close_many(d->fds, (d->size - offsetof(struct kdbus_item, fds)) / sizeof(int));
1105 else if (d->type == KDBUS_ITEM_PAYLOAD_MEMFD)
1106 safe_close(d->memfd.fd);
1109 bus_kernel_cmd_free(bus, (uint8_t*) k - (uint8_t*) bus->kdbus_buffer);
1112 int bus_kernel_write_message(sd_bus *bus, sd_bus_message *m, bool hint_sync_call) {
1113 struct kdbus_cmd_send cmd = { };
1118 assert(bus->state == BUS_RUNNING);
1120 /* If we can't deliver, we want room for the error message */
1121 r = bus_rqueue_make_room(bus);
1125 r = bus_message_setup_kmsg(bus, m);
1129 cmd.size = sizeof(cmd);
1130 cmd.msg_address = (uintptr_t)m->kdbus;
1132 /* If this is a synchronous method call, then let's tell the
1133 * kernel, so that it can pass CPU time/scheduling to the
1134 * destination for the time, if it wants to. If we
1135 * synchronously wait for the result anyway, we won't need CPU
1137 if (hint_sync_call) {
1138 m->kdbus->flags |= KDBUS_MSG_EXPECT_REPLY;
1139 cmd.flags |= KDBUS_SEND_SYNC_REPLY;
1142 r = ioctl(bus->output_fd, KDBUS_CMD_SEND, &cmd);
1144 _cleanup_(sd_bus_error_free) sd_bus_error error = SD_BUS_ERROR_NULL;
1145 sd_bus_message *reply;
1147 if (errno == EAGAIN || errno == EINTR)
1149 else if (errno == ENXIO || errno == ESRCH) {
1151 /* ENXIO: unique name not known
1152 * ESRCH: well-known name not known */
1154 if (m->header->type == SD_BUS_MESSAGE_METHOD_CALL)
1155 sd_bus_error_setf(&error, SD_BUS_ERROR_SERVICE_UNKNOWN, "Destination %s not known", m->destination);
1157 log_debug("Could not deliver message to %s as destination is not known. Ignoring.", m->destination);
1161 } else if (errno == EADDRNOTAVAIL) {
1163 /* EADDRNOTAVAIL: activation is possible, but turned off in request flags */
1165 if (m->header->type == SD_BUS_MESSAGE_METHOD_CALL)
1166 sd_bus_error_setf(&error, SD_BUS_ERROR_SERVICE_UNKNOWN, "Activation of %s not requested", m->destination);
1168 log_debug("Could not deliver message to %s as destination is not activated. Ignoring.", m->destination);
1174 r = bus_message_new_synthetic_error(
1176 BUS_MESSAGE_COOKIE(m),
1183 r = bus_seal_synthetic_message(bus, reply);
1187 bus->rqueue[bus->rqueue_size++] = reply;
1189 } else if (hint_sync_call) {
1190 struct kdbus_msg *k;
1192 k = (struct kdbus_msg *)((uint8_t *)bus->kdbus_buffer + cmd.reply.offset);
1195 if (k->payload_type == KDBUS_PAYLOAD_DBUS) {
1197 r = bus_kernel_make_message(bus, k);
1199 close_kdbus_msg(bus, k);
1201 /* Anybody can send us invalid messages, let's just drop them. */
1202 if (r == -EBADMSG || r == -EPROTOTYPE)
1203 log_debug_errno(r, "Ignoring invalid synchronous reply: %m");
1208 log_debug("Ignoring message with unknown payload type %llu.", k->payload_type);
1209 close_kdbus_msg(bus, k);
1216 static int push_name_owner_changed(
1219 const char *old_owner,
1220 const char *new_owner,
1221 const struct kdbus_timestamp *ts) {
1223 _cleanup_(sd_bus_message_unrefp) sd_bus_message *m = NULL;
1228 r = sd_bus_message_new_signal(
