// SPDX-License-Identifier: AGPL-3.0-or-later /* PASST - Plug A Simple Socket Transport * for qemu/UNIX domain socket mode * * PASTA - Pack A Subtle Tap Abstraction * for network namespace/tap device mode * * udp.c - UDP L2-L4 translation routines * * Copyright (c) 2020-2021 Red Hat GmbH * Author: Stefano Brivio */ /** * DOC: Theory of Operation * * * For UDP, a reduced version of port-based connection tracking is implemented * with two purposes: * - binding ephemeral ports when they're used as source port by the guest, so * that replies on those ports can be forwarded back to the guest, with a * fixed timeout for this binding * - packets received from the local host get their source changed to a local * address (gateway address) so that they can be forwarded to the guest, and * packets sent as replies by the guest need their destination address to * be changed back to the address of the local host. This is dynamic to allow * connections from the gateway as well, and uses the same fixed 180s timeout * * Sockets for bound ports are created at initialisation time, one set for IPv4 * and one for IPv6. * * Packets are forwarded back and forth, by prepending and stripping UDP headers * in the obvious way, with no port translation. * * In PASTA mode, the L2-L4 translation is skipped for connections to ports * bound between namespaces using the loopback interface, messages are directly * transferred between L4 sockets instead. These are called spliced connections * for consistency with the TCP implementation, but the splice() syscall isn't * actually used as it wouldn't make sense for datagram-based connections: a * pair of recvmmsg() and sendmmsg() deals with this case. * * The connection tracking for PASTA mode is slightly complicated by the absence * of actual connections, see struct udp_splice_port, and these examples: * * - from init to namespace: * * - forward direction: 127.0.0.1:5000 -> 127.0.0.1:80 in init from bound * socket s, with epoll reference: index = 80, splice = UDP_TO_NS * - if udp_splice_map[V4][5000].ns_conn_sock: * - send packet to udp4_splice_map[5000].ns_conn_sock * - otherwise: * - create new socket udp_splice_map[V4][5000].ns_conn_sock * - connect in namespace to 127.0.0.1:80 (note: this destination port * might be remapped to another port instead) * - get source port of new connected socket (10000) with getsockname() * - add to epoll with reference: index = 10000, splice: UDP_BACK_TO_INIT * - set udp_splice_map[V4][10000].init_bound_sock to s * - set udp_splice_map[V4][10000].init_dst_port to 5000 * - update udp_splice_map[V4][5000].ns_conn_ts with current time * * - reverse direction: 127.0.0.1:80 -> 127.0.0.1:10000 in namespace from * connected socket s, having epoll reference: index = 10000, * splice = UDP_BACK_TO_INIT * - if udp_splice_map[V4][10000].init_bound_sock: * - send to udp_splice_map[V4][10000].init_bound_sock, with destination * port udp_splice_map[V4][10000].init_dst_port (5000) * - otherwise, discard * * - from namespace to init: * * - forward direction: 127.0.0.1:2000 -> 127.0.0.1:22 in namespace from bound * socket s, with epoll reference: index = 22, splice = UDP_TO_INIT * - if udp4_splice_map[V4][2000].init_conn_sock: * - send packet to udp4_splice_map[2000].init_conn_sock * - otherwise: * - create new socket udp_splice_map[V4][2000].init_conn_sock * - connect in init to 127.0.0.1:22 (note: this destination port * might be remapped to another port instead) * - get source port of new connected socket (4000) with getsockname() * - add to epoll with reference: index = 4000, splice = UDP_BACK_TO_NS * - set udp_splice_map[V4][4000].ns_bound_sock to s * - set udp_splice_map[V4][4000].ns_dst_port to 2000 * - update udp_splice_map[V4][4000].init_conn_ts with current time * * - reverse direction: 127.0.0.1:22 -> 127.0.0.1:4000 in init from connected * socket s, having epoll reference: index = 4000, splice = UDP_BACK_TO_NS * - if udp_splice_map[V4][4000].ns_bound_sock: * - send to udp_splice_map[V4][4000].ns_bound_sock, with