/* -*- Mode: C; tab-width: 4; indent-tabs-mode: t; c-basic-offset: 4 -*- */ /* nm-linux-platform.c - Linux kernel & udev network configuration layer * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2, or (at your option) * any later version. * * This program 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 General Public License for more details. * * You should have received a copy of the GNU General Public License along * with this program; if not, write to the Free Software Foundation, Inc., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. * * Copyright (C) 2012-2015 Red Hat, Inc. */ #include "nm-default.h" #include "nm-linux-platform.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "nm-utils.h" #include "nm-core-internal.h" #include "nm-setting-vlan.h" #include "nm-core-utils.h" #include "nmp-object.h" #include "nmp-netns.h" #include "nm-platform-utils.h" #include "nm-platform-private.h" #include "wifi/wifi-utils.h" #include "wifi/wifi-utils-wext.h" #include "nm-utils/unaligned.h" #include "nm-utils/nm-udev-utils.h" #define VLAN_FLAG_MVRP 0x8 /* nm-internal error codes for libnl. Make sure they don't overlap. */ #define _NLE_NM_NOBUFS 500 #define _NLE_MSG_TRUNC 501 /*****************************************************************************/ #define IFQDISCSIZ 32 /*****************************************************************************/ #ifndef IFLA_PROMISCUITY #define IFLA_PROMISCUITY 30 #endif #define IFLA_NUM_TX_QUEUES 31 #define IFLA_NUM_RX_QUEUES 32 #define IFLA_CARRIER 33 #define IFLA_PHYS_PORT_ID 34 #define IFLA_LINK_NETNSID 37 #define __IFLA_MAX 39 #define IFLA_INET6_TOKEN 7 #define IFLA_INET6_ADDR_GEN_MODE 8 #define __IFLA_INET6_MAX 9 #define IFLA_VLAN_PROTOCOL 5 #define __IFLA_VLAN_MAX 6 #define IFA_FLAGS 8 #define __IFA_MAX 9 #define IFLA_MACVLAN_FLAGS 2 #define __IFLA_MACVLAN_MAX 3 #define IFLA_IPTUN_LINK 1 #define IFLA_IPTUN_LOCAL 2 #define IFLA_IPTUN_REMOTE 3 #define IFLA_IPTUN_TTL 4 #define IFLA_IPTUN_TOS 5 #define IFLA_IPTUN_ENCAP_LIMIT 6 #define IFLA_IPTUN_FLOWINFO 7 #define IFLA_IPTUN_FLAGS 8 #define IFLA_IPTUN_PROTO 9 #define IFLA_IPTUN_PMTUDISC 10 #define __IFLA_IPTUN_MAX 19 #ifndef IFLA_IPTUN_MAX #define IFLA_IPTUN_MAX (__IFLA_IPTUN_MAX - 1) #endif static const gboolean RTA_PREF_SUPPORTED_AT_COMPILETIME = (RTA_MAX >= 20 /* RTA_PREF */); G_STATIC_ASSERT (RTA_MAX == (__RTA_MAX - 1)); #define RTA_PREF 20 #undef RTA_MAX #define RTA_MAX (MAX ((__RTA_MAX - 1), RTA_PREF)) #ifndef MACVLAN_FLAG_NOPROMISC #define MACVLAN_FLAG_NOPROMISC 1 #endif #define IP6_FLOWINFO_TCLASS_MASK 0x0FF00000 #define IP6_FLOWINFO_TCLASS_SHIFT 20 #define IP6_FLOWINFO_FLOWLABEL_MASK 0x000FFFFF /*****************************************************************************/ #define IFLA_MACSEC_UNSPEC 0 #define IFLA_MACSEC_SCI 1 #define IFLA_MACSEC_PORT 2 #define IFLA_MACSEC_ICV_LEN 3 #define IFLA_MACSEC_CIPHER_SUITE 4 #define IFLA_MACSEC_WINDOW 5 #define IFLA_MACSEC_ENCODING_SA 6 #define IFLA_MACSEC_ENCRYPT 7 #define IFLA_MACSEC_PROTECT 8 #define IFLA_MACSEC_INC_SCI 9 #define IFLA_MACSEC_ES 10 #define IFLA_MACSEC_SCB 11 #define IFLA_MACSEC_REPLAY_PROTECT 12 #define IFLA_MACSEC_VALIDATION 13 #define IFLA_MACSEC_PAD 14 #define __IFLA_MACSEC_MAX 15 /*****************************************************************************/ #define _NMLOG_PREFIX_NAME "platform-linux" #define _NMLOG_DOMAIN LOGD_PLATFORM #define _NMLOG2_DOMAIN LOGD_PLATFORM #define _NMLOG(level, ...) _LOG ( level, _NMLOG_DOMAIN, platform, __VA_ARGS__) #define _NMLOG_err(errsv, level, ...) _LOG_err (errsv, level, _NMLOG_DOMAIN, platform, __VA_ARGS__) #define _NMLOG2(level, ...) _LOG ( level, _NMLOG2_DOMAIN, NULL, __VA_ARGS__) #define _NMLOG2_err(errsv, level, ...) _LOG_err (errsv, level, _NMLOG2_DOMAIN, NULL, __VA_ARGS__) #define _LOG_print(__level, __domain, __errsv, self, ...) \ G_STMT_START { \ char __prefix[32]; \ const char *__p_prefix = _NMLOG_PREFIX_NAME; \ NMPlatform *const __self = (self); \ \ if (__self && nm_platform_get_log_with_ptr (__self)) { \ g_snprintf (__prefix, sizeof (__prefix), "%s[%p]", _NMLOG_PREFIX_NAME, __self); \ __p_prefix = __prefix; \ } \ _nm_log (__level, __domain, __errsv, NULL, NULL, \ "%s: " _NM_UTILS_MACRO_FIRST (__VA_ARGS__), \ __p_prefix _NM_UTILS_MACRO_REST (__VA_ARGS__)); \ } G_STMT_END #define _LOG(level, domain, self, ...) \ G_STMT_START { \ const NMLogLevel __level = (level); \ const NMLogDomain __domain = (domain); \ \ if (nm_logging_enabled (__level, __domain)) { \ _LOG_print (__level, __domain, 0, self, __VA_ARGS__); \ } \ } G_STMT_END #define _LOG_err(errsv, level, domain, self, ...) \ G_STMT_START { \ const NMLogLevel __level = (level); \ const NMLogDomain __domain = (domain); \ \ if (nm_logging_enabled (__level, __domain)) { \ int __errsv = (errsv); \ \ /* The %m format specifier (GNU extension) would alread allow you to specify the error * message conveniently (and nm_log would get that right too). But we don't want to depend * on that, so instead append the message at the end. * Currently users are expected not to use %m in the format string. */ \ _LOG_print (__level, __domain, __errsv, self, \ _NM_UTILS_MACRO_FIRST (__VA_ARGS__) ": %s (%d)" \ _NM_UTILS_MACRO_REST (__VA_ARGS__), \ g_strerror (__errsv), __errsv); \ } \ } G_STMT_END #define LOG_FMT_IP_TUNNEL "adding %s '%s' parent %u local %s remote %s" /****************************************************************** * Forward declarations and enums ******************************************************************/ typedef enum { INFINIBAND_ACTION_CREATE_CHILD, INFINIBAND_ACTION_DELETE_CHILD, } InfinibandAction; enum { DELAYED_ACTION_IDX_REFRESH_ALL_LINKS, DELAYED_ACTION_IDX_REFRESH_ALL_IP4_ADDRESSES, DELAYED_ACTION_IDX_REFRESH_ALL_IP6_ADDRESSES, DELAYED_ACTION_IDX_REFRESH_ALL_IP4_ROUTES, DELAYED_ACTION_IDX_REFRESH_ALL_IP6_ROUTES, _DELAYED_ACTION_IDX_REFRESH_ALL_NUM, }; typedef enum { DELAYED_ACTION_TYPE_NONE = 0, DELAYED_ACTION_TYPE_REFRESH_ALL_LINKS = (1LL << DELAYED_ACTION_IDX_REFRESH_ALL_LINKS), DELAYED_ACTION_TYPE_REFRESH_ALL_IP4_ADDRESSES = (1LL << DELAYED_ACTION_IDX_REFRESH_ALL_IP4_ADDRESSES), DELAYED_ACTION_TYPE_REFRESH_ALL_IP6_ADDRESSES = (1LL << DELAYED_ACTION_IDX_REFRESH_ALL_IP6_ADDRESSES), DELAYED_ACTION_TYPE_REFRESH_ALL_IP4_ROUTES = (1LL << DELAYED_ACTION_IDX_REFRESH_ALL_IP4_ROUTES), DELAYED_ACTION_TYPE_REFRESH_ALL_IP6_ROUTES = (1LL << DELAYED_ACTION_IDX_REFRESH_ALL_IP6_ROUTES), DELAYED_ACTION_TYPE_REFRESH_LINK = (1LL << 5), DELAYED_ACTION_TYPE_MASTER_CONNECTED = (1LL << 6), DELAYED_ACTION_TYPE_READ_NETLINK = (1LL << 7), DELAYED_ACTION_TYPE_WAIT_FOR_NL_RESPONSE = (1LL << 8), __DELAYED_ACTION_TYPE_MAX, DELAYED_ACTION_TYPE_REFRESH_ALL = DELAYED_ACTION_TYPE_REFRESH_ALL_LINKS | DELAYED_ACTION_TYPE_REFRESH_ALL_IP4_ADDRESSES | DELAYED_ACTION_TYPE_REFRESH_ALL_IP6_ADDRESSES | DELAYED_ACTION_TYPE_REFRESH_ALL_IP4_ROUTES | DELAYED_ACTION_TYPE_REFRESH_ALL_IP6_ROUTES, DELAYED_ACTION_TYPE_MAX = __DELAYED_ACTION_TYPE_MAX -1, } DelayedActionType; #define FOR_EACH_DELAYED_ACTION(iflags, flags_all) \ for ((iflags) = (DelayedActionType) 0x1LL; (iflags) <= DELAYED_ACTION_TYPE_MAX; (iflags) <<= 1) \ if (NM_FLAGS_HAS (flags_all, iflags)) typedef enum { /* Negative values are errors from kernel. Add dummy member to * make enum signed. */ _WAIT_FOR_NL_RESPONSE_RESULT_SYSTEM_ERROR = -1, WAIT_FOR_NL_RESPONSE_RESULT_UNKNOWN = 0, WAIT_FOR_NL_RESPONSE_RESULT_RESPONSE_OK, WAIT_FOR_NL_RESPONSE_RESULT_RESPONSE_UNKNOWN, WAIT_FOR_NL_RESPONSE_RESULT_FAILED_RESYNC, WAIT_FOR_NL_RESPONSE_RESULT_FAILED_POLL, WAIT_FOR_NL_RESPONSE_RESULT_FAILED_TIMEOUT, WAIT_FOR_NL_RESPONSE_RESULT_FAILED_DISPOSING, } WaitForNlResponseResult; typedef void (*WaitForNlResponseCallback) (NMPlatform *platform, guint32 seq_number, WaitForNlResponseResult seq_result, gpointer user_data); static void delayed_action_schedule (NMPlatform *platform, DelayedActionType action_type, gpointer user_data); static gboolean delayed_action_handle_all (NMPlatform *platform, gboolean read_netlink); static void do_request_link_no_delayed_actions (NMPlatform *platform, int ifindex, const char *name); static void do_request_all_no_delayed_actions (NMPlatform *platform, DelayedActionType action_type); static void cache_on_change (NMPlatform *platform, NMPCacheOpsType cache_op, const NMPObject *obj_old, const NMPObject *obj_new); static void cache_prune_all (NMPlatform *platform); static gboolean event_handler_read_netlink (NMPlatform *platform, gboolean wait_for_acks); /*****************************************************************************/ static NMPlatformError wait_for_nl_response_to_plerr (WaitForNlResponseResult seq_result) { if (seq_result == WAIT_FOR_NL_RESPONSE_RESULT_RESPONSE_OK) return NM_PLATFORM_ERROR_SUCCESS; if (seq_result < 0) return (NMPlatformError) seq_result; return NM_PLATFORM_ERROR_NETLINK; } static const char * wait_for_nl_response_to_string (WaitForNlResponseResult seq_result, char *buf, gsize buf_size) { char *buf0 = buf; switch (seq_result) { case WAIT_FOR_NL_RESPONSE_RESULT_UNKNOWN: nm_utils_strbuf_append_str (&buf, &buf_size, "unknown"); break; case WAIT_FOR_NL_RESPONSE_RESULT_RESPONSE_OK: nm_utils_strbuf_append_str (&buf, &buf_size, "success"); break; case WAIT_FOR_NL_RESPONSE_RESULT_RESPONSE_UNKNOWN: nm_utils_strbuf_append_str (&buf, &buf_size, "failure"); break; default: if (seq_result < 0) nm_utils_strbuf_append (&buf, &buf_size, "failure %d (%s)", -((int) seq_result), g_strerror (-((int) seq_result))); else nm_utils_strbuf_append (&buf, &buf_size, "internal failure %d", (int) seq_result); break; } return buf0; } /***************************************************************************** * Support IFLA_INET6_ADDR_GEN_MODE *****************************************************************************/ static int _support_user_ipv6ll = 0; #define _support_user_ipv6ll_still_undecided() (G_UNLIKELY (_support_user_ipv6ll == 0)) static void _support_user_ipv6ll_detect (struct nlattr **tb) { gboolean supported; nm_assert (_support_user_ipv6ll_still_undecided ()); /* IFLA_INET6_ADDR_GEN_MODE was added in kernel 3.17, dated 5 October, 2014. */ supported = !!tb[IFLA_INET6_ADDR_GEN_MODE]; _support_user_ipv6ll = supported ? 1 : -1; _LOG2D ("kernel-support: IFLA_INET6_ADDR_GEN_MODE: %s", supported ? "detected" : "not detected"); } static gboolean _support_user_ipv6ll_get (void) { if (_support_user_ipv6ll_still_undecided ()) { _support_user_ipv6ll = 1; _LOG2D ("kernel-support: IFLA_INET6_ADDR_GEN_MODE: %s", "failed to detect; assume support"); } return _support_user_ipv6ll >= 0; } /***************************************************************************** * extended IFA_FLAGS support *****************************************************************************/ static int _support_kernel_extended_ifa_flags = 0; #define _support_kernel_extended_ifa_flags_still_undecided() (G_UNLIKELY (_support_kernel_extended_ifa_flags == 0)) static void _support_kernel_extended_ifa_flags_detect (struct nl_msg *msg) { struct nlmsghdr *msg_hdr; gboolean support; nm_assert (_support_kernel_extended_ifa_flags_still_undecided ()); nm_assert (msg); msg_hdr = nlmsg_hdr (msg); nm_assert (msg_hdr && msg_hdr->nlmsg_type == RTM_NEWADDR); /* IFA_FLAGS is set for IPv4 and IPv6 addresses. It was added first to IPv6, * but if we encounter an IPv4 address with IFA_FLAGS, we surely have support. */ if (NM_IN_SET (((struct ifaddrmsg *) nlmsg_data (msg_hdr))->ifa_family, AF_INET, AF_INET6)) return; /* see if the nl_msg contains the IFA_FLAGS attribute. If it does, * we assume, that the kernel supports extended flags, IFA_F_MANAGETEMPADDR * and IFA_F_NOPREFIXROUTE for IPv6. They were added together in kernel 3.14, * dated 30 March, 2014. * * For IPv4, IFA_F_NOPREFIXROUTE was added later, but there is no easy * way to detect kernel support. */ support = !!nlmsg_find_attr (msg_hdr, sizeof (struct ifaddrmsg), IFA_FLAGS); _support_kernel_extended_ifa_flags = support ? 1 : -1; _LOG2D ("kernel-support: extended-ifa-flags: %s", support ? "detected" : "not detected"); } static gboolean _support_kernel_extended_ifa_flags_get (void) { if (_support_kernel_extended_ifa_flags_still_undecided ()) { _LOG2D ("kernel-support: extended-ifa-flags: %s", "unable to detect kernel support for handling IPv6 temporary addresses. Assume support"); _support_kernel_extended_ifa_flags = 1; } return _support_kernel_extended_ifa_flags >= 0; } /***************************************************************************** * Support RTA_PREF *****************************************************************************/ static int _support_rta_pref = 0; #define _support_rta_pref_still_undecided() (G_UNLIKELY (_support_rta_pref == 0)) static void _support_rta_pref_detect (struct nlattr **tb) { gboolean supported; nm_assert (_support_rta_pref_still_undecided ()); /* RTA_PREF was added in kernel 4.1, dated 21 June, 2015. */ supported = !!tb[RTA_PREF]; _support_rta_pref = supported ? 1 : -1; _LOG2D ("kernel-support: RTA_PREF: ability to set router preference for IPv6 routes: %s", supported ? "detected" : "not detected"); } static gboolean _support_rta_pref_get (void) { if (_support_rta_pref_still_undecided ()) { /* if we couldn't detect support, we fallback on compile-time check, whether * RTA_PREF is present in the kernel headers. */ _support_rta_pref = RTA_PREF_SUPPORTED_AT_COMPILETIME ? 1 : -1; _LOG2D ("kernel-support: RTA_PREF: ability to set router preference for IPv6 routes: %s", RTA_PREF_SUPPORTED_AT_COMPILETIME ? "assume support" : "assume no support"); } return _support_rta_pref >= 0; } /****************************************************************** * Various utilities ******************************************************************/ static int _vlan_qos_mapping_cmp_from (gconstpointer a, gconstpointer b, gpointer user_data) { const NMVlanQosMapping *map_a = a; const NMVlanQosMapping *map_b = b; if (map_a->from != map_b->from) return map_a->from < map_b->from ? -1 : 1; return 0; } static int _vlan_qos_mapping_cmp_from_ptr (gconstpointer a, gconstpointer b, gpointer user_data) { return _vlan_qos_mapping_cmp_from (*((const NMVlanQosMapping **) a), *((const NMVlanQosMapping **) b), NULL); } /****************************************************************** * NMLinkType functions ******************************************************************/ typedef struct { const NMLinkType nm_type; const char *type_string; /* IFLA_INFO_KIND / rtnl_link_get_type() where applicable; the rtnl type * should only be specified if the device type can be created without * additional parameters, and if the device type can be determined from * the rtnl_type. eg, tun/tap should not be specified since both * tun and tap devices use "tun", and InfiniBand should not be * specified because a PKey is required at creation. Drivers set this * value from their 'struct rtnl_link_ops' structure. */ const char *rtnl_type; /* uevent DEVTYPE where applicable, from /sys/class/net//uevent; * drivers set this value from their SET_NETDEV_DEV() call and the * 'struct device_type' name member. */ const char *devtype; } LinkDesc; static const LinkDesc linktypes[] = { { NM_LINK_TYPE_NONE, "none", NULL, NULL }, { NM_LINK_TYPE_UNKNOWN, "unknown", NULL, NULL }, { NM_LINK_TYPE_ETHERNET, "ethernet", NULL, NULL }, { NM_LINK_TYPE_INFINIBAND, "infiniband", NULL, NULL }, { NM_LINK_TYPE_OLPC_MESH, "olpc-mesh", NULL, NULL }, { NM_LINK_TYPE_WIFI, "wifi", NULL, "wlan" }, { NM_LINK_TYPE_WWAN_NET, "wwan", NULL, "wwan" }, { NM_LINK_TYPE_WIMAX, "wimax", "wimax", "wimax" }, { NM_LINK_TYPE_BNEP, "bluetooth", NULL, "bluetooth" }, { NM_LINK_TYPE_DUMMY, "dummy", "dummy", NULL }, { NM_LINK_TYPE_GRE, "gre", "gre", NULL }, { NM_LINK_TYPE_GRETAP, "gretap", "gretap", NULL }, { NM_LINK_TYPE_IFB, "ifb", "ifb", NULL }, { NM_LINK_TYPE_IP6TNL, "ip6tnl", "ip6tnl", NULL }, { NM_LINK_TYPE_IPIP, "ipip", "ipip", NULL }, { NM_LINK_TYPE_LOOPBACK, "loopback", NULL, NULL }, { NM_LINK_TYPE_MACSEC, "macsec", "macsec", NULL }, { NM_LINK_TYPE_MACVLAN, "macvlan", "macvlan", NULL }, { NM_LINK_TYPE_MACVTAP, "macvtap", "macvtap", NULL }, { NM_LINK_TYPE_OPENVSWITCH, "openvswitch", "openvswitch", NULL }, { NM_LINK_TYPE_PPP, "ppp", NULL, "ppp" }, { NM_LINK_TYPE_SIT, "sit", "sit", NULL }, { NM_LINK_TYPE_TAP, "tap", NULL, NULL }, { NM_LINK_TYPE_TUN, "tun", NULL, NULL }, { NM_LINK_TYPE_VETH, "veth", "veth", NULL }, { NM_LINK_TYPE_VLAN, "vlan", "vlan", "vlan" }, { NM_LINK_TYPE_VXLAN, "vxlan", "vxlan", "vxlan" }, { NM_LINK_TYPE_BRIDGE, "bridge", "bridge", "bridge" }, { NM_LINK_TYPE_BOND, "bond", "bond", "bond" }, { NM_LINK_TYPE_TEAM, "team", "team", NULL }, }; static const char * nm_link_type_to_rtnl_type_string (NMLinkType type) { int i; for (i = 0; i < G_N_ELEMENTS (linktypes); i++) { if (type == linktypes[i].nm_type) return linktypes[i].rtnl_type; } g_return_val_if_reached (NULL); } const char * nm_link_type_to_string (NMLinkType type) { int i; for (i = 0; i < G_N_ELEMENTS (linktypes); i++) { if (type == linktypes[i].nm_type) return linktypes[i].type_string; } g_return_val_if_reached (NULL); } /****************************************************************** * Utilities ******************************************************************/ /* _timestamp_nl_to_ms: * @timestamp_nl: a timestamp from ifa_cacheinfo. * @monotonic_ms: *now* in CLOCK_MONOTONIC. Needed to estimate the current * uptime and how often timestamp_nl wrapped. * * Convert the timestamp from ifa_cacheinfo to CLOCK_MONOTONIC milliseconds. * The ifa_cacheinfo fields tstamp and cstamp contains timestamps that counts * with in 1/100th of a second of clock_gettime(CLOCK_MONOTONIC). However, * the uint32 counter wraps every 497 days of uptime, so we have to compensate * for that. */ static gint64 _timestamp_nl_to_ms (guint32 timestamp_nl, gint64 monotonic_ms) { const gint64 WRAP_INTERVAL = (((gint64) G_MAXUINT32) + 1) * (1000 / 100); gint64 timestamp_nl_ms; /* convert timestamp from 1/100th of a second to msec. */ timestamp_nl_ms = ((gint64) timestamp_nl) * (1000 / 100); /* timestamp wraps every 497 days. Try to compensate for that.*/ if (timestamp_nl_ms > monotonic_ms) { /* timestamp_nl_ms is in the future. Truncate it to *now* */ timestamp_nl_ms = monotonic_ms; } else if (monotonic_ms >= WRAP_INTERVAL) { timestamp_nl_ms += (monotonic_ms / WRAP_INTERVAL) * WRAP_INTERVAL; if (timestamp_nl_ms > monotonic_ms) timestamp_nl_ms -= WRAP_INTERVAL; } return timestamp_nl_ms; } static guint32 _addrtime_timestamp_to_nm (guint32 timestamp, gint32 *out_now_nm) { struct timespec tp; gint64 now_nl, now_nm, result; int err; /* timestamp is unset. Default to 1. */ if (!timestamp) { if (out_now_nm) *out_now_nm = 0; return 1; } /* do all the calculations in milliseconds scale */ err = clock_gettime (CLOCK_MONOTONIC, &tp); g_assert (err == 0); now_nm = nm_utils_get_monotonic_timestamp_ms (); now_nl = (((gint64) tp.tv_sec) * ((gint64) 1000)) + (tp.tv_nsec / (NM_UTILS_NS_PER_SECOND/1000)); result = now_nm - (now_nl - _timestamp_nl_to_ms (timestamp, now_nl)); if (out_now_nm) *out_now_nm = now_nm / 1000; /* converting the timestamp into nm_utils_get_monotonic_timestamp_ms() scale is * a good guess but fails in the following situations: * * - If the address existed before start of the process, the timestamp in nm scale would * be negative or zero. In this case we default to 1. * - during hibernation, the CLOCK_MONOTONIC/timestamp drifts from * nm_utils_get_monotonic_timestamp_ms() scale. */ if (result <= 1000) return 1; if (result > now_nm) return now_nm / 1000; return result / 1000; } static guint32 _addrtime_extend_lifetime (guint32 lifetime, guint32 seconds) { guint64 v; if ( lifetime == NM_PLATFORM_LIFETIME_PERMANENT || seconds == 0) return lifetime; v = (guint64) lifetime + (guint64) seconds; return MIN (v, NM_PLATFORM_LIFETIME_PERMANENT - 1); } /* The rtnl_addr object contains relative lifetimes @valid and @preferred * that count in seconds, starting from the moment when the kernel constructed * the netlink message. * * There is also a field rtnl_addr_last_update_time(), which is the absolute * time in 1/100th of a second of clock_gettime (CLOCK_MONOTONIC) when the address * was modified (wrapping every 497 days). * Immediately at the time when the address was last modified, #NOW and @last_update_time * are the same, so (only) in that case @valid and @preferred are anchored at @last_update_time. * However, this is not true in general. As time goes by, whenever kernel sends a new address * via netlink, the lifetimes keep counting down. **/ static void _addrtime_get_lifetimes (guint32 timestamp, guint32 lifetime, guint32 preferred, guint32 *out_timestamp, guint32 *out_lifetime, guint32 *out_preferred) { gint32 now; if ( lifetime != NM_PLATFORM_LIFETIME_PERMANENT || preferred != NM_PLATFORM_LIFETIME_PERMANENT) { if (preferred > lifetime) preferred = lifetime; timestamp = _addrtime_timestamp_to_nm (timestamp, &now); if (now == 0) { /* strange. failed to detect the last-update time and assumed that timestamp is 1. */ nm_assert (timestamp == 1); now = nm_utils_get_monotonic_timestamp_s (); } if (timestamp < now) { guint32 diff = now - timestamp; lifetime = _addrtime_extend_lifetime (lifetime, diff); preferred = _addrtime_extend_lifetime (preferred, diff); } else nm_assert (timestamp == now); } else timestamp = 0; *out_timestamp = timestamp; *out_lifetime = lifetime; *out_preferred = preferred; } /*****************************************************************************/ static const NMPObject * _lookup_cached_link (const NMPCache *cache, int ifindex, gboolean *completed_from_cache, const NMPObject **link_cached) { const NMPObject *obj; nm_assert (completed_from_cache && link_cached); if (!