/* $Id: pxping.c 54124 2015-02-10 11:22:04Z vboxsync $ */ /** @file * NAT Network - ping proxy, raw sockets version. */ /* * Copyright (C) 2013-2014 Oracle Corporation * * This file is part of VirtualBox Open Source Edition (OSE), as * available from http://www.virtualbox.org. This file is free software; * you can redistribute it and/or modify it under the terms of the GNU * General Public License (GPL) as published by the Free Software * Foundation, in version 2 as it comes in the "COPYING" file of the * VirtualBox OSE distribution. VirtualBox OSE is distributed in the * hope that it will be useful, but WITHOUT ANY WARRANTY of any kind. */ #define LOG_GROUP LOG_GROUP_NAT_SERVICE #include "winutils.h" #include "proxy.h" #include "proxy_pollmgr.h" #include "pxremap.h" #include #ifndef RT_OS_WINDOWS #include #include #ifdef RT_OS_DARWIN # define __APPLE_USE_RFC_3542 #endif #include #include #include #include #include #include #else #include #include #include #include #include "winpoll.h" #endif #include "lwip/opt.h" #include "lwip/sys.h" #include "lwip/tcpip.h" #include "lwip/inet_chksum.h" #include "lwip/ip.h" #include "lwip/icmp.h" #if defined(RT_OS_LINUX) && !defined(__USE_GNU) #if __GLIBC_PREREQ(2, 8) /* * XXX: This is gross. in6_pktinfo is now hidden behind _GNU_SOURCE * https://sourceware.org/bugzilla/show_bug.cgi?id=6775 * * But in older glibc versions, e.g. RHEL5, it is not! I don't want * to deal with _GNU_SOURCE now, so as a kludge check for glibc * version. It seems the __USE_GNU guard was introduced in 2.8. */ struct in6_pktinfo { struct in6_addr ipi6_addr; unsigned int ipi6_ifindex; }; #endif /* __GLIBC_PREREQ */ #endif /* RT_OS_LINUX && !__USE_GNU */ /* forward */ struct ping_pcb; /** * Global state for ping proxy collected in one entity to minimize * globals. There's only one instance of this structure. * * Raw ICMP sockets are promiscuous, so it doesn't make sense to have * multiple. If this code ever needs to support multiple netifs, the * netif member should be exiled into "pcb". */ struct pxping { SOCKET sock4; #if defined(RT_OS_DARWIN) || defined(RT_OS_SOLARIS) # define DF_WITH_IP_HDRINCL int hdrincl; #else int df; #endif int ttl; int tos; SOCKET sock6; #ifdef RT_OS_WINDOWS LPFN_WSARECVMSG pfWSARecvMsg6; #endif int hopl; struct pollmgr_handler pmhdl4; struct pollmgr_handler pmhdl6; struct netif *netif; /** * Protect lwIP and pmgr accesses to the list of pcbs. */ sys_mutex_t lock; /* * We need to find pcbs both from the guest side and from the host * side. If we need to support industrial grade ping throughput, * we will need two pcb hashes. For now, a short linked list * should be enough. Cf. pxping_pcb_for_request() and * pxping_pcb_for_reply(). */ #define PXPING_MAX_PCBS 8 size_t npcbs; struct ping_pcb *pcbs; #define TIMEOUT 5 int timer_active; size_t timeout_slot; struct ping_pcb *timeout_list[TIMEOUT]; }; /** * Quasi PCB for ping. */ struct ping_pcb { ipX_addr_t src; ipX_addr_t dst; u8_t is_ipv6; u8_t is_mapped; u16_t guest_id; u16_t host_id; /** * Desired slot in pxping::timeout_list. See pxping_timer(). */ size_t timeout_slot; /** * Chaining for pxping::timeout_list */ struct ping_pcb **pprev_timeout; struct ping_pcb *next_timeout; /** * Chaining for pxping::pcbs */ struct ping_pcb *next; union { struct sockaddr_in sin; struct sockaddr_in6 sin6; } peer; }; /** * lwIP thread callback message for IPv4 ping. * * We pass raw IP datagram for ip_output_if() so we only need pbuf and * netif (from pxping). */ struct ping_msg { struct tcpip_msg msg; struct pxping *pxping; struct pbuf *p; }; /** * lwIP thread callback message for IPv6 ping. * * We cannot obtain raw IPv6 datagram from host without extra trouble, * so we pass ICMPv6 payload in pbuf and also other parameters to * ip6_output_if(). */ struct ping6_msg { struct tcpip_msg msg; struct pxping *pxping; struct pbuf *p; ip6_addr_t src, dst; int hopl, tclass; }; #ifdef RT_OS_WINDOWS static int pxping_init_windows(struct pxping *pxping); #endif static void pxping_recv4(void *arg, struct pbuf *p); static void pxping_recv6(void *arg, struct pbuf *p); static void pxping_timer(void *arg); static