destination port * udp_splice_map[4000].ns_dst_port (2000) * - otherwise, discard */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "checksum.h" #include "util.h" #include "passt.h" #include "tap.h" #include "pcap.h" #define UDP_CONN_TIMEOUT 180 /* s, timeout for ephemeral or local bind */ #define UDP_SPLICE_FRAMES 128 #define UDP_TAP_FRAMES 128 /** * struct udp_tap_port - Port tracking based on tap-facing source port * @sock: Socket bound to source port used as index * @ts: Activity timestamp from tap, used for socket aging * @ts_local: Timestamp of tap packet to gateway address, aging for local bind * @loopback: Whether local bind should use loopback address as source */ struct udp_tap_port { int sock; time_t ts; time_t ts_local; int loopback; }; /** * struct udp_splice_port - Source port tracking for traffic between namespaces * @ns_conn_sock: Socket connected in namespace for init source port * @init_conn_sock: Socket connected in init for namespace source port * @ns_conn_ts: Timestamp of activity for socket connected in namespace * @init_conn_ts: Timestamp of activity for socket connceted in init * @ns_dst_port: Destination port in namespace for init source port * @init_dst_port: Destination port in init for namespace source port * @ns_bound_sock: Bound socket in namespace for this source port in init * @init_bound_sock: Bound socket in init for this source port in namespace */ struct udp_splice_port { int ns_conn_sock; int init_conn_sock; time_t ns_conn_ts; time_t init_conn_ts; in_port_t ns_dst_port; in_port_t init_dst_port; int ns_bound_sock; int init_bound_sock; }; /* Port tracking, arrays indexed by packet source port (host order) */ static struct udp_tap_port udp_tap_map [IP_VERSIONS][USHRT_MAX]; static struct udp_splice_port udp_splice_map [IP_VERSIONS][USHRT_MAX]; /* Port re-mappings as delta, indexed by original destination port */ static in_port_t udp_port_delta_to_tap [USHRT_MAX]; static in_port_t udp_port_delta_from_tap [USHRT_MAX]; static in_port_t udp_port_delta_to_init [USHRT_MAX]; static in_port_t udp_port_delta_from_init[USHRT_MAX]; enum udp_act_type { UDP_ACT_TAP, UDP_ACT_NS_CONN, UDP_ACT_INIT_CONN, UDP_ACT_TYPE_MAX, }; /* Activity-based aging for bindings */ static uint8_t udp_act[IP_VERSIONS][UDP_ACT_TYPE_MAX][USHRT_MAX / 8]; /* Static buffers */ /** * udp4_l2_buf_t - Pre-cooked IPv4 packet buffers for tap connections * @s_in: Source socket address, filled in by recvmmsg() * @psum: Partial IP header checksum (excluding tot_len and saddr) * @vnet_len: 4-byte qemu vnet buffer length descriptor, only for passt mode * @eh: Pre-filled Ethernet header * @iph: Pre-filled IP header (except for tot_len and saddr) * @uh: Headroom for UDP header * @data: Storage for UDP payload */ static struct udp4_l2_buf_t { struct sockaddr_in s_in; uint32_t psum; uint32_t vnet_len; struct ethhdr eh; struct iphdr iph; struct udphdr uh; uint8_t data[USHRT_MAX - (sizeof(struct iphdr) + sizeof(struct udphdr))]; } __attribute__ ((packed, aligned(__alignof__(unsigned int)))) udp4_l2_buf[UDP_TAP_FRAMES]; /** * udp6_l2_buf_t - Pre-cooked IPv6 packet buffers for tap connections * @s_in6: Source socket address, filled in by recvmmsg() * @vnet_len: 4-byte qemu vnet buffer length descriptor, only for passt mode * @eh: Pre-filled Ethernet header * @ip6h: Pre-filled IP header (except for payload_len and addresses) * @uh: Headroom for UDP header * @data: Storage for UDP payload */ struct udp6_l2_buf_t { struct sockaddr_in6 s_in6; #ifdef __AVX2__ /* Align ip6h to 32-byte boundary. */ uint8_t pad[64 - (sizeof(struct sockaddr_in6) + sizeof(struct ethhdr) + sizeof(uint32_t))]; #endif uint32_t vnet_len; struct ethhdr eh; struct ipv6hdr ip6h; struct udphdr uh; uint8_t data[USHRT_MAX - (sizeof(struct ipv6hdr) + sizeof(struct udphdr))]; #ifdef __AVX2__ } __attribute__ ((packed, aligned(32))) #else } __attribute__ ((packed, aligned(__alignof__(unsigned int)))) #endif udp6_l2_buf[UDP_TAP_FRAMES]; static struct sockaddr_storage udp_splice_namebuf; static uint8_t