*completed_from_cache) { obj = ifindex > 0 && cache ? nmp_cache_lookup_link (cache, ifindex) : NULL; if (obj && obj->_link.netlink.is_in_netlink) *link_cached = obj; else *link_cached = NULL; *completed_from_cache = TRUE; } return *link_cached; } /*****************************************************************************/ #define DEVTYPE_PREFIX "DEVTYPE=" static char * _linktype_read_devtype (int dirfd) { char *contents = NULL; char *cont, *end; nm_assert (dirfd >= 0); if (nm_utils_file_get_contents (dirfd, "uevent", 1*1024*1024, &contents, NULL, NULL) < 0) return NULL; for (cont = contents; cont; cont = end) { end = strpbrk (cont, "\r\n"); if (end) *end++ = '\0'; if (strncmp (cont, DEVTYPE_PREFIX, NM_STRLEN (DEVTYPE_PREFIX)) == 0) { cont += NM_STRLEN (DEVTYPE_PREFIX); memmove (contents, cont, strlen (cont) + 1); return contents; } } g_free (contents); return NULL; } static NMLinkType _linktype_get_type (NMPlatform *platform, const NMPCache *cache, const char *kind, int ifindex, const char *ifname, unsigned flags, unsigned arptype, gboolean *completed_from_cache, const NMPObject **link_cached, const char **out_kind) { guint i; NMTST_ASSERT_PLATFORM_NETNS_CURRENT (platform); nm_assert (ifname); if (completed_from_cache) { const NMPObject *obj; obj = _lookup_cached_link (cache, ifindex, completed_from_cache, link_cached); /* If we detected the link type before, we stick to that * decision unless the "kind" no "name" changed. If "name" changed, * it means that their type may not have been determined correctly * due to race conditions while accessing sysfs. * * This way, we save edditional ethtool/sysctl lookups, but moreover, * we keep the linktype stable and don't change it as long as the link * exists. * * Note that kernel *can* reuse the ifindex (on integer overflow, and * when moving interfce to other netns). Thus here there is a tiny potential * of messing stuff up. */ if ( obj && !NM_IN_SET (obj->link.type, NM_LINK_TYPE_UNKNOWN, NM_LINK_TYPE_NONE) && nm_streq (ifname, obj->link.name) && ( !kind || !g_strcmp0 (kind, obj->link.kind))) { nm_assert (obj->link.kind == g_intern_string (obj->link.kind)); *out_kind = obj->link.kind; return obj->link.type; } } *out_kind = g_intern_string (kind); if (kind) { for (i = 0; i < G_N_ELEMENTS (linktypes); i++) { if (g_strcmp0 (kind, linktypes[i].rtnl_type) == 0) return linktypes[i].nm_type; } if (!strcmp (kind, "tun")) { NMPlatformTunProperties props; if ( platform && nm_platform_link_tun_get_properties (platform, ifindex, &props)) { if (!g_strcmp0 (props.mode, "tap")) return NM_LINK_TYPE_TAP; if (!g_strcmp0 (props.mode, "tun")) return NM_LINK_TYPE_TUN; } /* try guessing the type using the link flags instead... */ if (flags & IFF_POINTOPOINT) return NM_LINK_TYPE_TUN; return NM_LINK_TYPE_TAP; } } if (arptype == ARPHRD_LOOPBACK) return NM_LINK_TYPE_LOOPBACK; else if (arptype == ARPHRD_INFINIBAND) return NM_LINK_TYPE_INFINIBAND; else if (arptype == ARPHRD_SIT) return NM_LINK_TYPE_SIT; else if (arptype == ARPHRD_TUNNEL6) return NM_LINK_TYPE_IP6TNL; else if (arptype == ARPHRD_PPP) return NM_LINK_TYPE_PPP; { NMPUtilsEthtoolDriverInfo driver_info; /* Fallback OVS detection for kernel <= 3.16 */ if (nmp_utils_ethtool_get_driver_info (ifindex, &driver_info)) { if (nm_streq (driver_info.driver, "openvswitch")) return NM_LINK_TYPE_OPENVSWITCH; if (arptype == 256) { /* Some s390 CTC-type devices report 256 for the encapsulation type * for some reason, but we need to call them Ethernet. */ if (nm_streq (driver_info.driver, "ctcm")) return NM_LINK_TYPE_ETHERNET; } } } { nm_auto_close int dirfd = -1; gs_free char *devtype = NULL; char ifname_verified[IFNAMSIZ]; dirfd = nmp_utils_sysctl_open_netdir (ifindex, ifname, ifname_verified); if (dirfd >= 0) { if (faccessat (dirfd, "anycast_mask", F_OK, 0) == 0) return NM_LINK_TYPE_OLPC_MESH; devtype = _linktype_read_devtype (dirfd); for (i = 0; devtype && i < G_N_ELEMENTS (linktypes); i++) { if (g_strcmp0 (devtype, linktypes[i].devtype) == 0) { if (linktypes[i].nm_type == NM_LINK_TYPE_BNEP) { /* Both BNEP and 6lowpan use DEVTYPE=bluetooth, so we must * use arptype to distinguish between them. */ if (arptype != ARPHRD_ETHER) continue; } return linktypes[i].nm_type; } } /* Fallback for drivers that don't call SET_NETDEV_DEVTYPE() */ if (wifi_utils_is_wifi (dirfd, ifname_verified)) return NM_LINK_TYPE_WIFI; } if (arptype == ARPHRD_ETHER) { /* Misc non-upstream WWAN drivers. rmnet is Qualcomm's proprietary * modem interface, ccmni is MediaTek's. FIXME: these drivers should * really set devtype=WWAN. */ if (g_str_has_prefix (ifname, "rmnet") || g_str_has_prefix (ifname, "rev_rmnet") || g_str_has_prefix (ifname, "ccmni")) return NM_LINK_TYPE_WWAN_NET; /* Standard wired ethernet interfaces don't report an rtnl_link_type, so * only allow fallback to Ethernet if no type is given. This should * prevent future virtual network drivers from being treated as Ethernet * when they should be Generic instead. */ if (!kind && !devtype) return NM_LINK_TYPE_ETHERNET; /* The USB gadget interfaces behave and look like ordinary ethernet devices * aside from the DEVTYPE. */ if (!g_strcmp0 (devtype, "gadget")) return NM_LINK_TYPE_ETHERNET; /* Distributed Switch Architecture switch chips */ if (!g_strcmp0 (devtype, "dsa")) return NM_LINK_TYPE_ETHERNET; } } return NM_LINK_TYPE_UNKNOWN; } /****************************************************************** * libnl unility functions and wrappers ******************************************************************/ #define NLMSG_TAIL(nmsg) \ ((struct rtattr *) (((char *) (nmsg)) + NLMSG_ALIGN((nmsg)->nlmsg_len))) /* copied from iproute2's addattr_l(). */ static gboolean _nl_addattr_l (struct nlmsghdr *n, int maxlen, int type, const void *data, int alen) { int len = RTA_LENGTH (alen); struct rtattr *rta; if (NLMSG_ALIGN (n->nlmsg_len) + RTA_ALIGN (len) > maxlen) return FALSE; rta = NLMSG_TAIL (n); rta->rta_type = type; rta->rta_len = len; memcpy (RTA_DATA (rta), data, alen); n->nlmsg_len = NLMSG_ALIGN (n->nlmsg_len) + RTA_ALIGN (len); return TRUE; } static void _nm_auto_nl_msg_cleanup (void *ptr) { nlmsg_free (*((struct nl_msg **) ptr)); } #define nm_auto_nlmsg nm_auto(_nm_auto_nl_msg_cleanup) static const char * _nl_nlmsghdr_to_str (const struct nlmsghdr *hdr, char *buf, gsize len) { const char *b; const char *s; guint flags, flags_before; const char *prefix; nm_utils_to_string_buffer_init (&buf, &len); b = buf; switch (hdr->nlmsg_type) { case RTM_NEWLINK: s = "NEWLINK"; break; case RTM_DELLINK: s = "DELLINK"; break; case RTM_NEWADDR: s = "NEWADDR"; break; case RTM_DELADDR: s = "DELADDR"; break; case RTM_NEWROUTE: s = "NEWROUTE"; break; case RTM_DELROUTE: s = "DELROUTE"; break; default: s = NULL; break; } if (s) nm_utils_strbuf_append (&buf, &len, "RTM_%s", s); else nm_utils_strbuf_append (&buf, &len, "(%u)", (unsigned) hdr->nlmsg_type); flags = hdr->nlmsg_flags; if (!flags) { nm_utils_strbuf_append_str (&buf, &len, ", flags 0"); goto flags_done; } #define _F(f, n) \ G_STMT_START { \ if (NM_FLAGS_ALL (flags, f)) { \ flags &= ~(f); \ nm_utils_strbuf_append (&buf, &len, "%s%s", prefix, n); \ if (!flags) \ goto flags_done; \ prefix = ","; \ } \ } G_STMT_END prefix = ", flags "; flags_before = flags; _F (NLM_F_REQUEST, "request"); _F (NLM_F_MULTI, "multi"); _F (NLM_F_ACK, "ack"); _F (NLM_F_ECHO, "echo"); _F (NLM_F_DUMP_INTR, "dump_intr"); _F (0x20 /*NLM_F_DUMP_FILTERED*/, "dump_filtered"); if (flags_before != flags) prefix = ";"; switch (hdr->nlmsg_type) { case RTM_NEWLINK: case RTM_NEWADDR: case RTM_NEWROUTE: _F (NLM_F_REPLACE, "replace"); _F (NLM_F_EXCL, "excl"); _F (NLM_F_CREATE, "create"); _F (NLM_F_APPEND, "append"); break; case RTM_GETLINK: case RTM_GETADDR: case RTM_GETROUTE: _F (NLM_F_DUMP, "dump"); _F (NLM_F_ROOT, "root"); _F (NLM_F_MATCH, "match"); _F (NLM_F_ATOMIC, "atomic"); break; } #undef _F if (flags_before != flags) prefix = ";"; nm_utils_strbuf_append (&buf, &len, "%s0x%04x", prefix, flags); flags_done: nm_utils_strbuf_append (&buf, &len, ", seq %u", (unsigned) hdr->nlmsg_seq); return b; } static int _nl_nla_parse (struct nlattr *tb[], int maxtype, struct nlattr *head, int len, const struct nla_policy *policy) { return nla_parse (tb, maxtype, head, len, (struct nla_policy *) policy); } #define nla_parse(...) _nl_nla_parse(__VA_ARGS__) static int _nl_nlmsg_parse (struct nlmsghdr *nlh, int hdrlen, struct nlattr *tb[], int maxtype, const struct nla_policy *policy) { return nlmsg_parse (nlh, hdrlen, tb, maxtype, (struct nla_policy *) policy); } #define nlmsg_parse(...) _nl_nlmsg_parse(__VA_ARGS__) static int _nl_nla_parse_nested (struct nlattr *tb[], int maxtype, struct nlattr *nla, const struct nla_policy *policy) { return nla_parse_nested (tb, maxtype, nla, (struct nla_policy *) policy); } #define nla_parse_nested(...) _nl_nla_parse_nested(__VA_ARGS__) /****************************************************************** * NMPObject/netlink functions ******************************************************************/ #define _check_addr_or_errout(tb, attr, addr_len) \ ({ \ const struct nlattr *__t = (tb)[(attr)]; \ \ if (__t) { \ if (nla_len (__t) != (addr_len)) { \ goto errout; \ } \ } \ !!__t; \ }) /*****************************************************************************/ /* Copied and heavily modified from libnl3's inet6_parse_protinfo(). */ static gboolean _parse_af_inet6 (NMPlatform *platform, struct nlattr *attr, NMUtilsIPv6IfaceId *out_token, gboolean *out_token_valid, guint8 *out_addr_gen_mode_inv, gboolean *out_addr_gen_mode_valid) { static const struct nla_policy policy[IFLA_INET6_MAX+1] = { [IFLA_INET6_FLAGS] = { .type = NLA_U32 }, [IFLA_INET6_CACHEINFO] = { .minlen = nm_offsetofend (struct ifla_cacheinfo, retrans_time) }, [IFLA_INET6_CONF] = { .minlen = 4 }, [IFLA_INET6_STATS] = { .minlen = 8 }, [IFLA_INET6_ICMP6STATS] = { .minlen = 8 }, [IFLA_INET6_TOKEN] = { .minlen = sizeof(struct in6_addr) }, [IFLA_INET6_ADDR_GEN_MODE] = { .type = NLA_U8 }, }; struct nlattr *tb[IFLA_INET6_MAX+1]; int err; struct in6_addr i6_token; gboolean token_valid = FALSE; gboolean addr_gen_mode_valid = FALSE; guint8 i6_addr_gen_mode_inv = 0; gboolean success = FALSE; err = nla_parse_nested (tb, IFLA_INET6_MAX, attr, policy); if (err < 0) goto errout; if (tb[IFLA_INET6_CONF] && nla_len(tb[IFLA_INET6_CONF]) % 4) goto errout; if (tb[IFLA_INET6_STATS] && nla_len(tb[IFLA_INET6_STATS]) % 8) goto errout; if (tb[IFLA_INET6_ICMP6STATS] && nla_len(tb[IFLA_INET6_ICMP6STATS]) % 8) goto errout; if (_check_addr_or_errout (tb, IFLA_INET6_TOKEN, sizeof (struct in6_addr))) { nla_memcpy (&i6_token, tb[IFLA_INET6_TOKEN], sizeof (struct in6_addr)); token_valid = TRUE; } /* Hack to detect support addrgenmode of the kernel. We only parse * netlink messages that we receive from kernel, hence this check * is valid. */ if (_support_user_ipv6ll_still_undecided ()) _support_user_ipv6ll_detect (tb); if (tb[IFLA_INET6_ADDR_GEN_MODE]) { i6_addr_gen_mode_inv = _nm_platform_uint8_inv (nla_get_u8 (tb[IFLA_INET6_ADDR_GEN_MODE])); if (i6_addr_gen_mode_inv == 0) { /* an inverse addrgenmode of zero is unexpected. We need to reserve zero * to signal "unset". */ goto errout; } addr_gen_mode_valid = TRUE; } success = TRUE; if (token_valid) { *out_token_valid = token_valid; nm_utils_ipv6_interface_identifier_get_from_addr (out_token, &i6_token); } if (addr_gen_mode_valid) { *out_addr_gen_mode_valid = addr_gen_mode_valid; *out_addr_gen_mode_inv = i6_addr_gen_mode_inv; } errout: return success; } /*****************************************************************************/ static NMPObject * _parse_lnk_gre (const char *kind, struct nlattr *info_data) { static const struct nla_policy policy[IFLA_GRE_MAX + 1] = { [IFLA_GRE_LINK] = { .type = NLA_U32 }, [IFLA_GRE_IFLAGS] = { .type = NLA_U16 }, [IFLA_GRE_OFLAGS] = { .type = NLA_U16 }, [IFLA_GRE_IKEY] = { .type = NLA_U32 }, [IFLA_GRE_OKEY] = { .type = NLA_U32 }, [IFLA_GRE_LOCAL] = { .type = NLA_U32 }, [IFLA_GRE_REMOTE] = { .type = NLA_U32 }, [IFLA_GRE_TTL] = { .type = NLA_U8 }, [IFLA_GRE_TOS] = { .type = NLA_U8 }, [IFLA_GRE_PMTUDISC] = { .type = NLA_U8 }, }; struct nlattr *tb[IFLA_GRE_MAX + 1]; int err; NMPObject *obj; NMPlatformLnkGre *props; if (!info_data || g_strcmp0 (kind, "gre")) return NULL; err = nla_parse_nested (tb, IFLA_GRE_MAX, info_data, policy); if (err < 0) return NULL; obj = nmp_object_new (NMP_OBJECT_TYPE_LNK_GRE, NULL); props = &obj->lnk_gre; props->parent_ifindex = tb[IFLA_GRE_LINK] ? nla_get_u32 (tb[IFLA_GRE_LINK]) : 0; props->input_flags = tb[IFLA_GRE_IFLAGS] ? ntohs (nla_get_u16 (tb[IFLA_GRE_IFLAGS])) : 0; props->output_flags = tb[IFLA_GRE_OFLAGS] ? ntohs (nla_get_u16 (tb[IFLA_GRE_OFLAGS])) : 0; props->input_key = tb[IFLA_GRE_IKEY] ? ntohl (nla_get_u32 (tb[IFLA_GRE_IKEY])) : 0; props->output_key = tb[IFLA_GRE_OKEY] ? ntohl (nla_get_u32 (tb[IFLA_GRE_OKEY])) : 0; props->local = tb[IFLA_GRE_LOCAL] ? nla_get_u32 (tb[IFLA_GRE_LOCAL]) : 0; props->remote = tb[IFLA_GRE_REMOTE] ? nla_get_u32 (tb[IFLA_GRE_REMOTE]) : 0; props->tos = tb[IFLA_GRE_TOS] ? nla_get_u8 (tb[IFLA_GRE_TOS]) : 0; props->ttl = tb[IFLA_GRE_TTL] ? nla_get_u8 (tb[IFLA_GRE_TTL]) : 0; props->path_mtu_discovery = !tb[IFLA_GRE_PMTUDISC] || !!nla_get_u8 (tb[IFLA_GRE_PMTUDISC]); return obj; } /*****************************************************************************/ /* IFLA_IPOIB_* were introduced in the 3.7 kernel, but the kernel headers * we're building against might not have those properties even though the * running kernel might. */ #define IFLA_IPOIB_UNSPEC 0 #define IFLA_IPOIB_PKEY 1 #define IFLA_IPOIB_MODE 2 #define IFLA_IPOIB_UMCAST 3 #undef IFLA_IPOIB_MAX #define IFLA_IPOIB_MAX IFLA_IPOIB_UMCAST #define IPOIB_MODE_DATAGRAM 0 /* using unreliable datagram QPs */ #define IPOIB_MODE_CONNECTED 1 /* using connected QPs */ static NMPObject * _parse_lnk_infiniband (const char *kind, struct nlattr *info_data) { static const struct nla_policy policy[IFLA_IPOIB_MAX + 1] = { [IFLA_IPOIB_PKEY] = { .type = NLA_U16 }, [IFLA_IPOIB_MODE] = { .type = NLA_U16 }, [IFLA_IPOIB_UMCAST] = { .type = NLA_U16 }, }; struct nlattr *tb[IFLA_IPOIB_MAX + 1]; NMPlatformLnkInfiniband *info; NMPObject *obj; int err; const char *mode; if (!info_data || g_strcmp0 (kind, "ipoib")) return NULL; err = nla_parse_nested (tb, IFLA_IPOIB_MAX, info_data, policy); if (err < 0) return NULL; if (!tb[IFLA_IPOIB_PKEY] || !tb[IFLA_IPOIB_MODE]) return NULL; switch (nla_get_u16 (tb[IFLA_IPOIB_MODE])) { case IPOIB_MODE_DATAGRAM: mode = "datagram"; break; case IPOIB_MODE_CONNECTED: mode = "connected"; break; default: return NULL; } obj = nmp_object_new (NMP_OBJECT_TYPE_LNK_INFINIBAND, NULL); info = &obj->lnk_infiniband; info->p_key = nla_get_u16 (tb[IFLA_IPOIB_PKEY]); info->mode = mode; return obj; } /*****************************************************************************/ static NMPObject * _parse_lnk_ip6tnl (const char *kind, struct nlattr *info_data) { static const struct nla_policy policy[IFLA_IPTUN_MAX + 1] = { [IFLA_IPTUN_LINK] = { .type = NLA_U32 }, [IFLA_IPTUN_LOCAL] = { .type = NLA_UNSPEC, .minlen = sizeof (struct in6_addr)}, [IFLA_IPTUN_REMOTE] = { .type = NLA_UNSPEC, .minlen = sizeof (struct in6_addr)}, [IFLA_IPTUN_TTL] = { .type = NLA_U8 }, [IFLA_IPTUN_ENCAP_LIMIT] = { .type = NLA_U8 }, [IFLA_IPTUN_FLOWINFO] = { .type = NLA_U32 }, [IFLA_IPTUN_PROTO] = { .type = NLA_U8 }, }; struct nlattr *tb[IFLA_IPTUN_MAX + 1]; int err; NMPObject *obj; NMPlatformLnkIp6Tnl *props; guint32 flowinfo; if (!info_data || g_strcmp0 (kind, "ip6tnl")) return NULL; err = nla_parse_nested (tb, IFLA_IPTUN_MAX, info_data, policy); if (err < 0) return NULL; obj = nmp_object_new (NMP_OBJECT_TYPE_LNK_IP6TNL, NULL); props = &obj->lnk_ip6tnl; if (tb[IFLA_IPTUN_LINK]) props->parent_ifindex = nla_get_u32 (tb[IFLA_IPTUN_LINK]); if (tb[IFLA_IPTUN_LOCAL]) memcpy (&props->local, nla_data (tb[IFLA_IPTUN_LOCAL]), sizeof (props->local)); if (tb[IFLA_IPTUN_REMOTE]) memcpy (&props->remote, nla_data (tb[IFLA_IPTUN_REMOTE]), sizeof (props->remote)); if (tb[IFLA_IPTUN_TTL]) props->ttl = nla_get_u8 (tb[IFLA_IPTUN_TTL]); if (tb[IFLA_IPTUN_ENCAP_LIMIT]) props->encap_limit = nla_get_u8 (tb[IFLA_IPTUN_ENCAP_LIMIT]); if (tb[IFLA_IPTUN_FLOWINFO]) { flowinfo = ntohl (nla_get_u32 (tb[IFLA_IPTUN_FLOWINFO])); props->flow_label = flowinfo & IP6_FLOWINFO_FLOWLABEL_MASK; props->tclass = (flowinfo & IP6_FLOWINFO_TCLASS_MASK) >> IP6_FLOWINFO_TCLASS_SHIFT; } if (tb[IFLA_IPTUN_PROTO]) props->proto = nla_get_u8 (tb[IFLA_IPTUN_PROTO]); return obj; } /*****************************************************************************/ static NMPObject * _parse_lnk_ipip (const char *kind, struct nlattr *info_data) { static const struct nla_policy policy[IFLA_IPTUN_MAX + 1] = { [IFLA_IPTUN_LINK] = { .type = NLA_U32 }, [IFLA_IPTUN_LOCAL] = { .type = NLA_U32 }, [IFLA_IPTUN_REMOTE] = { .type = NLA_U32 }, [IFLA_IPTUN_TTL] = { .type = NLA_U8 }, [IFLA_IPTUN_TOS] = { .type = NLA_U8 }, [IFLA_IPTUN_PMTUDISC] = { .type = NLA_U8 }, }; struct nlattr *tb[IFLA_IPTUN_MAX + 1]; int err; NMPObject *obj; NMPlatformLnkIpIp *props; if (!info_data || g_strcmp0 (kind, "ipip")) return NULL; err = nla_parse_nested (tb, IFLA_IPTUN_MAX, info_data, policy); if (err < 0) return NULL; obj = nmp_object_new (NMP_OBJECT_TYPE_LNK_IPIP, NULL); props = &obj->lnk_ipip; props->parent_ifindex = tb[IFLA_IPTUN_LINK] ? nla_get_u32 (tb[IFLA_IPTUN_LINK]) : 0; props->local = tb[IFLA_IPTUN_LOCAL] ? nla_get_u32 (tb[IFLA_IPTUN_LOCAL]) : 0; props->remote = tb[IFLA_IPTUN_REMOTE] ? nla_get_u32 (tb[IFLA_IPTUN_REMOTE]) : 0; props->tos = tb[IFLA_IPTUN_TOS] ? nla_get_u8 (tb[IFLA_IPTUN_TOS]) : 0; props->ttl = tb[IFLA_IPTUN_TTL] ? nla_get_u8 (tb[IFLA_IPTUN_TTL]) : 0; props->path_mtu_discovery = !tb[IFLA_IPTUN_PMTUDISC] || !!nla_get_u8 (tb[IFLA_IPTUN_PMTUDISC]); return obj; } /*****************************************************************************/ static NMPObject * _parse_lnk_macvlan (const char *kind, struct nlattr *info_data) { static const struct nla_policy policy[IFLA_MACVLAN_MAX + 1] = { [IFLA_MACVLAN_MODE] = { .type = NLA_U32 }, [IFLA_MACVLAN_FLAGS] = { .type = NLA_U16 }, }; NMPlatformLnkMacvlan *props; struct nlattr *tb[IFLA_MACVLAN_MAX + 1]; int err; NMPObject *obj; gboolean tap; if (!info_data) return NULL; if (!g_strcmp0 (kind, "macvlan")) tap = FALSE; else if (!g_strcmp0 (kind, "macvtap")) tap = TRUE; else return NULL; err = nla_parse_nested (tb, IFLA_MACVLAN_MAX, info_data, policy); if (err < 0) return NULL; if (!tb[IFLA_MACVLAN_MODE]) return NULL; obj = nmp_object_new (tap ? NMP_OBJECT_TYPE_LNK_MACVTAP : NMP_OBJECT_TYPE_LNK_MACVLAN, NULL); props = &obj->lnk_macvlan; props->mode = nla_get_u32 (tb[IFLA_MACVLAN_MODE]); props->tap = tap; if (tb[IFLA_MACVLAN_FLAGS]) props->no_promisc = NM_FLAGS_HAS (nla_get_u16 (tb[IFLA_MACVLAN_FLAGS]), MACVLAN_FLAG_NOPROMISC); return obj; } /*****************************************************************************/ static NMPObject * _parse_lnk_macsec (const char *kind, struct nlattr *info_data) { static const struct nla_policy policy[__IFLA_MACSEC_MAX] = { [IFLA_MACSEC_SCI] = { .type = NLA_U64 }, [IFLA_MACSEC_ICV_LEN] = { .type = NLA_U8 }, [IFLA_MACSEC_CIPHER_SUITE] = { .type = NLA_U64 }, [IFLA_MACSEC_WINDOW] = { .type = NLA_U32 }, [IFLA_MACSEC_ENCODING_SA] = { .type = NLA_U8 }, [IFLA_MACSEC_ENCRYPT] = { .type = NLA_U8 }, [IFLA_MACSEC_PROTECT] = { .type = NLA_U8 }, [IFLA_MACSEC_INC_SCI] = { .type = NLA_U8 }, [IFLA_MACSEC_ES] = { .type = NLA_U8 }, [IFLA_MACSEC_SCB] = { .type = NLA_U8 }, [IFLA_MACSEC_REPLAY_PROTECT] = { .type = NLA_U8 }, [IFLA_MACSEC_VALIDATION] = { .type = NLA_U8 }, }; struct nlattr *tb[__IFLA_MACSEC_MAX]; int err; NMPObject *obj; NMPlatformLnkMacsec *props; if (!info_data || !nm_streq0 (kind, "macsec")) return NULL; err = nla_parse_nested (tb, __IFLA_MACSEC_MAX - 1, info_data, policy); if (err < 0) return NULL; obj = nmp_object_new (NMP_OBJECT_TYPE_LNK_MACSEC, NULL); props = &obj->lnk_macsec; props->sci = tb[IFLA_MACSEC_SCI] ? be64toh (nla_get_u64 (tb[IFLA_MACSEC_SCI])) : 0; props->icv_length = tb[IFLA_MACSEC_ICV_LEN] ? nla_get_u8 (tb[IFLA_MACSEC_ICV_LEN]) : 0; props->cipher_suite = tb [IFLA_MACSEC_CIPHER_SUITE] ? nla_get_u64 (tb[IFLA_MACSEC_CIPHER_SUITE]) : 0; props->window = tb [IFLA_MACSEC_WINDOW] ? nla_get_u32 (tb[IFLA_MACSEC_WINDOW]) : 0; props->encoding_sa = tb[IFLA_MACSEC_ENCODING_SA] ? !!nla_get_u8 (tb[IFLA_MACSEC_ENCODING_SA]) : 0; props->encrypt = tb[IFLA_MACSEC_ENCRYPT] ? !!nla_get_u8 (tb[IFLA_MACSEC_ENCRYPT]) : 0; props->protect = tb[IFLA_MACSEC_PROTECT] ? !!nla_get_u8 (tb[IFLA_MACSEC_PROTECT]) : 0; props->include_sci = tb[IFLA_MACSEC_INC_SCI] ? !!nla_get_u8 (tb[IFLA_MACSEC_INC_SCI]) : 0; props->es = tb[IFLA_MACSEC_ES] ? !!nla_get_u8 (tb[IFLA_MACSEC_ES]) : 0; props->scb = tb[IFLA_MACSEC_SCB] ? !!nla_get_u8 (tb[IFLA_MACSEC_SCB]) : 0; props->replay_protect = tb[IFLA_MACSEC_REPLAY_PROTECT] ? !!nla_get_u8 (tb[IFLA_MACSEC_REPLAY_PROTECT]) : 0; props->validation = tb[IFLA_MACSEC_VALIDATION] ? nla_get_u8 (tb[IFLA_MACSEC_VALIDATION]) : 0; return obj; } /*****************************************************************************/ static NMPObject * _parse_lnk_sit (const char *kind, struct nlattr *info_data) { static const struct nla_policy policy[IFLA_IPTUN_MAX + 1] = { [IFLA_IPTUN_LINK] = { .type = NLA_U32 }, [IFLA_IPTUN_LOCAL] = { .type = NLA_U32 }, [IFLA_IPTUN_REMOTE] = { .type = NLA_U32 }, [IFLA_IPTUN_TTL] = { .type = NLA_U8 }, [IFLA_IPTUN_TOS] = { .type = NLA_U8 }, [IFLA_IPTUN_PMTUDISC] = { .type = NLA_U8 }, [IFLA_IPTUN_FLAGS] = { .type = NLA_U16 }, [IFLA_IPTUN_PROTO] = { .type = NLA_U8 }, }; struct nlattr *tb[IFLA_IPTUN_MAX + 1]; int err; NMPObject *obj; NMPlatformLnkSit *props; if (!info_data || g_strcmp0 (kind, "sit")) return NULL; err = nla_parse_nested (tb, IFLA_IPTUN_MAX, info_data, policy); if (err < 0) return NULL; obj = nmp_object_new (NMP_OBJECT_TYPE_LNK_SIT, NULL); props = &obj->lnk_sit; props->parent_ifindex = tb[IFLA_IPTUN_LINK] ? nla_get_u32 (tb[IFLA_IPTUN_LINK]) : 0; props->local = tb[IFLA_IPTUN_LOCAL] ? nla_get_u32 (tb[IFLA_IPTUN_LOCAL]) : 0; props->remote = tb[IFLA_IPTUN_REMOTE] ? nla_get_u32 (tb[IFLA_IPTUN_REMOTE]) : 0; props->tos = tb[IFLA_IPTUN_TOS] ? nla_get_u8 (tb[IFLA_IPTUN_TOS]) : 0; props->ttl = tb[IFLA_IPTUN_TTL] ? nla_get_u8 (tb[IFLA_IPTUN_TTL]) : 0; props->path_mtu_discovery = !tb[IFLA_IPTUN_PMTUDISC] || !!nla_get_u8 (tb[IFLA_IPTUN_PMTUDISC]); props->flags = tb[IFLA_IPTUN_FLAGS] ? nla_get_u16 (tb[IFLA_IPTUN_FLAGS]) : 0; props->proto = tb[IFLA_IPTUN_PROTO] ? nla_get_u8 (tb[IFLA_IPTUN_PROTO]) : 0; return obj; } /*****************************************************************************/ static gboolean _vlan_qos_mapping_from_nla (struct nlattr *nlattr, const NMVlanQosMapping **out_map, guint *out_n_map) { struct nlattr *nla; int remaining; gs_unref_ptrarray GPtrArray *array = NULL; G_STATIC_ASSERT (sizeof (NMVlanQosMapping) == sizeof (struct ifla_vlan_qos_mapping)); G_STATIC_ASSERT (sizeof (((NMVlanQosMapping *) 0)->to) == sizeof (((struct ifla_vlan_qos_mapping *) 0)->to)); G_STATIC_ASSERT (sizeof (((NMVlanQosMapping *) 0)->from) == sizeof (((struct ifla_vlan_qos_mapping *) 0)->from)); G_STATIC_ASSERT (sizeof (NMVlanQosMapping) == sizeof (((NMVlanQosMapping *) 0)->from) + sizeof (((NMVlanQosMapping *) 0)->to)); nm_assert (out_map && !*out_map); nm_assert (out_n_map && !*out_n_map); if (!nlattr) return TRUE; array = g_ptr_array_new (); nla_for_each_nested (nla, nlattr, remaining) { if (nla_len (nla) < sizeof(NMVlanQosMapping)) return FALSE; g_ptr_array_add (array, nla_data (nla)); } if (array->len > 0) { NMVlanQosMapping *list; guint i, j; /* The sorting is necessary, because for egress mapping, kernel * doesn't sent the items strictly sorted by the from field. */ g_ptr_array_sort_with_data (array, _vlan_qos_mapping_cmp_from_ptr, NULL); list = g_new (NMVlanQosMapping, array->len); for (i = 0, j = 0; i < array->len; i++) { NMVlanQosMapping *map; map = array->pdata[i]; /* kernel doesn't really send us duplicates. Just be extra cautious * because we want strong guarantees about the sort order and uniqueness * of our mapping list (for simpler equality comparison). */ if ( j > 0 && list[j - 1].from == map->from) list[j - 1] = *map; else list[j++] = *map; } *out_n_map = j; *out_map = list; } return TRUE; } /* Copied and heavily modified from libnl3's vlan_parse() */ static NMPObject * _parse_lnk_vlan (const char *kind, struct nlattr *info_data) { static const struct nla_policy policy[IFLA_VLAN_MAX+1] = { [IFLA_VLAN_ID] = { .type = NLA_U16 }, [IFLA_VLAN_FLAGS] = { .minlen = nm_offsetofend (struct ifla_vlan_flags, flags) }, [IFLA_VLAN_INGRESS_QOS] = { .type = NLA_NESTED }, [IFLA_VLAN_EGRESS_QOS] = { .type = NLA_NESTED }, [IFLA_VLAN_PROTOCOL] = { .type = NLA_U16 }, }; struct nlattr *tb[IFLA_VLAN_MAX+1]; int err; nm_auto_nmpobj NMPObject *obj = NULL; NMPObject *obj_result; if (!info_data || g_strcmp0 (kind, "vlan")) return NULL; if ((err = nla_parse_nested (tb, IFLA_VLAN_MAX, info_data, policy)) < 0) return NULL; if (!tb[IFLA_VLAN_ID]) return NULL; obj = nmp_object_new (NMP_OBJECT_TYPE_LNK_VLAN, NULL); obj->lnk_vlan.id = nla_get_u16 (tb[IFLA_VLAN_ID]); if (tb[IFLA_VLAN_FLAGS]) { struct ifla_vlan_flags flags; nla_memcpy (&flags, tb[IFLA_VLAN_FLAGS], sizeof(flags)); obj->lnk_vlan.flags = flags.flags; } if (!_vlan_qos_mapping_from_nla (tb[IFLA_VLAN_INGRESS_QOS], &obj->_lnk_vlan.ingress_qos_map, &obj->_lnk_vlan.n_ingress_qos_map)) return NULL; if (!