void pxping_timer_needed(struct pxping *pxping); static struct ping_pcb *pxping_pcb_for_request(struct pxping *pxping, int is_ipv6, ipX_addr_t *src, ipX_addr_t *dst, u16_t guest_id); static struct ping_pcb *pxping_pcb_for_reply(struct pxping *pxping, int is_ipv6, ipX_addr_t *dst, u16_t host_id); static FNRTSTRFORMATTYPE pxping_pcb_rtstrfmt; static struct ping_pcb *pxping_pcb_allocate(struct pxping *pxping); static void pxping_pcb_register(struct pxping *pxping, struct ping_pcb *pcb); static void pxping_pcb_deregister(struct pxping *pxping, struct ping_pcb *pcb); static void pxping_pcb_delete(struct pxping *pxping, struct ping_pcb *pcb); static void pxping_timeout_add(struct pxping *pxping, struct ping_pcb *pcb); static void pxping_timeout_del(struct pxping *pxping, struct ping_pcb *pcb); static int pxping_pmgr_pump(struct pollmgr_handler *handler, SOCKET fd, int revents); static void pxping_pmgr_icmp4(struct pxping *pxping); static void pxping_pmgr_icmp4_echo(struct pxping *pxping, u16_t iplen, struct sockaddr_in *peer); static void pxping_pmgr_icmp4_error(struct pxping *pxping, u16_t iplen, struct sockaddr_in *peer); static void pxping_pmgr_icmp6(struct pxping *pxping); static void pxping_pmgr_icmp6_echo(struct pxping *pxping, ip6_addr_t *src, ip6_addr_t *dst, int hopl, int tclass, u16_t icmplen); static void pxping_pmgr_icmp6_error(struct pxping *pxping, ip6_addr_t *src, ip6_addr_t *dst, int hopl, int tclass, u16_t icmplen); static void pxping_pmgr_forward_inbound(struct pxping *pxping, u16_t iplen); static void pxping_pcb_forward_inbound(void *arg); static void pxping_pmgr_forward_inbound6(struct pxping *pxping, ip6_addr_t *src, ip6_addr_t *dst, u8_t hopl, u8_t tclass, u16_t icmplen); static void pxping_pcb_forward_inbound6(void *arg); /* * NB: This is not documented except in RTFS. * * If ip_output_if() is passed dest == NULL then it treats p as * complete IP packet with payload pointing to the IP header. It does * not build IP header, ignores all header-related arguments, fetches * real destination from the header in the pbuf and outputs pbuf to * the specified netif. */ #define ip_raw_output_if(p, netif) \ (ip_output_if((p), NULL, NULL, 0, 0, 0, (netif))) static struct pxping g_pxping; err_t pxping_init(struct netif *netif, SOCKET sock4, SOCKET sock6) { const int on = 1; int status; if (sock4 == INVALID_SOCKET && sock6 == INVALID_SOCKET) { return ERR_VAL; } g_pxping.netif = netif; sys_mutex_new(&g_pxping.lock); g_pxping.sock4 = sock4; if (g_pxping.sock4 != INVALID_SOCKET) { #ifdef DF_WITH_IP_HDRINCL g_pxping.hdrincl = 0; #else g_pxping.df = -1; #endif g_pxping.ttl = -1; g_pxping.tos = 0; #ifdef RT_OS_LINUX { const int dont = IP_PMTUDISC_DONT; status = setsockopt(sock4, IPPROTO_IP, IP_MTU_DISCOVER, &dont, sizeof(dont)); if (status != 0) { DPRINTF(("IP_MTU_DISCOVER: %R[sockerr]\n", SOCKERRNO())); } } #endif /* RT_OS_LINUX */ g_pxping.pmhdl4.callback = pxping_pmgr_pump; g_pxping.pmhdl4.data = (void *)&g_pxping; g_pxping.pmhdl4.slot = -1; pollmgr_add(&g_pxping.pmhdl4, g_pxping.sock4, POLLIN); ping_proxy_accept(pxping_recv4, &g_pxping); } g_pxping.sock6 = sock6; #ifdef RT_OS_WINDOWS /* we need recvmsg */ if (g_pxping.sock6 != INVALID_SOCKET) { status = pxping_init_windows(&g_pxping); if (status == SOCKET_ERROR) { g_pxping.sock6 = INVALID_SOCKET; /* close(sock6); */ } } #endif if (g_pxping.sock6 != INVALID_SOCKET) { g_pxping.hopl = -1; #if !defined(IPV6_RECVPKTINFO) #define IPV6_RECVPKTINFO (IPV6_PKTINFO) #endif status = setsockopt(sock6, IPPROTO_IPV6, IPV6_RECVPKTINFO, (const char *)&on, sizeof(on)); if (status < 0) { DPRINTF(("IPV6_RECVPKTINFO: %R[sockerr]\n", SOCKERRNO())); /* XXX: for now this is fatal */ } #if !defined(IPV6_RECVHOPLIMIT) #define IPV6_RECVHOPLIMIT (IPV6_HOPLIMIT) #endif status = setsockopt(sock6, IPPROTO_IPV6, IPV6_RECVHOPLIMIT, (const char *)&on, sizeof(on)); if (status < 0) { DPRINTF(("IPV6_RECVHOPLIMIT: %R[sockerr]\n", SOCKERRNO())); } #ifdef IPV6_RECVTCLASS /* new in RFC 3542, there's no RFC 2292 counterpart */ /* TODO: IPV6_RECVTCLASS */ #endif g_pxping.pmhdl6.callback = pxping_pmgr_pump; g_pxping.pmhdl6.data = (void *)&g_pxping; g_pxping.pmhdl6.slot = -1; pollmgr_add(&g_pxping.pmhdl6, g_pxping.sock6, POLLIN); ping6_proxy_accept(pxping_recv6, &g_pxping); } status = RTStrFormatTypeRegister("ping_pcb", pxping_pcb_rtstrfmt, NULL); AssertRC(status); return ERR_OK; } #ifdef RT_OS_WINDOWS static int pxping_init_windows(struct pxping *pxping) { GUID WSARecvMsgGUID = WSAID_WSARECVMSG; DWORD nread; int status; pxping->pfWSARecvMsg6 = NULL; status = WSAIoctl(pxping->sock6, SIO_GET_EXTENSION_FUNCTION_POINTER, &WSARecvMsgGUID, sizeof(WSARecvMsgGUID), &pxping->pfWSARecvMsg6, sizeof(pxping->pfWSARecvMsg6), &nread, NULL, NULL); return status; } #endif /* RT_OS_WINDOWS */ static u32_t chksum_delta_16(u16_t oval, u16_t nval) { u32_t sum = (u16_t)~oval; sum += nval; return sum; } static u32_t chksum_update_16(u16_t *oldp, u16_t nval) { u32_t sum = chksum_delta_16(*oldp, nval); *oldp = nval; return sum; } static u32_t chksum_delta_32(u32_t oval, u32_t nval) { u32_t sum = ~oval; sum = FOLD_U32T(sum); sum += FOLD_U32T(nval); return sum; } static u32_t chksum_update_32(u32_t *oldp, u32_t nval) { u32_t sum = chksum_delta_32(*oldp, nval); *oldp = nval; return sum; } static u32_t chksum_delta_ipv6(const ip6_addr_t *oldp, const ip6_addr_t *newp) { u32_t sum; sum = chksum_delta_32(oldp->addr[0], newp->addr[0]); sum += chksum_delta_32(oldp->addr[1], newp->addr[1]); sum += chksum_delta_32(oldp->addr[2], newp->addr[2]); sum += chksum_delta_32(oldp->addr[3], newp->addr[3]); return sum; } static u32_t chksum_update_ipv6(ip6_addr_t *oldp, const ip6_addr_t *newp) { u32_t sum; sum = chksum_update_32(&oldp->addr[0], newp->addr[0]); sum += chksum_update_32(&oldp->addr[1], newp->addr[1]); sum += chksum_update_32(&oldp->addr[2], newp->addr[2]); sum += chksum_update_32(&oldp->addr[3], newp->addr[3]); return sum; } /** * ICMP Echo Request in pbuf "p" is to be proxied. */ static void pxping_recv4(void *arg, struct pbuf *p) { struct pxping *pxping = (struct pxping *)arg; struct ping_pcb *pcb; #ifdef DF_WITH_IP_HDRINCL struct ip_hdr iph_orig; #endif struct icmp_echo_hdr icmph_orig; struct ip_hdr *iph; struct icmp_echo_hdr *icmph; int df, ttl, tos; u32_t sum; u16_t iphlen; int status; iphlen = ip_current_header_tot_len(); if (iphlen != IP_HLEN) { /* we don't do options */ pbuf_free(p); return; } iph = (/* UNCONST */ struct ip_hdr *)ip_current_header(); icmph = (struct icmp_echo_hdr *)p->payload; pcb = pxping_pcb_for_request(pxping, 0, ipX_current_src_addr(), ipX_current_dest_addr(), icmph->id); if (pcb == NULL) { pbuf_free(p); return; } DPRINTF(("ping %p: %R[ping_pcb] seq %d len %u ttl %d\n", pcb, pcb, ntohs(icmph->seqno), (unsigned int)p->tot_len, IPH_TTL(iph))); ttl = IPH_TTL(iph); if (!pcb->is_mapped) { if (RT_UNLIKELY(ttl == 1)) { status = pbuf_header(p, iphlen); /* back to IP header */ if (RT_LIKELY(status == 0)) { icmp_time_exceeded(p, ICMP_TE_TTL); } pbuf_free(p); return; } --ttl; } /* * OS X doesn't provide a socket option to control fragmentation. * Solaris doesn't provide IP_DONTFRAG on all releases we support. * In this case we have to use IP_HDRINCL. We don't want to use * it always since it doesn't handle fragmentation (but that's ok * for DF) and Windows doesn't do automatic source address * selection with IP_HDRINCL. */ df = (IPH_OFFSET(iph) & PP_HTONS(IP_DF)) != 0; #ifdef DF_WITH_IP_HDRINCL if (df != pxping->hdrincl) { status = setsockopt(pxping->sock4, IPPROTO_IP, IP_HDRINCL, &df, sizeof(df)); if (RT_LIKELY(status == 0)) { pxping->hdrincl = df; } else { DPRINTF(("IP_HDRINCL: %R[sockerr]\n", SOCKERRNO())); } } if (pxping->hdrincl) { status = pbuf_header(p, iphlen); /* back to IP header */ if (RT_UNLIKELY(status != 0)) { pbuf_free(p); return; } /* we will overwrite IP header, save original for ICMP errors */ memcpy(&iph_orig, iph, iphlen); if (pcb->is_mapped) { ip4_addr_set_u32(&iph->dest, pcb->peer.sin.sin_addr.s_addr); } if (g_proxy_options->src4 != NULL) { ip4_addr_set_u32(&iph->src, g_proxy_options->src4->sin_addr.s_addr); } else { /* let the kernel select suitable source address */ ip_addr_set_any(&iph->src); } IPH_TTL_SET(iph, ttl); /* already decremented */ IPH_ID_SET(iph, 0); /* kernel will