/* * lib/nl.c Core Netlink Interface * * This library 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 version 2.1 * of the License. * * Copyright (c) 2003-2006 Thomas Graf */ /** * @defgroup nl Core Netlink API * @brief * * @par 1) Creating the netlink handle * @code * struct nl_handle *handle; * * // Allocate and initialize a new netlink handle * handle = nl_handle_new(); * * // Are multiple handles being allocated? You have to provide a unique * // netlink process id and overwrite the default local process id. * nl_handle_set_pid(handle, MY_UNIQUE_PID); * * // Is this socket used for event processing? You need to disable sequence * // number checking in order to be able to receive messages not explicitely * // requested. * nl_disable_sequence_check(handle); * * // Use nl_handle_get_fd() to fetch the file description, for example to * // put a socket into non-blocking i/o mode. * fcntl(nl_handle_get_fd(handle), F_SETFL, O_NONBLOCK); * @endcode * * @par 2) Joining Groups * @code * // You may join/subscribe to as many groups as you want, don't forget * // to eventually disable sequence number checking. Note: Joining must * // be done before connecting/binding the socket. * nl_join_groups(handle, GROUP_ID1 | GROUP_ID2); * @endcode * * @par 3) Connecting the socket * @code * // Bind and connect the socket to a protocol, NETLINK_ROUTE in this example. * nl_connect(handle, NETLINK_ROUTE); * @endcode * * @par 4) Sending data * @code * // The most rudimentary method is to use nl_sendto() simply pushing * // a piece of data to the other netlink peer. This method is not * // recommended. * const char buf[] = { 0x01, 0x02, 0x03, 0x04 }; * nl_sendto(handle, buf, sizeof(buf)); * * // A more comfortable interface is nl_send() taking a pointer to * // a netlink message. * struct nl_msg *msg = my_msg_builder(); * nl_send(handle, nlmsg_hdr(msg)); * * // nl_sendmsg() provides additional control over the sendmsg() message * // header in order to allow more specific addressing of multiple peers etc. * struct msghdr hdr = { ... }; * nl_sendmsg(handle, nlmsg_hdr(msg), &hdr); * * // You're probably too lazy to fill out the netlink pid, sequence number * // and message flags all the time. nl_send_auto_complete() automatically * // extends your message header as needed with an appropriate sequence * // number, the netlink pid stored in the netlink handle and the message * // flags NLM_F_REQUEST and NLM_F_ACK * nl_send_auto_complete(handle, nlmsg_hdr(msg)); * * // Simple protocols don't require the complex message construction interface * // and may favour nl_send_simple() to easly send a bunch of payload * // encapsulated in a netlink message header. * nl_send_simple(handle, MY_MSG_TYPE, 0, buf, sizeof(buf)); * @endcode * * @par 5) Receiving data * @code * // nl_recv() receives a single message allocating a buffer for the message * // content and gives back the pointer to you. * struct sockaddr_nl peer; * unsigned char *msg; * nl_recv(handle, &peer, &msg); * * // nl_recvmsgs() receives a bunch of messages until the callback system * // orders it to state, usually after receving a compolete multi part * // message series. * nl_recvmsgs(handle, my_callback_configuration); * * // nl_recvmsgs_def() acts just like nl_recvmsg() but uses the callback * // configuration stored in the handle. * nl_recvmsgs_def(handle); * * // In case you want to wait for the ACK to be recieved that you requested * // with your latest message, you can call nl_wait_for_ack() * nl_wait_for_ack(handle); * @endcode * * @par 6) Cleaning up * @code * // Close the socket first to release kernel memory * nl_close(handle); * * // Finally destroy the netlink