/*-*- Mode: C; c-basic-offset: 8; indent-tabs-mode: nil -*-*/ /*** This file is part of systemd. Copyright 2013 Lennart Poettering systemd is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 2.1 of the License, or (at your option) any later version. systemd is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with systemd; If not, see . ***/ #ifdef HAVE_VALGRIND_MEMCHECK_H #include #endif #include #include #include #include "util.h" #include "bus-internal.h" #include "bus-message.h" #include "bus-kernel.h" #include "bus-bloom.h" int bus_kernel_parse_unique_name(const char *s, uint64_t *id) { int r; assert(s); assert(id); if (!startswith(s, ":1.")) return 0; r = safe_atou64(s + 3, id); if (r < 0) return r; return 1; } static void append_payload_vec(struct kdbus_item **d, const void *p, size_t sz) { assert(d); assert(sz > 0); *d = ALIGN8_PTR(*d); /* Note that p can be NULL, which encodes a region full of * zeroes, which is useful to optimize certain padding * conditions */ (*d)->size = offsetof(struct kdbus_item, vec) + sizeof(struct kdbus_vec); (*d)->type = KDBUS_MSG_PAYLOAD_VEC; (*d)->vec.address = PTR_TO_UINT64(p); (*d)->vec.size = sz; *d = (struct kdbus_item *) ((uint8_t*) *d + (*d)->size); } static void append_payload_memfd(struct kdbus_item **d, int memfd, size_t sz) { assert(d); assert(memfd >= 0); assert(sz > 0); *d = ALIGN8_PTR(*d); (*d)->size = offsetof(struct kdbus_item, memfd) + sizeof(struct kdbus_memfd); (*d)->type = KDBUS_MSG_PAYLOAD_MEMFD; (*d)->memfd.fd = memfd; (*d)->memfd.size = sz; *d = (struct kdbus_item *) ((uint8_t*) *d + (*d)->size); } static void append_destination(struct kdbus_item **d, const char *s, size_t length) { assert(d); assert(s); *d = ALIGN8_PTR(*d); (*d)->size = offsetof(struct kdbus_item, str) + length + 1; (*d)->type = KDBUS_MSG_DST_NAME; memcpy((*d)->str, s, length + 1); *d = (struct kdbus_item *) ((uint8_t*) *d + (*d)->size); } static void* append_bloom(struct kdbus_item **d, size_t length) { void *r; assert(d); *d = ALIGN8_PTR(*d); (*d)->size = offsetof(struct kdbus_item, data) + length; (*d)->type = KDBUS_MSG_BLOOM; r = (*d)->data; *d = (struct kdbus_item *) ((uint8_t*) *d + (*d)->size); return r; } static void append_fds(struct kdbus_item **d, const int fds[], unsigned n_fds) { assert(d); assert(fds); assert(n_fds > 0); *d = ALIGN8_PTR(*d); (*d)->size = offsetof(struct kdbus_item, fds) + sizeof(int) * n_fds; (*d)->type = KDBUS_MSG_FDS; memcpy((*d)->fds, fds, sizeof(int) * n_fds); *d = (struct kdbus_item *) ((uint8_t*) *d + (*d)->size); } static int bus_message_setup_bloom(sd_bus_message *m, void *bloom) { unsigned i; int r; assert(m); assert(bloom); memset(bloom, 0, BLOOM_SIZE); bloom_add_pair(bloom, "message-type", bus_message_type_to_string(m->header->type)); if (m->interface) bloom_add_pair(bloom, "interface", m->interface); if (m->member) bloom_add_pair(bloom, "member", m->member); if (m->path) { bloom_add_pair(bloom, "path", m->path); bloom_add_pair(bloom, "path-slash-prefix", m->path); bloom_add_prefixes(bloom, "path-slash-prefix", m->path, '/'); } r = sd_bus_message_rewind(m, true); if (r < 0) return r; for (i = 0; i < 64; i++) { char type; const char *t; char buf[sizeof("arg")-1 + 2 + sizeof("-slash-prefix")]; char *e; r = sd_bus_message_peek_type(m, &type, NULL); if (r < 0) return r; if (type != SD_BUS_TYPE_STRING && type != SD_BUS_TYPE_OBJECT_PATH && type != SD_BUS_TYPE_SIGNATURE) break; r = sd_bus_message_read_basic(m, type, &t); if (r < 0) return r; e = stpcpy(buf, "arg"); if (i < 10) *(e++) = '0' + i; else { *(e++) = '0' + (i / 10); *(e++) = '0' + (i % 10); } *e = 0; bloom_add_pair(bloom, buf, t); strcpy(e, "-dot-prefix"); bloom_add_prefixes(bloom, buf, t, '.'); strcpy(e, "-slash-prefix"); bloom_add_prefixes(bloom, buf, t, '/'); } return 0; } static int bus_message_setup_kmsg(sd_bus *b, sd_bus_message *m) { struct bus_body_part *part; struct kdbus_item *d; bool well_known; uint64_t unique; size_t sz, dl; unsigned i; int r; assert(b); assert(m); assert(m->sealed); if (m->kdbus) return 0; if (m->destination) { r = bus_kernel_parse_unique_name(m->destination, &unique); if (r < 0) return r; well_known = r == 0; } else well_known = false; sz = offsetof(struct kdbus_msg, items); assert_cc(ALIGN8(offsetof(struct kdbus_item, vec) + sizeof(struct kdbus_vec)) == ALIGN8(offsetof(struct kdbus_item, memfd) + sizeof(struct kdbus_memfd))); /* Add in fixed header, fields header and payload */ sz += (1 + m->n_body_parts) * ALIGN8(offsetof(struct kdbus_item, vec) + sizeof(struct kdbus_vec)); /* Add space for bloom filter */ sz += ALIGN8(offsetof(struct kdbus_item, data) + BLOOM_SIZE); /* Add in well-known destination header */ if (well_known) { dl = strlen(m->destination); sz += ALIGN8(offsetof(struct kdbus_item, str) + dl + 1); } /* Add space for unix fds */ if (m->n_fds > 0) sz += ALIGN8(offsetof(struct kdbus_item, fds) + sizeof(int)*m->n_fds); m->kdbus = memalign(8, sz); if (!m->kdbus) { r = -ENOMEM; goto fail; } m->free_kdbus = true; memset(m->kdbus, 0, sz); m->kdbus->flags = ((m->header->flags & SD_BUS_MESSAGE_NO_REPLY_EXPECTED) ? 0 : KDBUS_MSG_FLAGS_EXPECT_REPLY) | ((m->header->flags & SD_BUS_MESSAGE_NO_AUTO_START) ? KDBUS_MSG_FLAGS_NO_AUTO_START : 0); m->kdbus->dst_id = well_known ? 0 : m->destination ? unique : KDBUS_DST_ID_BROADCAST; m->kdbus->payload_type = KDBUS_PAYLOAD_DBUS1; m->kdbus->cookie = m->header->serial; m->kdbus->timeout_ns = m->timeout * NSEC_PER_USEC; d = m->kdbus->items; if (well_known) append_destination(&d, m->destination, dl); append_payload_vec(&d, m->header, BUS_MESSAGE_BODY_BEGIN(m)); MESSAGE_FOREACH_PART(part, i, m) { if (part->is_zero) { /* If this is padding then simply send a * vector with a NULL data pointer which the * kernel will just pass through. This is the * most efficient way to encode zeroes */ append_payload_vec(&d, NULL, part->size); continue; } if (part->memfd >= 0 && part->sealed && m->destination) { /* Try to send a memfd, if the part is * sealed and this is not a broadcast. Since we can only */ append_payload_memfd(&d, part->memfd, part->size); continue; } /* Otherwise let's send a vector to the actual data, * for that we need to map it first. */ r = bus_body_part_map(part); if (r < 0) goto fail; append_payload_vec(&d, part->data, part->size); } if (m->kdbus->dst_id == KDBUS_DST_ID_BROADCAST) { void *p; p = append_bloom(&d, BLOOM_SIZE); r = bus_message_setup_bloom(m, p); if (r < 0) goto fail; } if (m->n_fds > 0) append_fds(&d, m->fds, m->n_fds); m->kdbus->size = (uint8_t*) d - (uint8_t*) m->kdbus; assert(m->kdbus->size <= sz); return 0; fail: m->poisoned = true; return r; } int bus_kernel_take_fd(sd_bus *b) { struct kdbus_cmd_hello hello; int r; assert(b); if (b->is_server) return -EINVAL; b->use_memfd = 1; zero(hello); hello.size = sizeof(hello); hello.conn_flags = b->hello_flags; hello.pool_size = KDBUS_POOL_SIZE; r = ioctl(b->input_fd, KDBUS_CMD_HELLO, &hello); if (r < 0) return -errno; if (!b->kdbus_buffer) { b->kdbus_buffer = mmap(NULL, KDBUS_POOL_SIZE, PROT_READ, MAP_SHARED, b->input_fd, 0); if (b->kdbus_buffer == MAP_FAILED) { b->kdbus_buffer = NULL; return -errno; } } /* The higher 32bit of both flags fields are considered * 'incompatible flags'. Refuse them all for now. */ if (hello.bus_flags > 0xFFFFFFFFULL || hello.conn_flags > 0xFFFFFFFFULL) return -ENOTSUP; if (hello.bloom_size != BLOOM_SIZE) return -ENOTSUP; if (asprintf(&b->unique_name, ":1.%llu", (unsigned long long) hello.id) < 0) return -ENOMEM; b->is_kernel = true; b->bus_client = true; b->can_fds = !!(hello.conn_flags & KDBUS_HELLO_ACCEPT_FD); r = bus_start_running(b); if (r < 0) return r; return 1; } int bus_kernel_connect(sd_bus *b) { assert(b); assert(b->input_fd < 0); assert(b->output_fd < 0); assert(b->kernel); if (b->is_server) return -EINVAL; b->input_fd = open(b->kernel, O_RDWR|O_NOCTTY|O_CLOEXEC); if (b->input_fd < 0) return -errno; b->output_fd = b->input_fd; return bus_kernel_take_fd(b); } int bus_kernel_write_message(sd_bus *bus, sd_bus_message *m) { int r; assert(bus); assert(m); assert(bus->state == BUS_RUNNING); r = bus_message_setup_kmsg(bus, m); if (r < 0) return r; r = ioctl(bus->output_fd, KDBUS_CMD_MSG_SEND, m->kdbus); if (r < 0) return errno == EAGAIN ? 0 : -errno; return 1; } static void close_kdbus_msg(sd_bus *bus, struct kdbus_msg *k) { uint64_t off; struct kdbus_item *d; assert(bus); assert(k); off = (uint8_t *)k - (uint8_t *)bus->kdbus_buffer; ioctl(bus->input_fd, KDBUS_CMD_MSG_RELEASE, &off); KDBUS_PART_FOREACH(d, k, items) { if (d->type == KDBUS_MSG_FDS) close_many(d->fds, (d->size - offsetof(struct kdbus_item, fds)) / sizeof(int)); else if (d->type == KDBUS_MSG_PAYLOAD_MEMFD) close_nointr_nofail(d->memfd.fd); } } static int bus_kernel_make_message(sd_bus *bus, struct kdbus_msg *k, sd_bus_message **ret) { sd_bus_message *m = NULL; struct kdbus_item *d; unsigned n_fds = 0; _cleanup_free_ int *fds = NULL; struct bus_header *h = NULL; size_t total, n_bytes = 0, idx = 0; const char *destination = NULL, *seclabel = NULL; int r; assert(bus); assert(k); assert(ret); if (k->payload_type != KDBUS_PAYLOAD_DBUS1) return 0; KDBUS_PART_FOREACH(d, k, items) { size_t l; l = d->size - offsetof(struct kdbus_item, data); if (d->type == KDBUS_MSG_PAYLOAD_OFF) { if (!h) { h = (struct bus_header *)((uint8_t *)bus->kdbus_buffer + d->vec.offset); if (!bus_header_is_complete(h, d->vec.size)) return -EBADMSG; } n_bytes += d->vec.size; } else if (d->type == KDBUS_MSG_PAYLOAD_MEMFD) { if (!h) return -EBADMSG; n_bytes += d->memfd.size; } else if (d->type == KDBUS_MSG_FDS) { int *f; unsigned j; j = l / sizeof(int); f = realloc(fds, sizeof(int) * (n_fds + j)); if (!f) return -ENOMEM; fds = f; memcpy(fds + n_fds, d->fds, sizeof(int) * j); n_fds += j; } else if (d->type == KDBUS_MSG_SRC_SECLABEL) seclabel = d->str; } if (!h) return -EBADMSG; r = bus_header_message_size(h, &total); if (r < 0) return r; if (n_bytes != total) return -EBADMSG; r = bus_message_from_header(bus, h, sizeof(struct bus_header), fds, n_fds, NULL, seclabel, 0, &m); if (r < 0) return r; KDBUS_PART_FOREACH(d, k, items) { size_t l; l = d->size - offsetof(struct kdbus_item, data); if (d->type == KDBUS_MSG_PAYLOAD_OFF) { size_t begin_body; begin_body = BUS_MESSAGE_BODY_BEGIN(m); if (idx + d->vec.size > begin_body) { struct bus_body_part *part; /* Contains body material */ part = message_append_part(m); if (!part) { r = -ENOMEM; goto fail; } /* A -1 offset is NUL padding. */ part->is_zero = d->vec.offset == ~0ULL; if (idx >= begin_body) { if (!part->is_zero) part->data = (uint8_t *)bus->kdbus_buffer + d->vec.offset; part->size = d->vec.size; } else { if (!part->is_zero) part->data = (uint8_t *)bus->kdbus_buffer + d->vec.offset + (begin_body - idx); part->size = d->vec.size - (begin_body - idx); } part->sealed = true; } idx += d->vec.size; } else if (d->type == KDBUS_MSG_PAYLOAD_MEMFD) { struct bus_body_part *part; if (idx < BUS_MESSAGE_BODY_BEGIN(m)) { r = -EBADMSG; goto fail; } part = message_append_part(m); if (!part) { r = -ENOMEM; goto fail; } part->memfd = d->memfd.fd; part->size = d->memfd.size; part->sealed = true; idx += d->memfd.size; } else if (d->type == KDBUS_MSG_SRC_CREDS) { m->creds.pid_starttime = d->creds.starttime / NSEC_PER_USEC; m->creds.uid = d->creds.uid; m->creds.gid = d->creds.gid; m->creds.pid = d->creds.pid; m->creds.tid = d->creds.tid; m->creds.mask |= (SD_BUS_CREDS_UID|SD_BUS_CREDS_GID|SD_BUS_CREDS_PID|SD_BUS_CREDS_PID_STARTTIME|SD_BUS_CREDS_TID) & bus->creds_mask; } else if (d->type == KDBUS_MSG_TIMESTAMP) { m->realtime = d->timestamp.realtime_ns / NSEC_PER_USEC; m->monotonic = d->timestamp.monotonic_ns / NSEC_PER_USEC; } else if (d->type == KDBUS_MSG_SRC_PID_COMM) { m->creds.comm = d->str; m->creds.mask |= SD_BUS_CREDS_COMM & bus->creds_mask; } else if (d->type == KDBUS_MSG_SRC_TID_COMM) { m->creds.tid_comm = d->str; m->creds.mask |= SD_BUS_CREDS_TID_COMM & bus->creds_mask; } else if (d->type == KDBUS_MSG_SRC_EXE) { m->creds.exe = d->str; m->creds.mask |= SD_BUS_CREDS_EXE & bus->creds_mask; } else if (d->type == KDBUS_MSG_SRC_CMDLINE) { m->creds.cmdline = d->str; m->creds.cmdline_length = l; m->creds.mask |= SD_BUS_CREDS_CMDLINE & bus->creds_mask; } else if (d->type == KDBUS_MSG_SRC_CGROUP) { m->creds.cgroup = d->str; 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; } else if (d->type == KDBUS_MSG_SRC_AUDIT) { m->creds.audit_session_id = d->audit.sessionid; m->creds.audit_login_uid = d->audit.loginuid; m->creds.mask |= (SD_BUS_CREDS_AUDIT_SESSION_ID|SD_BUS_CREDS_AUDIT_LOGIN_UID) & bus->creds_mask; } else if (d->type == KDBUS_MSG_SRC_CAPS) { m->creds.capability = d->data; m->creds.capability_size = l; 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; } else if (d->type == KDBUS_MSG_DST_NAME) destination = d->str; else if (d->type != KDBUS_MSG_FDS && d->type != KDBUS_MSG_SRC_SECLABEL && d->type != KDBUS_MSG_SRC_NAMES) log_debug("Got unknown field from kernel %llu", d->type); } r = bus_message_parse_fields(m); if (r < 0) goto fail; if (k->src_id == KDBUS_SRC_ID_KERNEL) m->sender = "org.freedesktop.DBus"; else { snprintf(m->sender_buffer, sizeof(m->sender_buffer), ":1.%llu", (unsigned long long) k->src_id); m->sender = m->sender_buffer; } if (!m->destination) { if (destination) m->destination = destination; else if (k->dst_id != KDBUS_DST_ID_WELL_KNOWN_NAME && k->dst_id != KDBUS_DST_ID_BROADCAST) { snprintf(m->destination_buffer, sizeof(m->destination_buffer), ":1.