udp_splice_buf[UDP_SPLICE_FRAMES][USHRT_MAX]; /* recvmmsg()/sendmmsg() data for tap */ static struct iovec udp4_l2_iov_sock [UDP_TAP_FRAMES]; static struct iovec udp6_l2_iov_sock [UDP_TAP_FRAMES]; static struct iovec udp4_l2_iov_tap [UDP_TAP_FRAMES]; static struct iovec udp6_l2_iov_tap [UDP_TAP_FRAMES]; static struct mmsghdr udp4_l2_mh_sock [UDP_TAP_FRAMES]; static struct mmsghdr udp6_l2_mh_sock [UDP_TAP_FRAMES]; static struct mmsghdr udp4_l2_mh_tap [UDP_TAP_FRAMES]; static struct mmsghdr udp6_l2_mh_tap [UDP_TAP_FRAMES]; /* recvmmsg()/sendmmsg() data for "spliced" connections */ static struct iovec udp_splice_iov_recv [UDP_SPLICE_FRAMES]; static struct mmsghdr udp_splice_mmh_recv [UDP_SPLICE_FRAMES]; static struct iovec udp_splice_iov_send [UDP_SPLICE_FRAMES]; static struct mmsghdr udp_splice_mmh_send [UDP_SPLICE_FRAMES]; static struct iovec udp_splice_iov_sendto [UDP_SPLICE_FRAMES]; static struct mmsghdr udp_splice_mmh_sendto [UDP_SPLICE_FRAMES]; /** * udp_remap_to_tap() - Set delta for port translation to/from guest/tap * @port: Original destination port, host order * @delta: Delta to be added to original destination port */ void udp_remap_to_tap(in_port_t port, in_port_t delta) { udp_port_delta_to_tap[port] = delta; udp_port_delta_from_tap[port + delta] = USHRT_MAX - delta; } /** * udp_remap_to_init() - Set delta for port translation to/from init namespace * @port: Original destination port, host order * @delta: Delta to be added to original destination port */ void udp_remap_to_init(in_port_t port, in_port_t delta) { udp_port_delta_to_init[port] = delta; udp_port_delta_from_init[port + delta] = USHRT_MAX - delta; } /** * udp_update_check4() - Update checksum with variable parts from stored one * @buf: L2 packet buffer with final IPv4 header */ static void udp_update_check4(struct udp4_l2_buf_t *buf) { uint32_t sum = buf->psum; sum += buf->iph.tot_len; sum += (buf->iph.saddr >> 16) & 0xffff; sum += buf->iph.saddr & 0xffff; buf->iph.check = (uint16_t)~csum_fold(sum); } /** * udp_update_l2_buf() - Update L2 buffers with Ethernet and IPv4 addresses * @eth_d: Ethernet destination address, NULL if unchanged * @eth_s: Ethernet source address, NULL if unchanged * @ip_da: Pointer to IPv4 destination address, NULL if unchanged */ void udp_update_l2_buf(unsigned char *eth_d, unsigned char *eth_s, const uint32_t *ip_da) { int i; for (i = 0; i < UDP_TAP_FRAMES; i++) { struct udp4_l2_buf_t *b4 = &udp4_l2_buf[i]; struct udp6_l2_buf_t *b6 = &udp6_l2_buf[i]; if (eth_d) { memcpy(b4->eh.h_dest, eth_d, ETH_ALEN); memcpy(b6->eh.h_dest, eth_d, ETH_ALEN); } if (eth_s) { memcpy(b4->eh.h_source, eth_s, ETH_ALEN); memcpy(b6->eh.h_source, eth_s, ETH_ALEN); } if (ip_da) { b4->iph.daddr = *ip_da; if (!i) { b4->iph.saddr = 0; b4->iph.tot_len = 0; b4->iph.check = 0; b4->psum = sum_16b(&b4->iph, 20); } else { b4->psum = udp4_l2_buf[0].psum; } } } } /** * udp_sock4_iov_init() - Initialise scatter-gather L2 buffers for IPv4 sockets */ static void udp_sock4_iov_init(void) { struct mmsghdr *h; int i; for (i = 0; i < ARRAY_SIZE(udp4_l2_buf); i++) { udp4_l2_buf[i] = (struct udp4_l2_buf_t) { { 0 }, 0, 0, L2_BUF_ETH_IP4_INIT, L2_BUF_IP4_INIT(IPPROTO_UDP), {{{ 0 }}}, { 0 }, }; } for (i = 0, h = udp4_l2_mh_sock; i < UDP_TAP_FRAMES; i++, h++) { struct msghdr *mh = &h->msg_hdr; mh->msg_name = &udp4_l2_buf[i].s_in; mh->msg_namelen = sizeof(udp4_l2_buf[i].s_in); udp4_l2_iov_sock[i].iov_base = udp4_l2_buf[i].data; udp4_l2_iov_sock[i].iov_len = sizeof(udp4_l2_buf[i].data); mh->msg_iov = &udp4_l2_iov_sock[i]; mh->msg_iovlen = 1; } for (i = 0, h = udp4_l2_mh_tap; i < UDP_TAP_FRAMES; i++, h++) { struct msghdr *mh = &h->msg_hdr; udp4_l2_iov_tap[i].iov_base = &udp4_l2_buf[i].vnet_len; mh->msg_iov = &udp4_l2_iov_tap[i]; mh->msg_iovlen = 1; } } /** * udp_sock6_iov_init() - Initialise scatter-gather L2 buffers for IPv6 sockets */ static void udp_sock6_iov_init(void) { struct mmsghdr *h; int i; for (i = 0; i < ARRAY_SIZE(udp6_l2_buf); i++) { udp6_l2_buf[i] = (struct udp6_l2_buf_t) { { 0 }, #ifdef __AVX2__ { 0 }, #endif 