handle * nl_handle_destroy(handle); * @endcode * * @{ */ #include #include #include #include #include #include /** * @name Handle Management * @{ */ /** * Allocate and initialize new non-default netlink handle. * @arg kind Kind of callback handler to use per default. * * Allocates and initializes a new netlink handle, the netlink process id * is set to the local process id which may conflict if multiple handles * are created, therefore you may have to overwrite it using * nl_handle_set_pid(). The initial sequence number is initialized to the * current UNIX time. * * @return Newly allocated netlink handle or NULL. */ struct nl_handle *nl_handle_alloc_nondefault(enum nl_cb_kind kind) { struct nl_handle *handle; handle = calloc(1, sizeof(*handle)); if (!handle) goto errout; handle->h_cb = nl_cb_new(kind); if (!handle->h_cb) goto errout; handle->h_local.nl_family = AF_NETLINK; handle->h_peer.nl_family = AF_NETLINK; handle->h_local.nl_pid = getpid(); handle->h_seq_expect = handle->h_seq_next = time(0); return handle; errout: nl_handle_destroy(handle); nl_errno(ENOMEM); return NULL; } /** * Allocate and initialize new netlink handle. * * Allocates and initializes a new netlink handle, the netlink process id * is set to the local process id which may conflict if multiple handles * are created, therefore you may have to overwrite it using * nl_handle_set_pid(). The initial sequence number is initialized to the * current UNIX time. The default callback (NL_CB_DEFAULT) handlers are * being used. * * @return Newly allocated netlink handle or NULL. */ struct nl_handle *nl_handle_alloc(void) { return nl_handle_alloc_nondefault(NL_CB_DEFAULT); } /** * Destroy netlink handle. * @arg handle Netlink handle. */ void nl_handle_destroy(struct nl_handle *handle) { if (!handle) return; nl_cb_destroy(handle->h_cb); free(handle); } /** @} */ /** * @name Utilities * @{ */ /** * Set socket buffer size of netlink handle. * @arg handle Netlink handle. * @arg rxbuf New receive socket buffer size in bytes. * @arg txbuf New transmit socket buffer size in bytes. * * Sets the socket buffer size of a netlink handle to the specified * values \c rxbuf and \c txbuf. Providing a value of \c 0 assumes a * good default value. * * @note It is not required to call this function prior to nl_connect(). * @return 0 on sucess or a negative error code. */ int nl_set_buffer_size(struct nl_handle *handle, int rxbuf, int txbuf) { int err; if (rxbuf <= 0) rxbuf = 32768; if (txbuf <= 0) txbuf = 32768; err = setsockopt(handle->h_fd, SOL_SOCKET, SO_SNDBUF, &txbuf, sizeof(txbuf)); if (err < 0) return nl_error(errno, "setsockopt(SO_SNDBUF) failed"); err = setsockopt(handle->h_fd, SOL_SOCKET, SO_RCVBUF, &rxbuf, sizeof(rxbuf)); if (err < 0) return nl_error(errno, "setsockopt(SO_RCVBUF) failed"); handle->h_flags |= NL_SOCK_BUFSIZE_SET; return 0; } /** * Enable/disable credential passing on netlink handle. * @arg handle Netlink handle * @arg state New state (0 - disabled, 1 - enabled) */ int nl_set_passcred(struct nl_handle *handle, int state) { int err; err = setsockopt(handle->h_fd, SOL_SOCKET, SO_PASSCRED, &state, sizeof(state)); if (err < 0) return nl_error(errno, "setsockopt(SO_PASSCRED) failed"); if (state) handle->h_flags |= NL_SOCK_PASSCRED; else handle->h_flags &= ~NL_SOCK_PASSCRED; return 0; } /** * Join multicast groups. * @arg handle Netlink handle. * @arg groups Bitmask of groups to join. * * @note Joining of groups must be done prior to connecting/binding * the socket (nl_connect()). */ void nl_join_groups(struct nl_handle *handle, int groups) { handle->h_local.nl_groups |= groups; } #ifndef SOL_NETLINK #define SOL_NETLINK 270 #endif int nl_join_group(struct