_vlan_qos_mapping_from_nla (tb[IFLA_VLAN_EGRESS_QOS], &obj->_lnk_vlan.egress_qos_map, &obj->_lnk_vlan.n_egress_qos_map)) return NULL; obj_result = obj; obj = NULL; return obj_result; } /*****************************************************************************/ /* The installed kernel headers might not have VXLAN stuff at all, or * they might have the original properties, but not PORT, GROUP6, or LOCAL6. * So until we depend on kernel >= 3.11, we just ignore the actual enum * in if_link.h and define the values ourselves. */ #define IFLA_VXLAN_UNSPEC 0 #define IFLA_VXLAN_ID 1 #define IFLA_VXLAN_GROUP 2 #define IFLA_VXLAN_LINK 3 #define IFLA_VXLAN_LOCAL 4 #define IFLA_VXLAN_TTL 5 #define IFLA_VXLAN_TOS 6 #define IFLA_VXLAN_LEARNING 7 #define IFLA_VXLAN_AGEING 8 #define IFLA_VXLAN_LIMIT 9 #define IFLA_VXLAN_PORT_RANGE 10 #define IFLA_VXLAN_PROXY 11 #define IFLA_VXLAN_RSC 12 #define IFLA_VXLAN_L2MISS 13 #define IFLA_VXLAN_L3MISS 14 #define IFLA_VXLAN_PORT 15 #define IFLA_VXLAN_GROUP6 16 #define IFLA_VXLAN_LOCAL6 17 #undef IFLA_VXLAN_MAX #define IFLA_VXLAN_MAX IFLA_VXLAN_LOCAL6 /* older kernel header might not contain 'struct ifla_vxlan_port_range'. * Redefine it. */ struct nm_ifla_vxlan_port_range { guint16 low; guint16 high; }; static NMPObject * _parse_lnk_vxlan (const char *kind, struct nlattr *info_data) { static const struct nla_policy policy[IFLA_VXLAN_MAX + 1] = { [IFLA_VXLAN_ID] = { .type = NLA_U32 }, [IFLA_VXLAN_GROUP] = { .type = NLA_U32 }, [IFLA_VXLAN_GROUP6] = { .type = NLA_UNSPEC, .minlen = sizeof (struct in6_addr) }, [IFLA_VXLAN_LINK] = { .type = NLA_U32 }, [IFLA_VXLAN_LOCAL] = { .type = NLA_U32 }, [IFLA_VXLAN_LOCAL6] = { .type = NLA_UNSPEC, .minlen = sizeof (struct in6_addr) }, [IFLA_VXLAN_TOS] = { .type = NLA_U8 }, [IFLA_VXLAN_TTL] = { .type = NLA_U8 }, [IFLA_VXLAN_LEARNING] = { .type = NLA_U8 }, [IFLA_VXLAN_AGEING] = { .type = NLA_U32 }, [IFLA_VXLAN_LIMIT] = { .type = NLA_U32 }, [IFLA_VXLAN_PORT_RANGE] = { .type = NLA_UNSPEC, .minlen = sizeof (struct nm_ifla_vxlan_port_range) }, [IFLA_VXLAN_PROXY] = { .type = NLA_U8 }, [IFLA_VXLAN_RSC] = { .type = NLA_U8 }, [IFLA_VXLAN_L2MISS] = { .type = NLA_U8 }, [IFLA_VXLAN_L3MISS] = { .type = NLA_U8 }, [IFLA_VXLAN_PORT] = { .type = NLA_U16 }, }; NMPlatformLnkVxlan *props; struct nlattr *tb[IFLA_VXLAN_MAX + 1]; struct nm_ifla_vxlan_port_range *range; int err; NMPObject *obj; if (!info_data || g_strcmp0 (kind, "vxlan")) return NULL; err = nla_parse_nested (tb, IFLA_VXLAN_MAX, info_data, policy); if (err < 0) return NULL; obj = nmp_object_new (NMP_OBJECT_TYPE_LNK_VXLAN, NULL); props = &obj->lnk_vxlan; if (tb[IFLA_VXLAN_LINK]) props->parent_ifindex = nla_get_u32 (tb[IFLA_VXLAN_LINK]); if (tb[IFLA_VXLAN_ID]) props->id = nla_get_u32 (tb[IFLA_VXLAN_ID]); if (tb[IFLA_VXLAN_GROUP]) props->group = nla_get_u32 (tb[IFLA_VXLAN_GROUP]); if (tb[IFLA_VXLAN_LOCAL]) props->local = nla_get_u32 (tb[IFLA_VXLAN_LOCAL]); if (tb[IFLA_VXLAN_GROUP6]) memcpy (&props->group6, nla_data (tb[IFLA_VXLAN_GROUP6]), sizeof (props->group6)); if (tb[IFLA_VXLAN_LOCAL6]) memcpy (&props->local6, nla_data (tb[IFLA_VXLAN_LOCAL6]), sizeof (props->local6)); if (tb[IFLA_VXLAN_AGEING]) props->ageing = nla_get_u32 (tb[IFLA_VXLAN_AGEING]); if (tb[IFLA_VXLAN_LIMIT]) props->limit = nla_get_u32 (tb[IFLA_VXLAN_LIMIT]); if (tb[IFLA_VXLAN_TOS]) props->tos = nla_get_u8 (tb[IFLA_VXLAN_TOS]); if (tb[IFLA_VXLAN_TTL]) props->ttl = nla_get_u8 (tb[IFLA_VXLAN_TTL]); if (tb[IFLA_VXLAN_PORT]) props->dst_port = ntohs (nla_get_u16 (tb[IFLA_VXLAN_PORT])); if (tb[IFLA_VXLAN_PORT_RANGE]) { range = nla_data (tb[IFLA_VXLAN_PORT_RANGE]); props->src_port_min = ntohs (range->low); props->src_port_max = ntohs (range->high); } if (tb[IFLA_VXLAN_LEARNING]) props->learning = !!nla_get_u8 (tb[IFLA_VXLAN_LEARNING]); if (tb[IFLA_VXLAN_PROXY]) props->proxy = !!nla_get_u8 (tb[IFLA_VXLAN_PROXY]); if (tb[IFLA_VXLAN_RSC]) props->rsc = !!nla_get_u8 (tb[IFLA_VXLAN_RSC]); if (tb[IFLA_VXLAN_L2MISS]) props->l2miss = !!nla_get_u8 (tb[IFLA_VXLAN_L2MISS]); if (tb[IFLA_VXLAN_L3MISS]) props->l3miss = !!nla_get_u8 (tb[IFLA_VXLAN_L3MISS]); return obj; } /*****************************************************************************/ /* Copied and heavily modified from libnl3's link_msg_parser(). */ static NMPObject * _new_from_nl_link (NMPlatform *platform, const NMPCache *cache, struct nlmsghdr *nlh, gboolean id_only) { static const struct nla_policy policy[IFLA_MAX+1] = { [IFLA_IFNAME] = { .type = NLA_STRING, .maxlen = IFNAMSIZ }, [IFLA_MTU] = { .type = NLA_U32 }, [IFLA_TXQLEN] = { .type = NLA_U32 }, [IFLA_LINK] = { .type = NLA_U32 }, [IFLA_WEIGHT] = { .type = NLA_U32 }, [IFLA_MASTER] = { .type = NLA_U32 }, [IFLA_OPERSTATE] = { .type = NLA_U8 }, [IFLA_LINKMODE] = { .type = NLA_U8 }, [IFLA_LINKINFO] = { .type = NLA_NESTED }, [IFLA_QDISC] = { .type = NLA_STRING, .maxlen = IFQDISCSIZ }, [IFLA_STATS] = { .minlen = nm_offsetofend (struct rtnl_link_stats, tx_compressed) }, [IFLA_STATS64] = { .minlen = nm_offsetofend (struct rtnl_link_stats64, tx_compressed)}, [IFLA_MAP] = { .minlen = nm_offsetofend (struct rtnl_link_ifmap, port) }, [IFLA_IFALIAS] = { .type = NLA_STRING, .maxlen = IFALIASZ }, [IFLA_NUM_VF] = { .type = NLA_U32 }, [IFLA_AF_SPEC] = { .type = NLA_NESTED }, [IFLA_PROMISCUITY] = { .type = NLA_U32 }, [IFLA_NUM_TX_QUEUES] = { .type = NLA_U32 }, [IFLA_NUM_RX_QUEUES] = { .type = NLA_U32 }, [IFLA_GROUP] = { .type = NLA_U32 }, [IFLA_CARRIER] = { .type = NLA_U8 }, [IFLA_PHYS_PORT_ID] = { .type = NLA_UNSPEC }, [IFLA_NET_NS_PID] = { .type = NLA_U32 }, [IFLA_NET_NS_FD] = { .type = NLA_U32 }, }; static const struct nla_policy policy_link_info[IFLA_INFO_MAX+1] = { [IFLA_INFO_KIND] = { .type = NLA_STRING }, [IFLA_INFO_DATA] = { .type = NLA_NESTED }, [IFLA_INFO_XSTATS] = { .type = NLA_NESTED }, }; const struct ifinfomsg *ifi; struct nlattr *tb[IFLA_MAX+1]; struct nlattr *li[IFLA_INFO_MAX+1]; struct nlattr *nl_info_data = NULL; const char *nl_info_kind = NULL; int err; nm_auto_nmpobj NMPObject *obj = NULL; NMPObject *obj_result = NULL; gboolean completed_from_cache_val = FALSE; gboolean *completed_from_cache = cache ? &completed_from_cache_val : NULL; const NMPObject *link_cached = NULL; NMPObject *lnk_data = NULL; gboolean address_complete_from_cache = TRUE; gboolean lnk_data_complete_from_cache = TRUE; gboolean af_inet6_token_valid = FALSE; gboolean af_inet6_addr_gen_mode_valid = FALSE; if (!nlmsg_valid_hdr (nlh, sizeof (*ifi))) return NULL; ifi = nlmsg_data(nlh); if (ifi->ifi_family != AF_UNSPEC) return NULL; obj = nmp_object_new_link (ifi->ifi_index); if (id_only) goto id_only_handled; err = nlmsg_parse (nlh, sizeof (*ifi), tb, IFLA_MAX, policy); if (err < 0) goto errout; if (!tb[IFLA_IFNAME]) goto errout; nla_strlcpy(obj->link.name, tb[IFLA_IFNAME], IFNAMSIZ); if (!obj->link.name[0]) goto errout; if (!tb[IFLA_MTU]) { /* Kernel has two places that send RTM_GETLINK messages: * net/core/rtnetlink.c and net/wireless/ext-core.c. * Unfotunatelly ext-core.c sets only IFLA_WIRELESS and * IFLA_IFNAME. This confuses code in this function, because * it cannot get complete set of data for the interface and * later incomplete object this function creates is used to * overwrite existing data in NM's cache. * Since ext-core.c doesn't set IFLA_MTU we can use it as a * signal to ignore incoming message. * To some extent this is a hack and correct approach is to * merge objects per-field. */ goto errout; } obj->link.mtu = nla_get_u32 (tb[IFLA_MTU]); if (tb[IFLA_LINKINFO]) { err = nla_parse_nested (li, IFLA_INFO_MAX, tb[IFLA_LINKINFO], policy_link_info); if (err < 0) goto errout; if (li[IFLA_INFO_KIND]) nl_info_kind = nla_get_string (li[IFLA_INFO_KIND]); nl_info_data = li[IFLA_INFO_DATA]; } if (tb[IFLA_STATS64]) { /* tb[IFLA_STATS64] is only guaranteed to be 32bit-aligned, * so in general we can't access the rtnl_link_stats64 struct * members directly on 64bit architectures. */ char *stats = nla_data (tb[IFLA_STATS64]); #define READ_STAT64(member) \ unaligned_read_ne64 (stats + offsetof (struct rtnl_link_stats64, member)) obj->link.rx_packets = READ_STAT64 (rx_packets); obj->link.rx_bytes = READ_STAT64 (rx_bytes); obj->link.tx_packets = READ_STAT64 (tx_packets); obj->link.tx_bytes = READ_STAT64 (tx_bytes); } obj->link.n_ifi_flags = ifi->ifi_flags; obj->link.connected = NM_FLAGS_HAS (obj->link.n_ifi_flags, IFF_LOWER_UP); obj->link.arptype = ifi->ifi_type; obj->link.type = _linktype_get_type (platform, cache, nl_info_kind, obj->link.ifindex, obj->link.name, obj->link.n_ifi_flags, obj->link.arptype, completed_from_cache, &link_cached, &obj->link.kind); if (tb[IFLA_MASTER]) obj->link.master = nla_get_u32 (tb[IFLA_MASTER]); if (tb[IFLA_LINK]) { if (!tb[IFLA_LINK_NETNSID]) obj->link.parent = nla_get_u32 (tb[IFLA_LINK]); else obj->link.parent = NM_PLATFORM_LINK_OTHER_NETNS; } if (tb[IFLA_ADDRESS]) { int l = nla_len (tb[IFLA_ADDRESS]); if (l > 0 && l <= NM_UTILS_HWADDR_LEN_MAX) { G_STATIC_ASSERT (NM_UTILS_HWADDR_LEN_MAX == sizeof (obj->link.addr.data)); memcpy (obj->link.addr.data, nla_data (tb[IFLA_ADDRESS]), l); obj->link.addr.len = l; } address_complete_from_cache = FALSE; } if (tb[IFLA_AF_SPEC]) { struct nlattr *af_attr; int remaining; nla_for_each_nested (af_attr, tb[IFLA_AF_SPEC], remaining) { switch (nla_type (af_attr)) { case AF_INET6: _parse_af_inet6 (platform, af_attr, &obj->link.inet6_token, &af_inet6_token_valid, &obj->link.inet6_addr_gen_mode_inv, &af_inet6_addr_gen_mode_valid); break; } } } switch (obj->link.type) { case NM_LINK_TYPE_GRE: lnk_data = _parse_lnk_gre (nl_info_kind, nl_info_data); break; case NM_LINK_TYPE_INFINIBAND: lnk_data = _parse_lnk_infiniband (nl_info_kind, nl_info_data); break; case NM_LINK_TYPE_IP6TNL: lnk_data = _parse_lnk_ip6tnl (nl_info_kind, nl_info_data); break; case NM_LINK_TYPE_IPIP: lnk_data = _parse_lnk_ipip (nl_info_kind, nl_info_data); break; case NM_LINK_TYPE_MACSEC: lnk_data = _parse_lnk_macsec (nl_info_kind, nl_info_data); break; case NM_LINK_TYPE_MACVLAN: case NM_LINK_TYPE_MACVTAP: lnk_data = _parse_lnk_macvlan (nl_info_kind, nl_info_data); break; case NM_LINK_TYPE_SIT: lnk_data = _parse_lnk_sit (nl_info_kind, nl_info_data); break; case NM_LINK_TYPE_VLAN: lnk_data = _parse_lnk_vlan (nl_info_kind, nl_info_data); break; case NM_LINK_TYPE_VXLAN: lnk_data = _parse_lnk_vxlan (nl_info_kind, nl_info_data); break; default: lnk_data_complete_from_cache = FALSE; break; } if ( completed_from_cache && ( lnk_data_complete_from_cache || address_complete_from_cache || !af_inet6_token_valid || !af_inet6_addr_gen_mode_valid || !tb[IFLA_STATS64])) { _lookup_cached_link (cache, obj->link.ifindex, completed_from_cache, &link_cached); if (link_cached) { if ( lnk_data_complete_from_cache && link_cached->link.type == obj->link.type && link_cached->_link.netlink.lnk && ( !lnk_data || nmp_object_equal (lnk_data, link_cached->_link.netlink.lnk))) { /* We always try to look into the cache and reuse the object there. * We do that, because we consider the lnk object as immutable and don't * modify it after creating. Hence we can share it and reuse. * * Also, sometimes the info-data is missing for updates. In this case * we want to keep the previously received lnk_data. */ nmp_object_unref (lnk_data); lnk_data = (NMPObject *) nmp_object_ref (link_cached->_link.netlink.lnk); } if (address_complete_from_cache) obj->link.addr = link_cached->link.addr; if (!af_inet6_token_valid) obj->link.inet6_token = link_cached->link.inet6_token; if (!af_inet6_addr_gen_mode_valid) obj->link.inet6_addr_gen_mode_inv = link_cached->link.inet6_addr_gen_mode_inv; if (!tb[IFLA_STATS64]) { obj->link.rx_packets = link_cached->link.rx_packets; obj->link.rx_bytes = link_cached->link.rx_bytes; obj->link.tx_packets = link_cached->link.tx_packets; obj->link.tx_bytes = link_cached->link.tx_bytes; } } } obj->_link.netlink.lnk = lnk_data; obj->_link.netlink.is_in_netlink = TRUE; id_only_handled: obj_result = obj; obj = NULL; errout: return obj_result; } /* Copied and heavily modified from libnl3's addr_msg_parser(). */ static NMPObject * _new_from_nl_addr (struct nlmsghdr *nlh, gboolean id_only) { static const struct nla_policy policy[IFA_MAX+1] = { [IFA_LABEL] = { .type = NLA_STRING, .maxlen = IFNAMSIZ }, [IFA_CACHEINFO] = { .minlen = nm_offsetofend (struct ifa_cacheinfo, tstamp) }, }; const struct ifaddrmsg *ifa; struct nlattr *tb[IFA_MAX+1]; int err; gboolean is_v4; nm_auto_nmpobj NMPObject *obj = NULL; NMPObject *obj_result = NULL; int addr_len; guint32 lifetime, preferred, timestamp; if (!nlmsg_valid_hdr (nlh, sizeof (*ifa))) return NULL; ifa = nlmsg_data(nlh); if (!NM_IN_SET (ifa->ifa_family, AF_INET, AF_INET6)) goto errout; is_v4 = ifa->ifa_family == AF_INET; err = nlmsg_parse (nlh, sizeof(*ifa), tb, IFA_MAX, policy); if (err < 0) goto errout; addr_len = is_v4 ? sizeof (in_addr_t) : sizeof (struct in6_addr); if (ifa->ifa_prefixlen > (is_v4 ? 32 : 128)) goto errout; /*****************************************************************/ obj = nmp_object_new (is_v4 ? NMP_OBJECT_TYPE_IP4_ADDRESS : NMP_OBJECT_TYPE_IP6_ADDRESS, NULL); obj->ip_address.ifindex = ifa->ifa_index; obj->ip_address.plen = ifa->ifa_prefixlen; _check_addr_or_errout (tb, IFA_ADDRESS, addr_len); _check_addr_or_errout (tb, IFA_LOCAL, addr_len); if (is_v4) { /* For IPv4, kernel omits IFA_LOCAL/IFA_ADDRESS if (and only if) they * are effectively 0.0.0.0 (all-zero). */ if (tb[IFA_LOCAL]) memcpy (&obj->ip4_address.address, nla_data (tb[IFA_LOCAL]), addr_len); if (tb[IFA_ADDRESS]) memcpy (&obj->ip4_address.peer_address, nla_data (tb[IFA_ADDRESS]), addr_len); } else { /* For IPv6, IFA_ADDRESS is always present. * * If IFA_LOCAL is missing, IFA_ADDRESS is @address and @peer_address * is :: (all-zero). * * If unexpectely IFA_ADDRESS is missing, make the best of it -- but it _should_ * actually be there. */ if (tb[IFA_ADDRESS] || tb[IFA_LOCAL]) { if (tb[IFA_LOCAL]) { memcpy (&obj->ip6_address.address, nla_data (tb[IFA_LOCAL]), addr_len); if (tb[IFA_ADDRESS]) memcpy (&obj->ip6_address.peer_address, nla_data (tb[IFA_ADDRESS]), addr_len); else obj->ip6_address.peer_address = obj->ip6_address.address; } else memcpy (&obj->ip6_address.address, nla_data (tb[IFA_ADDRESS]), addr_len); } } obj->ip_address.addr_source = NM_IP_CONFIG_SOURCE_KERNEL; obj->ip_address.n_ifa_flags = tb[IFA_FLAGS] ? nla_get_u32 (tb[IFA_FLAGS]) : ifa->ifa_flags; if (is_v4) { if (tb[IFA_LABEL]) { char label[IFNAMSIZ]; nla_strlcpy (label, tb[IFA_LABEL], IFNAMSIZ); /* Check for ':'; we're only interested in labels used as interface aliases */ if (strchr (label, ':')) g_strlcpy (obj->ip4_address.label, label, sizeof (obj->ip4_address.label)); } } lifetime = NM_PLATFORM_LIFETIME_PERMANENT; preferred = NM_PLATFORM_LIFETIME_PERMANENT; timestamp = 0; /* IPv6 only */ if (tb[IFA_CACHEINFO]) { const struct ifa_cacheinfo *ca = nla_data(tb[IFA_CACHEINFO]); lifetime = ca->ifa_valid; preferred = ca->ifa_prefered; timestamp = ca->tstamp; } _addrtime_get_lifetimes (timestamp, lifetime, preferred, &obj->ip_address.timestamp, &obj->ip_address.lifetime, &obj->ip_address.preferred); obj_result = obj; obj = NULL; errout: return obj_result; } /* Copied and heavily modified from libnl3's rtnl_route_parse() and parse_multipath(). */ static NMPObject * _new_from_nl_route (struct nlmsghdr *nlh, gboolean id_only) { static const struct nla_policy policy[RTA_MAX+1] = { [RTA_TABLE] = { .type = NLA_U32 }, [RTA_IIF] = { .type = NLA_U32 }, [RTA_OIF] = { .type = NLA_U32 }, [RTA_PRIORITY] = { .type = NLA_U32 }, [RTA_PREF] = { .type = NLA_U8 }, [RTA_FLOW] = { .type = NLA_U32 }, [RTA_CACHEINFO] = { .minlen = nm_offsetofend (struct rta_cacheinfo, rta_tsage) }, [RTA_METRICS] = { .type = NLA_NESTED }, [RTA_MULTIPATH] = { .type = NLA_NESTED }, }; const struct rtmsg *rtm; struct nlattr *tb[RTA_MAX + 1]; int err; gboolean is_v4; nm_auto_nmpobj NMPObject *obj = NULL; NMPObject *obj_result = NULL; int addr_len; struct { gboolean is_present; int ifindex; NMIPAddr gateway; } nh; guint32 mss; guint32 window = 0, cwnd = 0, initcwnd = 0, initrwnd = 0, mtu = 0, lock = 0; if (!nlmsg_valid_hdr (nlh, sizeof (*rtm))) return NULL; rtm = nlmsg_data(nlh); /***************************************************************** * only handle ~normal~ routes. *****************************************************************/ if (!NM_IN_SET (rtm->rtm_family, AF_INET, AF_INET6)) goto errout; if (rtm->rtm_type != RTN_UNICAST) goto errout; err = nlmsg_parse (nlh, sizeof (struct rtmsg), tb, RTA_MAX, policy); if (err < 0) goto errout; /*****************************************************************/ is_v4 = rtm->rtm_family == AF_INET; addr_len = is_v4 ? sizeof (in_addr_t) : sizeof (struct in6_addr); if (rtm->rtm_dst_len > (is_v4 ? 32 : 128)) goto errout; /***************************************************************** * parse nexthops. Only handle routes with one nh. *****************************************************************/ memset (&nh, 0, sizeof (nh)); if (tb[RTA_MULTIPATH]) { struct rtnexthop *rtnh = nla_data (tb[RTA_MULTIPATH]); size_t tlen = nla_len(tb[RTA_MULTIPATH]); while (tlen >= sizeof(*rtnh) && tlen >= rtnh->rtnh_len) { if (nh.is_present) { /* we don't support multipath routes. */ goto errout; } nh.is_present = TRUE; nh.ifindex = rtnh->rtnh_ifindex; if (rtnh->rtnh_len > sizeof(*rtnh)) { struct nlattr *ntb[RTA_MAX + 1]; err = nla_parse (ntb, RTA_MAX, (struct nlattr *) RTNH_DATA(rtnh), rtnh->rtnh_len - sizeof (*rtnh), policy); if (err < 0) goto errout; if (_check_addr_or_errout (ntb, RTA_GATEWAY, addr_len)) memcpy (&nh.gateway, nla_data (ntb[RTA_GATEWAY]), addr_len); } tlen -= RTNH_ALIGN(rtnh->rtnh_len); rtnh = RTNH_NEXT(rtnh); } } if ( tb[RTA_OIF] || tb[RTA_GATEWAY] || tb[RTA_FLOW]) { int ifindex = 0; NMIPAddr gateway = { }; if (tb[RTA_OIF]) ifindex = nla_get_u32 (tb[RTA_OIF]); if (_check_addr_or_errout (tb, RTA_GATEWAY, addr_len)) memcpy (&gateway, nla_data (tb[RTA_GATEWAY]), addr_len); if (!nh.is_present) { /* If no nexthops have been provided via RTA_MULTIPATH * we add it as regular nexthop to maintain backwards * compatibility */ nh.ifindex = ifindex; nh.gateway = gateway; } else { /* Kernel supports new style nexthop configuration, * verify that it is a duplicate and ignore old-style nexthop. */ if ( nh.ifindex != ifindex || memcmp (&nh.gateway, &gateway, addr_len) != 0) goto errout; } } else if (!nh.is_present) goto errout; /*****************************************************************/ mss = 0; if (tb[RTA_METRICS]) { struct nlattr *mtb[RTAX_MAX + 1]; static const struct nla_policy rtax_policy[RTAX_MAX + 1] = { [RTAX_LOCK] = { .type = NLA_U32 }, [RTAX_ADVMSS] = { .type = NLA_U32 }, [RTAX_WINDOW] = { .type = NLA_U32 }, [RTAX_CWND] = { .type = NLA_U32 }, [RTAX_INITCWND] = { .type = NLA_U32 }, [RTAX_INITRWND] = { .type = NLA_U32 }, [RTAX_MTU] = { .type = NLA_U32 }, }; err = nla_parse_nested (mtb, RTAX_MAX, tb[RTA_METRICS], rtax_policy); if (err < 0) goto errout; if (mtb[RTAX_LOCK]) lock = nla_get_u32 (mtb[RTAX_LOCK]); if (mtb[RTAX_ADVMSS]) mss = nla_get_u32 (mtb[RTAX_ADVMSS]); if (mtb[RTAX_WINDOW]) window = nla_get_u32 (mtb[RTAX_WINDOW]); if (mtb[RTAX_CWND]) cwnd = nla_get_u32 (mtb[RTAX_CWND]); if (mtb[RTAX_INITCWND]) initcwnd = nla_get_u32 (mtb[RTAX_INITCWND]); if (mtb[RTAX_INITRWND]) initrwnd = nla_get_u32 (mtb[RTAX_INITRWND]); if (mtb[RTAX_MTU]) mtu = nla_get_u32 (mtb[RTAX_MTU]); } /*****************************************************************/ obj = nmp_object_new (is_v4 ? NMP_OBJECT_TYPE_IP4_ROUTE : NMP_OBJECT_TYPE_IP6_ROUTE, NULL); obj->ip_route.table_coerced = nm_platform_route_table_coerce ( tb[RTA_TABLE] ? nla_get_u32 (tb[RTA_TABLE]) : (guint32) rtm->rtm_table); obj->ip_route.ifindex = nh.ifindex; if (_check_addr_or_errout (tb, RTA_DST, addr_len)) memcpy (obj->ip_route.network_ptr, nla_data (tb[RTA_DST]), addr_len); obj->ip_route.plen = rtm->rtm_dst_len; if (tb[RTA_PRIORITY]) obj->ip_route.metric = nla_get_u32(tb[RTA_PRIORITY]); if (is_v4) obj->ip4_route.gateway = nh.gateway.addr4; else obj->ip6_route.gateway = nh.gateway.addr6; if (is_v4) obj->ip4_route.scope_inv = nm_platform_route_scope_inv (rtm->rtm_scope); if (_check_addr_or_errout (tb, RTA_PREFSRC, addr_len)) { if (is_v4) memcpy (&obj->ip4_route.pref_src, nla_data (tb[RTA_PREFSRC]), addr_len); else memcpy (&obj->ip6_route.pref_src, nla_data (tb[RTA_PREFSRC]), addr_len); } if (is_v4) obj->ip4_route.tos = rtm->rtm_tos; else { if (tb[RTA_SRC]) { _check_addr_or_errout (tb, RTA_SRC, addr_len); memcpy (&obj->ip6_route.src, nla_data (tb[RTA_SRC]), addr_len); } obj->ip6_route.src_plen = rtm->rtm_src_len; } obj->ip_route.mss = mss; obj->ip_route.window = window; obj->ip_route.cwnd = cwnd; obj->ip_route.initcwnd = initcwnd; obj->ip_route.initrwnd = initrwnd; obj->ip_route.mtu = mtu; obj->ip_route.lock_window = NM_FLAGS_HAS (lock, 1 << RTAX_WINDOW); obj->ip_route.lock_cwnd = NM_FLAGS_HAS (lock, 1 << RTAX_CWND); obj->ip_route.lock_initcwnd = NM_FLAGS_HAS (lock, 1 << RTAX_INITCWND); obj->ip_route.lock_initrwnd = NM_FLAGS_HAS (lock, 1 << RTAX_INITRWND); obj->ip_route.lock_mtu = NM_FLAGS_HAS (lock, 1 << RTAX_MTU); if (!is_v4) { /* Detect support for RTA_PREF by inspecting the netlink message. */ if (_support_rta_pref_still_undecided ()) _support_rta_pref_detect (tb); if (tb[RTA_PREF]) obj->ip6_route.rt_pref = nla_get_u8 (tb[RTA_PREF]); } if (NM_FLAGS_HAS (rtm->rtm_flags, RTM_F_CLONED)) { /* we must not straight way reject cloned routes, because we might have cached * a non-cloned route. If we now receive an update of the route with the route * being cloned, we must still return the object, so that we can remove the old * one from the cache. * * This happens, because this route is not nmp_object_is_alive(). * */ obj->ip_route.rt_cloned = TRUE; } obj->ip_route.rt_source = nmp_utils_ip_config_source_from_rtprot (rtm->rtm_protocol); obj_result = obj; obj = NULL; errout: return obj_result; } /** * nmp_object_new_from_nl: * @platform: (allow-none): for creating certain objects, the constructor wants to check * sysfs. For this the platform instance is needed. If missing, the object might not * be correctly detected. * @cache: (allow-none): for certain objects, the netlink message doesn't contain all the information. * If a cache is given, the object is completed with information from the cache. * @nlh: the netlink message header * @id_only: whether only to create an empty object with only the ID fields set. * * Returns: %NULL or a newly created NMPObject instance. **/ static NMPObject * nmp_object_new_from_nl (NMPlatform *platform, const NMPCache *cache, struct nl_msg *msg, gboolean id_only) { struct nlmsghdr *msghdr; if (nlmsg_get_proto (msg) != NETLINK_ROUTE) return NULL; msghdr = nlmsg_hdr (msg); switch (msghdr->nlmsg_type) { case RTM_NEWLINK: case RTM_DELLINK: case RTM_GETLINK: case RTM_SETLINK: return _new_from_nl_link (platform, cache, msghdr, id_only); case RTM_NEWADDR: case RTM_DELADDR: case RTM_GETADDR: return _new_from_nl_addr (msghdr, id_only); case RTM_NEWROUTE: case RTM_DELROUTE: case RTM_GETROUTE: return _new_from_nl_route (msghdr, id_only); default: return NULL; } } /*****************************************************************************/ static gboolean _nl_msg_new_link_set_afspec (struct nl_msg *msg, int addr_gen_mode, NMUtilsIPv6IfaceId *iid) { struct nlattr *af_spec; struct nlattr *af_attr; nm_assert (msg); if (!(af_spec = nla_nest_start (msg, IFLA_AF_SPEC))) goto nla_put_failure; if (addr_gen_mode >= 0 || iid) { if (!(af_attr = nla_nest_start (msg, AF_INET6))) goto nla_put_failure; if (addr_gen_mode >= 0) NLA_PUT_U8 (msg, IFLA_INET6_ADDR_GEN_MODE, addr_gen_mode); if (iid) { struct in6_addr i6_token = { .s6_addr = { 0, } }; nm_utils_ipv6_addr_set_interface_identifier (&i6_token, *iid); NLA_PUT (msg, IFLA_INET6_TOKEN, sizeof (struct in6_addr), &i6_token); } nla_nest_end (msg, af_attr); } nla_nest_end (msg, af_spec); return TRUE; nla_put_failure: return FALSE; } static gboolean _nl_msg_new_link_set_linkinfo (struct nl_msg *msg, NMLinkType link_type, const char *veth_peer) { struct nlattr *info; const char *kind; nm_assert (msg); nm_assert (!!veth_peer == (link_type == NM_LINK_TYPE_VETH)); kind = nm_link_type_to_rtnl_type_string (link_type); if (!kind) goto nla_put_failure; if (!(info = nla_nest_start (msg, IFLA_LINKINFO))) goto nla_put_failure; NLA_PUT_STRING (msg, IFLA_INFO_KIND, kind); if (veth_peer) { struct ifinfomsg ifi = { }; struct nlattr *data, *info_peer; if (!(data = nla_nest_start (msg, IFLA_INFO_DATA))) goto nla_put_failure; if (!(info_peer = nla_nest_start (msg, 1 /*VETH_INFO_PEER*/))) goto nla_put_failure; if (nlmsg_append (msg, &ifi, sizeof (ifi), NLMSG_ALIGNTO) < 0) goto nla_put_failure; NLA_PUT_STRING (msg, IFLA_IFNAME, veth_peer); nla_nest_end (msg, info_peer); nla_nest_end (msg, data); } nla_nest_end (msg, info); return TRUE; nla_put_failure: g_return_val_if_reached (FALSE); } static gboolean _nl_msg_new_link_set_linkinfo_vlan (struct nl_msg *msg, int vlan_id, guint32 flags_mask, guint32 flags_set, const NMVlanQosMapping *ingress_qos, int ingress_qos_len, const NMVlanQosMapping *egress_qos, int egress_qos_len) { struct nlattr *info; struct nlattr *data; guint i; gboolean has_any_vlan_properties = FALSE; #define VLAN_XGRESS_PRIO_VALID(from) (((from) & ~(guint32) 0x07) == 0) nm_assert (msg); /* We must not create an empty IFLA_LINKINFO section. Otherwise, kernel * rejects the request as invalid. */ if ( flags_mask != 0 || vlan_id >= 0) has_any_vlan_properties = TRUE; if ( !has_any_vlan_properties && ingress_qos && ingress_qos_len > 0) { for (i = 0; i < ingress_qos_len; i++) { if (VLAN_XGRESS_PRIO_VALID (ingress_qos[i].from)) { has_any_vlan_properties = TRUE; break; } } } if ( !has_any_vlan_properties && egress_qos && egress_qos_len > 0) { for (i = 0; i < egress_qos_len; i++) { if (VLAN_XGRESS_PRIO_VALID (egress_qos[i].to)) { has_any_vlan_properties = TRUE; break; } } } if (!has_any_vlan_properties) return TRUE; if (!(info = nla_nest_start (msg, IFLA_LINKINFO))) goto nla_put_failure; NLA_PUT_STRING (msg, IFLA_INFO_KIND, "vlan"); if (!(data = nla_nest_start (msg, IFLA_INFO_DATA))) goto nla_put_failure; if (vlan_id >= 0) NLA_PUT_U16 (msg, IFLA_VLAN_ID, vlan_id); if (flags_mask != 0) { struct ifla_vlan_flags flags = { .flags = flags_mask & flags_set, .mask = flags_mask, }; NLA_PUT (msg, IFLA_VLAN_FLAGS, sizeof (flags), &flags); } if (ingress_qos && ingress_qos_len > 0) { struct nlattr *qos = NULL; for (i = 0; i < ingress_qos_len; i++) { /* Silently ignore invalid mappings. Kernel would truncate * them and modify the wrong mapping. */ if (VLAN_XGRESS_PRIO_VALID (ingress_qos[i].from)) { if (!qos) { if (!(qos = nla_nest_start (msg, IFLA_VLAN_INGRESS_QOS))) goto nla_put_failure; } NLA_PUT (msg, i, sizeof (ingress_qos[i]), &ingress_qos[i]); } } if (qos) nla_nest_end (msg, qos); } if (egress_qos && egress_qos_len > 0) { struct nlattr *qos = NULL; for (i = 0; i < egress_qos_len; i++) { if (VLAN_XGRESS_PRIO_VALID (egress_qos[i].to)) { if (!qos) { if (!(qos = nla_nest_start(msg, IFLA_VLAN_EGRESS_QOS))) goto nla_put_failure; } NLA_PUT (msg, i, sizeof (egress_qos[i]), &egress_qos[i]); } } if (qos) nla_nest_end(msg, qos); } nla_nest_end (msg, data); nla_nest_end (msg, info); return TRUE; nla_put_failure: return FALSE; } static struct nl_msg * _nl_msg_new_link (int nlmsg_type, int nlmsg_flags, int ifindex, const char *ifname, unsigned flags_mask, unsigned flags_set) { struct nl_msg *msg; struct ifinfomsg ifi = { .ifi_change = flags_mask, .ifi_flags = flags_set, .ifi_index = ifindex, }; nm_assert (NM_IN_SET (nlmsg_type, RTM_DELLINK, RTM_NEWLINK, RTM_GETLINK)); if (!