1231 "/org/freedesktop/DBus",
1232 "org.freedesktop.DBus",
1233 "NameOwnerChanged");
1237 r = sd_bus_message_append(m, "sss", name, old_owner, new_owner);
1241 bus_message_set_sender_driver(bus, m);
1242 message_set_timestamp(bus, m, ts);
1244 r = bus_seal_synthetic_message(bus, m);
1248 bus->rqueue[bus->rqueue_size++] = m;
1254 static int translate_name_change(
1256 const struct kdbus_msg *k,
1257 const struct kdbus_item *d,
1258 const struct kdbus_timestamp *ts) {
1260 char new_owner[UNIQUE_NAME_MAX], old_owner[UNIQUE_NAME_MAX];
1266 if (d->type == KDBUS_ITEM_NAME_ADD || (d->name_change.old_id.flags & (KDBUS_NAME_IN_QUEUE|KDBUS_NAME_ACTIVATOR)))
1269 sprintf(old_owner, ":1.%llu", d->name_change.old_id.id);
1271 if (d->type == KDBUS_ITEM_NAME_REMOVE || (d->name_change.new_id.flags & (KDBUS_NAME_IN_QUEUE|KDBUS_NAME_ACTIVATOR))) {
1273 if (isempty(old_owner))
1278 sprintf(new_owner, ":1.%llu", d->name_change.new_id.id);
1280 return push_name_owner_changed(bus, d->name_change.name, old_owner, new_owner, ts);
1283 static int translate_id_change(
1285 const struct kdbus_msg *k,
1286 const struct kdbus_item *d,
1287 const struct kdbus_timestamp *ts) {
1289 char owner[UNIQUE_NAME_MAX];
1295 sprintf(owner, ":1.%llu", d->id_change.id);
1297 return push_name_owner_changed(
1299 d->type == KDBUS_ITEM_ID_ADD ? NULL : owner,
1300 d->type == KDBUS_ITEM_ID_ADD ? owner : NULL,
1304 static int translate_reply(
1306 const struct kdbus_msg *k,
1307 const struct kdbus_item *d,
1308 const struct kdbus_timestamp *ts) {
1310 _cleanup_(sd_bus_message_unrefp) sd_bus_message *m = NULL;
1317 r = bus_message_new_synthetic_error(
1320 d->type == KDBUS_ITEM_REPLY_TIMEOUT ?
1321 &SD_BUS_ERROR_MAKE_CONST(SD_BUS_ERROR_NO_REPLY, "Method call timed out") :
1322 &SD_BUS_ERROR_MAKE_CONST(SD_BUS_ERROR_NO_REPLY, "Method call peer died"),
1327 message_set_timestamp(bus, m, ts);
1329 r = bus_seal_synthetic_message(bus, m);
1333 bus->rqueue[bus->rqueue_size++] = m;
1339 static int bus_kernel_translate_message(sd_bus *bus, struct kdbus_msg *k) {
1340 static int (* const translate[])(sd_bus *bus, const struct kdbus_msg *k, const struct kdbus_item *d, const struct kdbus_timestamp *ts) = {
1341 [KDBUS_ITEM_NAME_ADD - _KDBUS_ITEM_KERNEL_BASE] = translate_name_change,
1342 [KDBUS_ITEM_NAME_REMOVE - _KDBUS_ITEM_KERNEL_BASE] = translate_name_change,
1343 [KDBUS_ITEM_NAME_CHANGE - _KDBUS_ITEM_KERNEL_BASE] = translate_name_change,
1345 [KDBUS_ITEM_ID_ADD - _KDBUS_ITEM_KERNEL_BASE] = translate_id_change,
1346 [KDBUS_ITEM_ID_REMOVE - _KDBUS_ITEM_KERNEL_BASE] = translate_id_change,
1348 [KDBUS_ITEM_REPLY_TIMEOUT - _KDBUS_ITEM_KERNEL_BASE] = translate_reply,
1349 [KDBUS_ITEM_REPLY_DEAD - _KDBUS_ITEM_KERNEL_BASE] = translate_reply,
1352 struct kdbus_item *d, *found = NULL;
1353 struct kdbus_timestamp *ts = NULL;
1357 assert(k->payload_type == KDBUS_PAYLOAD_KERNEL);
1359 KDBUS_ITEM_FOREACH(d, k, items) {
1360 if (d->type == KDBUS_ITEM_TIMESTAMP)