nl_handle *handle, int group) { int err; err = setsockopt(handle->h_fd, SOL_NETLINK, NETLINK_ADD_MEMBERSHIP, &group, sizeof(group)); if (err < 0) return nl_error(errno, "setsockopt(NETLINK_ADD_MEMBERSHIP) " "failed"); return 0; } static int noop_seq_check(struct nl_msg *msg, void *arg) { return NL_PROCEED; } /** * Disable sequence number checking. * @arg handle Netlink handle. * * Disables checking of sequence numbers on the netlink handle. This is * required to allow messages to be processed which were not requested by * a preceding request message, e.g. netlink events. */ void nl_disable_sequence_check(struct nl_handle *handle) { nl_cb_set(nl_handle_get_cb(handle), NL_CB_SEQ_CHECK, NL_CB_CUSTOM, noop_seq_check, NULL); } /** @} */ /** * @name Acccess Functions * @{ */ /** * Get netlink process identifier of netlink handle. * @arg handle Netlink handle. * @return Netlink process identifier. */ pid_t nl_handle_get_pid(struct nl_handle *handle) { return handle->h_local.nl_pid; } /** * Set netlink process identifier of netlink handle. * @arg handle Netlink handle. * @arg pid New netlink process identifier. */ void nl_handle_set_pid(struct nl_handle *handle, pid_t pid) { handle->h_local.nl_pid = pid; } /** * Get netlink process identifier of peer from netlink handle. * @arg handle Netlink handle. * @return Netlink process identifier. */ pid_t nl_handle_get_peer_pid(struct nl_handle *handle) { return handle->h_peer.nl_pid; } /** * Set netlink process identifier of peer in netlink handle. * @arg handle Netlink handle. * @arg pid New netlink process identifier. */ void nl_handle_set_peer_pid(struct nl_handle *handle, pid_t pid) { handle->h_peer.nl_pid = pid; } /** * Get file descriptor of netlink handle. * @arg handle Netlink handle. * @return File descriptor of netlink socket or -1 if not connected. */ int nl_handle_get_fd(struct nl_handle *handle) { return handle->h_fd; } /** * Get local netlink address of netlink handle. * @arg handle Netlink handle. * @return Local netlink address. */ struct sockaddr_nl *nl_handle_get_local_addr(struct nl_handle *handle) { return &handle->h_local; } /** * Get peer netlink address of netlink handle. * @arg handle Netlink handle. * @note The peer address is undefined while the socket is unconnected. * @return Netlink address of the peer. */ struct sockaddr_nl *nl_handle_get_peer_addr(struct nl_handle *handle) { return &handle->h_peer; } /** * Get callback configuration of netlink handle. * @arg handle Netlink handle. * @return Currently active callback configuration or NULL if not available. */ struct nl_cb *nl_handle_get_cb(struct nl_handle *handle) { return handle->h_cb; } /** @} */ /** * @name Connection Management * @{ */ /** * Create and connect netlink socket. * @arg handle Netlink handle. * @arg protocol Netlink protocol to use. * * Creates a netlink socket using the specified protocol, binds the socket * and issues a connection attempt. * * @return 0 on success or a negative error code. */ int nl_connect(struct nl_handle *handle, int protocol) { int err; socklen_t addrlen; handle->h_fd = socket(AF_NETLINK, SOCK_RAW, protocol); if (handle->h_fd < 0) return nl_error(1, "socket(AF_NETLINK, ...) failed"); if (!