(msg = nlmsg_alloc_simple (nlmsg_type, nlmsg_flags))) g_return_val_if_reached (NULL); if (nlmsg_append (msg, &ifi, sizeof (ifi), NLMSG_ALIGNTO) < 0) goto nla_put_failure; if (ifname) NLA_PUT_STRING (msg, IFLA_IFNAME, ifname); return msg; nla_put_failure: nlmsg_free (msg); g_return_val_if_reached (NULL); } /* Copied and modified from libnl3's build_addr_msg(). */ static struct nl_msg * _nl_msg_new_address (int nlmsg_type, int nlmsg_flags, int family, int ifindex, gconstpointer address, guint8 plen, gconstpointer peer_address, guint32 flags, int scope, guint32 lifetime, guint32 preferred, const char *label) { struct nl_msg *msg; struct ifaddrmsg am = { .ifa_family = family, .ifa_index = ifindex, .ifa_prefixlen = plen, .ifa_flags = flags, }; gsize addr_len; nm_assert (NM_IN_SET (family, AF_INET, AF_INET6)); nm_assert (NM_IN_SET (nlmsg_type, RTM_NEWADDR, RTM_DELADDR)); msg = nlmsg_alloc_simple (nlmsg_type, nlmsg_flags); if (!msg) g_return_val_if_reached (NULL); if (scope == -1) { /* Allow having scope unset, and detect the scope (including IPv4 compatibility hack). */ if ( family == AF_INET && address && *((char *) address) == 127) scope = RT_SCOPE_HOST; else scope = RT_SCOPE_UNIVERSE; } am.ifa_scope = scope, addr_len = family == AF_INET ? sizeof (in_addr_t) : sizeof (struct in6_addr); if (nlmsg_append (msg, &am, sizeof (am), NLMSG_ALIGNTO) < 0) goto nla_put_failure; if (address) NLA_PUT (msg, IFA_LOCAL, addr_len, address); if (peer_address) NLA_PUT (msg, IFA_ADDRESS, addr_len, peer_address); else if (address) NLA_PUT (msg, IFA_ADDRESS, addr_len, address); if (label && label[0]) NLA_PUT_STRING (msg, IFA_LABEL, label); if ( family == AF_INET && nlmsg_type != RTM_DELADDR && address && *((in_addr_t *) address) != 0) { in_addr_t broadcast; broadcast = *((in_addr_t *) address) | ~_nm_utils_ip4_prefix_to_netmask (plen); NLA_PUT (msg, IFA_BROADCAST, addr_len, &broadcast); } if ( lifetime != NM_PLATFORM_LIFETIME_PERMANENT || preferred != NM_PLATFORM_LIFETIME_PERMANENT) { struct ifa_cacheinfo ca = { .ifa_valid = lifetime, .ifa_prefered = preferred, }; NLA_PUT (msg, IFA_CACHEINFO, sizeof(ca), &ca); } if (flags & ~((guint32) 0xFF)) { /* only set the IFA_FLAGS attribute, if they actually contain additional * flags that are not already set to am.ifa_flags. * * Older kernels refuse RTM_NEWADDR and RTM_NEWROUTE messages with EINVAL * if they contain unknown netlink attributes. See net/core/rtnetlink.c, which * was fixed by kernel commit 661d2967b3f1b34eeaa7e212e7b9bbe8ee072b59. */ NLA_PUT_U32 (msg, IFA_FLAGS, flags); } return msg; nla_put_failure: nlmsg_free (msg); g_return_val_if_reached (NULL); } static guint32 ip_route_get_lock_flag (const NMPlatformIPRoute *route) { return (((guint32) route->lock_window) << RTAX_WINDOW) | (((guint32) route->lock_cwnd) << RTAX_CWND) | (((guint32) route->lock_initcwnd) << RTAX_INITCWND) | (((guint32) route->lock_initrwnd) << RTAX_INITRWND) | (((guint32) route->lock_mtu) << RTAX_MTU); } /* Copied and modified from libnl3's build_route_msg() and rtnl_route_build_msg(). */ static struct nl_msg * _nl_msg_new_route (int nlmsg_type, guint16 nlmsgflags, const NMPObject *obj) { struct nl_msg *msg; const NMPClass *klass = NMP_OBJECT_GET_CLASS (obj); gboolean is_v4 = klass->addr_family == AF_INET; const guint32 lock = ip_route_get_lock_flag (NMP_OBJECT_CAST_IP_ROUTE (obj)); const guint32 table = nm_platform_route_table_uncoerce (NMP_OBJECT_CAST_IP_ROUTE (obj)->table_coerced, TRUE); struct rtmsg rtmsg = { .rtm_family = klass->addr_family, .rtm_tos = is_v4 ? obj->ip4_route.tos : 0, .rtm_table = table <= 0xFF ? table : RT_TABLE_UNSPEC, .rtm_protocol = nmp_utils_ip_config_source_coerce_to_rtprot (obj->ip_route.rt_source), .rtm_scope = is_v4 ? nm_platform_route_scope_inv (obj->ip4_route.scope_inv) : RT_SCOPE_NOWHERE, .rtm_type = RTN_UNICAST, .rtm_flags = 0, .rtm_dst_len = obj->ip_route.plen, .rtm_src_len = is_v4 ? 0 : NMP_OBJECT_CAST_IP6_ROUTE (obj)->src_plen, }; gsize addr_len; nm_assert (NM_IN_SET (NMP_OBJECT_GET_TYPE (obj), NMP_OBJECT_TYPE_IP4_ROUTE, NMP_OBJECT_TYPE_IP6_ROUTE)); nm_assert (NM_IN_SET (nlmsg_type, RTM_NEWROUTE, RTM_DELROUTE)); msg = nlmsg_alloc_simple (nlmsg_type, (int) nlmsgflags); if (!msg) g_return_val_if_reached (NULL); if (nlmsg_append (msg, &rtmsg, sizeof (rtmsg), NLMSG_ALIGNTO) < 0) goto nla_put_failure; addr_len = is_v4 ? sizeof (in_addr_t) : sizeof (struct in6_addr); NLA_PUT (msg, RTA_DST, addr_len, is_v4 ? (gconstpointer) &obj->ip4_route.network : (gconstpointer) &obj->ip6_route.network); if (!is_v4) { if (!IN6_IS_ADDR_UNSPECIFIED (&NMP_OBJECT_CAST_IP6_ROUTE (obj)->src)) NLA_PUT (msg, RTA_SRC, addr_len, &obj->ip6_route.src); } NLA_PUT_U32 (msg, RTA_PRIORITY, obj->ip_route.metric); if (table > 0xFF) NLA_PUT_U32 (msg, RTA_TABLE, table); if (is_v4) { if (NMP_OBJECT_CAST_IP4_ROUTE (obj)->pref_src) NLA_PUT (msg, RTA_PREFSRC, addr_len, &obj->ip4_route.pref_src); } else { if (!IN6_IS_ADDR_UNSPECIFIED (&NMP_OBJECT_CAST_IP6_ROUTE (obj)->pref_src)) NLA_PUT (msg, RTA_PREFSRC, addr_len, &obj->ip6_route.pref_src); } if ( obj->ip_route.mss || obj->ip_route.window || obj->ip_route.cwnd || obj->ip_route.initcwnd || obj->ip_route.initrwnd || obj->ip_route.mtu || lock) { struct nlattr *metrics; metrics = nla_nest_start (msg, RTA_METRICS); if (!metrics) goto nla_put_failure; if (obj->ip_route.mss) NLA_PUT_U32 (msg, RTAX_ADVMSS, obj->ip_route.mss); if (obj->ip_route.window) NLA_PUT_U32 (msg, RTAX_WINDOW, obj->ip_route.window); if (obj->ip_route.cwnd) NLA_PUT_U32 (msg, RTAX_CWND, obj->ip_route.cwnd); if (obj->ip_route.initcwnd) NLA_PUT_U32 (msg, RTAX_INITCWND, obj->ip_route.initcwnd); if (obj->ip_route.initrwnd) NLA_PUT_U32 (msg, RTAX_INITRWND, obj->ip_route.initrwnd); if (obj->ip_route.mtu) NLA_PUT_U32 (msg, RTAX_MTU, obj->ip_route.mtu); if (lock) NLA_PUT_U32 (msg, RTAX_LOCK, lock); nla_nest_end(msg, metrics); } /* We currently don't have need for multi-hop routes... */ if (is_v4) { NLA_PUT (msg, RTA_GATEWAY, addr_len, &obj->ip4_route.gateway); } else { if (!IN6_IS_ADDR_UNSPECIFIED (&obj->ip6_route.gateway)) NLA_PUT (msg, RTA_GATEWAY, addr_len, &obj->ip6_route.gateway); } NLA_PUT_U32 (msg, RTA_OIF, obj->ip_route.ifindex); if ( !is_v4 && obj->ip6_route.rt_pref != NM_ICMPV6_ROUTER_PREF_MEDIUM) NLA_PUT_U8 (msg, RTA_PREF, obj->ip6_route.rt_pref); return msg; nla_put_failure: nlmsg_free (msg); g_return_val_if_reached (NULL); } /****************************************************************** * NMPlatform types and functions ******************************************************************/ typedef enum { DELAYED_ACTION_RESPONSE_TYPE_VOID = 0, DELAYED_ACTION_RESPONSE_TYPE_REFRESH_ALL_IN_PROGRESS = 1, DELAYED_ACTION_RESPONSE_TYPE_ROUTE_GET = 2, } DelayedActionWaitForNlResponseType; typedef struct { guint32 seq_number; WaitForNlResponseResult seq_result; DelayedActionWaitForNlResponseType response_type; gint64 timeout_abs_ns; WaitForNlResponseResult *out_seq_result; union { gint *out_refresh_all_in_progess; NMPObject **out_route_get; gpointer out_data; } response; } DelayedActionWaitForNlResponseData; typedef struct { struct nl_sock *nlh; guint32 nlh_seq_next; #ifdef NM_MORE_LOGGING guint32 nlh_seq_last_handled; #endif guint32 nlh_seq_last_seen; GIOChannel *event_channel; guint event_id; bool pruning[_DELAYED_ACTION_IDX_REFRESH_ALL_NUM]; bool sysctl_get_warned; GHashTable *sysctl_get_prev_values; NMUdevClient *udev_client; struct { /* which delayed actions are scheduled, as marked in @flags. * Some types have additional arguments in the fields below. */ DelayedActionType flags; /* counter that a refresh all action is in progress, separated * by type. */ gint refresh_all_in_progess[_DELAYED_ACTION_IDX_REFRESH_ALL_NUM]; GPtrArray *list_master_connected; GPtrArray *list_refresh_link; GArray *list_wait_for_nl_response; gint is_handling; } delayed_action; GHashTable *wifi_data; } NMLinuxPlatformPrivate; struct _NMLinuxPlatform { NMPlatform parent; NMLinuxPlatformPrivate _priv; }; struct _NMLinuxPlatformClass { NMPlatformClass parent; }; G_DEFINE_TYPE (NMLinuxPlatform, nm_linux_platform, NM_TYPE_PLATFORM) #define NM_LINUX_PLATFORM_GET_PRIVATE(self) _NM_GET_PRIVATE_VOID(self, NMLinuxPlatform, NM_IS_LINUX_PLATFORM) NMPlatform * nm_linux_platform_new (gboolean log_with_ptr, gboolean netns_support) { gboolean use_udev = FALSE; if ( nmp_netns_is_initial () && access ("/sys", W_OK) == 0) use_udev = TRUE; return g_object_new (NM_TYPE_LINUX_PLATFORM, NM_PLATFORM_LOG_WITH_PTR, log_with_ptr, NM_PLATFORM_USE_UDEV, use_udev, NM_PLATFORM_NETNS_SUPPORT, netns_support, NULL); } void nm_linux_platform_setup (void) { nm_platform_setup (nm_linux_platform_new (FALSE, FALSE)); } /*****************************************************************************/ #define ASSERT_SYSCTL_ARGS(pathid, dirfd, path) \ G_STMT_START { \ const char *const _pathid = (pathid); \ const int _dirfd = (dirfd); \ const char *const _path = (path); \ \ nm_assert (_path && _path[0]); \ g_assert (!strstr (_path, "/../")); \ if (_dirfd < 0) { \ nm_assert (!_pathid); \ nm_assert (_path[0] == '/'); \ nm_assert ( g_str_has_prefix (_path, "/proc/sys/") \ || g_str_has_prefix (_path, "/sys/")); \ } else { \ nm_assert (_pathid && _pathid[0] && _pathid[0] != '/'); \ nm_assert (_path[0] != '/'); \ } \ } G_STMT_END static void _log_dbg_sysctl_set_impl (NMPlatform *platform, const char *pathid, int dirfd, const char *path, const char *value) { GError *error = NULL; char *contents; gs_free char *value_escaped = g_strescape (value, NULL); if (nm_utils_file_get_contents (dirfd, path, 1*1024*1024, &contents, NULL, &error) < 0) { _LOGD ("sysctl: setting '%s' to '%s' (current value cannot be read: %s)", pathid, value_escaped, error->message); g_clear_error (&error); return; } g_strstrip (contents); if (nm_streq (contents, value)) _LOGD ("sysctl: setting '%s' to '%s' (current value is identical)", pathid, value_escaped); else { gs_free char *contents_escaped = g_strescape (contents, NULL); _LOGD ("sysctl: setting '%s' to '%s' (current value is '%s')", pathid, value_escaped, contents_escaped); } g_free (contents); } #define _log_dbg_sysctl_set(platform, pathid, dirfd, path, value) \ G_STMT_START { \ if (_LOGD_ENABLED ()) { \ _log_dbg_sysctl_set_impl (platform, pathid, dirfd, path, value); \ } \ } G_STMT_END static gboolean sysctl_set (NMPlatform *platform, const char *pathid, int dirfd, const char *path, const char *value) { nm_auto_pop_netns NMPNetns *netns = NULL; int fd, tries; gssize nwrote; gsize len; char *actual; gs_free char *actual_free = NULL; int errsv; g_return_val_if_fail (path != NULL, FALSE); g_return_val_if_fail (value != NULL, FALSE); ASSERT_SYSCTL_ARGS (pathid, dirfd, path); if (dirfd < 0) { if (!nm_platform_netns_push (platform, &netns)) { errno = ENETDOWN; return FALSE; } pathid = path; fd = open (path, O_WRONLY | O_TRUNC | O_CLOEXEC); if (fd == -1) { errsv = errno; if (errsv == ENOENT) { _LOGD ("sysctl: failed to open '%s': (%d) %s", pathid, errsv, strerror (errsv)); } else { _LOGE ("sysctl: failed to open '%s': (%d) %s", pathid, errsv, strerror (errsv)); } errno = errsv; return FALSE; } } else { fd = openat (dirfd, path, O_WRONLY | O_TRUNC | O_CLOEXEC); if (fd == -1) { errsv = errno; if (errsv == ENOENT) { _LOGD ("sysctl: failed to openat '%s': (%d) %s", pathid, errsv, strerror (errsv)); } else { _LOGE ("sysctl: failed to openat '%s': (%d) %s", pathid, errsv, strerror (errsv)); } errno = errsv; return FALSE; } } _log_dbg_sysctl_set (platform, pathid, dirfd, path, value); /* Most sysfs and sysctl options don't care about a trailing LF, while some * (like infiniband) do. So always add the LF. Also, neither sysfs nor * sysctl support partial writes so the LF must be added to the string we're * about to write. */ len = strlen (value) + 1; if (len > 512) actual = actual_free = g_malloc (len + 1); else actual = g_alloca (len + 1); memcpy (actual, value, len - 1); actual[len - 1] = '\n'; actual[len] = '\0'; /* Try to write the entire value three times if a partial write occurs */ errsv = 0; for (tries = 0, nwrote = 0; tries < 3 && nwrote < len - 1; tries++) { nwrote = write (fd, actual, len); if (nwrote == -1) { errsv = errno; if (errsv == EINTR) { _LOGD ("sysctl: interrupted, will try again"); continue; } break; } } if (nwrote == -1 && errsv != EEXIST) { _LOGE ("sysctl: failed to set '%s' to '%s': (%d) %s", path, value, errsv, strerror (errsv)); } else if (nwrote < len - 1) { _LOGE ("sysctl: failed to set '%s' to '%s' after three attempts", path, value); } if (nwrote < len - 1) { if (close (fd) != 0) { if (errsv != 0) errno = errsv; } else if (errsv != 0) errno = errsv; else errno = EIO; return FALSE; } if (close (fd) != 0) { /* errno is already properly set. */ return FALSE; } /* success. errno is undefined (no need to set). */ return TRUE; } static GSList *sysctl_clear_cache_list; static void _nm_logging_clear_platform_logging_cache_impl (void) { while (sysctl_clear_cache_list) { NMLinuxPlatformPrivate *priv = NM_LINUX_PLATFORM_GET_PRIVATE (sysctl_clear_cache_list->data); sysctl_clear_cache_list = g_slist_delete_link (sysctl_clear_cache_list, sysctl_clear_cache_list); g_hash_table_destroy (priv->sysctl_get_prev_values); priv->sysctl_get_prev_values = NULL; priv->sysctl_get_warned = FALSE; } } static void _log_dbg_sysctl_get_impl (NMPlatform *platform, const char *pathid, const char *contents) { NMLinuxPlatformPrivate *priv = NM_LINUX_PLATFORM_GET_PRIVATE (platform); const char *prev_value = NULL; if (!priv->sysctl_get_prev_values) { _nm_logging_clear_platform_logging_cache = _nm_logging_clear_platform_logging_cache_impl; sysctl_clear_cache_list = g_slist_prepend (sysctl_clear_cache_list, platform); priv->sysctl_get_prev_values = g_hash_table_new_full (g_str_hash, g_str_equal, g_free, g_free); } else prev_value = g_hash_table_lookup (priv->sysctl_get_prev_values, pathid); if (prev_value) { if (strcmp (prev_value, contents) != 0) { gs_free char *contents_escaped = g_strescape (contents, NULL); gs_free char *prev_value_escaped = g_strescape (prev_value, NULL); _LOGD ("sysctl: reading '%s': '%s' (changed from '%s' on last read)", pathid, contents_escaped, prev_value_escaped); g_hash_table_insert (priv->sysctl_get_prev_values, g_strdup (pathid), g_strdup (contents)); } } else { gs_free char *contents_escaped = g_strescape (contents, NULL); _LOGD ("sysctl: reading '%s': '%s'", pathid, contents_escaped); g_hash_table_insert (priv->sysctl_get_prev_values, g_strdup (pathid), g_strdup (contents)); if ( !priv->sysctl_get_warned && g_hash_table_size (priv->sysctl_get_prev_values) > 50000) { _LOGW ("sysctl: the internal cache for debug-logging of sysctl values grew pretty large. You can clear it by disabling debug-logging: `nmcli general logging level KEEP domains PLATFORM:INFO`."); priv->sysctl_get_warned = TRUE; } } } #define _log_dbg_sysctl_get(platform, pathid, contents) \ G_STMT_START { \ if (_LOGD_ENABLED ()) \ _log_dbg_sysctl_get_impl (platform, pathid, contents); \ } G_STMT_END static char * sysctl_get (NMPlatform *platform, const char *pathid, int dirfd, const char *path) { nm_auto_pop_netns NMPNetns *netns = NULL; GError *error = NULL; char *contents; ASSERT_SYSCTL_ARGS (pathid, dirfd, path); if (dirfd < 0) { if (!nm_platform_netns_push (platform, &netns)) return NULL; pathid = path; } if (nm_utils_file_get_contents (dirfd, path, 1*1024*1024, &contents, NULL, &error) < 0) { /* We assume FAILED means EOPNOTSUP */ if ( g_error_matches (error, G_FILE_ERROR, G_FILE_ERROR_NOENT) || g_error_matches (error, G_FILE_ERROR, G_FILE_ERROR_NODEV) || g_error_matches (error, G_FILE_ERROR, G_FILE_ERROR_FAILED)) _LOGD ("error reading %s: %s", pathid, error->message); else _LOGE ("error reading %s: %s", pathid, error->message); g_clear_error (&error); return NULL; } g_strstrip (contents); _log_dbg_sysctl_get (platform, pathid, contents); return contents; } /*****************************************************************************/ static NMPlatformKernelSupportFlags check_kernel_support (NMPlatform *platform, NMPlatformKernelSupportFlags request_flags) { NMPlatformKernelSupportFlags response = 0; nm_assert (NM_IS_LINUX_PLATFORM (platform)); if (NM_FLAGS_HAS (request_flags, NM_PLATFORM_KERNEL_SUPPORT_EXTENDED_IFA_FLAGS)) { if (_support_kernel_extended_ifa_flags_get ()) response |= NM_PLATFORM_KERNEL_SUPPORT_EXTENDED_IFA_FLAGS; } if (NM_FLAGS_HAS (request_flags, NM_PLATFORM_KERNEL_SUPPORT_USER_IPV6LL)) { if (_support_user_ipv6ll_get ()) response |= NM_PLATFORM_KERNEL_SUPPORT_USER_IPV6LL; } if (NM_FLAGS_HAS (request_flags, NM_PLATFORM_KERNEL_SUPPORT_RTA_PREF)) { if (_support_rta_pref_get ()) response |= NM_PLATFORM_KERNEL_SUPPORT_RTA_PREF; } return response; } static void process_events (NMPlatform *platform) { delayed_action_handle_all (platform, TRUE); } /*****************************************************************************/ _NM_UTILS_LOOKUP_DEFINE (static, delayed_action_refresh_from_object_type, NMPObjectType, DelayedActionType, NM_UTILS_LOOKUP_DEFAULT_NM_ASSERT (DELAYED_ACTION_TYPE_NONE), NM_UTILS_LOOKUP_ITEM (NMP_OBJECT_TYPE_LINK, DELAYED_ACTION_TYPE_REFRESH_ALL_LINKS), NM_UTILS_LOOKUP_ITEM (NMP_OBJECT_TYPE_IP4_ADDRESS, DELAYED_ACTION_TYPE_REFRESH_ALL_IP4_ADDRESSES), NM_UTILS_LOOKUP_ITEM (NMP_OBJECT_TYPE_IP6_ADDRESS, DELAYED_ACTION_TYPE_REFRESH_ALL_IP6_ADDRESSES), NM_UTILS_LOOKUP_ITEM (NMP_OBJECT_TYPE_IP4_ROUTE, DELAYED_ACTION_TYPE_REFRESH_ALL_IP4_ROUTES), NM_UTILS_LOOKUP_ITEM (NMP_OBJECT_TYPE_IP6_ROUTE, DELAYED_ACTION_TYPE_REFRESH_ALL_IP6_ROUTES), NM_UTILS_LOOKUP_ITEM_IGNORE_OTHER (), ); _NM_UTILS_LOOKUP_DEFINE (static, delayed_action_refresh_to_object_type, DelayedActionType, NMPObjectType, NM_UTILS_LOOKUP_DEFAULT_NM_ASSERT (NMP_OBJECT_TYPE_UNKNOWN), NM_UTILS_LOOKUP_ITEM (DELAYED_ACTION_TYPE_REFRESH_ALL_LINKS, NMP_OBJECT_TYPE_LINK), NM_UTILS_LOOKUP_ITEM (DELAYED_ACTION_TYPE_REFRESH_ALL_IP4_ADDRESSES, NMP_OBJECT_TYPE_IP4_ADDRESS), NM_UTILS_LOOKUP_ITEM (DELAYED_ACTION_TYPE_REFRESH_ALL_IP6_ADDRESSES, NMP_OBJECT_TYPE_IP6_ADDRESS), NM_UTILS_LOOKUP_ITEM (DELAYED_ACTION_TYPE_REFRESH_ALL_IP4_ROUTES, NMP_OBJECT_TYPE_IP4_ROUTE), NM_UTILS_LOOKUP_ITEM (DELAYED_ACTION_TYPE_REFRESH_ALL_IP6_ROUTES, NMP_OBJECT_TYPE_IP6_ROUTE), NM_UTILS_LOOKUP_ITEM_IGNORE_OTHER (), ); _NM_UTILS_LOOKUP_DEFINE (static, delayed_action_refresh_all_to_idx, DelayedActionType, guint, NM_UTILS_LOOKUP_DEFAULT_NM_ASSERT (0), NM_UTILS_LOOKUP_ITEM (DELAYED_ACTION_TYPE_REFRESH_ALL_LINKS, DELAYED_ACTION_IDX_REFRESH_ALL_LINKS), NM_UTILS_LOOKUP_ITEM (DELAYED_ACTION_TYPE_REFRESH_ALL_IP4_ADDRESSES, DELAYED_ACTION_IDX_REFRESH_ALL_IP4_ADDRESSES), NM_UTILS_LOOKUP_ITEM (DELAYED_ACTION_TYPE_REFRESH_ALL_IP6_ADDRESSES, DELAYED_ACTION_IDX_REFRESH_ALL_IP6_ADDRESSES), NM_UTILS_LOOKUP_ITEM (DELAYED_ACTION_TYPE_REFRESH_ALL_IP4_ROUTES, DELAYED_ACTION_IDX_REFRESH_ALL_IP4_ROUTES), NM_UTILS_LOOKUP_ITEM (DELAYED_ACTION_TYPE_REFRESH_ALL_IP6_ROUTES, DELAYED_ACTION_IDX_REFRESH_ALL_IP6_ROUTES), NM_UTILS_LOOKUP_ITEM_IGNORE_OTHER (), ); NM_UTILS_LOOKUP_STR_DEFINE_STATIC (delayed_action_to_string, DelayedActionType, NM_UTILS_LOOKUP_DEFAULT_NM_ASSERT ("unknown"), NM_UTILS_LOOKUP_STR_ITEM (DELAYED_ACTION_TYPE_REFRESH_ALL_LINKS, "refresh-all-links"), NM_UTILS_LOOKUP_STR_ITEM (DELAYED_ACTION_TYPE_REFRESH_ALL_IP4_ADDRESSES, "refresh-all-ip4-addresses"), NM_UTILS_LOOKUP_STR_ITEM (DELAYED_ACTION_TYPE_REFRESH_ALL_IP6_ADDRESSES, "refresh-all-ip6-addresses"), NM_UTILS_LOOKUP_STR_ITEM (DELAYED_ACTION_TYPE_REFRESH_ALL_IP4_ROUTES, "refresh-all-ip4-routes"), NM_UTILS_LOOKUP_STR_ITEM (DELAYED_ACTION_TYPE_REFRESH_ALL_IP6_ROUTES, "refresh-all-ip6-routes"), NM_UTILS_LOOKUP_STR_ITEM (DELAYED_ACTION_TYPE_REFRESH_LINK, "refresh-link"), NM_UTILS_LOOKUP_STR_ITEM (DELAYED_ACTION_TYPE_MASTER_CONNECTED, "master-connected"), NM_UTILS_LOOKUP_STR_ITEM (DELAYED_ACTION_TYPE_READ_NETLINK, "read-netlink"), NM_UTILS_LOOKUP_STR_ITEM (DELAYED_ACTION_TYPE_WAIT_FOR_NL_RESPONSE, "wait-for-nl-response"), NM_UTILS_LOOKUP_ITEM_IGNORE (DELAYED_ACTION_TYPE_NONE), NM_UTILS_LOOKUP_ITEM_IGNORE (DELAYED_ACTION_TYPE_REFRESH_ALL), NM_UTILS_LOOKUP_ITEM_IGNORE (__DELAYED_ACTION_TYPE_MAX), ); static const char * delayed_action_to_string_full (DelayedActionType action_type, gpointer user_data, char *buf, gsize buf_size) { char *buf0 = buf; const DelayedActionWaitForNlResponseData *data; nm_utils_strbuf_append_str (&buf, &buf_size, delayed_action_to_string (action_type)); switch (action_type) { case DELAYED_ACTION_TYPE_MASTER_CONNECTED: nm_utils_strbuf_append (&buf, &buf_size, " (master-ifindex %d)", GPOINTER_TO_INT (user_data)); break; case DELAYED_ACTION_TYPE_REFRESH_LINK: nm_utils_strbuf_append (&buf, &buf_size, " (ifindex %d)", GPOINTER_TO_INT (user_data)); break; case DELAYED_ACTION_TYPE_WAIT_FOR_NL_RESPONSE: data = user_data; if (data) { gint64 timeout = data->timeout_abs_ns - nm_utils_get_monotonic_timestamp_ns (); char b[255]; nm_utils_strbuf_append (&buf, &buf_size, " (seq %u, timeout in %s%"G_GINT64_FORMAT".%09"G_GINT64_FORMAT", response-type %d%s%s)", data->seq_number, timeout < 0 ? "-" : "", (timeout < 0 ? -timeout : timeout) / NM_UTILS_NS_PER_SECOND, (timeout < 0 ? -timeout : timeout) % NM_UTILS_NS_PER_SECOND, (int) data->response_type, data->seq_result ? ", " : "", data->seq_result ? wait_for_nl_response_to_string (data->seq_result, b, sizeof (b)) : ""); } else nm_utils_strbuf_append_str (&buf, &buf_size, " (any)"); break; default: nm_assert (!user_data); break; } return buf0; } #define _LOGt_delayed_action(action_type, user_data, operation) \ G_STMT_START { \ char _buf[255]; \ \ _LOGt ("delayed-action: %s %s", \ ""operation, \ delayed_action_to_string_full (action_type, user_data, _buf, sizeof (_buf))); \ } G_STMT_END /*****************************************************************************/ static gboolean delayed_action_refresh_all_in_progress (NMPlatform *platform, DelayedActionType action_type) { NMLinuxPlatformPrivate *priv = NM_LINUX_PLATFORM_GET_PRIVATE (platform); nm_assert (nm_utils_is_power_of_two (action_type)); nm_assert (NM_FLAGS_ANY (action_type, DELAYED_ACTION_TYPE_REFRESH_ALL)); nm_assert (!NM_FLAGS_ANY (action_type, ~DELAYED_ACTION_TYPE_REFRESH_ALL)); if (NM_FLAGS_ANY (priv->delayed_action.flags, action_type)) return TRUE; if (priv->delayed_action.refresh_all_in_progess[delayed_action_refresh_all_to_idx (action_type)] > 0) return TRUE; return FALSE; } static void delayed_action_wait_for_nl_response_complete (NMPlatform *platform, guint idx, WaitForNlResponseResult seq_result) { NMLinuxPlatformPrivate *priv = NM_LINUX_PLATFORM_GET_PRIVATE (platform); DelayedActionWaitForNlResponseData *data; nm_assert (NM_FLAGS_HAS (priv->delayed_action.flags, DELAYED_ACTION_TYPE_WAIT_FOR_NL_RESPONSE)); nm_assert (idx < priv->delayed_action.list_wait_for_nl_response->len); nm_assert (seq_result); data = &g_array_index (priv->delayed_action.list_wait_for_nl_response, DelayedActionWaitForNlResponseData, idx); _LOGt_delayed_action (DELAYED_ACTION_TYPE_WAIT_FOR_NL_RESPONSE, data, "complete"); if (priv->delayed_action.list_wait_for_nl_response->len <= 1) priv->delayed_action.flags &= ~DELAYED_ACTION_TYPE_WAIT_FOR_NL_RESPONSE; if (data->out_seq_result) *data->out_seq_result = seq_result; switch (data->response_type) { case DELAYED_ACTION_RESPONSE_TYPE_VOID: break; case DELAYED_ACTION_RESPONSE_TYPE_REFRESH_ALL_IN_PROGRESS: if (data->response.out_refresh_all_in_progess) { nm_assert (*data->response.out_refresh_all_in_progess > 0); *data->response.out_refresh_all_in_progess -= 1; data->response.out_refresh_all_in_progess = NULL; } break; case DELAYED_ACTION_RESPONSE_TYPE_ROUTE_GET: if (data->response.out_route_get) { nm_assert (!