1362 else if (d->type >= _KDBUS_ITEM_KERNEL_BASE && d->type < _KDBUS_ITEM_KERNEL_BASE + ELEMENTSOF(translate)) {
1367 log_debug("Got unknown field from kernel %llu", d->type);
1371 log_debug("Didn't find a kernel message to translate.");
1375 return translate[found->type - _KDBUS_ITEM_KERNEL_BASE](bus, k, found, ts);
1378 int bus_kernel_read_message(sd_bus *bus, bool hint_priority, int64_t priority) {
1379 struct kdbus_cmd_recv recv = { .size = sizeof(recv) };
1380 struct kdbus_msg *k;
1385 r = bus_rqueue_make_room(bus);
1389 if (hint_priority) {
1390 recv.flags |= KDBUS_RECV_USE_PRIORITY;
1391 recv.priority = priority;
1394 r = ioctl(bus->input_fd, KDBUS_CMD_RECV, &recv);
1395 if (recv.return_flags & KDBUS_RECV_RETURN_DROPPED_MSGS)
1396 log_debug("%s: kdbus reports %" PRIu64 " dropped broadcast messages, ignoring.", strna(bus->description), (uint64_t) recv.dropped_msgs);
1398 if (errno == EAGAIN)
1404 k = (struct kdbus_msg *)((uint8_t *)bus->kdbus_buffer + recv.msg.offset);
1405 if (k->payload_type == KDBUS_PAYLOAD_DBUS) {
1406 r = bus_kernel_make_message(bus, k);
1408 /* Anybody can send us invalid messages, let's just drop them. */
1409 if (r == -EBADMSG || r == -EPROTOTYPE) {
1410 log_debug_errno(r, "Ignoring invalid message: %m");
1415 close_kdbus_msg(bus, k);
1416 } else if (k->payload_type == KDBUS_PAYLOAD_KERNEL) {
1417 r = bus_kernel_translate_message(bus, k);
1418 close_kdbus_msg(bus, k);
1420 log_debug("Ignoring message with unknown payload type %llu.", k->payload_type);
1422 close_kdbus_msg(bus, k);
1425 return r < 0 ? r : 1;
1428 int bus_kernel_pop_memfd(sd_bus *bus, void **address, size_t *mapped, size_t *allocated) {
1429 struct memfd_cache *c;
1436 if (!bus || !bus->is_kernel)
1439 assert_se(pthread_mutex_lock(&bus->memfd_cache_mutex) == 0);
1441 if (bus->n_memfd_cache <= 0) {
1444 assert_se(pthread_mutex_unlock(&bus->memfd_cache_mutex) == 0);
1446 r = memfd_new(bus->description);
1456 c = &bus->memfd_cache[--bus->n_memfd_cache];
1459 assert(c->mapped == 0 || c->address);
1461 *address = c->address;
1462 *mapped = c->mapped;
1463 *allocated = c->allocated;
1466 assert_se(pthread_mutex_unlock(&bus->memfd_cache_mutex) == 0);
1471 static void close_and_munmap(int fd, void *address, size_t size) {
1473 assert_se(munmap(address, PAGE_ALIGN(size)) >= 0);
1478 void bus_kernel_push_memfd(sd_bus *bus, int fd, void *address, size_t mapped, size_t allocated) {
1479 struct memfd_cache *c;
1480 uint64_t max_mapped = PAGE_ALIGN(MEMFD_CACHE_ITEM_SIZE_MAX);
1483 assert(mapped == 0 || address);
1485 if (!bus || !bus->is_kernel) {
1486 close_and_munmap(fd, address, mapped);
1490 assert_se(pthread_mutex_lock(&bus->memfd_cache_mutex) == 0);
1492 if (bus->n_memfd_cache >= ELEMENTSOF(bus->memfd_cache)) {
1493 assert_se(pthread_mutex_unlock(&bus->memfd_cache_mutex) == 0);
1495 close_and_munmap(fd, address, mapped);
1499 c = &bus->memfd_cache[bus->n_memfd_cache++];
1501 c->address = address;