(handle->h_flags & NL_SOCK_BUFSIZE_SET)) { err = nl_set_buffer_size(handle, 0, 0); if (err < 0) return err; } err = bind(handle->h_fd, (struct sockaddr*) &handle->h_local, sizeof(handle->h_local)); if (err < 0) return nl_error(1, "bind() failed"); addrlen = sizeof(handle->h_local); err = getsockname(handle->h_fd, (struct sockaddr *) &handle->h_local, &addrlen); if (err < 0) return nl_error(1, "getsockname failed"); if (addrlen != sizeof(handle->h_local)) return nl_error(EADDRNOTAVAIL, "Invalid address length"); if (handle->h_local.nl_family != AF_NETLINK) return nl_error(EPFNOSUPPORT, "Address format not supported"); handle->h_proto = protocol; return 0; } /** * Close/Disconnect netlink socket. * @arg handle Netlink handle */ void nl_close(struct nl_handle *handle) { if (handle->h_fd >= 0) { close(handle->h_fd); handle->h_fd = -1; } handle->h_proto = 0; } /** @} */ /** * @name Send * @{ */ /** * Send raw data over netlink socket. * @arg handle Netlink handle. * @arg buf Data buffer. * @arg size Size of data buffer. * @return Number of characters written on success or a negative error code. */ int nl_sendto(struct nl_handle *handle, void *buf, size_t size) { int ret; ret = sendto(handle->h_fd, buf, size, 0, (struct sockaddr *) &handle->h_peer, sizeof(handle->h_peer)); if (ret < 0) return nl_errno(errno); return ret; } /** * Send netlink message with control over sendmsg() message header. * @arg handle Netlink handle. * @arg msg Netlink message to be sent. * @arg hdr Sendmsg() message header. * @return Number of characters sent on sucess or a negative error code. */ int nl_sendmsg(struct nl_handle *handle, struct nl_msg *msg, struct msghdr *hdr) { struct nl_cb *cb; int ret; struct iovec iov = { .iov_base = (void *) nlmsg_hdr(msg), .iov_len = nlmsg_hdr(msg)->nlmsg_len, }; hdr->msg_iov = &iov; hdr->msg_iovlen = 1; nlmsg_set_src(msg, &handle->h_local); cb = nl_handle_get_cb(handle); if (cb->cb_set[NL_CB_MSG_OUT]) if (nl_cb_call(cb, NL_CB_MSG_OUT, msg) != NL_PROCEED) return 0; ret = sendmsg(handle->h_fd, hdr, 0); if (ret < 0) return nl_errno(errno); return ret; } /** * Send netlink message. * @arg handle Netlink handle * @arg msg Netlink message to be sent. * @see nl_sendmsg() * @return Number of characters sent on success or a negative error code. */ int nl_send(struct nl_handle *handle, struct nl_msg *msg) { struct sockaddr_nl *dst; struct ucred *creds; struct msghdr hdr = { .msg_name = (void *) &handle->h_peer, .msg_namelen = sizeof(struct sockaddr_nl), }; /* Overwrite destination if specified in the message itself, defaults * to the peer address of the handle. */ dst = nlmsg_get_dst(msg); if (dst->nl_family == AF_NETLINK) hdr.msg_name = dst; /* Add credentials if present. */ creds = nlmsg_get_creds(msg); if (creds != NULL) { char buf[CMSG_SPACE(sizeof(struct ucred))]; struct cmsghdr *cmsg; hdr.msg_control = buf; hdr.msg_controllen = sizeof(buf); cmsg = CMSG_FIRSTHDR(&hdr); cmsg->cmsg_level = SOL_SOCKET; cmsg->cmsg_type = SCM_CREDENTIALS; cmsg->cmsg_len = CMSG_LEN(sizeof(struct ucred)); memcpy(CMSG_DATA(cmsg), creds, sizeof(struct ucred)); } return nl_sendmsg(handle, msg, &hdr); } /** * Send netlink message and check & extend header values as needed. * @arg handle Netlink handle. * @arg msg Netlink message to be sent. * * Checks the netlink message \c nlh for completness and extends it * as required before sending it out. Checked fields include pid, * sequence nr, and flags. * * @see nl_send() * @return Number of characters sent or a negative error code. */ int nl_send_auto_complete(struct nl_handle *handle, struct nl_msg *msg) { struct nlmsghdr *nlh; nlh = nlmsg_hdr(msg); if (nlh->nlmsg_pid == 0) nlh->nlmsg_pid = handle->h_local.nl_pid; if (nlh->nlmsg_seq == 0) nlh->nlmsg_seq = handle->h_seq_next++; nlh->nlmsg_flags |= (NLM_F_REQUEST | NLM_F_ACK); if (handle->h_cb->cb_send_ow) return handle->h_cb->cb_send_ow(handle, msg); else return nl_send(handle, msg); } /** * Send simple netlink message using nl_send_auto_complete() * @arg handle Netlink handle. * @arg type Netlink message type. * @arg flags Netlink message flags. * @arg buf Data buffer. * @arg size Size of data