*data->response.out_route_get); data->response.out_route_get = NULL; } break; } g_array_remove_index_fast (priv->delayed_action.list_wait_for_nl_response, idx); } static void delayed_action_wait_for_nl_response_complete_all (NMPlatform *platform, WaitForNlResponseResult fallback_result) { NMLinuxPlatformPrivate *priv = NM_LINUX_PLATFORM_GET_PRIVATE (platform); if (NM_FLAGS_HAS (priv->delayed_action.flags, DELAYED_ACTION_TYPE_WAIT_FOR_NL_RESPONSE)) { while (priv->delayed_action.list_wait_for_nl_response->len > 0) { const DelayedActionWaitForNlResponseData *data; guint idx = priv->delayed_action.list_wait_for_nl_response->len - 1; WaitForNlResponseResult r; data = &g_array_index (priv->delayed_action.list_wait_for_nl_response, DelayedActionWaitForNlResponseData, idx); /* prefer the result that we already have. */ r = data->seq_result ? : fallback_result; delayed_action_wait_for_nl_response_complete (platform, idx, r); } } nm_assert (!NM_FLAGS_HAS (priv->delayed_action.flags, DELAYED_ACTION_TYPE_WAIT_FOR_NL_RESPONSE)); nm_assert (priv->delayed_action.list_wait_for_nl_response->len == 0); } /*****************************************************************************/ static void delayed_action_handle_MASTER_CONNECTED (NMPlatform *platform, int master_ifindex) { nm_auto_nmpobj const NMPObject *obj_old = NULL; nm_auto_nmpobj const NMPObject *obj_new = NULL; NMPCacheOpsType cache_op; cache_op = nmp_cache_update_link_master_connected (nm_platform_get_cache (platform), master_ifindex, &obj_old, &obj_new); if (cache_op == NMP_CACHE_OPS_UNCHANGED) return; cache_on_change (platform, cache_op, obj_old, obj_new); nm_platform_cache_update_emit_signal (platform, cache_op, obj_old, obj_new); } static void delayed_action_handle_REFRESH_LINK (NMPlatform *platform, int ifindex) { do_request_link_no_delayed_actions (platform, ifindex, NULL); } static void delayed_action_handle_REFRESH_ALL (NMPlatform *platform, DelayedActionType flags) { do_request_all_no_delayed_actions (platform, flags); } static void delayed_action_handle_READ_NETLINK (NMPlatform *platform) { event_handler_read_netlink (platform, FALSE); } static void delayed_action_handle_WAIT_FOR_NL_RESPONSE (NMPlatform *platform) { event_handler_read_netlink (platform, TRUE); } static gboolean delayed_action_handle_one (NMPlatform *platform) { NMLinuxPlatformPrivate *priv = NM_LINUX_PLATFORM_GET_PRIVATE (platform); gpointer user_data; if (priv->delayed_action.flags == DELAYED_ACTION_TYPE_NONE) return FALSE; /* First process DELAYED_ACTION_TYPE_MASTER_CONNECTED actions. * This type of action is entirely cache-internal and is here to resolve a * cache inconsistency. It should be fixed right away. */ if (NM_FLAGS_HAS (priv->delayed_action.flags, DELAYED_ACTION_TYPE_MASTER_CONNECTED)) { nm_assert (priv->delayed_action.list_master_connected->len > 0); user_data = priv->delayed_action.list_master_connected->pdata[0]; g_ptr_array_remove_index_fast (priv->delayed_action.list_master_connected, 0); if (priv->delayed_action.list_master_connected->len == 0) priv->delayed_action.flags &= ~DELAYED_ACTION_TYPE_MASTER_CONNECTED; nm_assert (_nm_utils_ptrarray_find_first ((gconstpointer *) priv->delayed_action.list_master_connected->pdata, priv->delayed_action.list_master_connected->len, user_data) < 0); _LOGt_delayed_action (DELAYED_ACTION_TYPE_MASTER_CONNECTED, user_data, "handle"); delayed_action_handle_MASTER_CONNECTED (platform, GPOINTER_TO_INT (user_data)); return TRUE; } nm_assert (priv->delayed_action.list_master_connected->len == 0); /* Next we prefer read-netlink, because the buffer size is limited and we want to process events * from netlink early. */ if (NM_FLAGS_HAS (priv->delayed_action.flags, DELAYED_ACTION_TYPE_READ_NETLINK)) { _LOGt_delayed_action (DELAYED_ACTION_TYPE_READ_NETLINK, NULL, "handle"); priv->delayed_action.flags &= ~DELAYED_ACTION_TYPE_READ_NETLINK; delayed_action_handle_READ_NETLINK (platform); return TRUE; } if (NM_FLAGS_ANY (priv->delayed_action.flags, DELAYED_ACTION_TYPE_REFRESH_ALL)) { DelayedActionType flags, iflags; flags = priv->delayed_action.flags & DELAYED_ACTION_TYPE_REFRESH_ALL; priv->delayed_action.flags &= ~DELAYED_ACTION_TYPE_REFRESH_ALL; if (_LOGt_ENABLED ()) { FOR_EACH_DELAYED_ACTION (iflags, flags) { _LOGt_delayed_action (iflags, NULL, "handle"); } } delayed_action_handle_REFRESH_ALL (platform, flags); return TRUE; } if (NM_FLAGS_HAS (priv->delayed_action.flags, DELAYED_ACTION_TYPE_REFRESH_LINK)) { nm_assert (priv->delayed_action.list_refresh_link->len > 0); user_data = priv->delayed_action.list_refresh_link->pdata[0]; g_ptr_array_remove_index_fast (priv->delayed_action.list_refresh_link, 0); if (priv->delayed_action.list_refresh_link->len == 0) priv->delayed_action.flags &= ~DELAYED_ACTION_TYPE_REFRESH_LINK; nm_assert (_nm_utils_ptrarray_find_first ((gconstpointer *) priv->delayed_action.list_refresh_link->pdata, priv->delayed_action.list_refresh_link->len, user_data) < 0); _LOGt_delayed_action (DELAYED_ACTION_TYPE_REFRESH_LINK, user_data, "handle"); delayed_action_handle_REFRESH_LINK (platform, GPOINTER_TO_INT (user_data)); return TRUE; } if (NM_FLAGS_HAS (priv->delayed_action.flags, DELAYED_ACTION_TYPE_WAIT_FOR_NL_RESPONSE)) { nm_assert (priv->delayed_action.list_wait_for_nl_response->len > 0); _LOGt_delayed_action (DELAYED_ACTION_TYPE_WAIT_FOR_NL_RESPONSE, NULL, "handle"); delayed_action_handle_WAIT_FOR_NL_RESPONSE (platform); return TRUE; } return FALSE; } static gboolean delayed_action_handle_all (NMPlatform *platform, gboolean read_netlink) { NMLinuxPlatformPrivate *priv = NM_LINUX_PLATFORM_GET_PRIVATE (platform); gboolean any = FALSE; g_return_val_if_fail (priv->delayed_action.is_handling == 0, FALSE); priv->delayed_action.is_handling++; if (read_netlink) delayed_action_schedule (platform, DELAYED_ACTION_TYPE_READ_NETLINK, NULL); while (delayed_action_handle_one (platform)) any = TRUE; priv->delayed_action.is_handling--; cache_prune_all (platform); return any; } static void delayed_action_schedule (NMPlatform *platform, DelayedActionType action_type, gpointer user_data) { NMLinuxPlatformPrivate *priv = NM_LINUX_PLATFORM_GET_PRIVATE (platform); DelayedActionType iflags; nm_assert (action_type != DELAYED_ACTION_TYPE_NONE); switch (action_type) { case DELAYED_ACTION_TYPE_REFRESH_LINK: if (_nm_utils_ptrarray_find_first ((gconstpointer *) priv->delayed_action.list_refresh_link->pdata, priv->delayed_action.list_refresh_link->len, user_data) < 0) g_ptr_array_add (priv->delayed_action.list_refresh_link, user_data); break; case DELAYED_ACTION_TYPE_MASTER_CONNECTED: if (_nm_utils_ptrarray_find_first ((gconstpointer *) priv->delayed_action.list_master_connected->pdata, priv->delayed_action.list_master_connected->len, user_data) < 0) g_ptr_array_add (priv->delayed_action.list_master_connected, user_data); break; case DELAYED_ACTION_TYPE_WAIT_FOR_NL_RESPONSE: g_array_append_vals (priv->delayed_action.list_wait_for_nl_response, user_data, 1); break; default: nm_assert (!user_data); nm_assert (!NM_FLAGS_HAS (action_type, DELAYED_ACTION_TYPE_REFRESH_LINK)); nm_assert (!NM_FLAGS_HAS (action_type, DELAYED_ACTION_TYPE_MASTER_CONNECTED)); nm_assert (!NM_FLAGS_HAS (action_type, DELAYED_ACTION_TYPE_WAIT_FOR_NL_RESPONSE)); break; } priv->delayed_action.flags |= action_type; if (_LOGt_ENABLED ()) { FOR_EACH_DELAYED_ACTION (iflags, action_type) { _LOGt_delayed_action (iflags, user_data, "schedule"); } } } static void delayed_action_schedule_WAIT_FOR_NL_RESPONSE (NMPlatform *platform, guint32 seq_number, WaitForNlResponseResult *out_seq_result, DelayedActionWaitForNlResponseType response_type, gpointer response_out_data) { DelayedActionWaitForNlResponseData data = { .seq_number = seq_number, .timeout_abs_ns = nm_utils_get_monotonic_timestamp_ns () + (200 * (NM_UTILS_NS_PER_SECOND / 1000)), .out_seq_result = out_seq_result, .response_type = response_type, .response.out_data = response_out_data, }; delayed_action_schedule (platform, DELAYED_ACTION_TYPE_WAIT_FOR_NL_RESPONSE, &data); } /*****************************************************************************/ static void cache_prune_one_type (NMPlatform *platform, NMPObjectType obj_type) { NMDedupMultiIter iter; const NMPObject *obj; NMPCacheOpsType cache_op; NMPLookup lookup; NMPCache *cache = nm_platform_get_cache (platform); nmp_lookup_init_obj_type (&lookup, obj_type); nm_dedup_multi_iter_init (&iter, nmp_cache_lookup (cache, &lookup)); while (nm_dedup_multi_iter_next (&iter)) { if (iter.current->dirty) { nm_auto_nmpobj const NMPObject *obj_old = NULL; obj = iter.current->obj; _LOGt ("cache-prune: prune %s", nmp_object_to_string (obj, NMP_OBJECT_TO_STRING_ALL, NULL, 0)); cache_op = nmp_cache_remove (cache, obj, TRUE, TRUE, &obj_old); nm_assert (cache_op == NMP_CACHE_OPS_REMOVED); cache_on_change (platform, cache_op, obj_old, NULL); nm_platform_cache_update_emit_signal (platform, cache_op, obj_old, NULL); } } } static void cache_prune_all (NMPlatform *platform) { NMLinuxPlatformPrivate *priv = NM_LINUX_PLATFORM_GET_PRIVATE (platform); DelayedActionType iflags, action_type; action_type = DELAYED_ACTION_TYPE_REFRESH_ALL; FOR_EACH_DELAYED_ACTION (iflags, action_type) { bool *p = &priv->pruning[delayed_action_refresh_all_to_idx (iflags)]; if (*p) { *p = FALSE; cache_prune_one_type (platform, delayed_action_refresh_to_object_type (iflags)); } } } static void cache_on_change (NMPlatform *platform, NMPCacheOpsType cache_op, const NMPObject *obj_old, const NMPObject *obj_new) { const NMPClass *klass; char str_buf[sizeof (_nm_utils_to_string_buffer)]; char str_buf2[sizeof (_nm_utils_to_string_buffer)]; NMPCache *cache = nm_platform_get_cache (platform); ASSERT_nmp_cache_ops (cache, cache_op, obj_old, obj_new); nm_assert (cache_op != NMP_CACHE_OPS_UNCHANGED); klass = obj_old ? NMP_OBJECT_GET_CLASS (obj_old) : NMP_OBJECT_GET_CLASS (obj_new); _LOGt ("update-cache-%s: %s: %s%s%s", klass->obj_type_name, (cache_op == NMP_CACHE_OPS_UPDATED ? "UPDATE" : (cache_op == NMP_CACHE_OPS_REMOVED ? "REMOVE" : (cache_op == NMP_CACHE_OPS_ADDED) ? "ADD" : "???")), (cache_op != NMP_CACHE_OPS_ADDED ? nmp_object_to_string (obj_old, NMP_OBJECT_TO_STRING_ALL, str_buf2, sizeof (str_buf2)) : nmp_object_to_string (obj_new, NMP_OBJECT_TO_STRING_ALL, str_buf2, sizeof (str_buf2))), (cache_op == NMP_CACHE_OPS_UPDATED) ? " -> " : "", (cache_op == NMP_CACHE_OPS_UPDATED ? nmp_object_to_string (obj_new, NMP_OBJECT_TO_STRING_ALL, str_buf, sizeof (str_buf)) : "")); switch (klass->obj_type) { case NMP_OBJECT_TYPE_LINK: { /* check whether changing a slave link can cause a master link (bridge or bond) to go up/down */ if ( obj_old && nmp_cache_link_connected_needs_toggle_by_ifindex (cache, obj_old->link.master, obj_new, obj_old)) delayed_action_schedule (platform, DELAYED_ACTION_TYPE_MASTER_CONNECTED, GINT_TO_POINTER (obj_old->link.master)); if ( obj_new && (!obj_old || obj_old->link.master != obj_new->link.master) && nmp_cache_link_connected_needs_toggle_by_ifindex (cache, obj_new->link.master, obj_new, obj_old)) delayed_action_schedule (platform, DELAYED_ACTION_TYPE_MASTER_CONNECTED, GINT_TO_POINTER (obj_new->link.master)); } { /* check whether we are about to change a master link that needs toggling connected state. */ if ( obj_new /* <-- nonsensical, make coverity happy */ && nmp_cache_link_connected_needs_toggle (cache, obj_new, obj_new, obj_old)) delayed_action_schedule (platform, DELAYED_ACTION_TYPE_MASTER_CONNECTED, GINT_TO_POINTER (obj_new->link.ifindex)); } { int ifindex = 0; /* if we remove a link (from netlink), we must refresh the addresses and routes */ if ( cache_op == NMP_CACHE_OPS_REMOVED && obj_old /* <-- nonsensical, make coverity happy */) ifindex = obj_old->link.ifindex; else if ( cache_op == NMP_CACHE_OPS_UPDATED && obj_old && obj_new /* <-- nonsensical, make coverity happy */ && !obj_new->_link.netlink.is_in_netlink && obj_new->_link.netlink.is_in_netlink != obj_old->_link.netlink.is_in_netlink) ifindex = obj_new->link.ifindex; if (ifindex > 0) { delayed_action_schedule (platform, DELAYED_ACTION_TYPE_REFRESH_ALL_IP4_ADDRESSES | DELAYED_ACTION_TYPE_REFRESH_ALL_IP6_ADDRESSES | DELAYED_ACTION_TYPE_REFRESH_ALL_IP4_ROUTES | DELAYED_ACTION_TYPE_REFRESH_ALL_IP6_ROUTES, NULL); } } { int ifindex = -1; /* removal of a link could be caused by moving the link to another netns. * In this case, we potentially have to update other links that have this link as parent. * Currently, kernel misses to sent us a notification in this case * (https://bugzilla.redhat.com/show_bug.cgi?id=1262908). */ if ( cache_op == NMP_CACHE_OPS_REMOVED && obj_old /* <-- nonsensical, make coverity happy */ && obj_old->_link.netlink.is_in_netlink) ifindex = obj_old->link.ifindex; else if ( cache_op == NMP_CACHE_OPS_UPDATED && obj_old && obj_new /* <-- nonsensical, make coverity happy */ && obj_old->_link.netlink.is_in_netlink && !obj_new->_link.netlink.is_in_netlink) ifindex = obj_new->link.ifindex; if (ifindex > 0) { NMPLookup lookup; NMDedupMultiIter iter; const NMPlatformLink *l; nmp_lookup_init_obj_type (&lookup, NMP_OBJECT_TYPE_LINK); nmp_cache_iter_for_each_link (&iter, nmp_cache_lookup (cache, &lookup), &l) { if (l->parent == ifindex) delayed_action_schedule (platform, DELAYED_ACTION_TYPE_REFRESH_LINK, GINT_TO_POINTER (l->ifindex)); } } } { /* if a link goes down, we must refresh routes */ if ( cache_op == NMP_CACHE_OPS_UPDATED && obj_old && obj_new /* <-- nonsensical, make coverity happy */ && obj_old->_link.netlink.is_in_netlink && obj_new->_link.netlink.is_in_netlink && ( ( NM_FLAGS_HAS (obj_old->link.n_ifi_flags, IFF_UP) && !NM_FLAGS_HAS (obj_new->link.n_ifi_flags, IFF_UP)) || ( NM_FLAGS_HAS (obj_old->link.n_ifi_flags, IFF_LOWER_UP) && !NM_FLAGS_HAS (obj_new->link.n_ifi_flags, IFF_LOWER_UP)))) { /* FIXME: I suspect that IFF_LOWER_UP must not be considered, and I * think kernel does send RTM_DELROUTE events for IPv6 routes, so * we might not need to refresh IPv6 routes. */ delayed_action_schedule (platform, DELAYED_ACTION_TYPE_REFRESH_ALL_IP4_ROUTES | DELAYED_ACTION_TYPE_REFRESH_ALL_IP6_ROUTES, NULL); } } if ( NM_IN_SET (cache_op, NMP_CACHE_OPS_ADDED, NMP_CACHE_OPS_UPDATED) && (obj_new && obj_new->_link.netlink.is_in_netlink) && (!obj_old || !obj_old->_link.netlink.is_in_netlink)) { if (!obj_new->_link.netlink.lnk) { /* certain link-types also come with a IFLA_INFO_DATA/lnk_data. It may happen that * kernel didn't send this notification, thus when we first learn about a link * that lacks an lnk_data we re-request it again. * * For example https://bugzilla.redhat.com/show_bug.cgi?id=1284001 */ switch (obj_new->link.type) { case NM_LINK_TYPE_GRE: case NM_LINK_TYPE_IP6TNL: case NM_LINK_TYPE_INFINIBAND: case NM_LINK_TYPE_MACVLAN: case NM_LINK_TYPE_MACVTAP: case NM_LINK_TYPE_SIT: case NM_LINK_TYPE_VLAN: case NM_LINK_TYPE_VXLAN: delayed_action_schedule (platform, DELAYED_ACTION_TYPE_REFRESH_LINK, GINT_TO_POINTER (obj_new->link.ifindex)); break; default: break; } } if ( obj_new->link.type == NM_LINK_TYPE_VETH && obj_new->link.parent == 0) { /* the initial notification when adding a veth pair can lack the parent/IFLA_LINK * (https://bugzilla.redhat.com/show_bug.cgi?id=1285827). * Request it again. */ delayed_action_schedule (platform, DELAYED_ACTION_TYPE_REFRESH_LINK, GINT_TO_POINTER (obj_new->link.ifindex)); } if ( obj_new->link.type == NM_LINK_TYPE_ETHERNET && obj_new->link.addr.len == 0) { /* Due to a kernel bug, we sometimes receive spurious NEWLINK * messages after a wifi interface has disappeared. Since the * link is not present anymore we can't determine its type and * thus it will show up as a Ethernet one, with no address * specified. Request the link again to check if it really * exists. https://bugzilla.redhat.com/show_bug.cgi?id=1302037 */ delayed_action_schedule (platform, DELAYED_ACTION_TYPE_REFRESH_LINK, GINT_TO_POINTER (obj_new->link.ifindex)); } } { /* on enslave/release, we also refresh the master. */ int ifindex1 = 0, ifindex2 = 0; gboolean changed_master, changed_connected; changed_master = (obj_new && obj_new->_link.netlink.is_in_netlink && obj_new->link.master > 0 ? obj_new->link.master : 0) != (obj_old && obj_old->_link.netlink.is_in_netlink && obj_old->link.master > 0 ? obj_old->link.master : 0); changed_connected = (obj_new && obj_new->_link.netlink.is_in_netlink ? NM_FLAGS_HAS (obj_new->link.n_ifi_flags, IFF_LOWER_UP) : 2) != (obj_old && obj_old->_link.netlink.is_in_netlink ? NM_FLAGS_HAS (obj_old->link.n_ifi_flags, IFF_LOWER_UP) : 2); if (changed_master || changed_connected) { ifindex1 = (obj_old && obj_old->_link.netlink.is_in_netlink && obj_old->link.master > 0) ? obj_old->link.master : 0; ifindex2 = (obj_new && obj_new->_link.netlink.is_in_netlink && obj_new->link.master > 0) ? obj_new->link.master : 0; if (ifindex1 > 0) delayed_action_schedule (platform, DELAYED_ACTION_TYPE_REFRESH_LINK, GINT_TO_POINTER (ifindex1)); if (ifindex2 > 0 && ifindex1 != ifindex2) delayed_action_schedule (platform, DELAYED_ACTION_TYPE_REFRESH_LINK, GINT_TO_POINTER (ifindex2)); } } break; case NMP_OBJECT_TYPE_IP4_ADDRESS: case NMP_OBJECT_TYPE_IP6_ADDRESS: { /* Address deletion is sometimes accompanied by route deletion. We need to * check all routes belonging to the same interface. */ if (cache_op == NMP_CACHE_OPS_REMOVED) { delayed_action_schedule (platform, (klass->obj_type == NMP_OBJECT_TYPE_IP4_ADDRESS) ? DELAYED_ACTION_TYPE_REFRESH_ALL_IP4_ROUTES : DELAYED_ACTION_TYPE_REFRESH_ALL_IP6_ROUTES, NULL); } } break; default: break; } } /*****************************************************************************/ static guint32 _nlh_seq_next_get (NMLinuxPlatformPrivate *priv) { /* generate a new sequence number, but skip zero. */ return priv->nlh_seq_next++ ?: priv->nlh_seq_next++; } /** * _nl_send_nlmsghdr: * @platform: * @nlhdr: * @out_seq_result: * @response_type: * @response_out_data: * * Returns: 0 on success or a negative errno. Beware, it's an errno, not nlerror. */ static int _nl_send_nlmsghdr (NMPlatform *platform, struct nlmsghdr *nlhdr, WaitForNlResponseResult *out_seq_result, DelayedActionWaitForNlResponseType response_type, gpointer response_out_data) { NMLinuxPlatformPrivate *priv = NM_LINUX_PLATFORM_GET_PRIVATE (platform); guint32 seq; int nle; nm_assert (nlhdr); seq = _nlh_seq_next_get (priv); nlhdr->nlmsg_seq = seq; { struct sockaddr_nl nladdr = { .nl_family = AF_NETLINK, }; struct iovec iov = { .iov_base = nlhdr, .iov_len = nlhdr->nlmsg_len }; struct msghdr msg = { .msg_name = &nladdr, .msg_namelen = sizeof(nladdr), .msg_iov = &iov, .msg_iovlen = 1, }; int try_count; if (!nlhdr->nlmsg_pid) nlhdr->nlmsg_pid = nl_socket_get_local_port (priv->nlh); nlhdr->nlmsg_flags |= (NLM_F_REQUEST | NLM_F_ACK); try_count = 0; again: nle = sendmsg (nl_socket_get_fd (priv->nlh), &msg, 0); if (nle < 0) { nle = errno; if (nle == EINTR && try_count++ < 100) goto again; _LOGD ("netlink: nl-send-nlmsghdr: failed sending message: %s (%d)", g_strerror (nle), nle); return -nle; } } delayed_action_schedule_WAIT_FOR_NL_RESPONSE (platform, seq, out_seq_result, response_type, response_out_data); return 0; } /** * _nl_send_nlmsg: * @platform: * @nlmsg: * @out_seq_result: * @response_type: * @response_out_data: * * Returns: 0 on success, or a negative libnl3 error code (beware, it's not an errno). */ static int _nl_send_nlmsg (NMPlatform *platform, struct nl_msg *nlmsg, WaitForNlResponseResult *out_seq_result, DelayedActionWaitForNlResponseType response_type, gpointer response_out_data) { NMLinuxPlatformPrivate *priv = NM_LINUX_PLATFORM_GET_PRIVATE (platform); struct nlmsghdr *nlhdr; guint32 seq; int nle; nlhdr = nlmsg_hdr (nlmsg); seq = _nlh_seq_next_get (priv); nlhdr->nlmsg_seq = seq; nle = nl_send_auto (priv->nlh, nlmsg); if (nle < 0) { _LOGD ("netlink: nl-send-nlmsg: failed sending message: %s (%d)", nl_geterror (nle), nle); return nle; } delayed_action_schedule_WAIT_FOR_NL_RESPONSE (platform, seq, out_seq_result, response_type, response_out_data); return 0; } static void do_request_link_no_delayed_actions (NMPlatform *platform, int ifindex, const char *name) { NMLinuxPlatformPrivate *priv = NM_LINUX_PLATFORM_GET_PRIVATE (platform); nm_auto_nlmsg struct nl_msg *nlmsg = NULL; if (name && !name[0]) name = NULL; g_return_if_fail (ifindex > 0 || name); _LOGD ("do-request-link: %d %s", ifindex, name ? name : ""); if (ifindex > 0) { const NMDedupMultiEntry *entry; entry = nmp_cache_lookup_entry_link (nm_platform_get_cache (platform), ifindex); if (entry) { priv->pruning[DELAYED_ACTION_IDX_REFRESH_ALL_LINKS] = TRUE; nm_dedup_multi_entry_set_dirty (entry, TRUE); } } event_handler_read_netlink (platform, FALSE); nlmsg = _nl_msg_new_link (RTM_GETLINK, 0, ifindex, name, 0, 0); if (nlmsg) _nl_send_nlmsg (platform, nlmsg, NULL, DELAYED_ACTION_RESPONSE_TYPE_VOID, NULL); } static void do_request_link (NMPlatform *platform, int ifindex, const char *name) { do_request_link_no_delayed_actions (platform, ifindex, name); delayed_action_handle_all (platform, FALSE); } static void do_request_all_no_delayed_actions (NMPlatform *platform, DelayedActionType action_type) { NMLinuxPlatformPrivate *priv = NM_LINUX_PLATFORM_GET_PRIVATE (platform); DelayedActionType iflags; nm_assert (!NM_FLAGS_ANY (action_type, ~DELAYED_ACTION_TYPE_REFRESH_ALL)); action_type &= DELAYED_ACTION_TYPE_REFRESH_ALL; FOR_EACH_DELAYED_ACTION (iflags, action_type) { priv->pruning[delayed_action_refresh_all_to_idx (iflags)] = TRUE; nmp_cache_dirty_set_all (nm_platform_get_cache (platform), delayed_action_refresh_to_object_type (iflags)); } FOR_EACH_DELAYED_ACTION (iflags, action_type) { NMPObjectType obj_type = delayed_action_refresh_to_object_type (iflags); const NMPClass *klass = nmp_class_from_type (obj_type); nm_auto_nlmsg struct nl_msg *nlmsg = NULL; struct rtgenmsg gmsg = { .rtgen_family = klass->addr_family, }; int nle; gint *out_refresh_all_in_progess; out_refresh_all_in_progess = &priv->delayed_action.refresh_all_in_progess[delayed_action_refresh_all_to_idx (iflags)]; nm_assert (*out_refresh_all_in_progess >= 0); *out_refresh_all_in_progess += 1; /* clear any delayed action that request a refresh of this object type. */ priv->delayed_action.flags &= ~iflags; _LOGt_delayed_action (iflags, NULL, "handle (do-request-all)"); if (obj_type == NMP_OBJECT_TYPE_LINK) { priv->delayed_action.flags &= ~DELAYED_ACTION_TYPE_REFRESH_LINK; g_ptr_array_set_size (priv->delayed_action.list_refresh_link, 0); _LOGt_delayed_action (DELAYED_ACTION_TYPE_REFRESH_LINK, NULL, "clear (do-request-all)"); } event_handler_read_netlink (platform, FALSE); /* reimplement * nl_rtgen_request (sk, klass->rtm_gettype, klass->addr_family, NLM_F_DUMP); * because we need the sequence number. */ nlmsg = nlmsg_alloc_simple (klass->rtm_gettype, NLM_F_DUMP); if (!nlmsg) continue; nle = nlmsg_append (nlmsg, &gmsg, sizeof (gmsg), NLMSG_ALIGNTO); if (nle < 0) continue; if (_nl_send_nlmsg (platform, nlmsg, NULL, DELAYED_ACTION_RESPONSE_TYPE_REFRESH_ALL_IN_PROGRESS, out_refresh_all_in_progess) < 0) { nm_assert (*out_refresh_all_in_progess > 0); *out_refresh_all_in_progess -= 1; } } } static void do_request_one_type (NMPlatform *platform, NMPObjectType obj_type) { do_request_all_no_delayed_actions (platform, delayed_action_refresh_from_object_type (obj_type)); delayed_action_handle_all (platform, FALSE); } static void event_seq_check_refresh_all (NMPlatform *platform, guint32 seq_number) { NMLinuxPlatformPrivate *priv = NM_LINUX_PLATFORM_GET_PRIVATE (platform); DelayedActionWaitForNlResponseData *data; guint i; if (NM_IN_SET (seq_number, 0, priv->nlh_seq_last_seen)) return; if (NM_FLAGS_HAS (priv->delayed_action.flags, DELAYED_ACTION_TYPE_WAIT_FOR_NL_RESPONSE)) { nm_assert (priv->delayed_action.list_wait_for_nl_response->len > 0); for (i = 0; i < priv->delayed_action.list_wait_for_nl_response->len; i++) { data = &g_array_index (priv->delayed_action.list_wait_for_nl_response, DelayedActionWaitForNlResponseData, i); if ( data->response_type == DELAYED_ACTION_RESPONSE_TYPE_REFRESH_ALL_IN_PROGRESS && data->response.out_refresh_all_in_progess && data->seq_number == priv->nlh_seq_last_seen) { *data->response.out_refresh_all_in_progess -= 1; data->response.out_refresh_all_in_progess = NULL; break; } } } priv->nlh_seq_last_seen = seq_number; } static void event_seq_check (NMPlatform *platform, guint32 seq_number, WaitForNlResponseResult seq_result) { NMLinuxPlatformPrivate *priv = NM_LINUX_PLATFORM_GET_PRIVATE (platform); DelayedActionWaitForNlResponseData *data; guint i; if (seq_number == 0) return; if (NM_FLAGS_HAS (priv->delayed_action.flags, DELAYED_ACTION_TYPE_WAIT_FOR_NL_RESPONSE)) { nm_assert (priv->delayed_action.list_wait_for_nl_response->len > 0); for (i = 0; i < priv->delayed_action.list_wait_for_nl_response->len; i++) { data = &g_array_index (priv->delayed_action.list_wait_for_nl_response, DelayedActionWaitForNlResponseData, i); if (data->seq_number == seq_number) { /* We potentially receive many parts partial responses for the same sequence number. * Thus, we only remember the result, and collect it later. */ if (data->seq_result < 0) { /* we already saw an error for this seqence number. * Preserve it. */ } else if ( seq_result != WAIT_FOR_NL_RESPONSE_RESULT_RESPONSE_UNKNOWN || data->seq_result == WAIT_FOR_NL_RESPONSE_RESULT_UNKNOWN) data->seq_result = seq_result; return; } } } #ifdef NM_MORE_LOGGING if (seq_number != priv->nlh_seq_last_handled) _LOGt ("netlink: recvmsg: unwaited sequence number %u", seq_number); priv->nlh_seq_last_handled = seq_number; #endif } static void event_valid_msg (NMPlatform *platform, struct nl_msg *msg, gboolean handle_events) { NMLinuxPlatformPrivate *priv; nm_auto_nmpobj NMPObject *obj = NULL; NMPCacheOpsType cache_op; struct nlmsghdr *msghdr; char buf_nlmsghdr[400]; gboolean id_only = FALSE; NMPCache *cache = nm_platform_get_cache (platform); gboolean is_dump; msghdr = nlmsg_hdr (msg); if ( _support_kernel_extended_ifa_flags_still_undecided () && msghdr->nlmsg_type == RTM_NEWADDR) _support_kernel_extended_ifa_flags_detect (msg); if (!handle_events) return; if (NM_IN_SET (msghdr->nlmsg_type, RTM_DELLINK, RTM_DELADDR, RTM_DELROUTE)) { /* The event notifies about a deleted object. We don't need to initialize all * fields of the object. */ id_only = TRUE; } obj = nmp_object_new_from_nl (platform, cache, msg, id_only); if (!obj) { _LOGT ("event-notification: %s: ignore", _nl_nlmsghdr_to_str (msghdr, buf_nlmsghdr, sizeof (buf_nlmsghdr))); return; } switch (msghdr->nlmsg_type) { case RTM_NEWADDR: case RTM_NEWLINK: case RTM_NEWROUTE: is_dump = delayed_action_refresh_all_in_progress (platform, delayed_action_refresh_from_object_type (NMP_OBJECT_GET_TYPE (obj))); break; default: is_dump = FALSE; } _LOGT ("event-notification: %s%s: %s", _nl_nlmsghdr_to_str (msghdr, buf_nlmsghdr, sizeof (buf_nlmsghdr)), is_dump ? ", in-dump" : "", nmp_object_to_string (obj, id_only ? NMP_OBJECT_TO_STRING_ID : NMP_OBJECT_TO_STRING_PUBLIC, NULL, 0)); { nm_auto_nmpobj const NMPObject *obj_old = NULL; nm_auto_nmpobj const NMPObject *obj_new = NULL; switch (msghdr->nlmsg_type) { case RTM_NEWLINK: case RTM_NEWADDR: case RTM_GETLINK: cache_op = nmp_cache_update_netlink (cache, obj, is_dump, &obj_old, &obj_new); if (cache_op != NMP_CACHE_OPS_UNCHANGED) { cache_on_change (platform, cache_op, obj_old, obj_new); nm_platform_cache_update_emit_signal (platform, cache_op, obj_old, obj_new); } break; case RTM_NEWROUTE: { nm_auto_nmpobj const NMPObject *obj_replace = NULL; gboolean resync_required = FALSE; gboolean only_dirty = FALSE; if (obj->ip_route.rt_cloned) { /* a cloned route might be a response for RTM_GETROUTE. Check, whether it is. */ nm_assert (!nmp_object_is_alive (obj)); priv = NM_LINUX_PLATFORM_GET_PRIVATE (platform); if (NM_FLAGS_HAS (priv->delayed_action.flags, DELAYED_ACTION_TYPE_WAIT_FOR_NL_RESPONSE)) { guint i; nm_assert (priv->delayed_action.list_wait_for_nl_response->len > 0); for (i = 0; i < priv->delayed_action.list_wait_for_nl_response->len; i++) { DelayedActionWaitForNlResponseData *data = &g_array_index (priv->delayed_action.list_wait_for_nl_response, DelayedActionWaitForNlResponseData, i); if ( data->response_type == DELAYED_ACTION_RESPONSE_TYPE_ROUTE_GET && data->response.out_route_get) { nm_assert (!