0, L2_BUF_ETH_IP6_INIT, L2_BUF_IP6_INIT(IPPROTO_UDP), {{{ 0 }}}, { 0 }, }; } for (i = 0, h = udp6_l2_mh_sock; i < UDP_TAP_FRAMES; i++, h++) { struct msghdr *mh = &h->msg_hdr; mh->msg_name = &udp6_l2_buf[i].s_in6; mh->msg_namelen = sizeof(struct sockaddr_in6); udp6_l2_iov_sock[i].iov_base = udp6_l2_buf[i].data; udp6_l2_iov_sock[i].iov_len = sizeof(udp6_l2_buf[i].data); mh->msg_iov = &udp6_l2_iov_sock[i]; mh->msg_iovlen = 1; } for (i = 0, h = udp6_l2_mh_tap; i < UDP_TAP_FRAMES; i++, h++) { struct msghdr *mh = &h->msg_hdr; udp6_l2_iov_tap[i].iov_base = &udp6_l2_buf[i].vnet_len; mh->msg_iov = &udp6_l2_iov_tap[i]; mh->msg_iovlen = 1; } } /** * udp_splice_connect() - Create and connect socket for "spliced" binding * @c: Execution context * @v6: Set for IPv6 connections * @bound_sock: Originating bound socket * @src: Source port of original connection, host order * @dst: Destination port of original connection, host order * @splice: UDP_BACK_TO_INIT from init, UDP_BACK_TO_NS from namespace * * Return: connected socket, negative error code on failure * * #syscalls:pasta getsockname */ int udp_splice_connect(struct ctx *c, int v6, int bound_sock, in_port_t src, in_port_t dst, int splice) { struct epoll_event ev = { .events = EPOLLIN | EPOLLRDHUP | EPOLLHUP }; union epoll_ref ref = { .r.proto = IPPROTO_UDP, .r.p.udp.udp = { .splice = splice, .v6 = v6 } }; struct sockaddr_storage sa; struct udp_splice_port *sp; socklen_t sl = sizeof(sa); int s; s = socket(v6 ? AF_INET6 : AF_INET, SOCK_DGRAM | SOCK_NONBLOCK, IPPROTO_UDP); if (s < 0) return s; ref.r.s = s; if (v6) { struct sockaddr_in6 addr6 = { .sin6_family = AF_INET6, .sin6_port = htons(dst), .sin6_addr = IN6ADDR_LOOPBACK_INIT, }; if (connect(s, (struct sockaddr *)&addr6, sizeof(addr6))) goto fail; } else { struct sockaddr_in addr4 = { .sin_family = AF_INET, .sin_port = htons(dst), .sin_addr = { .s_addr = htonl(INADDR_LOOPBACK) }, }; if (connect(s, (struct sockaddr *)&addr4, sizeof(addr4))) goto fail; } if (getsockname(s, (struct sockaddr *)&sa, &sl)) goto fail; if (v6) { struct sockaddr_in6 sa6; memcpy(&sa6, &sa, sizeof(sa6)); ref.r.p.udp.udp.port = ntohs(sa6.sin6_port); } else { struct sockaddr_in sa4; memcpy(&sa4, &sa, sizeof(sa4)); ref.r.p.udp.udp.port = ntohs(sa4.sin_port); } sp = &udp_splice_map[v6 ? V6 : V4][ref.r.p.udp.udp.port]; if (splice == UDP_BACK_TO_INIT) { sp->init_bound_sock = bound_sock; sp->init_dst_port = src; udp_splice_map[v6 ? V6 : V4][src].ns_conn_sock = s; bitmap_set(udp_act[v6 ? V6 : V4][UDP_ACT_NS_CONN], src); } else if (splice == UDP_BACK_TO_NS) { sp->ns_bound_sock = bound_sock; sp->ns_dst_port = src; udp_splice_map[v6 ? V6 : V4][src].init_conn_sock = s; bitmap_set(udp_act[v6 ? V6 : V4][UDP_ACT_INIT_CONN], src); } ev.data.u64 = ref.u64; epoll_ctl(c->epollfd, EPOLL_CTL_ADD, s, &ev); return s; fail: close(s); return -1; } /** * struct udp_splice_connect_ns_arg - Arguments for udp_splice_connect_ns() * @c: Execution context * @v6: Set for inbound IPv6 connection * @bound_sock: Originating bound socket * @src: Source port of original connection, host order * @dst: Destination port of original connection, host order * @s: Newly created socket or negative error code */ struct udp_splice_connect_ns_arg { struct ctx *c; int v6; int bound_sock; in_port_t src; in_port_t dst; int s; }; /** * udp_splice_connect_ns() - Enter namespace and call udp_splice_connect() * @arg: See struct udp_splice_connect_ns_arg * * Return: 0 */ static int udp_splice_connect_ns(void *arg) { struct udp_splice_connect_ns_arg *a; a = (struct udp_splice_connect_ns_arg *)arg; if (ns_enter(a->c)) return 0; a->s = udp_splice_connect(a->c, a->v6, a->bound_sock, a->src, a->dst, UDP_BACK_TO_INIT); return 0; } /** * udp_sock_handler_splice() - Handler for socket mapped to "spliced" connection * @c: Execution context * @ref: epoll reference * @events: epoll events bitmap * @now: Current timestamp */ static void udp_sock_handler_splice(struct ctx *c, union epoll_ref ref, uint32_t events, struct timespec *now) { in_port_t src, dst = ref.r.p.udp.udp.port, send_dst = 0; struct msghdr *mh = &udp_splice_mmh_recv[0].msg_hdr; struct sockaddr_storage *sa_s = mh->msg_name; int s, v6 = ref.r.p.udp.udp.v6, n, i; if (!