buffer. * * Builds a netlink message with the specified type and flags and * appends the specified data as payload to the message. * * @see nl_send_auto_complete() * @return Number of characters sent on success or a negative error code. */ int nl_send_simple(struct nl_handle *handle, int type, int flags, void *buf, size_t size) { int err; struct nl_msg *msg; struct nlmsghdr nlh = { .nlmsg_len = nlmsg_msg_size(0), .nlmsg_type = type, .nlmsg_flags = flags, }; msg = nlmsg_build(&nlh); if (!msg) return nl_errno(ENOMEM); if (buf && size) nlmsg_append(msg, buf, size, 1); err = nl_send_auto_complete(handle, msg); nlmsg_free(msg); return err; } /** @} */ /** * @name Receive * @{ */ /** * Receive netlink message from netlink socket. * @arg handle Netlink handle. * @arg nla Destination pointer for peer's netlink address. * @arg buf Destination pointer for message content. * @arg creds Destination pointer for credentials. * * Receives a netlink message, allocates a buffer in \c *buf and * stores the message content. The peer's netlink address is stored * in \c *nla. The caller is responsible for freeing the buffer allocated * in \c *buf if a positive value is returned. Interruped system calls * are handled by repeating the read. The input buffer size is determined * by peeking before the actual read is done. * * A non-blocking sockets causes the function to return immediately if * no data is available. * * @return Number of octets read, 0 on EOF or a negative error code. */ int nl_recv(struct nl_handle *handle, struct sockaddr_nl *nla, unsigned char **buf, struct ucred **creds) { int n; int flags = MSG_PEEK; struct iovec iov = { .iov_len = 4096, }; struct msghdr msg = { .msg_name = (void *) nla, .msg_namelen = sizeof(sizeof(struct sockaddr_nl)), .msg_iov = &iov, .msg_iovlen = 1, .msg_control = NULL, .msg_controllen = 0, .msg_flags = 0, }; struct cmsghdr *cmsg; iov.iov_base = *buf = calloc(1, iov.iov_len); if (handle->h_flags & NL_SOCK_PASSCRED) { msg.msg_controllen = CMSG_SPACE(sizeof(struct ucred)); msg.msg_control = calloc(1, msg.msg_controllen); } retry: if ((n = recvmsg(handle->h_fd, &msg, flags)) <= 0) { if (!n) goto abort; else if (n < 0) { if (errno == EINTR) goto retry; else if (errno == EAGAIN) goto abort; else { free(msg.msg_control); free(*buf); return nl_error(errno, "recvmsg failed"); } } } if (iov.iov_len < n) { /* Provided buffer is not long enough, enlarge it * and try again. */ iov.iov_len *= 2; iov.iov_base = *buf = realloc(*buf, iov.iov_len); goto retry; } else if (msg.msg_flags & MSG_CTRUNC) { msg.msg_controllen *= 2; msg.msg_control = realloc(msg.msg_control, msg.msg_controllen); goto retry; } else if (flags != 0) { /* Buffer is big enough, do the actual reading */ flags = 0; goto retry; } if (msg.msg_namelen != sizeof(struct sockaddr_nl)) { free(msg.msg_control); free(*buf); return nl_error(EADDRNOTAVAIL, "socket address size mismatch"); } for (cmsg = CMSG_FIRSTHDR(&msg); cmsg; cmsg = CMSG_NXTHDR(&msg, cmsg)) { if (cmsg->cmsg_level == SOL_SOCKET && cmsg->cmsg_type == SCM_CREDENTIALS) { *creds = calloc(1, sizeof(struct ucred)); memcpy(*creds, CMSG_DATA(cmsg), sizeof(struct ucred)); break; } } free(msg.msg_control); return n; abort: free(msg.msg_control); free(*buf); return 0; } /** * Receive a set of messages from a netlink socket. * @arg handle netlink handle * @arg cb set of callbacks to control the behaviour. * * Repeatedly calls nl_recv() and parses the messages as netlink * messages. Stops reading if one of the callbacks returns * NL_EXIT or nl_recv returns either 0 or a negative error code. * * A non-blocking sockets causes the function to return immediately if * no data is available. * * @return 