set one */ #ifdef RT_OS_DARWIN /* wants ip_offset and ip_len fields in host order */ IPH_OFFSET_SET(iph, ntohs(IPH_OFFSET(iph))); IPH_LEN_SET(iph, ntohs(IPH_LEN(iph))); /* wants checksum of everything (sic!), in host order */ sum = inet_chksum_pbuf(p); IPH_CHKSUM_SET(iph, sum); #else /* !RT_OS_DARWIN */ IPH_CHKSUM_SET(iph, 0); /* kernel will recalculate */ #endif } else /* !pxping->hdrincl */ #endif /* DF_WITH_IP_HDRINCL */ { #if !defined(DF_WITH_IP_HDRINCL) /* control DF flag via setsockopt(2) */ #define USE_DF_OPTION(_Optname) \ const int dfopt = _Optname; \ const char * const dfoptname = #_Optname; #if defined(RT_OS_LINUX) USE_DF_OPTION(IP_MTU_DISCOVER); df = df ? IP_PMTUDISC_DO : IP_PMTUDISC_DONT; #elif defined(RT_OS_SOLARIS) || defined(RT_OS_FREEBSD) USE_DF_OPTION(IP_DONTFRAG); #elif defined(RT_OS_WINDOWS) USE_DF_OPTION(IP_DONTFRAGMENT); #endif if (df != pxping->df) { status = setsockopt(pxping->sock4, IPPROTO_IP, dfopt, (char *)&df, sizeof(df)); if (RT_LIKELY(status == 0)) { pxping->df = df; } else { DPRINTF(("%s: %R[sockerr]\n", dfoptname, SOCKERRNO())); } } #endif /* !DF_WITH_IP_HDRINCL */ if (ttl != pxping->ttl) { status = setsockopt(pxping->sock4, IPPROTO_IP, IP_TTL, (char *)&ttl, sizeof(ttl)); if (RT_LIKELY(status == 0)) { pxping->ttl = ttl; } else { DPRINTF(("IP_TTL: %R[sockerr]\n", SOCKERRNO())); } } tos = IPH_TOS(iph); if (tos != pxping->tos) { status = setsockopt(pxping->sock4, IPPROTO_IP, IP_TOS, (char *)&tos, sizeof(tos)); if (RT_LIKELY(status == 0)) { pxping->tos = tos; } else { DPRINTF(("IP_TOS: %R[sockerr]\n", SOCKERRNO())); } } } /* rewrite ICMP echo header */ memcpy(&icmph_orig, icmph, sizeof(*icmph)); sum = (u16_t)~icmph->chksum; sum += chksum_update_16(&icmph->id, pcb->host_id); sum = FOLD_U32T(sum); icmph->chksum = ~sum; status = proxy_sendto(pxping->sock4, p, &pcb->peer.sin, sizeof(pcb->peer.sin)); if (status != 0) { int error = -status; DPRINTF(("%s: sendto: %R[sockerr]\n", __func__, error)); #ifdef DF_WITH_IP_HDRINCL if (pxping->hdrincl) { /* restore original IP header */ memcpy(iph, &iph_orig, iphlen); } else #endif { status = pbuf_header(p, iphlen); /* back to IP header */ if (RT_UNLIKELY(status != 0)) { pbuf_free(p); return; } } /* restore original ICMP header */ memcpy(icmph, &icmph_orig, sizeof(*icmph)); /* * Some ICMP errors may be generated by the kernel and we read * them from the socket and forward them normally, hence the * ifdefs below. */ switch (error) { #if !( defined(RT_OS_SOLARIS) \ || (defined(RT_OS_LINUX) && !defined(DF_WITH_IP_HDRINCL)) \ ) case EMSGSIZE: icmp_dest_unreach(p, ICMP_DUR_FRAG); break; #endif case ENETDOWN: case ENETUNREACH: icmp_dest_unreach(p, ICMP_DUR_NET); break; case EHOSTDOWN: case EHOSTUNREACH: icmp_dest_unreach(p, ICMP_DUR_HOST); break; } } pbuf_free(p); } /** * ICMPv6 Echo Request in pbuf "p" is to be proxied. */ static void pxping_recv6(void *arg, struct pbuf *p) { struct pxping *pxping = (struct pxping *)arg; struct ping_pcb *pcb; struct ip6_hdr *iph; struct icmp6_echo_hdr *icmph; int hopl; u16_t iphlen; u16_t id, seq; int status; iph = (/* UNCONST */ struct ip6_hdr *)ip6_current_header(); iphlen = ip_current_header_tot_len(); icmph = (struct icmp6_echo_hdr *)p->payload; id = icmph->id; seq = icmph->seqno; pcb = pxping_pcb_for_request(pxping, 1, ipX_current_src_addr(), ipX_current_dest_addr(), id); if (pcb == NULL) { pbuf_free(p); return; } DPRINTF(("ping %p: %R[ping_pcb] seq %d len %u hopl %d\n", pcb, pcb, ntohs(seq), (unsigned int)p->tot_len, IP6H_HOPLIM(iph))); hopl = IP6H_HOPLIM(iph); if (!pcb->is_mapped) { if (hopl == 1) { status = pbuf_header(p, iphlen); /* back to IP header */ if (RT_LIKELY(status == 0)) { icmp6_time_exceeded(p, ICMP6_TE_HL); } pbuf_free(p); return; } --hopl; } /* * Rewrite ICMPv6 echo header. We don't need to recompute the * checksum since, unlike IPv4, checksum includes pseudo-header. * OS computes checksum for us on send() since it needs to select * source address. */ icmph->id = pcb->host_id; /* TODO: use control messages to save a syscall? */ if (hopl != pxping->hopl) { status = setsockopt(pxping->sock6, IPPROTO_IPV6, IPV6_UNICAST_HOPS, (char *)&hopl, sizeof(hopl)); if (status == 0) { pxping->hopl = hopl; } else { DPRINTF(("IPV6_HOPLIMIT: %R[sockerr]\n", SOCKERRNO())); } } status = proxy_sendto(pxping->sock6, p, &pcb->peer.sin6, sizeof(pcb->peer.sin6)); if (status != 0) { int error = -status; DPRINTF(("%s: sendto: %R[sockerr]\n", __func__, error)); status = pbuf_header(p, iphlen); /* back to IP header */ if (RT_UNLIKELY(status != 0)) { pbuf_free(p); return; } /* restore original ICMP header */ icmph->id = pcb->guest_id; switch (error) { case EACCES: icmp6_dest_unreach(p, ICMP6_DUR_PROHIBITED); break; #ifdef ENONET case ENONET: #endif case ENETDOWN: case ENETUNREACH: case EHOSTDOWN: case EHOSTUNREACH: icmp6_dest_unreach(p, ICMP6_DUR_NO_ROUTE); break; } } pbuf_free(p); } /** * Formatter for %R[ping_pcb]. */ static DECLCALLBACK(size_t) pxping_pcb_rtstrfmt(PFNRTSTROUTPUT pfnOutput, void *pvArgOutput, const char *pszType, const void *pvValue, int cchWidth, int cchPrecision, unsigned int fFlags, void *pvUser) { const struct ping_pcb *pcb = (const struct ping_pcb *)pvValue; size_t cb = 0; NOREF(cchWidth); NOREF(cchPrecision); NOREF(fFlags); NOREF(pvUser); AssertReturn(strcmp(pszType, "ping_pcb") == 0, 0); if (pcb == NULL) { return RTStrFormat(pfnOutput, pvArgOutput, NULL, NULL, "(null)"); } /* XXX: %RTnaipv4 takes the value, but %RTnaipv6 takes the pointer */ if (pcb->is_ipv6) { cb += RTStrFormat(pfnOutput, pvArgOutput, NULL, NULL, "%RTnaipv6 -> %RTnaipv6", &pcb->src, &pcb->dst); if (pcb->is_mapped) { cb += RTStrFormat(pfnOutput, pvArgOutput, NULL, NULL, " (%RTnaipv6)", &pcb->peer.sin6.sin6_addr); } } else { cb += RTStrFormat(pfnOutput, pvArgOutput, NULL, NULL, "%RTnaipv4 -> %RTnaipv4", ip4_addr_get_u32(ipX_2_ip(&pcb->src)), ip4_addr_get_u32(ipX_2_ip(&pcb->dst))); if (pcb->is_mapped) { cb += RTStrFormat(pfnOutput, pvArgOutput, NULL, NULL, " (%RTnaipv4)", pcb->peer.sin.sin_addr.s_addr); } } cb += RTStrFormat(pfnOutput, pvArgOutput, NULL, NULL, " id %04x->%04x", ntohs(pcb->guest_id), ntohs(pcb->host_id)); return cb; } static struct ping_pcb * pxping_pcb_allocate(struct pxping *pxping) { struct ping_pcb *pcb; if (pxping->npcbs >= PXPING_MAX_PCBS) { return NULL; } pcb = (struct ping_pcb *)malloc(sizeof(*pcb)); if (pcb == NULL) { return NULL; } ++pxping->npcbs; return pcb; } static void pxping_pcb_delete(struct pxping *pxping, struct ping_pcb *pcb) { LWIP_ASSERT1(pxping->npcbs > 0); LWIP_ASSERT1(pcb->next == NULL); LWIP_ASSERT1(pcb->pprev_timeout == NULL); DPRINTF(("%s: ping %p\n", __func__, (void *)pcb)); --pxping->npcbs; free(pcb); } static void pxping_timeout_add(struct pxping *pxping, struct ping_pcb *pcb) { struct ping_pcb **chain; LWIP_ASSERT1(pcb->pprev_timeout == NULL); chain = &pxping->timeout_list[pcb->timeout_slot]; if ((pcb->next_timeout = *chain) != NULL) { (*chain)->pprev_timeout = &pcb->next_timeout; } *chain = pcb; pcb->pprev_timeout = chain; } static void pxping_timeout_del(struct pxping *pxping, struct ping_pcb *pcb) { LWIP_UNUSED_ARG(pxping); LWIP_ASSERT1(pcb->pprev_timeout != NULL); if (pcb->next_timeout != NULL) { pcb->next_timeout->pprev_timeout = pcb->pprev_timeout; } *pcb->pprev_timeout = pcb->next_timeout; pcb->pprev_timeout = NULL; pcb->next_timeout = NULL; } static void pxping_pcb_register(struct pxping *pxping, struct ping_pcb *pcb) { pcb->next = pxping->pcbs; pxping->pcbs = pcb; pxping_timeout_add(pxping, pcb); } static void pxping_pcb_deregister(struct pxping *pxping, struct ping_pcb *pcb) { struct ping_pcb **p; for (p = &pxping->pcbs; *p != NULL; p = &(*p)->next) { if (*p == pcb) { *p = pcb->next; pcb->next = NULL; break; } } pxping_timeout_del(pxping, pcb); } static struct ping_pcb * pxping_pcb_for_request(struct pxping *pxping, int is_ipv6, ipX_addr_t *src, ipX_addr_t *dst, u16_t guest_id) { struct ping_pcb *pcb; /* on lwip thread, so no concurrent updates */ for (pcb = pxping->pcbs; pcb != NULL; pcb = pcb->next) { if (pcb->guest_id == guest_id && pcb->is_ipv6 == is_ipv6 && ipX_addr_cmp(is_ipv6, &pcb->dst, dst) && ipX_addr_cmp(is_ipv6, &pcb->src, src)) { break; } } if (pcb == NULL) { int mapped; pcb = pxping_pcb_allocate(pxping); if (pcb == NULL) { return NULL; } pcb->is_ipv6 = is_ipv6; ipX_addr_copy(is_ipv6, pcb->src, *src); ipX_addr_copy(is_ipv6, pcb->dst, *dst); pcb->guest_id = guest_id; #ifdef RT_OS_WINDOWS # define random() (rand()) #endif pcb->host_id = random() & 0xffffUL; pcb->pprev_timeout = NULL; pcb->next_timeout = NULL; if (is_ipv6) { pcb->peer.sin6.sin6_family = AF_INET6; #if HAVE_SA_LEN pcb->peer.sin6.sin6_len = sizeof(pcb->peer.sin6); #endif pcb->peer.sin6.sin6_port = htons(IPPROTO_ICMPV6); pcb->peer.sin6.sin6_flowinfo = 0; mapped = pxremap_outbound_ip6((ip6_addr_t *)&pcb->peer.sin6.sin6_addr, ipX_2_ip6(&pcb->dst)); } else { pcb->peer.sin.sin_family = AF_INET; #if HAVE_SA_LEN pcb->peer.sin.sin_len = sizeof(pcb->peer.sin); #endif pcb->peer.sin.sin_port = htons(IPPROTO_ICMP); mapped = pxremap_outbound_ip4((ip_addr_t *)&pcb->peer.sin.sin_addr, ipX_2_ip(&pcb->dst)); } if (mapped == PXREMAP_FAILED) { free(pcb); return NULL; } else { pcb->is_mapped = (mapped == PXREMAP_MAPPED); } pcb->timeout_slot = pxping->timeout_slot; sys_mutex_lock(&pxping->lock); pxping_pcb_register(pxping, pcb); sys_mutex_unlock(&pxping->lock); DPRINTF(("ping %p: %R[ping_pcb] - created\n", pcb, pcb)); pxping_timer_needed(pxping); } else { /* just bump up expiration timeout lazily */ DPRINTF(("ping %p: %R[ping_pcb] - slot %d -> %d\n", pcb, pcb, (unsigned int)pcb->timeout_slot, (unsigned int)pxping->timeout_slot)); pcb->timeout_slot = pxping->timeout_slot; } return pcb; } /** * Called on pollmgr thread. Caller must do the locking since caller * is going to use the returned pcb, which needs to be protected from * being expired by pxping_timer() on lwip thread. */ static struct ping_pcb * pxping_pcb_for_reply(struct pxping *pxping, int is_ipv6, ipX_addr_t *dst, u16_t host_id) { struct ping_pcb *pcb; for (pcb = pxping->pcbs; pcb != NULL; pcb = pcb->next) { if (pcb->host_id == host_id && pcb->is_ipv6 == is_ipv6 /* XXX: allow broadcast pings? */ && ipX_addr_cmp(is_ipv6, &pcb->dst, dst)) { return pcb; } } return NULL; } static void pxping_timer(void *arg) { struct pxping *pxping = (struct pxping *)arg; struct ping_pcb **chain, *pcb; pxping->timer_active = 0; /* * New slot points to the list of pcbs to check for expiration. */ LWIP_ASSERT1(pxping->timeout_slot < TIMEOUT); if (++pxping->timeout_slot == TIMEOUT) { pxping->timeout_slot = 0; } chain = &pxping->timeout_list[pxping->timeout_slot]; pcb = *chain; /* protect from pollmgr concurrent reads */ sys_mutex_lock(&pxping->lock); while (pcb != NULL) { struct ping_pcb *xpcb = pcb; pcb = pcb->next_timeout; if (xpcb->timeout_slot == pxping->timeout_slot) { /* expired */ pxping_pcb_deregister(pxping, xpcb); pxping_pcb_delete(pxping, xpcb); } else { /* * If there was another request, we updated timeout_slot * but delayed actually moving the pcb until now. */ pxping_timeout_del(pxping, xpcb); /* from current slot */ pxping_timeout_add(pxping, xpcb); /* to new slot */ } } sys_mutex_unlock(&pxping->lock); pxping_timer_needed(pxping); } static void pxping_timer_needed(struct pxping *pxping) { if (!pxping->timer_active && pxping->pcbs != NULL) { pxping->timer_active = 1; sys_timeout(1 * 1000, pxping_timer, pxping); } } static int pxping_pmgr_pump(struct pollmgr_handler *handler, SOCKET fd, int revents) { struct pxping *pxping; pxping = (struct pxping *)handler->data; LWIP_ASSERT1(fd == pxping->sock4 || fd == pxping->sock6); if (revents & ~(POLLIN|POLLERR)) { DPRINTF0(("%s: unexpected revents 0x%x\n", __func__, revents)); return POLLIN; } if (revents & POLLERR) { int sockerr = -1; socklen_t optlen = (socklen_t)sizeof(sockerr); int status; status = getsockopt(fd, SOL_SOCKET, SO_ERROR, (char *)&sockerr, &optlen); if (status < 0) { DPRINTF(("%s: sock %d: SO_ERROR failed: %R[sockerr]\n", __func__, fd, SOCKERRNO())); } else { DPRINTF(("%s: sock %d: %R[sockerr]\n", __func__, fd, sockerr)); } } if ((revents & POLLIN) == 0) { return POLLIN; } if (fd == pxping->sock4) { pxping_pmgr_icmp4(pxping); } else /* fd == pxping->sock6 */ { pxping_pmgr_icmp6(pxping); } return POLLIN; } /** * Process incoming ICMP message for the host. * NB: we will get a lot of spam here and have to sift through it. */ static void pxping_pmgr_icmp4(struct