(events & EPOLLIN)) return; n = recvmmsg(ref.r.s, udp_splice_mmh_recv, UDP_SPLICE_FRAMES, 0, NULL); if (n <= 0) return; if (v6) { struct sockaddr_in6 *sa = (struct sockaddr_in6 *)sa_s; src = htons(sa->sin6_port); } else { struct sockaddr_in *sa = (struct sockaddr_in *)sa_s; src = ntohs(sa->sin_port); } switch (ref.r.p.udp.udp.splice) { case UDP_TO_NS: src += udp_port_delta_from_init[src]; if (!(s = udp_splice_map[v6][src].ns_conn_sock)) { struct udp_splice_connect_ns_arg arg = { c, v6, ref.r.s, src, dst, -1, }; NS_CALL(udp_splice_connect_ns, &arg); if ((s = arg.s) < 0) return; } udp_splice_map[v6][src].ns_conn_ts = now->tv_sec; break; case UDP_BACK_TO_INIT: if (!(s = udp_splice_map[v6][dst].init_bound_sock)) return; send_dst = udp_splice_map[v6][dst].init_dst_port; break; case UDP_TO_INIT: src += udp_port_delta_from_tap[src]; if (!(s = udp_splice_map[v6][src].init_conn_sock)) { s = udp_splice_connect(c, v6, ref.r.s, src, dst, UDP_BACK_TO_NS); if (s < 0) return; } udp_splice_map[v6][src].init_conn_ts = now->tv_sec; break; case UDP_BACK_TO_NS: if (!(s = udp_splice_map[v6][dst].ns_bound_sock)) return; send_dst = udp_splice_map[v6][dst].ns_dst_port; break; default: return; } if (ref.r.p.udp.udp.splice == UDP_TO_NS || ref.r.p.udp.udp.splice == UDP_TO_INIT) { for (i = 0; i < n; i++) { struct msghdr *mh_s = &udp_splice_mmh_send[i].msg_hdr; mh_s->msg_iov->iov_len = udp_splice_mmh_recv[i].msg_len; } sendmmsg(s, udp_splice_mmh_send, n, MSG_NOSIGNAL); return; } for (i = 0; i < n; i++) { struct msghdr *mh_s = &udp_splice_mmh_sendto[i].msg_hdr; mh_s->msg_iov->iov_len = udp_splice_mmh_recv[i].msg_len; } if (v6) { *((struct sockaddr_in6 *)&udp_splice_namebuf) = ((struct sockaddr_in6) { .sin6_family = AF_INET6, .sin6_addr = IN6ADDR_LOOPBACK_INIT, .sin6_port = htons(send_dst), }); } else { *((struct sockaddr_in *)&udp_splice_namebuf) = ((struct sockaddr_in) { .sin_family = AF_INET, .sin_addr = { .s_addr = htonl(INADDR_LOOPBACK) }, .sin_port = htons(send_dst), }); } sendmmsg(s, udp_splice_mmh_sendto, n, MSG_NOSIGNAL); } /** * udp_sock_handler() - Handle new data from socket * @c: Execution context * @ref: epoll reference * @events: epoll events bitmap * @now: Current timestamp * * #syscalls recvmmsg * #syscalls:passt sendmmsg sendmsg */ void udp_sock_handler(struct ctx *c, union epoll_ref ref, uint32_t events, struct timespec *now) { int iov_in_msg, msg_i = 0, ret; ssize_t n, msglen, missing = 0; struct mmsghdr *tap_mmh; struct msghdr *cur_mh; unsigned int i; if (events == EPOLLERR) return; if (ref.r.p.udp.udp.splice) { udp_sock_handler_splice(c, ref, events, now); return; } if (ref.r.p.udp.udp.v6) { n = recvmmsg(ref.r.s, udp6_l2_mh_sock, UDP_TAP_FRAMES, 0, NULL); if (n <= 0) return; cur_mh = &udp6_l2_mh_tap[msg_i].msg_hdr; cur_mh->msg_iov = &udp6_l2_iov_tap[0]; msg_i = msglen = iov_in_msg = 0; for (i = 0; i < (unsigned)n; i++) { struct udp6_l2_buf_t *b = &udp6_l2_buf[i]; size_t ip_len, iov_len; ip_len = udp6_l2_mh_sock[i].msg_len + sizeof(b->ip6h) + sizeof(b->uh); b->ip6h.payload_len = htons(udp6_l2_mh_sock[i].msg_len + sizeof(b->uh)); if (IN6_IS_ADDR_LINKLOCAL(&b->s_in6.sin6_addr)) { b->ip6h.daddr = c->addr6_ll_seen; b->ip6h.saddr = b->s_in6.sin6_addr; } else if (IN6_IS_ADDR_LOOPBACK(&b->s_in6.sin6_addr) || !memcmp(&b->s_in6.sin6_addr, &c->addr6_seen, sizeof(c->addr6))) { in_port_t src = htons(b->s_in6.sin6_port); b->ip6h.daddr = c->addr6_ll_seen; if (IN6_IS_ADDR_LINKLOCAL(&c->gw6)) b->ip6h.saddr = c->gw6; else b->ip6h.saddr = c->addr6_ll; udp_tap_map[V6][src].ts_local = now->tv_sec; if (IN6_IS_ADDR_LOOPBACK(&b->s_in6.sin6_addr)) udp_tap_map[V6][src].loopback = 1; else udp_tap_map[V6][src].loopback = 0; bitmap_set(udp_act[V6][UDP_ACT_TAP], src); } else if (!IN6_IS_ADDR_UNSPECIFIED(&c->dns6_fwd) && !memcmp(&b->s_in6.sin6_addr, &c->dns6_fwd, sizeof(c->dns6_fwd)) && ntohs(b->s_in6.sin6_port) == 53) { b->ip6h.daddr = c->addr6_seen; b->ip6h.saddr = c->dns6_fwd; } else { b->ip6h.daddr = c->addr6_seen; b->ip6h.saddr = b->s_in6.sin6_addr; } b->uh.source = b->s_in6.sin6_port; b->uh.dest = htons(ref.r.p.udp.udp.port); b->uh.len = b->ip6h.payload_len; b->ip6h.hop_limit = IPPROTO_UDP; b->ip6h.version = 0; b->ip6h.nexthdr = 0; b->uh.check = 0; b->uh.check = csum(&b->ip6h, ip_len, 0); b->ip6h.version = 6; b->ip6h.nexthdr = IPPROTO_UDP; b->ip6h.hop_limit = 255; if (c->mode == MODE_PASTA) { ip_len += sizeof(struct ethhdr); if (write(c->fd_tap, &b->eh, ip_len) < 0) debug("tap write: %s", strerror(errno)); pcap((char *)&b->eh, ip_len); continue; } b->vnet_len = htonl(ip_len + sizeof(struct ethhdr)); iov_len = sizeof(uint32_t) + sizeof(struct ethhdr) + ip_len; udp6_l2_iov_tap[i].iov_len = iov_len; /* With bigger messages, qemu closes the connection. */ if (iov_in_msg && msglen + iov_len > SHRT_MAX) { cur_mh->msg_iovlen = iov_in_msg; cur_mh = &udp6_l2_mh_tap[++msg_i].msg_hdr; msglen = iov_in_msg = 0; cur_mh->msg_iov = &udp6_l2_iov_tap[i]; } msglen += iov_len; iov_in_msg++; } tap_mmh = udp6_l2_mh_tap; } else { n = recvmmsg(ref.r.s, udp4_l2_mh_sock, UDP_TAP_FRAMES, 0, NULL); if (n <= 0) return; cur_mh = &udp4_l2_mh_tap[msg_i].msg_hdr; cur_mh->msg_iov = &udp4_l2_iov_tap[0]; msg_i = msglen = iov_in_msg = 0; for (i = 0; i < (unsigned)n; i++) { struct udp4_l2_buf_t *b = &udp4_l2_buf[i]; size_t ip_len, iov_len; in_addr_t s_addr; ip_len = udp4_l2_mh_sock[i].msg_len + sizeof(b->iph) + sizeof(b->uh); b->iph.tot_len = htons(ip_len); s_addr = ntohl(b->s_in.sin_addr.s_addr); if (s_addr >> IN_CLASSA_NSHIFT == IN_LOOPBACKNET || s_addr == INADDR_ANY || s_addr == ntohl(c->addr4_seen)) { in_port_t src = htons(b->s_in.sin_port); b->iph.saddr = c->gw4; udp_tap_map[V4][src].ts_local = now->tv_sec; if (b->s_in.sin_addr.s_addr == c->addr4_seen) udp_tap_map[V4][src].loopback = 0; else udp_tap_map[V4][src].loopback = 1; bitmap_set(udp_act[V4][UDP_ACT_TAP], src); } else if (c->dns4_fwd && s_addr == ntohl(c->dns4[0]) && ntohs(b->s_in.sin_port) == 53) { b->iph.saddr = c->dns4_fwd; } else { b->iph.saddr = b->s_in.sin_addr.s_addr; } udp_update_check4(b); b->uh.source = b->s_in.sin_port; b->uh.dest = htons(ref.r.p.udp.udp.port); b->uh.len = ntohs(udp4_l2_mh_sock[i].msg_len + sizeof(b->uh)); if (c->mode == MODE_PASTA) { ip_len += sizeof(struct ethhdr); if (write(c->fd_tap, &b->eh, ip_len) < 0) debug("tap write: %s", strerror(errno)); pcap((char *)&b->eh, ip_len); continue; } b->vnet_len = htonl(ip_len + sizeof(struct ethhdr)); iov_len = sizeof(uint32_t) + sizeof(struct ethhdr) + ip_len; udp4_l2_iov_tap[i].iov_len = iov_len; /* With bigger messages, qemu closes the connection. */ if (iov_in_msg && msglen + iov_len > SHRT_MAX) { cur_mh->msg_iovlen = iov_in_msg; cur_mh = &udp4_l2_mh_tap[++msg_i].msg_hdr; msglen = iov_in_msg = 0; cur_mh->msg_iov = &udp4_l2_iov_tap[i]; } msglen += iov_len; iov_in_msg++; } tap_mmh = udp4_l2_mh_tap; } if (c->mode == MODE_PASTA) return; cur_mh->msg_iovlen = iov_in_msg; ret = sendmmsg(c->fd_tap, tap_mmh, msg_i + 1, MSG_NOSIGNAL | MSG_DONTWAIT); if (ret <= 0) return; /* If we lose some messages to sendmmsg() here, fine, it's UDP. However, * the last message needs to be delivered completely, otherwise qemu * will fail to reassemble the next message and close the connection. Go * through headers from the last sent message, counting bytes, and, if * and as soon as we see more bytes than sendmmsg() sent, re-send the * rest with a blocking call. * * In pictures, given this example: * * iov #0 iov #1 iov #2 iov #3 * tap_mmh[ret - 1].msg_hdr: .... ...... ..... ...... * tap_mmh[ret - 1].msg_len: 7 .... ... * * when 'msglen' reaches: 10 ^ * and 'missing' below is: 3 --- * * re-send everything from here: ^-- ----- ------ */ cur_mh = &tap_mmh[ret - 1].msg_hdr; for (i = 0, msglen = 0; i < cur_mh->msg_iovlen; i++) { if (missing <= 0) { msglen += cur_mh->msg_iov[i].iov_len; missing = msglen - tap_mmh[ret - 1].msg_len; } if (missing > 0) { uint8_t **iov_base; int first_offset; iov_base = (uint8_t **)&cur_mh->msg_iov[i].iov_base; first_offset = cur_mh->msg_iov[i].iov_len - missing; *iov_base += first_offset; cur_mh->msg_iov[i].iov_len = missing; cur_mh->msg_iov = &cur_mh->msg_iov[i]; sendmsg(c->fd_tap, cur_mh, MSG_NOSIGNAL); *iov_base -= first_offset; break; } } pcapmm(tap_mmh, ret); } /** * udp_tap_handler() - Handle packets from tap * @c: Execution context * @af: Address family, AF_INET or AF_INET6 * @addr: Destination address * @msg: Input messages * @count: Message count * @now: Current timestamp * * Return: count of consumed packets * * #syscalls sendmmsg */ int udp_tap_handler(struct ctx *c, int af, void *addr, struct tap_l4_msg *msg, int count, struct timespec *now) { /* The caller already checks that all the messages have the same source * and destination, so we can just take those from the first message. */ struct udphdr *uh = (struct udphdr *)(pkt_buf + msg[0].pkt_buf_offset); struct mmsghdr mm[UIO_MAXIOV] = { 0 }; struct iovec m[UIO_MAXIOV]; struct sockaddr_in6 s_in6; struct sockaddr_in s_in; struct sockaddr *sa; in_port_t src, dst; socklen_t sl; int i, s; (void)c; if (msg[0].l4_len < sizeof(*uh)) return 1; src = ntohs(uh->source); dst = ntohs(uh->dest); if (af == AF_INET) { s_in = (struct sockaddr_in) { .sin_family = AF_INET, .sin_port = uh->dest, .sin_addr = *(struct in_addr *)addr, }; sa = (struct sockaddr *)&s_in; sl = sizeof(s_in); if (!(s = udp_tap_map[V4][src].sock)) { union udp_epoll_ref uref = { .udp.bound = 1, .udp.port = src }; s = sock_l4(c, AF_INET, IPPROTO_UDP, src, 0, uref.u32); if (s <= 0) return count; udp_tap_map[V4][src].sock = s; bitmap_set(udp_act[V4][UDP_ACT_TAP], src); } udp_tap_map[V4][src].ts = now->tv_sec; if (s_in.sin_addr.s_addr == c->gw4 && !c->no_map_gw) { if (!udp_tap_map[V4][dst].ts_local || udp_tap_map[V4][dst].loopback) s_in.sin_addr.s_addr = htonl(INADDR_LOOPBACK); else s_in.sin_addr.s_addr = c->addr4_seen; } else if (s_in.sin_addr.s_addr == c->dns4_fwd && ntohs(s_in.sin_port) == 53) { s_in.sin_addr.s_addr = c->dns4[0]; } } else { s_in6 = (struct sockaddr_in6) { .sin6_family = AF_INET6, .sin6_port = uh->dest, .sin6_addr = *(struct in6_addr *)addr, }; enum bind_type bind_to = BIND_ANY; sa = (struct sockaddr *)&s_in6; sl = sizeof(s_in6); if (!memcmp(addr, &c->gw6, sizeof(c->gw6)) && !c->no_map_gw) { if (!udp_tap_map[V6][dst].ts_local || udp_tap_map[V6][dst].loopback) s_in6.sin6_addr = in6addr_loopback; else s_in6.sin6_addr = c->addr6_seen; } else if (!memcmp(addr, &c->dns6_fwd, sizeof(c->dns6_fwd)) && ntohs(s_in6.sin6_port) == 53) { s_in6.sin6_addr = c->dns6[0]; } else if (IN6_IS_ADDR_LINKLOCAL(&s_in6.sin6_addr)) { bind_to = BIND_LL; } if (!(s = udp_tap_map[V6][src].sock)) { union udp_epoll_ref uref = { .udp.bound = 1, .udp.v6 = 1, .udp.port = src }; s = sock_l4(c, AF_INET6, IPPROTO_UDP, src, bind_to, uref.u32); if (s <= 0) return count; udp_tap_map[V6][src].sock = s; bitmap_set(udp_act[V6][UDP_ACT_TAP], src); } udp_tap_map[V6][src].ts = now->tv_sec; } for (i = 0; i < count; i++) { struct udphdr *uh_send; uh_send = (struct udphdr *)(msg[i].pkt_buf_offset + pkt_buf); m[i].iov_base = (char *)(uh_send + 1); m[i].iov_len = msg[i].l4_len - sizeof(*uh_send); mm[i].msg_hdr.msg_name = sa; mm[i].msg_hdr.msg_namelen = sl; mm[i].msg_hdr.msg_iov = m + i; mm[i].msg_hdr.msg_iovlen = 1; } count = sendmmsg(s, mm, count, MSG_NOSIGNAL); if (count < 0) return 1; return count; } /** * udp_sock_init_ns() - Bind sockets in namespace for inbound connections * @arg: Execution context * * Return: 0 */ int udp_sock_init_ns(void *arg) { union udp_epoll_ref uref = { .udp.bound = 1, .udp.splice = UDP_TO_INIT }; struct ctx *c = (struct ctx *)arg; int dst; if (ns_enter(c)) return 0; for (dst = 0; dst < USHRT_MAX; dst++) { if (!bitmap_isset(c->udp.port_to_init, dst)) continue; uref.udp.port = dst + udp_port_delta_to_init[dst]; if (c->v4) { uref.udp.v6 = 0; sock_l4(c, AF_INET, IPPROTO_UDP, dst, BIND_LOOPBACK, uref.u32); } if (c->v6) { uref.udp.v6 = 1; sock_l4(c, AF_INET6, IPPROTO_UDP, dst, BIND_LOOPBACK, uref.u32); } } return 0; } /** * udp_splice_iov_init() - Set