*data->response.out_route_get); if (data->seq_number == nlmsg_hdr (msg)->nlmsg_seq) { *data->response.out_route_get = nmp_object_clone (obj, FALSE); data->response.out_route_get = NULL; break; } } } } } cache_op = nmp_cache_update_netlink_route (cache, obj, is_dump, msghdr->nlmsg_flags, &obj_old, &obj_new, &obj_replace, &resync_required); if (cache_op != NMP_CACHE_OPS_UNCHANGED) { if (obj_replace) { const NMDedupMultiEntry *entry_replace; /* we found an object that is to be replaced by the RTM_NEWROUTE message. * While we invoke the signal, the platform cache might change and invalidate * the findings. Mitigate that (for the most part), by marking the entry as * dirty and only delete @obj_replace if it is still dirty afterwards. * * Yes, there is a tiny tiny chance for still getting it wrong. But in practice, * the signal handlers do not cause to call the platform again, so the cache * is not really changing. -- if they would, it would anyway be dangerous to overflow * the stack and it's not ensured that the processing of netlink messages is * reentrant (maybe it is). */ entry_replace = nmp_cache_lookup_entry (cache, obj_replace); nm_assert (entry_replace && entry_replace->obj == obj_replace); nm_dedup_multi_entry_set_dirty (entry_replace, TRUE); only_dirty = TRUE; } cache_on_change (platform, cache_op, obj_old, obj_new); nm_platform_cache_update_emit_signal (platform, cache_op, obj_old, obj_new); } if (obj_replace) { /* the RTM_NEWROUTE message indicates that another route was replaced. * Remove it now. */ cache_op = nmp_cache_remove (cache, obj_replace, TRUE, only_dirty, NULL); if (cache_op != NMP_CACHE_OPS_UNCHANGED) { nm_assert (cache_op == NMP_CACHE_OPS_REMOVED); cache_on_change (platform, cache_op, obj_replace, NULL); nm_platform_cache_update_emit_signal (platform, cache_op, obj_replace, NULL); } } if (resync_required) { /* we'd like to avoid such resyncs as they are expensive and we should only rely on the * netlink events. This needs investigation. */ _LOGT ("schedule resync of routes after RTM_NEWROUTE"); delayed_action_schedule (platform, delayed_action_refresh_from_object_type (NMP_OBJECT_GET_TYPE (obj)), NULL); } break; } case RTM_DELLINK: case RTM_DELADDR: case RTM_DELROUTE: cache_op = nmp_cache_remove_netlink (cache, obj, &obj_old, &obj_new); if (cache_op != NMP_CACHE_OPS_UNCHANGED) { cache_on_change (platform, cache_op, obj_old, obj_new); nm_platform_cache_update_emit_signal (platform, cache_op, obj_old, obj_new); } break; default: break; } } } /*****************************************************************************/ static gboolean do_add_link_with_lookup (NMPlatform *platform, NMLinkType link_type, const char *name, struct nl_msg *nlmsg, const NMPlatformLink **out_link) { const NMPObject *obj = NULL; WaitForNlResponseResult seq_result = WAIT_FOR_NL_RESPONSE_RESULT_UNKNOWN; int nle; char s_buf[256]; NMPCache *cache = nm_platform_get_cache (platform); event_handler_read_netlink (platform, FALSE); nle = _nl_send_nlmsg (platform, nlmsg, &seq_result, DELAYED_ACTION_RESPONSE_TYPE_VOID, NULL); if (nle < 0) { _LOGE ("do-add-link[%s/%s]: failed sending netlink request \"%s\" (%d)", name, nm_link_type_to_string (link_type), nl_geterror (nle), -nle); NM_SET_OUT (out_link, NULL); return FALSE; } delayed_action_handle_all (platform, FALSE); nm_assert (seq_result); _NMLOG (seq_result == WAIT_FOR_NL_RESPONSE_RESULT_RESPONSE_OK ? LOGL_DEBUG : LOGL_WARN, "do-add-link[%s/%s]: %s", name, nm_link_type_to_string (link_type), wait_for_nl_response_to_string (seq_result, s_buf, sizeof (s_buf))); if (out_link) { obj = nmp_cache_lookup_link_full (cache, 0, name, FALSE, link_type, NULL, NULL); *out_link = NMP_OBJECT_CAST_LINK (obj); } return seq_result == WAIT_FOR_NL_RESPONSE_RESULT_RESPONSE_OK; } static NMPlatformError do_add_addrroute (NMPlatform *platform, const NMPObject *obj_id, struct nl_msg *nlmsg, gboolean suppress_netlink_failure) { WaitForNlResponseResult seq_result = WAIT_FOR_NL_RESPONSE_RESULT_UNKNOWN; int nle; char s_buf[256]; nm_assert (NM_IN_SET (NMP_OBJECT_GET_TYPE (obj_id), NMP_OBJECT_TYPE_IP4_ADDRESS, NMP_OBJECT_TYPE_IP6_ADDRESS, NMP_OBJECT_TYPE_IP4_ROUTE, NMP_OBJECT_TYPE_IP6_ROUTE)); event_handler_read_netlink (platform, FALSE); nle = _nl_send_nlmsg (platform, nlmsg, &seq_result, DELAYED_ACTION_RESPONSE_TYPE_VOID, NULL); if (nle < 0) { _LOGE ("do-add-%s[%s]: failure sending netlink request \"%s\" (%d)", NMP_OBJECT_GET_CLASS (obj_id)->obj_type_name, nmp_object_to_string (obj_id, NMP_OBJECT_TO_STRING_ID, NULL, 0), nl_geterror (nle), -nle); return NM_PLATFORM_ERROR_NETLINK; } delayed_action_handle_all (platform, FALSE); nm_assert (seq_result); _NMLOG (( seq_result == WAIT_FOR_NL_RESPONSE_RESULT_RESPONSE_OK || ( suppress_netlink_failure && seq_result < 0)) ? LOGL_DEBUG : LOGL_WARN, "do-add-%s[%s]: %s", NMP_OBJECT_GET_CLASS (obj_id)->obj_type_name, nmp_object_to_string (obj_id, NMP_OBJECT_TO_STRING_ID, NULL, 0), wait_for_nl_response_to_string (seq_result, s_buf, sizeof (s_buf))); if (NMP_OBJECT_GET_TYPE (obj_id) == NMP_OBJECT_TYPE_IP6_ADDRESS) { /* In rare cases, the object is not yet ready as we received the ACK from * kernel. Need to refetch. * * We want to safe the expensive refetch, thus we look first into the cache * whether the object exists. * * rh#1484434 */ if (!nmp_cache_lookup_obj (nm_platform_get_cache (platform), obj_id)) do_request_one_type (platform, NMP_OBJECT_GET_TYPE (obj_id)); } return wait_for_nl_response_to_plerr (seq_result); } static gboolean do_delete_object (NMPlatform *platform, const NMPObject *obj_id, struct nl_msg *nlmsg) { WaitForNlResponseResult seq_result = WAIT_FOR_NL_RESPONSE_RESULT_UNKNOWN; int nle; char s_buf[256]; gboolean success; const char *log_detail = ""; event_handler_read_netlink (platform, FALSE); nle = _nl_send_nlmsg (platform, nlmsg, &seq_result, DELAYED_ACTION_RESPONSE_TYPE_VOID, NULL); if (nle < 0) { _LOGE ("do-delete-%s[%s]: failure sending netlink request \"%s\" (%d)", NMP_OBJECT_GET_CLASS (obj_id)->obj_type_name, nmp_object_to_string (obj_id, NMP_OBJECT_TO_STRING_ID, NULL, 0), nl_geterror (nle), -nle); return FALSE; } delayed_action_handle_all (platform, FALSE); nm_assert (seq_result); success = TRUE; if (seq_result == WAIT_FOR_NL_RESPONSE_RESULT_RESPONSE_OK) { /* ok */ } else if (NM_IN_SET (-((int) seq_result), ESRCH, ENOENT)) log_detail = ", meaning the object was already removed"; else if ( NM_IN_SET (-((int) seq_result), ENXIO) && NM_IN_SET (NMP_OBJECT_GET_TYPE (obj_id), NMP_OBJECT_TYPE_IP6_ADDRESS)) { /* On RHEL7 kernel, deleting a non existing address fails with ENXIO */ log_detail = ", meaning the address was already removed"; } else if ( NM_IN_SET (-((int) seq_result), EADDRNOTAVAIL) && NM_IN_SET (NMP_OBJECT_GET_TYPE (obj_id), NMP_OBJECT_TYPE_IP4_ADDRESS, NMP_OBJECT_TYPE_IP6_ADDRESS)) log_detail = ", meaning the address was already removed"; else success = FALSE; _NMLOG (success ? LOGL_DEBUG : LOGL_WARN, "do-delete-%s[%s]: %s%s", NMP_OBJECT_GET_CLASS (obj_id)->obj_type_name, nmp_object_to_string (obj_id, NMP_OBJECT_TO_STRING_ID, NULL, 0), wait_for_nl_response_to_string (seq_result, s_buf, sizeof (s_buf)), log_detail); if (NMP_OBJECT_GET_TYPE (obj_id) == NMP_OBJECT_TYPE_IP6_ADDRESS) { /* In rare cases, the object is still there after we receive the ACK from * kernel. Need to refetch. * * We want to safe the expensive refetch, thus we look first into the cache * whether the object exists. * * rh#1484434 */ if (nmp_cache_lookup_obj (nm_platform_get_cache (platform), obj_id)) do_request_one_type (platform, NMP_OBJECT_GET_TYPE (obj_id)); } return success; } static WaitForNlResponseResult do_change_link_request (NMPlatform *platform, int ifindex, struct nl_msg *nlmsg) { nm_auto_pop_netns NMPNetns *netns = NULL; WaitForNlResponseResult seq_result = WAIT_FOR_NL_RESPONSE_RESULT_UNKNOWN; int nle; if (!nm_platform_netns_push (platform, &netns)) return WAIT_FOR_NL_RESPONSE_RESULT_UNKNOWN; retry: nle = _nl_send_nlmsg (platform, nlmsg, &seq_result, DELAYED_ACTION_RESPONSE_TYPE_VOID, NULL); if (nle < 0) { _LOGE ("do-change-link[%d]: failure sending netlink request \"%s\" (%d)", ifindex, nl_geterror (nle), -nle); return WAIT_FOR_NL_RESPONSE_RESULT_UNKNOWN; } /* always refetch the link after changing it. There seems to be issues * and we sometimes lack events. Nuke it from the orbit... */ delayed_action_schedule (platform, DELAYED_ACTION_TYPE_REFRESH_LINK, GINT_TO_POINTER (ifindex)); delayed_action_handle_all (platform, FALSE); nm_assert (seq_result); if ( NM_IN_SET (-((int) seq_result), EOPNOTSUPP) && nlmsg_hdr (nlmsg)->nlmsg_type == RTM_NEWLINK) { nlmsg_hdr (nlmsg)->nlmsg_type = RTM_SETLINK; goto retry; } return seq_result; } static NMPlatformError do_change_link_result (NMPlatform *platform, int ifindex, WaitForNlResponseResult seq_result) { char s_buf[256]; NMPlatformError result = NM_PLATFORM_ERROR_SUCCESS; NMLogLevel log_level = LOGL_DEBUG; const char *log_result = "failure", *log_detail = ""; if (seq_result == WAIT_FOR_NL_RESPONSE_RESULT_RESPONSE_OK) { log_result = "success"; } else if (NM_IN_SET (-((int) seq_result), EEXIST, EADDRINUSE)) { /* */ } else if (NM_IN_SET (-((int) seq_result), ESRCH, ENOENT)) { log_detail = ", firmware not found"; result = NM_PLATFORM_ERROR_NO_FIRMWARE; } else if (NM_IN_SET (-((int) seq_result), ENODEV)) { log_level = LOGL_DEBUG; result = NM_PLATFORM_ERROR_NOT_FOUND; } else { log_level = LOGL_WARN; result = NM_PLATFORM_ERROR_UNSPECIFIED; } _NMLOG (log_level, "do-change-link[%d]: %s changing link: %s%s", ifindex, log_result, wait_for_nl_response_to_string (seq_result, s_buf, sizeof (s_buf)), log_detail); return result; } static NMPlatformError do_change_link (NMPlatform *platform, int ifindex, struct nl_msg *nlmsg) { WaitForNlResponseResult seq_result; seq_result = do_change_link_request (platform, ifindex, nlmsg); return do_change_link_result (platform, ifindex, seq_result); } static gboolean link_add (NMPlatform *platform, const char *name, NMLinkType type, const char *veth_peer, const void *address, size_t address_len, const NMPlatformLink **out_link) { nm_auto_nlmsg struct nl_msg *nlmsg = NULL; if (type == NM_LINK_TYPE_BOND) { /* When the kernel loads the bond module, either via explicit modprobe * or automatically in response to creating a bond master, it will also * create a 'bond0' interface. Since the bond we're about to create may * or may not be named 'bond0' prevent potential confusion about a bond * that the user didn't want by telling the bonding module not to create * bond0 automatically. */ if (!g_file_test ("/sys/class/net/bonding_masters", G_FILE_TEST_EXISTS)) (void) nm_utils_modprobe (NULL, TRUE, "bonding", "max_bonds=0", NULL); } nlmsg = _nl_msg_new_link (RTM_NEWLINK, NLM_F_CREATE | NLM_F_EXCL, 0, name, 0, 0); if (!nlmsg) return FALSE; if (address && address_len) NLA_PUT (nlmsg, IFLA_ADDRESS, address_len, address); if (!_nl_msg_new_link_set_linkinfo (nlmsg, type, veth_peer)) return FALSE; return do_add_link_with_lookup (platform, type, name, nlmsg, out_link); nla_put_failure: g_return_val_if_reached (FALSE); } static gboolean link_delete (NMPlatform *platform, int ifindex) { nm_auto_nlmsg struct nl_msg *nlmsg = NULL; NMPObject obj_id; const NMPObject *obj; obj = nmp_cache_lookup_link (nm_platform_get_cache (platform), ifindex); if (!obj || !obj->_link.netlink.is_in_netlink) return FALSE; nlmsg = _nl_msg_new_link (RTM_DELLINK, 0, ifindex, NULL, 0, 0); nmp_object_stackinit_id_link (&obj_id, ifindex); return do_delete_object (platform, &obj_id, nlmsg); } static gboolean link_refresh (NMPlatform *platform, int ifindex) { do_request_link (platform, ifindex, NULL); return !!nm_platform_link_get_obj (platform, ifindex, TRUE); } static gboolean link_set_netns (NMPlatform *platform, int ifindex, int netns_fd) { nm_auto_nlmsg struct nl_msg *nlmsg = NULL; _LOGD ("link: move link %d to network namespace with fd %d", ifindex, netns_fd); nlmsg = _nl_msg_new_link (RTM_NEWLINK, 0, ifindex, NULL, 0, 0); if (!nlmsg) return FALSE; NLA_PUT (nlmsg, IFLA_NET_NS_FD, 4, &netns_fd); return do_change_link (platform, ifindex, nlmsg) == NM_PLATFORM_ERROR_SUCCESS; nla_put_failure: g_return_val_if_reached (FALSE); } static NMPlatformError link_change_flags (NMPlatform *platform, int ifindex, unsigned flags_mask, unsigned flags_set) { nm_auto_nlmsg struct nl_msg *nlmsg = NULL; char s_flags[100]; _LOGD ("link: change %d: flags: set 0x%x/0x%x ([%s] / [%s])", ifindex, flags_set, flags_mask, nm_platform_link_flags2str (flags_set, s_flags, sizeof (s_flags)), nm_platform_link_flags2str (flags_mask, NULL, 0)); nlmsg = _nl_msg_new_link (RTM_NEWLINK, 0, ifindex, NULL, flags_mask, flags_set); if (!nlmsg) return NM_PLATFORM_ERROR_UNSPECIFIED; return do_change_link (platform, ifindex, nlmsg); } static gboolean link_set_up (NMPlatform *platform, int ifindex, gboolean *out_no_firmware) { NMPlatformError plerr; plerr = link_change_flags (platform, ifindex, IFF_UP, IFF_UP); if (out_no_firmware) *out_no_firmware = plerr == NM_PLATFORM_ERROR_NO_FIRMWARE; return plerr == NM_PLATFORM_ERROR_SUCCESS; } static gboolean link_set_down (NMPlatform *platform, int ifindex) { return link_change_flags (platform, ifindex, IFF_UP, 0) == NM_PLATFORM_ERROR_SUCCESS; } static gboolean link_set_arp (NMPlatform *platform, int ifindex) { return link_change_flags (platform, ifindex, IFF_NOARP, 0) == NM_PLATFORM_ERROR_SUCCESS; } static gboolean link_set_noarp (NMPlatform *platform, int ifindex) { return link_change_flags (platform, ifindex, IFF_NOARP, IFF_NOARP) == NM_PLATFORM_ERROR_SUCCESS; } static const char * link_get_udi (NMPlatform *platform, int ifindex) { const NMPObject *obj = nm_platform_link_get_obj (platform, ifindex, TRUE); if ( !obj || !obj->_link.netlink.is_in_netlink || !obj->_link.udev.device) return NULL; return udev_device_get_syspath (obj->_link.udev.device); } static NMPlatformError link_set_user_ipv6ll_enabled (NMPlatform *platform, int ifindex, gboolean enabled) { nm_auto_nlmsg struct nl_msg *nlmsg = NULL; guint8 mode = enabled ? NM_IN6_ADDR_GEN_MODE_NONE : NM_IN6_ADDR_GEN_MODE_EUI64; _LOGD ("link: change %d: user-ipv6ll: set IPv6 address generation mode to %s", ifindex, nm_platform_link_inet6_addrgenmode2str (mode, NULL, 0)); if (!_support_user_ipv6ll_get ()) { _LOGD ("link: change %d: user-ipv6ll: not supported", ifindex); return NM_PLATFORM_ERROR_OPNOTSUPP; } nlmsg = _nl_msg_new_link (RTM_NEWLINK, 0, ifindex, NULL, 0, 0); if ( !nlmsg || !_nl_msg_new_link_set_afspec (nlmsg, mode, NULL)) g_return_val_if_reached (NM_PLATFORM_ERROR_BUG); return do_change_link (platform, ifindex, nlmsg); } static gboolean link_set_token (NMPlatform *platform, int ifindex, NMUtilsIPv6IfaceId iid) { nm_auto_nlmsg struct nl_msg *nlmsg = NULL; _LOGD ("link: change %d: token: set IPv6 address generation token to %s", ifindex, nm_utils_inet6_interface_identifier_to_token (iid, NULL)); nlmsg = _nl_msg_new_link (RTM_NEWLINK, 0, ifindex, NULL, 0, 0); if (!nlmsg || !_nl_msg_new_link_set_afspec (nlmsg, -1, &iid)) g_return_val_if_reached (FALSE); return do_change_link (platform, ifindex, nlmsg) == NM_PLATFORM_ERROR_SUCCESS; } static gboolean link_supports_carrier_detect (NMPlatform *platform, int ifindex) { nm_auto_pop_netns NMPNetns *netns = NULL; if (!nm_platform_netns_push (platform, &netns)) return FALSE; /* We use netlink for the actual carrier detection, but netlink can't tell * us whether the device actually supports carrier detection in the first * place. We assume any device that does implements one of these two APIs. */ return nmp_utils_ethtool_supports_carrier_detect (ifindex) || nmp_utils_mii_supports_carrier_detect (ifindex); } static gboolean link_supports_vlans (NMPlatform *platform, int ifindex) { nm_auto_pop_netns NMPNetns *netns = NULL; const NMPObject *obj; obj = nm_platform_link_get_obj (platform, ifindex, TRUE); /* Only ARPHRD_ETHER links can possibly support VLANs. */ if (!obj || obj->link.arptype != ARPHRD_ETHER) return FALSE; if (!nm_platform_netns_push (platform, &netns)) return FALSE; return nmp_utils_ethtool_supports_vlans (ifindex); } static gboolean link_supports_sriov (NMPlatform *platform, int ifindex) { nm_auto_pop_netns NMPNetns *netns = NULL; nm_auto_close int dirfd = -1; char ifname[IFNAMSIZ]; int total = -1; if (!nm_platform_netns_push (platform, &netns)) return FALSE; dirfd = nm_platform_sysctl_open_netdir (platform, ifindex, ifname); if (dirfd < 0) return FALSE; total = nm_platform_sysctl_get_int32 (platform, NMP_SYSCTL_PATHID_NETDIR (dirfd, ifname, "device/sriov_totalvfs"), -1); return total > 0; } static NMPlatformError link_set_address (NMPlatform *platform, int ifindex, gconstpointer address, size_t length) { nm_auto_nlmsg struct nl_msg *nlmsg = NULL; gs_free char *mac = NULL; WaitForNlResponseResult seq_result; char s_buf[256]; if (!address || !length) g_return_val_if_reached (NM_PLATFORM_ERROR_BUG); _LOGD ("link: change %d: address: %s (%lu bytes)", ifindex, (mac = nm_utils_hwaddr_ntoa (address, length)), (unsigned long) length); nlmsg = _nl_msg_new_link (RTM_NEWLINK, 0, ifindex, NULL, 0, 0); if (!nlmsg) g_return_val_if_reached (NM_PLATFORM_ERROR_UNSPECIFIED); NLA_PUT (nlmsg, IFLA_ADDRESS, length, address); seq_result = do_change_link_request (platform, ifindex, nlmsg); if (NM_IN_SET (-((int) seq_result), ENFILE)) { const NMPObject *obj_cache; /* workaround ENFILE which may be wrongly returned (bgo #770456). * If the MAC address is as expected, assume success? */ obj_cache = nmp_cache_lookup_link (nm_platform_get_cache (platform), ifindex); if ( obj_cache && obj_cache->link.addr.len == length && memcmp (obj_cache->link.addr.data, address, length) == 0) { _NMLOG (LOGL_DEBUG, "do-change-link[%d]: %s changing link: %s%s", ifindex, "success", wait_for_nl_response_to_string (seq_result, s_buf, sizeof (s_buf)), " (assume success changing address)"); return NM_PLATFORM_ERROR_SUCCESS; } } return do_change_link_result (platform, ifindex, seq_result); nla_put_failure: g_return_val_if_reached (NM_PLATFORM_ERROR_UNSPECIFIED); } static NMPlatformError link_set_name (NMPlatform *platform, int ifindex, const char *name) { nm_auto_nlmsg struct nl_msg *nlmsg = NULL; _LOGD ("link: change %d: name: %s", ifindex, name); nlmsg = _nl_msg_new_link (RTM_NEWLINK, 0, ifindex, NULL, 0, 0); if (!nlmsg) g_return_val_if_reached (NM_PLATFORM_ERROR_UNSPECIFIED); NLA_PUT (nlmsg, IFLA_IFNAME, strlen (name) + 1, name); return do_change_link (platform, ifindex, nlmsg) == NM_PLATFORM_ERROR_SUCCESS; nla_put_failure: g_return_val_if_reached (FALSE); } static gboolean link_get_permanent_address (NMPlatform *platform, int ifindex, guint8 *buf, size_t *length) { nm_auto_pop_netns NMPNetns *netns = NULL; if (!nm_platform_netns_push (platform, &netns)) return FALSE; return nmp_utils_ethtool_get_permanent_address (ifindex, buf, length); } static gboolean link_set_mtu (NMPlatform *platform, int ifindex, guint32 mtu) { nm_auto_nlmsg struct nl_msg *nlmsg = NULL; _LOGD ("link: change %d: mtu: %u", ifindex, (unsigned) mtu); nlmsg = _nl_msg_new_link (RTM_NEWLINK, 0, ifindex, NULL, 0, 0); if (!nlmsg) return FALSE; NLA_PUT_U32 (nlmsg, IFLA_MTU, mtu); return do_change_link (platform, ifindex, nlmsg) == NM_PLATFORM_ERROR_SUCCESS; nla_put_failure: g_return_val_if_reached (FALSE); } static gboolean link_set_sriov_num_vfs (NMPlatform *platform, int ifindex, guint num_vfs) { nm_auto_pop_netns NMPNetns *netns = NULL; nm_auto_close int dirfd = -1; int total, current; char ifname[IFNAMSIZ]; char buf[64]; _LOGD ("link: change %d: num VFs: %u", ifindex, num_vfs); if (!nm_platform_netns_push (platform, &netns)) return FALSE; dirfd = nm_platform_sysctl_open_netdir (platform, ifindex, ifname); if (!dirfd) return FALSE; total = nm_platform_sysctl_get_int32 (platform, NMP_SYSCTL_PATHID_NETDIR (dirfd, ifname, "device/sriov_totalvfs"), -1); if (total < 1) return FALSE; if (num_vfs > total) { _LOGW ("link: %d only supports %u VFs (requested %u)", ifindex, total, num_vfs); num_vfs = total; } current = nm_platform_sysctl_get_int32 (platform, NMP_SYSCTL_PATHID_NETDIR (dirfd, ifname, "device/sriov_numvfs"), -1); if (current == num_vfs) return TRUE; if (current != 0) { /* We need to destroy all other VFs before changing the value */ if (!nm_platform_sysctl_set (NM_PLATFORM_GET, NMP_SYSCTL_PATHID_NETDIR (dirfd, ifname, "device/sriov_numvfs"), "0")) { _LOGW ("link: couldn't set SR-IOV num_vfs to %d: %s", 0, strerror (errno)); return FALSE; } if (num_vfs == 0) return TRUE; } /* Finally, set the desired value */ if (!nm_platform_sysctl_set (NM_PLATFORM_GET, NMP_SYSCTL_PATHID_NETDIR (dirfd, ifname, "device/sriov_numvfs"), nm_sprintf_buf (buf, "%d", num_vfs))) { _LOGW ("link: couldn't set SR-IOV num_vfs to %d: %s", num_vfs, strerror (errno)); return FALSE; } return TRUE; } static char * link_get_physical_port_id (NMPlatform *platform, int ifindex) { nm_auto_close int dirfd = -1; char ifname_verified[IFNAMSIZ]; dirfd = nm_platform_sysctl_open_netdir (platform, ifindex, ifname_verified); if (dirfd < 0) return NULL; return sysctl_get (platform, NMP_SYSCTL_PATHID_NETDIR (dirfd, ifname_verified, "phys_port_id")); } static guint link_get_dev_id (NMPlatform *platform, int ifindex) { nm_auto_close int dirfd = -1; char ifname_verified[IFNAMSIZ]; dirfd = nm_platform_sysctl_open_netdir (platform, ifindex, ifname_verified); if (dirfd < 0) return 0; return nm_platform_sysctl_get_int_checked (platform, NMP_SYSCTL_PATHID_NETDIR (dirfd, ifname_verified, "dev_id"), 16, 0, G_MAXUINT16, 0); } static int vlan_add (NMPlatform *platform, const char *name, int parent, int vlan_id, guint32 vlan_flags, const NMPlatformLink **out_link) { nm_auto_nlmsg struct nl_msg *nlmsg = NULL; G_STATIC_ASSERT (NM_VLAN_FLAG_REORDER_HEADERS == (guint32) VLAN_FLAG_REORDER_HDR); G_STATIC_ASSERT (NM_VLAN_FLAG_GVRP == (guint32) VLAN_FLAG_GVRP); G_STATIC_ASSERT (NM_VLAN_FLAG_LOOSE_BINDING == (guint32) VLAN_FLAG_LOOSE_BINDING); G_STATIC_ASSERT (NM_VLAN_FLAG_MVRP == (guint32) VLAN_FLAG_MVRP); vlan_flags &= (guint32) NM_VLAN_FLAGS_ALL; _LOGD ("link: add vlan '%s', parent %d, vlan id %d, flags %X", name, parent, vlan_id, (unsigned) vlan_flags); nlmsg = _nl_msg_new_link (RTM_NEWLINK, NLM_F_CREATE | NLM_F_EXCL, 0, name, 0, 0); if (!nlmsg) return FALSE; NLA_PUT_U32 (nlmsg, IFLA_LINK, parent); if (!_nl_msg_new_link_set_linkinfo_vlan (nlmsg, vlan_id, NM_VLAN_FLAGS_ALL, vlan_flags, NULL, 0, NULL, 0)) return FALSE; return do_add_link_with_lookup (platform, NM_LINK_TYPE_VLAN, name, nlmsg, out_link); nla_put_failure: g_return_val_if_reached (FALSE); } static int link_gre_add (NMPlatform *platform, const char *name, const NMPlatformLnkGre *props, const NMPlatformLink **out_link) { nm_auto_nlmsg struct nl_msg *nlmsg = NULL; struct nlattr *info; struct nlattr *data; char buffer[INET_ADDRSTRLEN]; _LOGD (LOG_FMT_IP_TUNNEL, "gre", name, props->parent_ifindex, nm_utils_inet4_ntop (props->local, NULL), nm_utils_inet4_ntop (props->remote, buffer)); nlmsg = _nl_msg_new_link (RTM_NEWLINK, NLM_F_CREATE | NLM_F_EXCL, 0, name, 0, 0); if (!nlmsg) return FALSE; if (!(info = nla_nest_start (nlmsg, IFLA_LINKINFO))) goto nla_put_failure; NLA_PUT_STRING (nlmsg, IFLA_INFO_KIND, "gre"); if (!(data = nla_nest_start (nlmsg, IFLA_INFO_DATA))) goto nla_put_failure; if (props->parent_ifindex) NLA_PUT_U32 (nlmsg, IFLA_GRE_LINK, props->parent_ifindex); NLA_PUT_U32 (nlmsg, IFLA_GRE_LOCAL, props->local); NLA_PUT_U32 (nlmsg, IFLA_GRE_REMOTE, props->remote); NLA_PUT_U8 (nlmsg, IFLA_GRE_TTL, props->ttl); NLA_PUT_U8 (nlmsg, IFLA_GRE_TOS, props->tos); NLA_PUT_U8 (nlmsg, IFLA_GRE_PMTUDISC, !!props->path_mtu_discovery); NLA_PUT_U32 (nlmsg, IFLA_GRE_IKEY, htonl (props->input_key)); NLA_PUT_U32 (nlmsg, IFLA_GRE_OKEY, htonl (props->output_key)); NLA_PUT_U32 (nlmsg, IFLA_GRE_IFLAGS, htons (props->input_flags)); NLA_PUT_U32 (nlmsg, IFLA_GRE_OFLAGS, htons (props->output_flags)); nla_nest_end (nlmsg, data); nla_nest_end (nlmsg, info); return do_add_link_with_lookup (platform, NM_LINK_TYPE_GRE, name, nlmsg, out_link); nla_put_failure: g_return_val_if_reached (FALSE); } static int link_ip6tnl_add (NMPlatform *platform, const char *name, const NMPlatformLnkIp6Tnl *props, const NMPlatformLink **out_link) { nm_auto_nlmsg struct nl_msg *nlmsg = NULL; struct nlattr *info; struct nlattr *data; char buffer[INET_ADDRSTRLEN]; guint32 flowinfo; _LOGD (LOG_FMT_IP_TUNNEL, "ip6tnl", name, props->parent_ifindex, nm_utils_inet6_ntop (&props->local, NULL), nm_utils_inet6_ntop (&props->remote, buffer)); nlmsg = _nl_msg_new_link (RTM_NEWLINK, NLM_F_CREATE | NLM_F_EXCL, 0, name, 0, 0); if (!nlmsg) return FALSE; if (!