pxping *pxping) { struct sockaddr_in sin; socklen_t salen = sizeof(sin); ssize_t nread; struct ip_hdr *iph; struct icmp_echo_hdr *icmph; u16_t iplen, ipoff; memset(&sin, 0, sizeof(sin)); /* * Reads from raw IPv4 sockets deliver complete IP datagrams with * IP header included. */ nread = recvfrom(pxping->sock4, pollmgr_udpbuf, sizeof(pollmgr_udpbuf), 0, (struct sockaddr *)&sin, &salen); if (nread < 0) { DPRINTF(("%s: %R[sockerr]\n", __func__, SOCKERRNO())); return; } if (nread < IP_HLEN) { DPRINTF2(("%s: read %d bytes, IP header truncated\n", __func__, (unsigned int)nread)); return; } iph = (struct ip_hdr *)pollmgr_udpbuf; /* match version */ if (IPH_V(iph) != 4) { DPRINTF2(("%s: unexpected IP version %d\n", __func__, IPH_V(iph))); return; } /* no fragmentation */ ipoff = IPH_OFFSET(iph); #if defined(RT_OS_DARWIN) /* darwin reports IPH_OFFSET in host byte order */ ipoff = htons(ipoff); IPH_OFFSET_SET(iph, ipoff); #endif if ((ipoff & PP_HTONS(IP_OFFMASK | IP_MF)) != 0) { DPRINTF2(("%s: dropping fragmented datagram (0x%04x)\n", __func__, ntohs(ipoff))); return; } /* no options */ if (IPH_HL(iph) * 4 != IP_HLEN) { DPRINTF2(("%s: dropping datagram with options (IP header length %d)\n", __func__, IPH_HL(iph) * 4)); return; } if (IPH_PROTO(iph) != IP_PROTO_ICMP) { DPRINTF2(("%s: unexpected protocol %d\n", __func__, IPH_PROTO(iph))); return; } iplen = IPH_LEN(iph); #if !defined(RT_OS_DARWIN) /* darwin reports IPH_LEN in host byte order */ iplen = ntohs(iplen); #endif #if defined(RT_OS_DARWIN) || defined(RT_OS_SOLARIS) /* darwin and solaris change IPH_LEN to payload length only */ iplen += IP_HLEN; /* we verified there are no options */ IPH_LEN_SET(iph, htons(iplen)); #endif if (nread < iplen) { DPRINTF2(("%s: read %d bytes but total length is %d bytes\n", __func__, (unsigned int)nread, (unsigned int)iplen)); return; } if (iplen < IP_HLEN + ICMP_HLEN) { DPRINTF2(("%s: IP length %d bytes, ICMP header truncated\n", __func__, iplen)); return; } icmph = (struct icmp_echo_hdr *)(pollmgr_udpbuf + IP_HLEN); if (ICMPH_TYPE(icmph) == ICMP_ER) { pxping_pmgr_icmp4_echo(pxping, iplen, &sin); } else if (ICMPH_TYPE(icmph) == ICMP_DUR || ICMPH_TYPE(icmph) == ICMP_TE) { pxping_pmgr_icmp4_error(pxping, iplen, &sin); } #if 1 else { DPRINTF2(("%s: ignoring ICMP type %d\n", __func__, ICMPH_TYPE(icmph))); } #endif } /** * Check if this incoming ICMP echo reply is for one of our pings and * forward it to the guest. */ static void pxping_pmgr_icmp4_echo(struct pxping *pxping, u16_t iplen, struct sockaddr_in *peer) { struct ip_hdr *iph; struct icmp_echo_hdr *icmph; u16_t id, seq; ip_addr_t guest_ip, target_ip; int mapped; struct ping_pcb *pcb; u16_t guest_id; u16_t oipsum; u32_t sum; iph = (struct ip_hdr *)pollmgr_udpbuf; icmph = (struct icmp_echo_hdr *)(pollmgr_udpbuf + IP_HLEN); id = icmph->id; seq = icmph->seqno; DPRINTF(("<--- PING %RTnaipv4 id 0x%x seq %d\n", peer->sin_addr.s_addr, ntohs(id), ntohs(seq))); /* * Is this a reply to one of our pings? */ ip_addr_copy(target_ip, iph->src); mapped = pxremap_inbound_ip4(&target_ip, &target_ip); if (mapped == PXREMAP_FAILED) { return; } if (mapped == PXREMAP_ASIS && IPH_TTL(iph) == 1) { DPRINTF2(("%s: dropping packet with ttl 1\n", __func__)); return; } sys_mutex_lock(&pxping->lock); pcb = pxping_pcb_for_reply(pxping, 0, ip_2_ipX(&target_ip), id); if (pcb == NULL) { sys_mutex_unlock(&pxping->lock); DPRINTF2(("%s: no match\n", __func__)); return; } DPRINTF2(("%s: pcb %p\n", __func__, (void *)pcb)); /* save info before unlocking since pcb may expire */ ip_addr_copy(guest_ip, *ipX_2_ip(&pcb->src)); guest_id = pcb->guest_id; sys_mutex_unlock(&pxping->lock); /* * Rewrite headers and forward to guest. */ /* rewrite ICMP echo header */ sum = (u16_t)~icmph->chksum; sum += chksum_update_16(&icmph->id, guest_id); sum = FOLD_U32T(sum); icmph->chksum = ~sum; /* rewrite IP header */ oipsum = IPH_CHKSUM(iph); if (oipsum == 0) { /* Solaris doesn't compute checksum for local replies */ ip_addr_copy(iph->dest, guest_ip); if (mapped == PXREMAP_MAPPED) { ip_addr_copy(iph->src, target_ip); } else { IPH_TTL_SET(iph, IPH_TTL(iph) - 