up buffers and descriptors for recvmmsg/sendmmsg */ static void udp_splice_iov_init(void) { struct mmsghdr *h; struct iovec *iov; int i; for (i = 0, h = udp_splice_mmh_recv; i < UDP_SPLICE_FRAMES; i++, h++) { struct msghdr *mh = &h->msg_hdr; if (!i) { mh->msg_name = &udp_splice_namebuf; mh->msg_namelen = sizeof(udp_splice_namebuf); } mh->msg_iov = &udp_splice_iov_recv[i]; mh->msg_iovlen = 1; } for (i = 0, iov = udp_splice_iov_recv; i < UDP_SPLICE_FRAMES; i++, iov++) { iov->iov_base = udp_splice_buf[i]; iov->iov_len = sizeof(udp_splice_buf[i]); } for (i = 0, h = udp_splice_mmh_send; i < UDP_SPLICE_FRAMES; i++, h++) { struct msghdr *mh = &h->msg_hdr; mh->msg_iov = &udp_splice_iov_send[i]; mh->msg_iovlen = 1; } for (i = 0, iov = udp_splice_iov_send; i < UDP_SPLICE_FRAMES; i++, iov++) { iov->iov_base = udp_splice_buf[i]; } for (i = 0, h = udp_splice_mmh_sendto; i < UDP_SPLICE_FRAMES; i++, h++) { struct msghdr *mh = &h->msg_hdr; mh->msg_name = &udp_splice_namebuf; mh->msg_namelen = sizeof(udp_splice_namebuf); mh->msg_iov = &udp_splice_iov_sendto[i]; mh->msg_iovlen = 1; } for (i = 0, iov = udp_splice_iov_sendto; i < UDP_SPLICE_FRAMES; i++, iov++) { iov->iov_base = udp_splice_buf[i]; } } /** * udp_sock_init() - Create and bind listening sockets for inbound packets * @c: Execution context * * Return: 0 on success, -1 on failure */ int udp_sock_init(struct ctx *c, struct timespec *now) { union udp_epoll_ref uref = { .udp.bound = 1 }; int dst, s; (void)now; for (dst = 0; dst < USHRT_MAX; dst++) { if (!bitmap_isset(c->udp.port_to_tap, dst)) continue; uref.udp.port = dst + udp_port_delta_to_tap[dst]; if (c->v4) { uref.udp.splice = 0; uref.udp.v6 = 0; s = sock_l4(c, AF_INET, IPPROTO_UDP, dst, c->mode == MODE_PASTA ? BIND_EXT : BIND_ANY, uref.u32); if (s > 0) udp_tap_map[V4][uref.udp.port].sock = s; if (c->mode == MODE_PASTA) { uref.udp.splice = UDP_TO_NS; sock_l4(c, AF_INET, IPPROTO_UDP, dst, BIND_LOOPBACK, uref.u32); } } if (c->v6) { uref.udp.splice = 0; uref.udp.v6 = 1; s = sock_l4(c, AF_INET6, IPPROTO_UDP, dst, c->mode == MODE_PASTA ? BIND_EXT : BIND_ANY, uref.u32); if (s > 0) udp_tap_map[V6][uref.udp.port].sock = s; if (c->mode == MODE_PASTA) { uref.udp.splice = UDP_TO_NS; sock_l4(c, AF_INET6, IPPROTO_UDP, dst, BIND_LOOPBACK, uref.u32); } } } if (c->v4) udp_sock4_iov_init(); if (c->v6) udp_sock6_iov_init(); if (c->mode == MODE_PASTA) { udp_splice_iov_init(); NS_CALL(udp_sock_init_ns, c); } return 0; } /** * udp_timer_one() - Handler for timed events on one port * @c: Execution context * @v6: Set for IPv6 connections * @type: Socket type * @port: Port number, host order * @ts: Timestamp from caller */ static void udp_timer_one(struct ctx *c, int v6, enum udp_act_type type, in_port_t port, struct timespec *ts) { struct udp_splice_port *sp; struct udp_tap_port *tp; int s = -1; switch (type) { case UDP_ACT_TAP: tp = &udp_tap_map[v6 ? V6 : V4][port]; if (ts->tv_sec - tp->ts > UDP_CONN_TIMEOUT) s = tp->sock; if (ts->tv_sec - tp->ts_local > UDP_CONN_TIMEOUT) tp->ts_local = 0; break; case UDP_ACT_INIT_CONN: sp = &udp_splice_map[v6 ? V6 : V4][port]; if (ts->tv_sec - sp->init_conn_ts > UDP_CONN_TIMEOUT) s = sp->init_conn_sock; break; case UDP_ACT_NS_CONN: sp = &udp_splice_map[v6 ? V6 : V4][port]; if (ts->tv_sec - sp->ns_conn_ts > UDP_CONN_TIMEOUT) s = sp->ns_conn_sock; break; default: return; } if (s > 0) { epoll_ctl(c->epollfd, EPOLL_CTL_DEL, s, NULL); close(s); bitmap_clear(udp_act[v6 ? V6 : V4][type], port); } } /** * udp_timer() - Scan activity bitmaps for ports with associated timed events * @c: Execution context * @ts: Timestamp from caller */ void udp_timer(struct ctx *c, struct timespec *ts) { int n, t, v6 = 0; unsigned int i; long *word, tmp; if (!c->v4) v6 = 1; v6: for (t = 0; t < UDP_ACT_TYPE_MAX; t++) { word = (long *)udp_act[v6 ? V6 : V4][t]; for (i = 0; i < ARRAY_SIZE(udp_act[0][0]); i += sizeof(long), word++) { tmp = *word; while ((n = ffsl(tmp))) { tmp &= ~(1UL << (n - 1)); udp_timer_one(c, v6, t, i * 8 + n - 1, ts); } } } if (!v6 && c->v6) { v6 = 1; goto v6; } }