%llu", (unsigned long long) k->dst_id); m->destination = m->destination_buffer; } } /* We take possession of the kmsg struct now */ m->kdbus = k; m->release_kdbus = true; m->free_fds = true; fds = NULL; *ret = m; return 1; fail: if (m) { struct bus_body_part *part; unsigned i; /* Make sure the memfds are not freed twice */ MESSAGE_FOREACH_PART(part, i, m) if (part->memfd >= 0) part->memfd = -1; sd_bus_message_unref(m); } return r; } int bus_kernel_read_message(sd_bus *bus, sd_bus_message **m) { uint64_t off; struct kdbus_msg *k; int r; assert(bus); assert(m); r = ioctl(bus->input_fd, KDBUS_CMD_MSG_RECV, &off); if (r < 0) { if (errno == EAGAIN) return 0; return -errno; } k = (struct kdbus_msg *)((uint8_t *)bus->kdbus_buffer + off); r = bus_kernel_make_message(bus, k, m); if (r <= 0) close_kdbus_msg(bus, k); return r < 0 ? r : 1; } int bus_kernel_create(const char *name, char **s) { struct kdbus_cmd_bus_make *make; struct kdbus_item *n; size_t l; int fd; char *p; assert(name); assert(s); fd = open("/dev/kdbus/control", O_RDWR|O_NOCTTY|O_CLOEXEC); if (fd < 0) return -errno; l = strlen(name); make = alloca0(offsetof(struct kdbus_cmd_bus_make, items) + KDBUS_PART_HEADER_SIZE + sizeof(uint64_t) + KDBUS_PART_HEADER_SIZE + DECIMAL_STR_MAX(uid_t) + 1 + l + 1); n = make->items; n->type = KDBUS_MAKE_NAME; sprintf(n->str, "%lu-%s", (unsigned long) getuid(), name); n->size = KDBUS_PART_HEADER_SIZE + strlen(n->str) + 1; make->size = offsetof(struct kdbus_cmd_bus_make, items) + n->size; make->flags = KDBUS_MAKE_POLICY_OPEN; make->bus_flags = 0; make->bloom_size = BLOOM_SIZE; assert_cc(BLOOM_SIZE % 8 == 0); p = strjoin("/dev/kdbus/", n->str, "/bus", NULL); if (!p) return -ENOMEM; if (ioctl(fd, KDBUS_CMD_BUS_MAKE, make) < 0) { close_nointr_nofail(fd); free(p); return -errno; } if (s) *s = p; return fd; } int bus_kernel_pop_memfd(sd_bus *bus, void **address, size_t *size) { struct memfd_cache *c; int fd; assert(address); assert(size); if (!bus || !bus->is_kernel) return -ENOTSUP; assert_se(pthread_mutex_lock(&bus->memfd_cache_mutex) >= 0); if (bus->n_memfd_cache <= 0) { int r; assert_se(pthread_mutex_unlock(&bus->memfd_cache_mutex) >= 0); r = ioctl(bus->input_fd, KDBUS_CMD_MEMFD_NEW, &fd); if (r < 0) return -errno; *address = NULL; *size = 0; return fd; } c = &bus->memfd_cache[--bus->n_memfd_cache]; assert(c->fd >= 0); assert(c->size == 0 || c->address); *address = c->address; *size = c->size; fd = c->fd; assert_se(pthread_mutex_unlock(&bus->memfd_cache_mutex) >= 0); return fd; } static void close_and_munmap(int fd, void *address, size_t size) { if (size > 0) assert_se(munmap(address, PAGE_ALIGN(size)) >= 0); close_nointr_nofail(fd); } void bus_kernel_push_memfd(sd_bus *bus, int fd, void *address, size_t size) { struct memfd_cache *c; uint64_t max_sz = PAGE_ALIGN(MEMFD_CACHE_ITEM_SIZE_MAX); assert(fd >= 0); assert(size == 0 || address); if (!bus || !bus->is_kernel) { close_and_munmap(fd, address, size); return; } assert_se(pthread_mutex_lock(&bus->memfd_cache_mutex) >= 0); if (bus->n_memfd_cache >= ELEMENTSOF(bus->memfd_cache)) { assert_se(pthread_mutex_unlock(&bus->memfd_cache_mutex) >= 0); close_and_munmap(fd, address, size); return; } c = &bus->memfd_cache[bus->n_memfd_cache++]; c->fd = fd; c->address = address; /* If overly long, let's return a bit to the OS */ if (size > max_sz) { assert_se(ioctl(fd, KDBUS_CMD_MEMFD_SIZE_SET, &max_sz) >= 0); assert_se(munmap((uint8_t*) address + max_sz, PAGE_ALIGN(size - max_sz)) >= 0); c->size = max_sz; } else c->size = size; assert_se(pthread_mutex_unlock(&bus->memfd_cache_mutex) >= 0); } void bus_kernel_flush_memfd(sd_bus *b) { unsigned i; assert(b); for (i = 0; i < b->n_memfd_cache; i++) close_and_munmap(b->memfd_cache[i].fd, b->memfd_cache[i].address, b->memfd_cache[i].size); }