1503 /* If overly long, let's return a bit to the OS */
1504 if (mapped > max_mapped) {
1505 assert_se(memfd_set_size(fd, max_mapped) >= 0);
1506 assert_se(munmap((uint8_t*) address + max_mapped, PAGE_ALIGN(mapped - max_mapped)) >= 0);
1507 c->mapped = c->allocated = max_mapped;
1510 c->allocated = allocated;
1513 assert_se(pthread_mutex_unlock(&bus->memfd_cache_mutex) == 0);
1516 void bus_kernel_flush_memfd(sd_bus *b) {
1521 for (i = 0; i < b->n_memfd_cache; i++)
1522 close_and_munmap(b->memfd_cache[i].fd, b->memfd_cache[i].address, b->memfd_cache[i].mapped);
1525 uint64_t request_name_flags_to_kdbus(uint64_t flags) {
1528 if (flags & SD_BUS_NAME_ALLOW_REPLACEMENT)
1529 f |= KDBUS_NAME_ALLOW_REPLACEMENT;
1531 if (flags & SD_BUS_NAME_REPLACE_EXISTING)
1532 f |= KDBUS_NAME_REPLACE_EXISTING;
1534 if (flags & SD_BUS_NAME_QUEUE)
1535 f |= KDBUS_NAME_QUEUE;
1540 uint64_t attach_flags_to_kdbus(uint64_t mask) {
1543 if (mask & (SD_BUS_CREDS_UID|SD_BUS_CREDS_EUID|SD_BUS_CREDS_SUID|SD_BUS_CREDS_FSUID|
1544 SD_BUS_CREDS_GID|SD_BUS_CREDS_EGID|SD_BUS_CREDS_SGID|SD_BUS_CREDS_FSGID))
1545 m |= KDBUS_ATTACH_CREDS;
1547 if (mask & (SD_BUS_CREDS_PID|SD_BUS_CREDS_TID|SD_BUS_CREDS_PPID))
1548 m |= KDBUS_ATTACH_PIDS;
1550 if (mask & SD_BUS_CREDS_COMM)
1551 m |= KDBUS_ATTACH_PID_COMM;
1553 if (mask & SD_BUS_CREDS_TID_COMM)
1554 m |= KDBUS_ATTACH_TID_COMM;
1556 if (mask & SD_BUS_CREDS_EXE)
1557 m |= KDBUS_ATTACH_EXE;
1559 if (mask & SD_BUS_CREDS_CMDLINE)
1560 m |= KDBUS_ATTACH_CMDLINE;
1562 if (mask & (SD_BUS_CREDS_CGROUP|SD_BUS_CREDS_UNIT|SD_BUS_CREDS_USER_UNIT|SD_BUS_CREDS_SLICE|SD_BUS_CREDS_SESSION|SD_BUS_CREDS_OWNER_UID))
1563 m |= KDBUS_ATTACH_CGROUP;
1565 if (mask & (SD_BUS_CREDS_EFFECTIVE_CAPS|SD_BUS_CREDS_PERMITTED_CAPS|SD_BUS_CREDS_INHERITABLE_CAPS|SD_BUS_CREDS_BOUNDING_CAPS))
1566 m |= KDBUS_ATTACH_CAPS;
1568 if (mask & SD_BUS_CREDS_SELINUX_CONTEXT)
1569 m |= KDBUS_ATTACH_SECLABEL;
1571 if (mask & (SD_BUS_CREDS_AUDIT_SESSION_ID|SD_BUS_CREDS_AUDIT_LOGIN_UID))
1572 m |= KDBUS_ATTACH_AUDIT;
1574 if (mask & SD_BUS_CREDS_WELL_KNOWN_NAMES)
1575 m |= KDBUS_ATTACH_NAMES;
1577 if (mask & SD_BUS_CREDS_DESCRIPTION)
1578 m |= KDBUS_ATTACH_CONN_DESCRIPTION;
1580 if (mask & SD_BUS_CREDS_SUPPLEMENTARY_GIDS)
1581 m |= KDBUS_ATTACH_AUXGROUPS;
1586 #if 0 /// UNNEEDED by elogind
1587 int bus_kernel_create_bus(const char *name, bool world, char **s) {
1588 struct kdbus_cmd *make;
1589 struct kdbus_item *n;
1596 fd = open("/sys/fs/kdbus/control", O_RDWR|O_NOCTTY|O_CLOEXEC);
1601 make = alloca0_align(offsetof(struct kdbus_cmd, items) +
1602 ALIGN8(offsetof(struct kdbus_item, bloom_parameter) + sizeof(struct kdbus_bloom_parameter)) +
1603 ALIGN8(offsetof(struct kdbus_item, data64) + sizeof(uint64_t)) +
1604 ALIGN8(offsetof(struct kdbus_item, str) + DECIMAL_STR_MAX(uid_t) + 1 + l + 1),
1607 make->size = offsetof(struct kdbus_cmd, items);
1609 /* Set the bloom parameters */
1611 n->size = offsetof(struct kdbus_item, bloom_parameter) +