0 on success or a negative error code from nl_recv(). */ int nl_recvmsgs(struct nl_handle *handle, struct nl_cb *cb) { int n, err = 0; unsigned char *buf = NULL; struct nlmsghdr *hdr; struct sockaddr_nl nla = {0}; struct nl_msg *msg = NULL; struct ucred *creds = NULL; continue_reading: if (cb->cb_recv_ow) n = cb->cb_recv_ow(handle, &nla, &buf, &creds); else n = nl_recv(handle, &nla, &buf, &creds); if (n <= 0) return n; NL_DBG(3, "recvmsgs(%p): Read %d bytes\n", handle, n); hdr = (struct nlmsghdr *) buf; while (nlmsg_ok(hdr, n)) { NL_DBG(3, "recgmsgs(%p): Processing valid message...\n", handle); nlmsg_free(msg); msg = nlmsg_convert(hdr); if (!msg) { err = nl_errno(ENOMEM); goto out; } nlmsg_set_proto(msg, handle->h_proto); nlmsg_set_src(msg, &nla); if (creds) nlmsg_set_creds(msg, creds); /* Raw callback is the first, it gives the most control * to the user and he can do his very own parsing. */ if (cb->cb_set[NL_CB_MSG_IN]) { err = nl_cb_call(cb, NL_CB_MSG_IN, msg); if (err == NL_SKIP) goto skip; else if (err == NL_EXIT || err < 0) goto out; } /* Sequence number checking. The check may be done by * the user, otherwise a very simple check is applied * enforcing strict ordering */ if (cb->cb_set[NL_CB_SEQ_CHECK]) { err = nl_cb_call(cb, NL_CB_SEQ_CHECK, msg); if (err == NL_SKIP) goto skip; else if (err == NL_EXIT || err < 0) goto out; } else if (hdr->nlmsg_seq != handle->h_seq_expect) { if (cb->cb_set[NL_CB_INVALID]) { err = nl_cb_call(cb, NL_CB_INVALID, msg); if (err == NL_SKIP) goto skip; else if (err == NL_EXIT || err < 0) goto out; } else goto out; } if (hdr->nlmsg_type == NLMSG_DONE || hdr->nlmsg_type == NLMSG_ERROR || hdr->nlmsg_type == NLMSG_NOOP || hdr->nlmsg_type == NLMSG_OVERRUN) { /* We can't check for !NLM_F_MULTI since some netlink * users in the kernel are broken. */ handle->h_seq_expect++; NL_DBG(3, "recvmsgs(%p): Increased expected " \ "sequence number to %d\n", handle, handle->h_seq_expect); } /* Other side wishes to see an ack for this message */ if (hdr->nlmsg_flags & NLM_F_ACK) { if (cb->cb_set[NL_CB_SEND_ACK]) { err = nl_cb_call(cb, NL_CB_SEND_ACK, msg); if (err == NL_SKIP) goto skip; else if (err == NL_EXIT || err < 0) goto out; } else { /* FIXME: implement */ } } /* messages terminates a multpart message, this is * usually the end of a message and therefore we slip * out of the loop by default. the user may overrule * this action by skipping this packet. */ if (hdr->nlmsg_type == NLMSG_DONE) { if (cb->cb_set[NL_CB_FINISH]) { err = nl_cb_call(cb, NL_CB_FINISH, msg); if (err == NL_SKIP) goto skip; else if (err == NL_EXIT || err < 0) goto out; } err = 0; goto out; } /* Message to be ignored, the default action is to * skip this message if no callback is specified. The * user may overrule this action by returning * NL_PROCEED. */ else if (hdr->nlmsg_type == NLMSG_NOOP) { if (cb->cb_set[NL_CB_SKIPPED]) { err = nl_cb_call(cb, NL_CB_SKIPPED, msg); if (err == NL_SKIP) goto skip; else if (err == NL_EXIT || err < 0) goto out; } else goto skip; } /* Data got lost, report back to user. The default action is to * quit parsing. The user may overrule this action by retuning * NL_SKIP or NL_PROCEED (dangerous) */ else if (hdr->nlmsg_type == NLMSG_OVERRUN) { if (cb->cb_set[NL_CB_OVERRUN]) { err = nl_cb_call(cb, NL_CB_OVERRUN, msg); if (err == NL_SKIP) goto skip; else if (err == NL_EXIT || err < 0) goto out; } else goto out; } /* Message carries a nlmsgerr */ else if (hdr->nlmsg_type == NLMSG_ERROR) { struct nlmsgerr *e = nlmsg_data(hdr); if (hdr->nlmsg_len < nlmsg_msg_size(sizeof(*e))) { /* Truncated error message, the default action * is to stop parsing. The user may overrule * this action by returning