(info = nla_nest_start (nlmsg, IFLA_LINKINFO))) goto nla_put_failure; NLA_PUT_STRING (nlmsg, IFLA_INFO_KIND, "ip6tnl"); if (!(data = nla_nest_start (nlmsg, IFLA_INFO_DATA))) goto nla_put_failure; if (props->parent_ifindex) NLA_PUT_U32 (nlmsg, IFLA_IPTUN_LINK, props->parent_ifindex); if (memcmp (&props->local, &in6addr_any, sizeof (in6addr_any))) NLA_PUT (nlmsg, IFLA_IPTUN_LOCAL, sizeof (props->local), &props->local); if (memcmp (&props->remote, &in6addr_any, sizeof (in6addr_any))) NLA_PUT (nlmsg, IFLA_IPTUN_REMOTE, sizeof (props->remote), &props->remote); NLA_PUT_U8 (nlmsg, IFLA_IPTUN_TTL, props->ttl); NLA_PUT_U8 (nlmsg, IFLA_IPTUN_ENCAP_LIMIT, props->encap_limit); flowinfo = props->flow_label & IP6_FLOWINFO_FLOWLABEL_MASK; flowinfo |= (props->tclass << IP6_FLOWINFO_TCLASS_SHIFT) & IP6_FLOWINFO_TCLASS_MASK; NLA_PUT_U32 (nlmsg, IFLA_IPTUN_FLOWINFO, htonl (flowinfo)); NLA_PUT_U8 (nlmsg, IFLA_IPTUN_PROTO, props->proto); nla_nest_end (nlmsg, data); nla_nest_end (nlmsg, info); return do_add_link_with_lookup (platform, NM_LINK_TYPE_IP6TNL, name, nlmsg, out_link); nla_put_failure: g_return_val_if_reached (FALSE); } static int link_ipip_add (NMPlatform *platform, const char *name, const NMPlatformLnkIpIp *props, const NMPlatformLink **out_link) { nm_auto_nlmsg struct nl_msg *nlmsg = NULL; struct nlattr *info; struct nlattr *data; char buffer[INET_ADDRSTRLEN]; _LOGD (LOG_FMT_IP_TUNNEL, "ipip", name, props->parent_ifindex, nm_utils_inet4_ntop (props->local, NULL), nm_utils_inet4_ntop (props->remote, buffer)); nlmsg = _nl_msg_new_link (RTM_NEWLINK, NLM_F_CREATE | NLM_F_EXCL, 0, name, 0, 0); if (!nlmsg) return FALSE; if (!(info = nla_nest_start (nlmsg, IFLA_LINKINFO))) goto nla_put_failure; NLA_PUT_STRING (nlmsg, IFLA_INFO_KIND, "ipip"); if (!(data = nla_nest_start (nlmsg, IFLA_INFO_DATA))) goto nla_put_failure; if (props->parent_ifindex) NLA_PUT_U32 (nlmsg, IFLA_IPTUN_LINK, props->parent_ifindex); NLA_PUT_U32 (nlmsg, IFLA_IPTUN_LOCAL, props->local); NLA_PUT_U32 (nlmsg, IFLA_IPTUN_REMOTE, props->remote); NLA_PUT_U8 (nlmsg, IFLA_IPTUN_TTL, props->ttl); NLA_PUT_U8 (nlmsg, IFLA_IPTUN_TOS, props->tos); NLA_PUT_U8 (nlmsg, IFLA_IPTUN_PMTUDISC, !!props->path_mtu_discovery); nla_nest_end (nlmsg, data); nla_nest_end (nlmsg, info); return do_add_link_with_lookup (platform, NM_LINK_TYPE_IPIP, name, nlmsg, out_link); nla_put_failure: g_return_val_if_reached (FALSE); } static int link_macsec_add (NMPlatform *platform, const char *name, int parent, const NMPlatformLnkMacsec *props, const NMPlatformLink **out_link) { nm_auto_nlmsg struct nl_msg *nlmsg = NULL; struct nlattr *info; struct nlattr *data; _LOGD ("adding macsec '%s' parent %u sci %llx", name, parent, (unsigned long long) props->sci); nlmsg = _nl_msg_new_link (RTM_NEWLINK, NLM_F_CREATE | NLM_F_EXCL, 0, name, 0, 0); if (!nlmsg) return FALSE; NLA_PUT_U32 (nlmsg, IFLA_LINK, parent); if (!(info = nla_nest_start (nlmsg, IFLA_LINKINFO))) goto nla_put_failure; NLA_PUT_STRING (nlmsg, IFLA_INFO_KIND, "macsec"); if (!(data = nla_nest_start (nlmsg, IFLA_INFO_DATA))) goto nla_put_failure; if (props->icv_length) NLA_PUT_U8 (nlmsg, IFLA_MACSEC_ICV_LEN, 16); if (props->cipher_suite) NLA_PUT_U64 (nlmsg, IFLA_MACSEC_CIPHER_SUITE, props->cipher_suite); if (props->replay_protect) NLA_PUT_U32 (nlmsg, IFLA_MACSEC_WINDOW, props->window); NLA_PUT_U64 (nlmsg, IFLA_MACSEC_SCI, htobe64 (props->sci)); NLA_PUT_U8 (nlmsg, IFLA_MACSEC_ENCODING_SA, props->encoding_sa); NLA_PUT_U8 (nlmsg, IFLA_MACSEC_ENCRYPT, props->encrypt); NLA_PUT_U8 (nlmsg, IFLA_MACSEC_PROTECT, props->protect); NLA_PUT_U8 (nlmsg, IFLA_MACSEC_INC_SCI, props->include_sci); NLA_PUT_U8 (nlmsg, IFLA_MACSEC_ES, props->es); NLA_PUT_U8 (nlmsg, IFLA_MACSEC_SCB, props->scb); NLA_PUT_U8 (nlmsg, IFLA_MACSEC_REPLAY_PROTECT, props->replay_protect); NLA_PUT_U8 (nlmsg, IFLA_MACSEC_VALIDATION, props->validation); nla_nest_end (nlmsg, data); nla_nest_end (nlmsg, info); return do_add_link_with_lookup (platform, NM_LINK_TYPE_MACSEC, name, nlmsg, out_link); nla_put_failure: g_return_val_if_reached (FALSE); } static int link_macvlan_add (NMPlatform *platform, const char *name, int parent, const NMPlatformLnkMacvlan *props, const NMPlatformLink **out_link) { nm_auto_nlmsg struct nl_msg *nlmsg = NULL; struct nlattr *info; struct nlattr *data; _LOGD ("adding %s '%s' parent %u mode %u", props->tap ? "macvtap" : "macvlan", name, parent, props->mode); nlmsg = _nl_msg_new_link (RTM_NEWLINK, NLM_F_CREATE | NLM_F_EXCL, 0, name, 0, 0); if (!nlmsg) return FALSE; NLA_PUT_U32 (nlmsg, IFLA_LINK, parent); if (!(info = nla_nest_start (nlmsg, IFLA_LINKINFO))) goto nla_put_failure; NLA_PUT_STRING (nlmsg, IFLA_INFO_KIND, props->tap ? "macvtap" : "macvlan"); if (!(data = nla_nest_start (nlmsg, IFLA_INFO_DATA))) goto nla_put_failure; NLA_PUT_U32 (nlmsg, IFLA_MACVLAN_MODE, props->mode); NLA_PUT_U16 (nlmsg, IFLA_MACVLAN_FLAGS, props->no_promisc ? MACVLAN_FLAG_NOPROMISC : 0); nla_nest_end (nlmsg, data); nla_nest_end (nlmsg, info); return do_add_link_with_lookup (platform, props->tap ? NM_LINK_TYPE_MACVTAP : NM_LINK_TYPE_MACVLAN, name, nlmsg, out_link); nla_put_failure: g_return_val_if_reached (FALSE); } static int link_sit_add (NMPlatform *platform, const char *name, const NMPlatformLnkSit *props, const NMPlatformLink **out_link) { nm_auto_nlmsg struct nl_msg *nlmsg = NULL; struct nlattr *info; struct nlattr *data; char buffer[INET_ADDRSTRLEN]; _LOGD (LOG_FMT_IP_TUNNEL, "sit", name, props->parent_ifindex, nm_utils_inet4_ntop (props->local, NULL), nm_utils_inet4_ntop (props->remote, buffer)); nlmsg = _nl_msg_new_link (RTM_NEWLINK, NLM_F_CREATE | NLM_F_EXCL, 0, name, 0, 0); if (!nlmsg) return FALSE; if (!(info = nla_nest_start (nlmsg, IFLA_LINKINFO))) goto nla_put_failure; NLA_PUT_STRING (nlmsg, IFLA_INFO_KIND, "sit"); if (!(data = nla_nest_start (nlmsg, IFLA_INFO_DATA))) goto nla_put_failure; if (props->parent_ifindex) NLA_PUT_U32 (nlmsg, IFLA_IPTUN_LINK, props->parent_ifindex); NLA_PUT_U32 (nlmsg, IFLA_IPTUN_LOCAL, props->local); NLA_PUT_U32 (nlmsg, IFLA_IPTUN_REMOTE, props->remote); NLA_PUT_U8 (nlmsg, IFLA_IPTUN_TTL, props->ttl); NLA_PUT_U8 (nlmsg, IFLA_IPTUN_TOS, props->tos); NLA_PUT_U8 (nlmsg, IFLA_IPTUN_PMTUDISC, !!props->path_mtu_discovery); nla_nest_end (nlmsg, data); nla_nest_end (nlmsg, info); return do_add_link_with_lookup (platform, NM_LINK_TYPE_SIT, name, nlmsg, out_link); nla_put_failure: g_return_val_if_reached (FALSE); } static gboolean link_vxlan_add (NMPlatform *platform, const char *name, const NMPlatformLnkVxlan *props, const NMPlatformLink **out_link) { nm_auto_nlmsg struct nl_msg *nlmsg = NULL; struct nlattr *info; struct nlattr *data; struct nm_ifla_vxlan_port_range port_range; g_return_val_if_fail (props, FALSE); _LOGD ("link: add vxlan '%s', parent %d, vxlan id %d", name, props->parent_ifindex, props->id); nlmsg = _nl_msg_new_link (RTM_NEWLINK, NLM_F_CREATE | NLM_F_EXCL, 0, name, 0, 0); if (!nlmsg) return FALSE; if (!(info = nla_nest_start (nlmsg, IFLA_LINKINFO))) goto nla_put_failure; NLA_PUT_STRING (nlmsg, IFLA_INFO_KIND, "vxlan"); if (!(data = nla_nest_start (nlmsg, IFLA_INFO_DATA))) goto nla_put_failure; NLA_PUT_U32 (nlmsg, IFLA_VXLAN_ID, props->id); if (props->group) NLA_PUT (nlmsg, IFLA_VXLAN_GROUP, sizeof (props->group), &props->group); else if (memcmp (&props->group6, &in6addr_any, sizeof (in6addr_any))) NLA_PUT (nlmsg, IFLA_VXLAN_GROUP6, sizeof (props->group6), &props->group6); if (props->local) NLA_PUT (nlmsg, IFLA_VXLAN_LOCAL, sizeof (props->local), &props->local); else if (memcmp (&props->local6, &in6addr_any, sizeof (in6addr_any))) NLA_PUT (nlmsg, IFLA_VXLAN_LOCAL6, sizeof (props->local6), &props->local6); if (props->parent_ifindex >= 0) NLA_PUT_U32 (nlmsg, IFLA_VXLAN_LINK, props->parent_ifindex); if (props->src_port_min || props->src_port_max) { port_range.low = htons (props->src_port_min); port_range.high = htons (props->src_port_max); NLA_PUT (nlmsg, IFLA_VXLAN_PORT_RANGE, sizeof (port_range), &port_range); } NLA_PUT_U16 (nlmsg, IFLA_VXLAN_PORT, htons (props->dst_port)); NLA_PUT_U8 (nlmsg, IFLA_VXLAN_TOS, props->tos); NLA_PUT_U8 (nlmsg, IFLA_VXLAN_TTL, props->ttl); NLA_PUT_U32 (nlmsg, IFLA_VXLAN_AGEING, props->ageing); NLA_PUT_U32 (nlmsg, IFLA_VXLAN_LIMIT, props->limit); NLA_PUT_U8 (nlmsg, IFLA_VXLAN_LEARNING, !!props->learning); NLA_PUT_U8 (nlmsg, IFLA_VXLAN_PROXY, !!props->proxy); NLA_PUT_U8 (nlmsg, IFLA_VXLAN_RSC, !!props->rsc); NLA_PUT_U8 (nlmsg, IFLA_VXLAN_L2MISS, !!props->l2miss); NLA_PUT_U8 (nlmsg, IFLA_VXLAN_L3MISS, !!props->l3miss); nla_nest_end (nlmsg, data); nla_nest_end (nlmsg, info); return do_add_link_with_lookup (platform, NM_LINK_TYPE_VXLAN, name, nlmsg, out_link); nla_put_failure: g_return_val_if_reached (FALSE); } static void _vlan_change_vlan_qos_mapping_create (gboolean is_ingress_map, gboolean reset_all, const NMVlanQosMapping *current_map, guint current_n_map, const NMVlanQosMapping *set_map, guint set_n_map, NMVlanQosMapping **out_map, guint *out_n_map) { NMVlanQosMapping *map; guint i, j, len; const guint INGRESS_RANGE_LEN = 8; nm_assert (out_map && !*out_map); nm_assert (out_n_map && !*out_n_map); if (!reset_all) current_n_map = 0; else if (is_ingress_map) current_n_map = INGRESS_RANGE_LEN; len = current_n_map + set_n_map; if (len == 0) return; map = g_new (NMVlanQosMapping, len); if (current_n_map) { if (is_ingress_map) { /* For the ingress-map, there are only 8 entries (0 to 7). * When the user requests to reset all entries, we don't actually * need the cached entries, we can just explicitly clear all possible * ones. * * That makes only a real difference in case our cache is out-of-date. * * For the egress map we cannot do that, because there are far too * many. There we can only clear the entries that we know about. */ for (i = 0; i < INGRESS_RANGE_LEN; i++) { map[i].from = i; map[i].to = 0; } } else { for (i = 0; i < current_n_map; i++) { map[i].from = current_map[i].from; map[i].to = 0; } } } if (set_n_map) memcpy (&map[current_n_map], set_map, sizeof (*set_map) * set_n_map); g_qsort_with_data (map, len, sizeof (*map), _vlan_qos_mapping_cmp_from, NULL); for (i = 0, j = 0; i < len; i++) { if ( ( is_ingress_map && !VLAN_XGRESS_PRIO_VALID (map[i].from)) || (!is_ingress_map && !VLAN_XGRESS_PRIO_VALID (map[i].to))) continue; if ( j > 0 && map[j - 1].from == map[i].from) map[j - 1] = map[i]; else map[j++] = map[i]; } *out_map = map; *out_n_map = j; } static gboolean link_vlan_change (NMPlatform *platform, int ifindex, NMVlanFlags flags_mask, NMVlanFlags flags_set, gboolean ingress_reset_all, const NMVlanQosMapping *ingress_map, gsize n_ingress_map, gboolean egress_reset_all, const NMVlanQosMapping *egress_map, gsize n_egress_map) { const NMPObject *obj_cache; nm_auto_nlmsg struct nl_msg *nlmsg = NULL; const NMPObjectLnkVlan *lnk; guint new_n_ingress_map = 0; guint new_n_egress_map = 0; gs_free NMVlanQosMapping *new_ingress_map = NULL; gs_free NMVlanQosMapping *new_egress_map = NULL; char s_flags[64]; char s_ingress[256]; char s_egress[256]; obj_cache = nmp_cache_lookup_link (nm_platform_get_cache (platform), ifindex); if ( !obj_cache || !obj_cache->_link.netlink.is_in_netlink) { _LOGD ("link: change %d: %s: link does not exist", ifindex, "vlan"); return FALSE; } lnk = obj_cache->_link.netlink.lnk ? &obj_cache->_link.netlink.lnk->_lnk_vlan : NULL; flags_set &= flags_mask; _vlan_change_vlan_qos_mapping_create (TRUE, ingress_reset_all, lnk ? lnk->ingress_qos_map : NULL, lnk ? lnk->n_ingress_qos_map : 0, ingress_map, n_ingress_map, &new_ingress_map, &new_n_ingress_map); _vlan_change_vlan_qos_mapping_create (FALSE, egress_reset_all, lnk ? lnk->egress_qos_map : NULL, lnk ? lnk->n_egress_qos_map : 0, egress_map, n_egress_map, &new_egress_map, &new_n_egress_map); _LOGD ("link: change %d: vlan:%s%s%s", ifindex, flags_mask ? nm_sprintf_buf (s_flags, " flags 0x%x/0x%x", (unsigned) flags_set, (unsigned) flags_mask) : "", new_n_ingress_map ? nm_platform_vlan_qos_mapping_to_string (" ingress-qos-map", new_ingress_map, new_n_ingress_map, s_ingress, sizeof (s_ingress)) : "", new_n_egress_map ? nm_platform_vlan_qos_mapping_to_string (" egress-qos-map", new_egress_map, new_n_egress_map, s_egress, sizeof (s_egress)) : ""); nlmsg = _nl_msg_new_link (RTM_NEWLINK, 0, ifindex, NULL, 0, 0); if ( !nlmsg || !_nl_msg_new_link_set_linkinfo_vlan (nlmsg, -1, flags_mask, flags_set, new_ingress_map, new_n_ingress_map, new_egress_map, new_n_egress_map)) g_return_val_if_reached (FALSE); return do_change_link (platform, ifindex, nlmsg) == NM_PLATFORM_ERROR_SUCCESS; } static int tun_add (NMPlatform *platform, const char *name, gboolean tap, gint64 owner, gint64 group, gboolean pi, gboolean vnet_hdr, gboolean multi_queue, const NMPlatformLink **out_link) { const NMPObject *obj; struct ifreq ifr = { }; int fd; fd = open ("/dev/net/tun", O_RDWR | O_CLOEXEC); if (fd < 0) return FALSE; nm_utils_ifname_cpy (ifr.ifr_name, name); ifr.ifr_flags = tap ? IFF_TAP : IFF_TUN; if (!pi) ifr.ifr_flags |= IFF_NO_PI; if (vnet_hdr) ifr.ifr_flags |= IFF_VNET_HDR; if (multi_queue) ifr.ifr_flags |= NM_IFF_MULTI_QUEUE; if (ioctl (fd, TUNSETIFF, &ifr)) { close (fd); return FALSE; } if (owner >= 0 && owner < G_MAXINT32) { if (ioctl (fd, TUNSETOWNER, (uid_t) owner)) { close (fd); return FALSE; } } if (group >= 0 && group < G_MAXINT32) { if (ioctl (fd, TUNSETGROUP, (gid_t) group)) { close (fd); return FALSE; } } if (ioctl (fd, TUNSETPERSIST, 1)) { close (fd); return FALSE; } do_request_link (platform, 0, name); obj = nmp_cache_lookup_link_full (nm_platform_get_cache (platform), 0, name, FALSE, tap ? NM_LINK_TYPE_TAP : NM_LINK_TYPE_TUN, NULL, NULL); if (out_link) *out_link = obj ? &obj->link : NULL; close (fd); return !!obj; } static gboolean link_enslave (NMPlatform *platform, int master, int slave) { nm_auto_nlmsg struct nl_msg *nlmsg = NULL; int ifindex = slave; _LOGD ("link: change %d: enslave: master %d", slave, master); nlmsg = _nl_msg_new_link (RTM_NEWLINK, 0, ifindex, NULL, 0, 0); if (!nlmsg) return FALSE; NLA_PUT_U32 (nlmsg, IFLA_MASTER, master); return do_change_link (platform, ifindex, nlmsg) == NM_PLATFORM_ERROR_SUCCESS; nla_put_failure: g_return_val_if_reached (FALSE); } static gboolean link_release (NMPlatform *platform, int master, int slave) { return link_enslave (platform, 0, slave); } /*****************************************************************************/ static gboolean _infiniband_partition_action (NMPlatform *platform, InfinibandAction action, int parent, int p_key, const NMPlatformLink **out_link) { nm_auto_close int dirfd = -1; char ifname_parent[IFNAMSIZ]; const NMPObject *obj; char id[20]; char name[IFNAMSIZ]; gboolean success; nm_assert (NM_IN_SET (action, INFINIBAND_ACTION_CREATE_CHILD, INFINIBAND_ACTION_DELETE_CHILD)); nm_assert (p_key > 0 && p_key <= 0xffff && p_key != 0x8000); dirfd = nm_platform_sysctl_open_netdir (platform, parent, ifname_parent); if (dirfd < 0) { errno = ENOENT; return FALSE; } nm_sprintf_buf (id, "0x%04x", p_key); if (action == INFINIBAND_ACTION_CREATE_CHILD) success = nm_platform_sysctl_set (platform, NMP_SYSCTL_PATHID_NETDIR (dirfd, ifname_parent, "create_child"), id); else success = nm_platform_sysctl_set (platform, NMP_SYSCTL_PATHID_NETDIR (dirfd, ifname_parent, "delete_child"), id); if (!success) { if ( action == INFINIBAND_ACTION_DELETE_CHILD && errno == ENODEV) return TRUE; return FALSE; } nm_utils_new_infiniband_name (name, ifname_parent, p_key); do_request_link (platform, 0, name); if (action == INFINIBAND_ACTION_DELETE_CHILD) return TRUE; obj = nmp_cache_lookup_link_full (nm_platform_get_cache (platform), 0, name, FALSE, NM_LINK_TYPE_INFINIBAND, NULL, NULL); if (out_link) *out_link = obj ? &obj->link : NULL; return !!obj; } static gboolean infiniband_partition_add (NMPlatform *platform, int parent, int p_key, const NMPlatformLink **out_link) { return _infiniband_partition_action (platform, INFINIBAND_ACTION_CREATE_CHILD, parent, p_key, out_link); } static gboolean infiniband_partition_delete (NMPlatform *platform, int parent, int p_key) { return _infiniband_partition_action (platform, INFINIBAND_ACTION_DELETE_CHILD, parent, p_key, NULL); } /*****************************************************************************/ static WifiData * wifi_get_wifi_data (NMPlatform *platform, int ifindex) { NMLinuxPlatformPrivate *priv = NM_LINUX_PLATFORM_GET_PRIVATE (platform); const NMPlatformLink *pllink; WifiData *wifi_data; wifi_data = g_hash_table_lookup (priv->wifi_data, GINT_TO_POINTER (ifindex)); pllink = nm_platform_link_get (platform, ifindex); if (!wifi_data) { if (pllink) { if (pllink->type == NM_LINK_TYPE_WIFI) wifi_data = wifi_utils_init (ifindex, TRUE); else if (pllink->type == NM_LINK_TYPE_OLPC_MESH) { /* The kernel driver now uses nl80211, but we force use of WEXT because * the cfg80211 interactions are not quite ready to support access to * mesh control through nl80211 just yet. */ #if HAVE_WEXT wifi_data = wifi_wext_init (ifindex, FALSE); #endif } if (wifi_data) g_hash_table_insert (priv->wifi_data, GINT_TO_POINTER (ifindex), wifi_data); } } return wifi_data; } #define WIFI_GET_WIFI_DATA_NETNS(wifi_data, platform, ifindex, retval) \ nm_auto_pop_netns NMPNetns *netns = NULL; \ WifiData *wifi_data; \ if (!nm_platform_netns_push (platform, &netns)) \ return retval; \ wifi_data = wifi_get_wifi_data (platform, ifindex); \ if (!wifi_data) \ return retval; static gboolean wifi_get_capabilities (NMPlatform *platform, int ifindex, NMDeviceWifiCapabilities *caps) { WIFI_GET_WIFI_DATA_NETNS (wifi_data, platform, ifindex, FALSE); if (caps) *caps = wifi_utils_get_caps (wifi_data); return TRUE; } static gboolean wifi_get_bssid (NMPlatform *platform, int ifindex, guint8 *bssid) { WIFI_GET_WIFI_DATA_NETNS (wifi_data, platform, ifindex, FALSE); return wifi_utils_get_bssid (wifi_data, bssid); } static guint32 wifi_get_frequency (NMPlatform *platform, int ifindex) { WIFI_GET_WIFI_DATA_NETNS (wifi_data, platform, ifindex, 0); return wifi_utils_get_freq (wifi_data); } static gboolean wifi_get_quality (NMPlatform *platform, int ifindex) { WIFI_GET_WIFI_DATA_NETNS (wifi_data, platform, ifindex, FALSE); return wifi_utils_get_qual (wifi_data); } static guint32 wifi_get_rate (NMPlatform *platform, int ifindex) { WIFI_GET_WIFI_DATA_NETNS (wifi_data, platform, ifindex, FALSE); return wifi_utils_get_rate (wifi_data); } static NM80211Mode wifi_get_mode (NMPlatform *platform, int ifindex) { WIFI_GET_WIFI_DATA_NETNS (wifi_data, platform, ifindex, NM_802_11_MODE_UNKNOWN); return wifi_utils_get_mode (wifi_data); } static void wifi_set_mode (NMPlatform *platform, int ifindex, NM80211Mode mode) { WIFI_GET_WIFI_DATA_NETNS (wifi_data, platform, ifindex, ); wifi_utils_set_mode (wifi_data, mode); } static void wifi_set_powersave (NMPlatform *platform, int ifindex, guint32 powersave) { WIFI_GET_WIFI_DATA_NETNS (wifi_data, platform, ifindex, ); wifi_utils_set_powersave (wifi_data, powersave); } static guint32 wifi_find_frequency (NMPlatform *platform, int ifindex, const guint32 *freqs) { WIFI_GET_WIFI_DATA_NETNS (wifi_data, platform, ifindex, 0); return wifi_utils_find_freq (wifi_data, freqs); } static void wifi_indicate_addressing_running (NMPlatform *platform, int ifindex, gboolean running) { WIFI_GET_WIFI_DATA_NETNS (wifi_data, platform, ifindex, ); wifi_utils_indicate_addressing_running (wifi_data, running); } /*****************************************************************************/ static gboolean link_can_assume (NMPlatform *platform, int ifindex) { NMPLookup lookup; const NMPObject *link, *o; NMDedupMultiIter iter; NMPCache *cache = nm_platform_get_cache (platform); if (ifindex <= 0) return FALSE; link = nm_platform_link_get_obj (platform, ifindex, TRUE); if (!link) return FALSE; if (!NM_FLAGS_HAS (link->link.n_ifi_flags, IFF_UP)) return FALSE; if (link->link.master > 0) return TRUE; nmp_lookup_init_addrroute (&lookup, NMP_OBJECT_TYPE_IP4_ADDRESS, ifindex); if (nmp_cache_lookup (cache, &lookup)) return TRUE; nmp_lookup_init_addrroute (&lookup, NMP_OBJECT_TYPE_IP6_ADDRESS, ifindex); nmp_cache_iter_for_each (&iter, nmp_cache_lookup (cache, &lookup), &o) { nm_assert (NMP_OBJECT_GET_TYPE (o) == NMP_OBJECT_TYPE_IP6_ADDRESS); if (!IN6_IS_ADDR_LINKLOCAL (&o->ip6_address.address)) return TRUE; } return FALSE; } /*****************************************************************************/ static guint32 mesh_get_channel (NMPlatform *platform, int ifindex) { WIFI_GET_WIFI_DATA_NETNS (wifi_data, platform, ifindex, 0); return wifi_utils_get_mesh_channel (wifi_data); } static gboolean mesh_set_channel (NMPlatform *platform, int ifindex, guint32 channel) { WIFI_GET_WIFI_DATA_NETNS (wifi_data, platform, ifindex, FALSE); return wifi_utils_set_mesh_channel (wifi_data, channel); } static gboolean mesh_set_ssid (NMPlatform *platform, int ifindex, const guint8 *ssid, gsize len) { WIFI_GET_WIFI_DATA_NETNS (wifi_data, platform, ifindex, FALSE); return wifi_utils_set_mesh_ssid (wifi_data, ssid, len); } /*****************************************************************************/ static gboolean link_get_wake_on_lan (NMPlatform *platform, int ifindex) { nm_auto_pop_netns NMPNetns *netns = NULL; NMLinkType type = nm_platform_link_get_type (platform, ifindex); if (!nm_platform_netns_push (platform, &netns)) return FALSE; if (type == NM_LINK_TYPE_ETHERNET) return nmp_utils_ethtool_get_wake_on_lan (ifindex); else if (type == NM_LINK_TYPE_WIFI) { WifiData *wifi_data = wifi_get_wifi_data (platform, ifindex); if (!wifi_data) return FALSE; return wifi_utils_get_wowlan (wifi_data); } else return FALSE; } static gboolean link_get_driver_info (NMPlatform *platform, int ifindex, char **out_driver_name, char **out_driver_version, char **out_fw_version) { nm_auto_pop_netns NMPNetns *netns = NULL; NMPUtilsEthtoolDriverInfo driver_info; if (!nm_platform_netns_push (platform, &netns)) return FALSE; if (!nmp_utils_ethtool_get_driver_info (ifindex, &driver_info)) return FALSE; NM_SET_OUT (out_driver_name, g_strdup (driver_info.driver)); NM_SET_OUT (out_driver_version, g_strdup (driver_info.version)); NM_SET_OUT (out_fw_version, g_strdup (driver_info.fw_version)); return TRUE; } /*****************************************************************************/ static gboolean ip4_address_add (NMPlatform *platform, int ifindex, in_addr_t addr, guint8 plen, in_addr_t peer_addr, guint32 lifetime, guint32 preferred, guint32 flags, const char *label) { NMPObject obj_id; nm_auto_nlmsg struct nl_msg *nlmsg = NULL; nlmsg = _nl_msg_new_address (RTM_NEWADDR, NLM_F_CREATE | NLM_F_REPLACE, AF_INET, ifindex, &addr, plen, &peer_addr, flags, nm_utils_ip4_address_is_link_local (addr) ? RT_SCOPE_LINK : RT_SCOPE_UNIVERSE, lifetime, preferred, label); nmp_object_stackinit_id_ip4_address (&obj_id, ifindex, addr, plen, peer_addr); return do_add_addrroute (platform, &obj_id, nlmsg, FALSE) == NM_PLATFORM_ERROR_SUCCESS; } static gboolean ip6_address_add (NMPlatform *platform, int ifindex, struct in6_addr addr, guint8 plen, struct in6_addr peer_addr, guint32 lifetime, guint32 preferred, guint32 flags) { NMPObject obj_id; nm_auto_nlmsg struct nl_msg *nlmsg = NULL; nlmsg = _nl_msg_new_address (RTM_NEWADDR, NLM_F_CREATE | NLM_F_REPLACE, AF_INET6, ifindex, &addr, plen, &peer_addr, flags, RT_SCOPE_UNIVERSE, lifetime, preferred, NULL); nmp_object_stackinit_id_ip6_address (&obj_id, ifindex, &addr); return do_add_addrroute (platform, &obj_id, nlmsg, FALSE) == NM_PLATFORM_ERROR_SUCCESS; } static gboolean ip4_address_delete (NMPlatform *platform, int ifindex, in_addr_t addr, guint8 plen, in_addr_t peer_address) { nm_auto_nlmsg struct nl_msg *nlmsg = NULL; NMPObject obj_id; nlmsg = _nl_msg_new_address (RTM_DELADDR, 0, AF_INET, ifindex, &addr, plen, &peer_address, 0, RT_SCOPE_NOWHERE, NM_PLATFORM_LIFETIME_PERMANENT, NM_PLATFORM_LIFETIME_PERMANENT, NULL); if (!nlmsg) g_return_val_if_reached (FALSE); nmp_object_stackinit_id_ip4_address (&obj_id, ifindex, addr, plen, peer_address); return do_delete_object (platform, &obj_id, nlmsg); } static gboolean ip6_address_delete (NMPlatform *platform, int ifindex, struct in6_addr addr, guint8 plen) { nm_auto_nlmsg struct nl_msg *nlmsg = NULL; NMPObject obj_id; nlmsg = _nl_msg_new_address (RTM_DELADDR, 0, AF_INET6, ifindex, &addr, plen, NULL, 0, RT_SCOPE_NOWHERE, NM_PLATFORM_LIFETIME_PERMANENT, NM_PLATFORM_LIFETIME_PERMANENT, NULL); if (!nlmsg) g_return_val_if_reached (FALSE); nmp_object_stackinit_id_ip6_address (&obj_id, ifindex, &addr); return do_delete_object (platform, &obj_id, nlmsg); } /*****************************************************************************/ static NMPlatformError ip_route_add (NMPlatform *platform, NMPNlmFlags flags, int addr_family, const NMPlatformIPRoute *route) { nm_auto_nlmsg struct nl_msg *nlmsg = NULL; NMPObject obj; switch (addr_family) { case AF_INET: nmp_object_stackinit (&obj, NMP_OBJECT_TYPE_IP4_ROUTE, (const NMPlatformObject *) route); break; case AF_INET6: nmp_object_stackinit (&obj, NMP_OBJECT_TYPE_IP6_ROUTE, (const NMPlatformObject *) route); break; default: nm_assert_not_reached (); } nm_platform_ip_route_normalize (addr_family, NMP_OBJECT_CAST_IP_ROUTE (&obj)); nlmsg = _nl_msg_new_route (RTM_NEWROUTE, flags & NMP_NLM_FLAG_FMASK, &obj); if (!nlmsg) g_return_val_if_reached (NM_PLATFORM_ERROR_BUG); return do_add_addrroute (platform, &obj, nlmsg, NM_FLAGS_HAS (flags, NMP_NLM_FLAG_SUPPRESS_NETLINK_FAILURE)); } static gboolean ip_route_delete (NMPlatform *platform, const NMPObject *obj) { nm_auto_nmpobj const NMPObject *obj_keep_alive = NULL; nm_auto_nlmsg struct nl_msg *nlmsg = NULL; nm_assert (NM_IN_SET (NMP_OBJECT_GET_TYPE (obj), NMP_OBJECT_TYPE_IP4_ROUTE, NMP_OBJECT_TYPE_IP6_ROUTE)); if (!NMP_OBJECT_IS_STACKINIT (obj)) obj_keep_alive = nmp_object_ref (obj); nlmsg = _nl_msg_new_route (RTM_DELROUTE, 0, obj); if (!nlmsg) g_return_val_if_reached (FALSE); return do_delete_object (platform, obj, nlmsg); } /*****************************************************************************/ static NMPlatformError ip_route_get (NMPlatform *platform, int addr_family, gconstpointer address, int oif_ifindex, NMPObject **out_route) { const gboolean is_v4 = (addr_family == AF_INET); const int addr_len = is_v4 ? 