1612 sizeof(struct kdbus_bloom_parameter);
1613 n->type = KDBUS_ITEM_BLOOM_PARAMETER;
1614 n->bloom_parameter.size = DEFAULT_BLOOM_SIZE;
1615 n->bloom_parameter.n_hash = DEFAULT_BLOOM_N_HASH;
1617 assert_cc(DEFAULT_BLOOM_SIZE > 0);
1618 assert_cc(DEFAULT_BLOOM_N_HASH > 0);
1620 make->size += ALIGN8(n->size);
1622 /* Provide all metadata via bus-owner queries */
1623 n = KDBUS_ITEM_NEXT(n);
1624 n->type = KDBUS_ITEM_ATTACH_FLAGS_SEND;
1625 n->size = offsetof(struct kdbus_item, data64) + sizeof(uint64_t);
1626 n->data64[0] = _KDBUS_ATTACH_ANY;
1627 make->size += ALIGN8(n->size);
1629 /* Set the a good name */
1630 n = KDBUS_ITEM_NEXT(n);
1631 sprintf(n->str, UID_FMT "-%s", getuid(), name);
1632 n->size = offsetof(struct kdbus_item, str) + strlen(n->str) + 1;
1633 n->type = KDBUS_ITEM_MAKE_NAME;
1634 make->size += ALIGN8(n->size);
1636 make->flags = world ? KDBUS_MAKE_ACCESS_WORLD : 0;
1638 if (ioctl(fd, KDBUS_CMD_BUS_MAKE, make) < 0) {
1641 /* Major API change? then the ioctls got shuffled around. */
1642 if (errno == ENOTTY)
1643 return -ESOCKTNOSUPPORT;
1651 p = strjoin("/sys/fs/kdbus/", n->str, "/bus");
1664 int bus_kernel_open_bus_fd(const char *bus, char **path) {
1671 len = strlen("/sys/fs/kdbus/") + DECIMAL_STR_MAX(uid_t) + 1 + strlen(bus) + strlen("/bus") + 1;
1678 p = newa(char, len);
1680 sprintf(p, "/sys/fs/kdbus/" UID_FMT "-%s/bus", getuid(), bus);
1682 fd = open(p, O_RDWR|O_NOCTTY|O_CLOEXEC);
1696 int bus_kernel_try_close(sd_bus *bus) {
1697 struct kdbus_cmd byebye = { .size = sizeof(byebye) };
1700 assert(bus->is_kernel);
1702 if (ioctl(bus->input_fd, KDBUS_CMD_BYEBYE, &byebye) < 0)
1708 #if 0 /// UNNEEDED by elogind
1709 int bus_kernel_drop_one(int fd) {
1710 struct kdbus_cmd_recv recv = {
1711 .size = sizeof(recv),
1712 .flags = KDBUS_RECV_DROP,
1717 if (ioctl(fd, KDBUS_CMD_RECV, &recv) < 0)
1724 int bus_kernel_realize_attach_flags(sd_bus *bus) {
1725 struct kdbus_cmd *update;
1726 struct kdbus_item *n;
1729 assert(bus->is_kernel);
1731 update = alloca0_align(offsetof(struct kdbus_cmd, items) +
1732 ALIGN8(offsetof(struct kdbus_item, data64) + sizeof(uint64_t)),
1736 n->type = KDBUS_ITEM_ATTACH_FLAGS_RECV;
1737 n->size = offsetof(struct kdbus_item, data64) + sizeof(uint64_t);
1738 n->data64[0] = bus->attach_flags;
1741 offsetof(struct kdbus_cmd, items) +
1744 if (ioctl(bus->input_fd, KDBUS_CMD_UPDATE, update) < 0)
1750 int bus_kernel_get_bus_name(sd_bus *bus, char **name) {
1751 struct kdbus_cmd_info cmd = {
1752 .size = sizeof(struct kdbus_cmd_info),
1754 struct kdbus_info *info;
1755 struct kdbus_item *item;
1761 assert(bus->is_kernel);
1763 r = ioctl(bus->input_fd, KDBUS_CMD_BUS_CREATOR_INFO, &cmd);
1767 info = (struct kdbus_info*) ((uint8_t*) bus->kdbus_buffer + cmd.offset);
1769 KDBUS_ITEM_FOREACH(item, info, items)
1770 if (item->type == KDBUS_ITEM_MAKE_NAME) {
1771 r = free_and_strdup(&n, item->str);
1775 bus_kernel_cmd_free(bus, cmd.offset);