NL_SKIP or * NL_PROCEED (dangerous) */ if (cb->cb_set[NL_CB_INVALID]) { err = nl_cb_call(cb, NL_CB_INVALID, msg); if (err == NL_SKIP) goto skip; else if (err == NL_EXIT || err < 0) goto out; } else goto out; } else if (e->error) { /* Error message reported back from kernel. */ if (cb->cb_err) { err = cb->cb_err(&nla, e, cb->cb_err_arg); if (err == NL_SKIP) goto skip; else if (err == NL_EXIT || err < 0) { nl_error(-e->error, "Netlink Error"); err = e->error; goto out; } } else { nl_error(-e->error, "Netlink Error"); err = e->error; goto out; } } else if (cb->cb_set[NL_CB_ACK]) { /* ACK */ err = nl_cb_call(cb, NL_CB_ACK, msg); if (err == NL_SKIP) goto skip; else if (err == NL_EXIT || err < 0) goto out; } } else { /* Valid message (not checking for MULTIPART bit to * get along with broken kernels. NL_SKIP has no * effect on this. */ if (cb->cb_set[NL_CB_VALID]) { err = nl_cb_call(cb, NL_CB_VALID, msg); if (err == NL_SKIP) goto skip; else if (err == NL_EXIT || err < 0) goto out; } } skip: hdr = nlmsg_next(hdr, &n); } nlmsg_free(msg); free(buf); free(creds); buf = NULL; msg = NULL; creds = NULL; /* Multipart message not yet complete, continue reading */ goto continue_reading; out: nlmsg_free(msg); free(buf); free(creds); return err; } /** * Receive a set of message from a netlink socket using handlers in nl_handle. * @arg handle netlink handle * * Calls nl_recvmsgs() with the handlers configured in the netlink handle. */ int nl_recvmsgs_def(struct nl_handle *handle) { if (handle->h_cb->cb_recvmsgs_ow) return handle->h_cb->cb_recvmsgs_ow(handle, handle->h_cb); else return nl_recvmsgs(handle, handle->h_cb); } static int ack_wait_handler(struct nl_msg *msg, void *arg) { return NL_EXIT; } /** * Wait for ACK. * @arg handle netlink handle * @pre The netlink socket must be in blocking state. * * Waits until an ACK is received for the latest not yet acknowledged * netlink message. */ int nl_wait_for_ack(struct nl_handle *handle) { int err; struct nl_cb *cb = nl_cb_clone(nl_handle_get_cb(handle)); nl_cb_set(cb, NL_CB_ACK, NL_CB_CUSTOM, ack_wait_handler, NULL); err = nl_recvmsgs(handle, cb); nl_cb_destroy(cb); return err; } /** @} */ /** * @name Netlink Family Translations * @{ */ static struct trans_tbl nlfamilies[] = { __ADD(NETLINK_ROUTE,route) __ADD(NETLINK_W1,w1) __ADD(NETLINK_USERSOCK,usersock) __ADD(NETLINK_FIREWALL,firewall) __ADD(NETLINK_INET_DIAG,inetdiag) __ADD(NETLINK_NFLOG,nflog) __ADD(NETLINK_XFRM,xfrm) __ADD(NETLINK_SELINUX,selinux) __ADD(NETLINK_ISCSI,iscsi) __ADD(NETLINK_AUDIT,audit) __ADD(NETLINK_FIB_LOOKUP,fib_lookup) __ADD(NETLINK_CONNECTOR,connector) __ADD(NETLINK_NETFILTER,netfilter) __ADD(NETLINK_IP6_FW,ip6_fw) __ADD(NETLINK_DNRTMSG,dnrtmsg) __ADD(NETLINK_KOBJECT_UEVENT,kobject_uevent) __ADD(NETLINK_GENERIC,generic) }; /** * Convert netlink family to character string. * @arg family Netlink family. * @arg buf Destination buffer. * @arg size Size of destination buffer. * * Converts a netlink family to a character string and stores it in * the specified destination buffer. * * @return The destination buffer or the family encoded in hexidecimal * form if no match was found. */ char * nl_nlfamily2str(int family, char *buf, size_t size) { return __type2str(family, buf, size, nlfamilies, ARRAY_SIZE(nlfamilies)); } /** * Convert character string to netlink family. * @arg name Name of netlink family. * * Converts the provided character string specifying a netlink * family to the corresponding numeric value. * * @return Numeric netlink family or a negative value if no match was found. */ int nl_str2nlfamily(const char *name) { return __str2type(name, nlfamilies, ARRAY_SIZE(nlfamilies)); } /** @} */ /** @} */