4 : 16; int try_count = 0; WaitForNlResponseResult seq_result; int nle; nm_auto_nlmsg NMPObject *route = NULL; nm_assert (NM_IS_LINUX_PLATFORM (platform)); nm_assert (NM_IN_SET (addr_family, AF_INET, AF_INET6)); nm_assert (address); do { struct { struct nlmsghdr n; struct rtmsg r; char buf[64]; } req = { .n.nlmsg_len = NLMSG_LENGTH (sizeof (struct rtmsg)), .n.nlmsg_flags = NLM_F_REQUEST, .n.nlmsg_type = RTM_GETROUTE, .r.rtm_family = addr_family, .r.rtm_tos = 0, .r.rtm_dst_len = is_v4 ? 32 : 128, .r.rtm_flags = 0x1000 /* RTM_F_LOOKUP_TABLE */, }; g_clear_pointer (&route, nmp_object_unref); if (!_nl_addattr_l (&req.n, sizeof (req), RTA_DST, address, addr_len)) nm_assert_not_reached (); if (oif_ifindex > 0) { gint32 ii = oif_ifindex; if (!_nl_addattr_l (&req.n, sizeof (req), RTA_OIF, &ii, sizeof (ii))) nm_assert_not_reached (); } seq_result = WAIT_FOR_NL_RESPONSE_RESULT_UNKNOWN; nle = _nl_send_nlmsghdr (platform, &req.n, &seq_result, DELAYED_ACTION_RESPONSE_TYPE_ROUTE_GET, &route); if (nle < 0) { _LOGE ("get-route: failure sending netlink request \"%s\" (%d)", g_strerror (-nle), -nle); return NM_PLATFORM_ERROR_UNSPECIFIED; } delayed_action_handle_all (platform, FALSE); /* Retry, if we failed due to a cache resync. That can happen when the netlink * socket fills up and we lost the response. */ } while ( seq_result == WAIT_FOR_NL_RESPONSE_RESULT_FAILED_RESYNC && ++try_count < 10); if (seq_result < 0) { /* negative seq_result is an errno from kernel. Map it to negative * NMPlatformError (which are also errno). */ return (NMPlatformError) seq_result; } if (seq_result == WAIT_FOR_NL_RESPONSE_RESULT_RESPONSE_OK) { if (route) { NM_SET_OUT (out_route, g_steal_pointer (&route)); return NM_PLATFORM_ERROR_SUCCESS; } seq_result = WAIT_FOR_NL_RESPONSE_RESULT_RESPONSE_UNKNOWN; } return NM_PLATFORM_ERROR_UNSPECIFIED; } /*****************************************************************************/ #define EVENT_CONDITIONS ((GIOCondition) (G_IO_IN | G_IO_PRI)) #define ERROR_CONDITIONS ((GIOCondition) (G_IO_ERR | G_IO_NVAL)) #define DISCONNECT_CONDITIONS ((GIOCondition) (G_IO_HUP)) static gboolean event_handler (GIOChannel *channel, GIOCondition io_condition, gpointer user_data) { delayed_action_handle_all (NM_PLATFORM (user_data), TRUE); return TRUE; } /*****************************************************************************/ /* copied from libnl3's recvmsgs() */ static int event_handler_recvmsgs (NMPlatform *platform, gboolean handle_events) { NMLinuxPlatformPrivate *priv = NM_LINUX_PLATFORM_GET_PRIVATE (platform); struct nl_sock *sk = priv->nlh; int n, err = 0, multipart = 0, interrupted = 0; struct nlmsghdr *hdr; WaitForNlResponseResult seq_result; /* nla is passed on to not only to nl_recv() but may also be passed to a function pointer provided by the caller which may or may not initialize the variable. Thomas Graf. */ struct sockaddr_nl nla = {0}; nm_auto_free struct ucred *creds = NULL; nm_auto_free unsigned char *buf = NULL; continue_reading: g_clear_pointer (&buf, free); g_clear_pointer (&creds, free); errno = 0; n = nl_recv (sk, &nla, &buf, &creds); if (n <= 0) { /* workaround libnl3 <= 3.2.15 returning danling pointers in case nl_recv() * fails. Fixed by libnl3 69468517d0de1675d80f24661ff57a5dbac7275c. */ buf = NULL; creds = NULL; } switch (n) { case 0: /* Work around a libnl bug fixed in 3.2.22 (375a6294) */ if (errno == EAGAIN) { /* EAGAIN is equal to EWOULDBLOCK. If it would not be, we'd have to * workaround libnl3 mapping EWOULDBLOCK to -NLE_FAILURE. */ G_STATIC_ASSERT (EAGAIN == EWOULDBLOCK); n = -NLE_AGAIN; } break; case -NLE_MSG_TRUNC: { int buf_size; /* the message receive buffer was too small. We lost one message, which * is unfortunate. Try to double the buffer size for the next time. */ buf_size = nl_socket_get_msg_buf_size (sk); if (buf_size < 512*1024) { buf_size *= 2; _LOGT ("netlink: recvmsg: increase message buffer size for recvmsg() to %d bytes", buf_size); if (nl_socket_set_msg_buf_size (sk, buf_size) < 0) nm_assert_not_reached (); if (!handle_events) goto continue_reading; } n = -_NLE_MSG_TRUNC; break; } case -NLE_NOMEM: if (errno == ENOBUFS) { /* we are very much interested in a overrun of the receive buffer. * nl_recv() maps all kinds of errors to NLE_NOMEM, so check also * for errno explicitly. And if so, hack our own return code to signal * the overrun. */ n = -_NLE_NM_NOBUFS; } break; } if (n <= 0) return n; hdr = (struct nlmsghdr *) buf; while (nlmsg_ok (hdr, n)) { nm_auto_nlmsg struct nl_msg *msg = NULL; gboolean abort_parsing = FALSE; gboolean process_valid_msg = FALSE; guint32 seq_number; char buf_nlmsghdr[400]; msg = nlmsg_convert (hdr); if (!msg) { err = -NLE_NOMEM; goto out; } nlmsg_set_proto (msg, NETLINK_ROUTE); nlmsg_set_src (msg, &nla); if (!creds || creds->pid) { if (creds) _LOGT ("netlink: recvmsg: received non-kernel message (pid %d)", creds->pid); else _LOGT ("netlink: recvmsg: received message without credentials"); err = 0; goto stop; } _LOGt ("netlink: recvmsg: new message %s", _nl_nlmsghdr_to_str (hdr, buf_nlmsghdr, sizeof (buf_nlmsghdr))); if (creds) nlmsg_set_creds (msg, creds); if (hdr->nlmsg_flags & NLM_F_MULTI) multipart = 1; if (hdr->nlmsg_flags & NLM_F_DUMP_INTR) { /* * We have to continue reading to clear * all messages until a NLMSG_DONE is * received and report the inconsistency. */ interrupted = 1; } /* Other side wishes to see an ack for this message */ if (hdr->nlmsg_flags & NLM_F_ACK) { /* FIXME: implement */ } seq_result = WAIT_FOR_NL_RESPONSE_RESULT_RESPONSE_UNKNOWN; if (hdr->nlmsg_type == NLMSG_DONE) { /* messages terminates a multipart 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. */ multipart = 0; seq_result = WAIT_FOR_NL_RESPONSE_RESULT_RESPONSE_OK; } else if (hdr->nlmsg_type == NLMSG_NOOP) { /* 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_OVERRUN) { /* 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) */ err = -NLE_MSG_OVERFLOW; abort_parsing = TRUE; } else if (hdr->nlmsg_type == NLMSG_ERROR) { /* Message carries a nlmsgerr */ struct nlmsgerr *e = nlmsg_data (hdr); if (hdr->nlmsg_len < nlmsg_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) */ err = -NLE_MSG_TRUNC; abort_parsing = TRUE; } else if (e->error) { int errsv = e->error > 0 ? e->error : -e->error; /* Error message reported back from kernel. */ _LOGD ("netlink: recvmsg: error message from kernel: %s (%d) for request %d", strerror (errsv), errsv, nlmsg_hdr (msg)->nlmsg_seq); seq_result = -errsv; } else seq_result = WAIT_FOR_NL_RESPONSE_RESULT_RESPONSE_OK; } else process_valid_msg = TRUE; seq_number = nlmsg_hdr (msg)->nlmsg_seq; /* check whether the seq number is different from before, and * whether the previous number (@nlh_seq_last_seen) is a pending * refresh-all request. In that case, the pending request is thereby * completed. * * We must do that before processing the message with event_valid_msg(), * because we must track the completion of the pending request before that. */ event_seq_check_refresh_all (platform, seq_number); if (process_valid_msg) { /* Valid message (not checking for MULTIPART bit to * get along with broken kernels. NL_SKIP has no * effect on this. */ event_valid_msg (platform, msg, handle_events); seq_result = WAIT_FOR_NL_RESPONSE_RESULT_RESPONSE_OK; } event_seq_check (platform, seq_number, seq_result); if (abort_parsing) goto stop; err = 0; hdr = nlmsg_next (hdr, &n); } if (multipart) { /* Multipart message not yet complete, continue reading */ goto continue_reading; } stop: if (!handle_events) { /* when we don't handle events, we want to drain all messages from the socket * without handling the messages (but still check for sequence numbers). * Repeat reading. */ goto continue_reading; } out: if (interrupted) err = -NLE_DUMP_INTR; return err; } /*****************************************************************************/ static gboolean event_handler_read_netlink (NMPlatform *platform, gboolean wait_for_acks) { nm_auto_pop_netns NMPNetns *netns = NULL; NMLinuxPlatformPrivate *priv = NM_LINUX_PLATFORM_GET_PRIVATE (platform); int r, nle; struct pollfd pfd; gboolean any = FALSE; gint64 now_ns; int timeout_ms; guint i; struct { guint32 seq_number; gint64 timeout_abs_ns; } data_next; if (!nm_platform_netns_push (platform, &netns)) return FALSE; while (TRUE) { while (TRUE) { nle = event_handler_recvmsgs (platform, TRUE); if (nle < 0) { switch (nle) { case -NLE_AGAIN: goto after_read; case -NLE_DUMP_INTR: _LOGD ("netlink: read: uncritical failure to retrieve incoming events: %s (%d)", nl_geterror (nle), nle); break; case -_NLE_MSG_TRUNC: case -_NLE_NM_NOBUFS: _LOGI ("netlink: read: %s. Need to resynchronize platform cache", ({ const char *_reason = "unknown"; switch (nle) { case -_NLE_MSG_TRUNC: _reason = "message truncated"; break; case -_NLE_NM_NOBUFS: _reason = "too many netlink events"; break; } _reason; })); event_handler_recvmsgs (platform, FALSE); delayed_action_wait_for_nl_response_complete_all (platform, WAIT_FOR_NL_RESPONSE_RESULT_FAILED_RESYNC); delayed_action_schedule (platform, DELAYED_ACTION_TYPE_REFRESH_ALL_LINKS | DELAYED_ACTION_TYPE_REFRESH_ALL_IP4_ADDRESSES | DELAYED_ACTION_TYPE_REFRESH_ALL_IP6_ADDRESSES | DELAYED_ACTION_TYPE_REFRESH_ALL_IP4_ROUTES | DELAYED_ACTION_TYPE_REFRESH_ALL_IP6_ROUTES, NULL); break; default: _LOGE ("netlink: read: failed to retrieve incoming events: %s (%d)", nl_geterror (nle), nle); break; } } any = TRUE; } after_read: if (!NM_FLAGS_HAS (priv->delayed_action.flags, DELAYED_ACTION_TYPE_WAIT_FOR_NL_RESPONSE)) return any; now_ns = 0; data_next.seq_number = 0; data_next.timeout_abs_ns = 0; for (i = 0; i < priv->delayed_action.list_wait_for_nl_response->len; ) { DelayedActionWaitForNlResponseData *data = &g_array_index (priv->delayed_action.list_wait_for_nl_response, DelayedActionWaitForNlResponseData, i); if (data->seq_result) delayed_action_wait_for_nl_response_complete (platform, i, data->seq_result); else if ((now_ns ?: (now_ns = nm_utils_get_monotonic_timestamp_ns ())) > data->timeout_abs_ns) delayed_action_wait_for_nl_response_complete (platform, i, WAIT_FOR_NL_RESPONSE_RESULT_FAILED_TIMEOUT); else { i++; if ( data_next.seq_number == 0 || data_next.timeout_abs_ns > data->timeout_abs_ns) { data_next.seq_number = data->seq_number; data_next.timeout_abs_ns = data->timeout_abs_ns; } } } if ( !wait_for_acks || !NM_FLAGS_HAS (priv->delayed_action.flags, DELAYED_ACTION_TYPE_WAIT_FOR_NL_RESPONSE)) return any; nm_assert (data_next.seq_number); nm_assert (data_next.timeout_abs_ns > 0); nm_assert (now_ns > 0); _LOGT ("netlink: read: wait for ACK for sequence number %u...", data_next.seq_number); timeout_ms = (data_next.timeout_abs_ns - now_ns) / (NM_UTILS_NS_PER_SECOND / 1000); memset (&pfd, 0, sizeof (pfd)); pfd.fd = nl_socket_get_fd (priv->nlh); pfd.events = POLLIN; r = poll (&pfd, 1, MAX (1, timeout_ms)); if (r == 0) { /* timeout and there is nothing to read. */ goto after_read; } if (r < 0) { int errsv = errno; if (errsv != EINTR) { _LOGE ("netlink: read: poll failed with %s", strerror (errsv)); delayed_action_wait_for_nl_response_complete_all (platform, WAIT_FOR_NL_RESPONSE_RESULT_FAILED_POLL); return any; } /* Continue to read again, even if there might be nothing to read after EINTR. */ } } } /*****************************************************************************/ static void cache_update_link_udev (NMPlatform *platform, int ifindex, struct udev_device *udevice) { nm_auto_nmpobj const NMPObject *obj_old = NULL; nm_auto_nmpobj const NMPObject *obj_new = NULL; NMPCacheOpsType cache_op; cache_op = nmp_cache_update_link_udev (nm_platform_get_cache (platform), ifindex, udevice, &obj_old, &obj_new); if (cache_op != NMP_CACHE_OPS_UNCHANGED) { nm_auto_pop_netns NMPNetns *netns = NULL; cache_on_change (platform, cache_op, obj_old, obj_new); if (!nm_platform_netns_push (platform, &netns)) return; nm_platform_cache_update_emit_signal (platform, cache_op, obj_old, obj_new); } } static void udev_device_added (NMPlatform *platform, struct udev_device *udevice) { const char *ifname; const char *ifindex_s; int ifindex; ifname = udev_device_get_sysname (udevice); if (!ifname) { _LOGD ("udev-add: failed to get device's interface"); return; } ifindex_s = udev_device_get_property_value (udevice, "IFINDEX"); if (!ifindex_s) { _LOGW ("udev-add[%s]failed to get device's ifindex", ifname); return; } ifindex = _nm_utils_ascii_str_to_int64 (ifindex_s, 10, 1, G_MAXINT, 0); if (ifindex <= 0) { _LOGW ("udev-add[%s]: retrieved invalid IFINDEX=%d", ifname, ifindex); return; } if (!udev_device_get_syspath (udevice)) { _LOGD ("udev-add[%s,%d]: couldn't determine device path; ignoring...", ifname, ifindex); return; } _LOGT ("udev-add[%s,%d]: device added", ifname, ifindex); cache_update_link_udev (platform, ifindex, udevice); } static gboolean _udev_device_removed_match_link (const NMPObject *obj, gpointer udevice) { return obj->_link.udev.device == udevice; } static void udev_device_removed (NMPlatform *platform, struct udev_device *udevice) { const char *ifindex_s; int ifindex = 0; ifindex_s = udev_device_get_property_value (udevice, "IFINDEX"); ifindex = _nm_utils_ascii_str_to_int64 (ifindex_s, 10, 1, G_MAXINT, 0); if (ifindex <= 0) { const NMPObject *obj; obj = nmp_cache_lookup_link_full (nm_platform_get_cache (platform), 0, NULL, FALSE, NM_LINK_TYPE_NONE, _udev_device_removed_match_link, udevice); if (obj) ifindex = obj->link.ifindex; } _LOGD ("udev-remove: IFINDEX=%d", ifindex); if (ifindex <= 0) return; cache_update_link_udev (platform, ifindex, NULL); } static void handle_udev_event (NMUdevClient *udev_client, struct udev_device *udevice, gpointer user_data) { nm_auto_pop_netns NMPNetns *netns = NULL; NMPlatform *platform = NM_PLATFORM (user_data); const char *subsys; const char *ifindex; guint64 seqnum; const char *action; action = udev_device_get_action (udevice); g_return_if_fail (action); subsys = udev_device_get_subsystem (udevice); g_return_if_fail (nm_streq0 (subsys, "net")); if (!nm_platform_netns_push (platform, &netns)) return; ifindex = udev_device_get_property_value (udevice, "IFINDEX"); seqnum = udev_device_get_seqnum (udevice); _LOGD ("UDEV event: action '%s' subsys '%s' device '%s' (%s); seqnum=%" G_GUINT64_FORMAT, action, subsys, udev_device_get_sysname (udevice), ifindex ? ifindex : "unknown", seqnum); if (NM_IN_STRSET (action, "add", "move")) udev_device_added (platform, udevice); else if (NM_IN_STRSET (action, "remove")) udev_device_removed (platform, udevice); } /*****************************************************************************/ static void nm_linux_platform_init (NMLinuxPlatform *self) { NMLinuxPlatformPrivate *priv = NM_LINUX_PLATFORM_GET_PRIVATE (self); priv->nlh_seq_next = 1; priv->delayed_action.list_master_connected = g_ptr_array_new (); priv->delayed_action.list_refresh_link = g_ptr_array_new (); priv->delayed_action.list_wait_for_nl_response = g_array_new (FALSE, TRUE, sizeof (DelayedActionWaitForNlResponseData)); priv->wifi_data = g_hash_table_new_full (NULL, NULL, NULL, (GDestroyNotify) wifi_utils_deinit); } static void constructed (GObject *_object) { NMPlatform *platform = NM_PLATFORM (_object); NMLinuxPlatformPrivate *priv = NM_LINUX_PLATFORM_GET_PRIVATE (platform); int channel_flags; gboolean status; int nle; nm_assert (!platform->_netns || platform->_netns == nmp_netns_get_current ()); if (nm_platform_get_use_udev (platform)) { priv->udev_client = nm_udev_client_new ((const char *[]) { "net", NULL }, handle_udev_event, platform); } _LOGD ("create (%s netns, %s, %s udev)", !platform->_netns ? "ignore" : "use", !platform->_netns && nmp_netns_is_initial () ? "initial netns" : (!nmp_netns_get_current () ? "no netns support" : nm_sprintf_bufa (100, "in netns[%p]%s", nmp_netns_get_current (), nmp_netns_get_current () == nmp_netns_get_initial () ? "/main" : "")), nm_platform_get_use_udev (platform) ? "use" : "no"); priv->nlh = nl_socket_alloc (); g_assert (priv->nlh); nle = nl_connect (priv->nlh, NETLINK_ROUTE); g_assert (!nle); nle = nl_socket_set_passcred (priv->nlh, 1); g_assert (!nle); /* No blocking for event socket, so that we can drain it safely. */ nle = nl_socket_set_nonblocking (priv->nlh); g_assert (!nle); /* use 8 MB for receive socket kernel queue. */ nle = nl_socket_set_buffer_size (priv->nlh, 8*1024*1024, 0); g_assert (!nle); /* explicitly set the msg buffer size and disable MSG_PEEK. * If we later encounter NLE_MSG_TRUNC, we will adjust the buffer size. */ nl_socket_disable_msg_peek (priv->nlh); nle = nl_socket_set_msg_buf_size (priv->nlh, 32 * 1024); g_assert (!nle); nle = nl_socket_add_memberships (priv->nlh, RTNLGRP_LINK, RTNLGRP_IPV4_IFADDR, RTNLGRP_IPV6_IFADDR, RTNLGRP_IPV4_ROUTE, RTNLGRP_IPV6_ROUTE, 0); g_assert (!nle); _LOGD ("Netlink socket for events established: port=%u, fd=%d", nl_socket_get_local_port (priv->nlh), nl_socket_get_fd (priv->nlh)); priv->event_channel = g_io_channel_unix_new (nl_socket_get_fd (priv->nlh)); g_io_channel_set_encoding (priv->event_channel, NULL, NULL); g_io_channel_set_close_on_unref (priv->event_channel, TRUE); channel_flags = g_io_channel_get_flags (priv->event_channel); status = g_io_channel_set_flags (priv->event_channel, channel_flags | G_IO_FLAG_NONBLOCK, NULL); g_assert (status); priv->event_id = g_io_add_watch (priv->event_channel, (EVENT_CONDITIONS | ERROR_CONDITIONS | DISCONNECT_CONDITIONS), event_handler, platform); /* complete construction of the GObject instance before populating the cache. */ G_OBJECT_CLASS (nm_linux_platform_parent_class)->constructed (_object); _LOGD ("populate platform cache"); delayed_action_schedule (platform, DELAYED_ACTION_TYPE_REFRESH_ALL_LINKS | DELAYED_ACTION_TYPE_REFRESH_ALL_IP4_ADDRESSES | DELAYED_ACTION_TYPE_REFRESH_ALL_IP6_ADDRESSES | DELAYED_ACTION_TYPE_REFRESH_ALL_IP4_ROUTES | DELAYED_ACTION_TYPE_REFRESH_ALL_IP6_ROUTES, NULL); delayed_action_handle_all (platform, FALSE); /* Set up udev monitoring */ if (priv->udev_client) { struct udev_enumerate *enumerator; struct udev_list_entry *devices, *l; /* And read initial device list */ enumerator = nm_udev_client_enumerate_new (priv->udev_client); udev_enumerate_add_match_is_initialized (enumerator); udev_enumerate_scan_devices (enumerator); devices = udev_enumerate_get_list_entry (enumerator); for (l = devices; l; l = udev_list_entry_get_next (l)) { struct udev_device *udevice; udevice = udev_device_new_from_syspath (udev_enumerate_get_udev (enumerator), udev_list_entry_get_name (l)); if (!udevice) continue; udev_device_added (platform, udevice); udev_device_unref (udevice); } udev_enumerate_unref (enumerator); } } static void dispose (GObject *object) { NMPlatform *platform = NM_PLATFORM (object); NMLinuxPlatformPrivate *priv = NM_LINUX_PLATFORM_GET_PRIVATE (platform); _LOGD ("dispose"); delayed_action_wait_for_nl_response_complete_all (platform, WAIT_FOR_NL_RESPONSE_RESULT_FAILED_DISPOSING); priv->delayed_action.flags = DELAYED_ACTION_TYPE_NONE; g_ptr_array_set_size (priv->delayed_action.list_master_connected, 0); g_ptr_array_set_size (priv->delayed_action.list_refresh_link, 0); G_OBJECT_CLASS (nm_linux_platform_parent_class)->dispose (object); } static void finalize (GObject *object) { NMLinuxPlatformPrivate *priv = NM_LINUX_PLATFORM_GET_PRIVATE (object); g_ptr_array_unref (priv->delayed_action.list_master_connected); g_ptr_array_unref (priv->delayed_action.list_refresh_link); g_array_unref (priv->delayed_action.list_wait_for_nl_response); g_source_remove (priv->event_id); g_io_channel_unref (priv->event_channel); nl_socket_free (priv->nlh); g_hash_table_unref (priv->wifi_data); if (priv->sysctl_get_prev_values) { sysctl_clear_cache_list = g_slist_remove (sysctl_clear_cache_list, object); g_hash_table_destroy (priv->sysctl_get_prev_values); } priv->udev_client = nm_udev_client_unref (priv->udev_client); G_OBJECT_CLASS (nm_linux_platform_parent_class)->finalize (object); } static void nm_linux_platform_class_init (NMLinuxPlatformClass *klass) { GObjectClass *object_class = G_OBJECT_CLASS (klass); NMPlatformClass *platform_class = NM_PLATFORM_CLASS (klass); object_class->constructed = constructed; object_class->dispose = dispose; object_class->finalize = finalize; platform_class->sysctl_set = sysctl_set; platform_class->sysctl_get = sysctl_get; platform_class->link_add = link_add; platform_class->link_delete = link_delete; platform_class->link_refresh = link_refresh; platform_class->link_set_netns = link_set_netns; platform_class->link_set_up = link_set_up; platform_class->link_set_down = link_set_down; platform_class->link_set_arp = link_set_arp; platform_class->link_set_noarp = link_set_noarp; platform_class->link_get_udi = link_get_udi; platform_class->link_set_user_ipv6ll_enabled = link_set_user_ipv6ll_enabled; platform_class->link_set_token = link_set_token; platform_class->link_set_address = link_set_address; platform_class->link_get_permanent_address = link_get_permanent_address; platform_class->link_set_mtu = link_set_mtu; platform_class->link_set_name = link_set_name; platform_class->link_set_sriov_num_vfs = link_set_sriov_num_vfs; platform_class->link_get_physical_port_id = link_get_physical_port_id; platform_class->link_get_dev_id = link_get_dev_id; platform_class->link_get_wake_on_lan = link_get_wake_on_lan; platform_class->link_get_driver_info = link_get_driver_info; platform_class->link_supports_carrier_detect = link_supports_carrier_detect; platform_class->link_supports_vlans = link_supports_vlans; platform_class->link_supports_sriov = link_supports_sriov; platform_class->link_enslave = link_enslave; platform_class->link_release = link_release; platform_class->link_can_assume = link_can_assume; platform_class->vlan_add = vlan_add; platform_class->link_vlan_change = link_vlan_change; platform_class->link_vxlan_add = link_vxlan_add; platform_class->tun_add = tun_add; platform_class->infiniband_partition_add = infiniband_partition_add; platform_class->infiniband_partition_delete = infiniband_partition_delete; platform_class->wifi_get_capabilities = wifi_get_capabilities; platform_class->wifi_get_bssid = wifi_get_bssid; platform_class->wifi_get_frequency = wifi_get_frequency; platform_class->wifi_get_quality = wifi_get_quality; platform_class->wifi_get_rate = wifi_get_rate; platform_class->wifi_get_mode = wifi_get_mode; platform_class->wifi_set_mode = wifi_set_mode; platform_class->wifi_set_powersave = wifi_set_powersave; platform_class->wifi_find_frequency = wifi_find_frequency; platform_class->wifi_indicate_addressing_running = wifi_indicate_addressing_running; platform_class->mesh_get_channel = mesh_get_channel; platform_class->mesh_set_channel = mesh_set_channel; platform_class->mesh_set_ssid = mesh_set_ssid; platform_class->link_gre_add = link_gre_add; platform_class->link_ip6tnl_add = link_ip6tnl_add; platform_class->link_macsec_add = link_macsec_add; platform_class->link_macvlan_add = link_macvlan_add; platform_class->link_ipip_add = link_ipip_add; platform_class->link_sit_add = link_sit_add; platform_class->ip4_address_add = ip4_address_add; platform_class->ip6_address_add = ip6_address_add; platform_class->ip4_address_delete = ip4_address_delete; platform_class->ip6_address_delete = ip6_address_delete; platform_class->ip_route_add = ip_route_add; platform_class->ip_route_delete = ip_route_delete; platform_class->ip_route_get = ip_route_get; platform_class->check_kernel_support = check_kernel_support; platform_class->process_events = process_events; }