1); } IPH_CHKSUM_SET(iph, inet_chksum(iph, ntohs(IPH_LEN(iph)))); } else { sum = (u16_t)~oipsum; sum += chksum_update_32((u32_t *)&iph->dest, ip4_addr_get_u32(&guest_ip)); if (mapped == PXREMAP_MAPPED) { sum += chksum_update_32((u32_t *)&iph->src, ip4_addr_get_u32(&target_ip)); } else { IPH_TTL_SET(iph, IPH_TTL(iph) - 1); sum += PP_NTOHS(~0x0100); } sum = FOLD_U32T(sum); IPH_CHKSUM_SET(iph, ~sum); } pxping_pmgr_forward_inbound(pxping, iplen); } /** * Check if this incoming ICMP error (destination unreachable or time * exceeded) is about one of our pings and forward it to the guest. */ static void pxping_pmgr_icmp4_error(struct pxping *pxping, u16_t iplen, struct sockaddr_in *peer) { struct ip_hdr *iph, *oiph; struct icmp_echo_hdr *icmph, *oicmph; u16_t oipoff, oiphlen, oiplen; u16_t id, seq; ip_addr_t guest_ip, target_ip, error_ip; int target_mapped, error_mapped; struct ping_pcb *pcb; u16_t guest_id; u32_t sum; iph = (struct ip_hdr *)pollmgr_udpbuf; icmph = (struct icmp_echo_hdr *)(pollmgr_udpbuf + IP_HLEN); /* * Inner IP datagram is not checked by the kernel and may be * anything, possibly malicious. */ oipoff = IP_HLEN + ICMP_HLEN; oiplen = iplen - oipoff; /* NB: truncated length, not IPH_LEN(oiph) */ if (oiplen < IP_HLEN) { DPRINTF2(("%s: original datagram truncated to %d bytes\n", __func__, oiplen)); } /* IP header of the original message */ oiph = (struct ip_hdr *)(pollmgr_udpbuf + oipoff); /* match version */ if (IPH_V(oiph) != 4) { DPRINTF2(("%s: unexpected IP version %d\n", __func__, IPH_V(oiph))); return; } /* can't match fragments except the first one */ if ((IPH_OFFSET(oiph) & PP_HTONS(IP_OFFMASK)) != 0) { DPRINTF2(("%s: ignoring fragment with offset %d\n", __func__, ntohs(IPH_OFFSET(oiph) & PP_HTONS(IP_OFFMASK)))); return; } if (IPH_PROTO(oiph) != IP_PROTO_ICMP) { #if 0 /* don't spam with every "destination unreachable" in the system */ DPRINTF2(("%s: ignoring protocol %d\n", __func__, IPH_PROTO(oiph))); #endif return; } oiphlen = IPH_HL(oiph) * 4; if (oiplen < oiphlen + ICMP_HLEN) { DPRINTF2(("%s: original datagram truncated to %d bytes\n", __func__, oiplen)); return; } oicmph = (struct icmp_echo_hdr *)(pollmgr_udpbuf + oipoff + oiphlen); if (ICMPH_TYPE(oicmph) != ICMP_ECHO) { DPRINTF2(("%s: ignoring ICMP error for original ICMP type %d\n", __func__, ICMPH_TYPE(oicmph))); return; } id = oicmph->id; seq = oicmph->seqno; DPRINTF2(("%s: ping %RTnaipv4 id 0x%x seq %d", __func__, ip4_addr_get_u32(&oiph->dest), ntohs(id), ntohs(seq))); if (ICMPH_TYPE(icmph) == ICMP_DUR) { DPRINTF2((" unreachable (code %d)\n", ICMPH_CODE(icmph))); } else { DPRINTF2((" time exceeded\n")); } /* * Is the inner (failed) datagram one of our pings? */ ip_addr_copy(target_ip, oiph->dest); /* inner (failed) */ target_mapped = pxremap_inbound_ip4(&target_ip, &target_ip); if (target_mapped == PXREMAP_FAILED) { return; } sys_mutex_lock(&pxping->lock); pcb = pxping_pcb_for_reply(pxping, 0, ip_2_ipX(&target_ip), id); if (pcb == NULL) { sys_mutex_unlock(&pxping->lock); DPRINTF2(("%s: no match\n", __func__)); return; } DPRINTF2(("%s: pcb %p\n", __func__, (void *)pcb)); /* save info before unlocking since pcb may expire */ ip_addr_copy(guest_ip, *ipX_2_ip(&pcb->src)); guest_id = pcb->guest_id; sys_mutex_unlock(&pxping->lock); /* * Rewrite both inner and outer headers and forward to guest. * Note that the checksum of the outer ICMP error message is * preserved by the changes we do to inner headers. */ ip_addr_copy(error_ip, iph->src); /* node that reports the error */ error_mapped = pxremap_inbound_ip4(&error_ip, &error_ip); if (error_mapped == PXREMAP_FAILED) { return; } if (error_mapped == PXREMAP_ASIS && IPH_TTL(iph) == 1) { DPRINTF2(("%s: dropping packet with ttl 1\n", __func__)); return; } /* rewrite inner ICMP echo header */ sum = (u16_t)~oicmph->chksum; sum += chksum_update_16(&oicmph->id, guest_id); sum = FOLD_U32T(sum); oicmph->chksum = ~sum; /* rewrite inner IP header */ #if defined(RT_OS_DARWIN) /* darwin converts inner length to host byte order too */ IPH_LEN_SET(oiph, htons(IPH_LEN(oiph))); #endif sum = (u16_t)~IPH_CHKSUM(oiph); sum += chksum_update_32((u32_t *)&oiph->src, ip4_addr_get_u32(&guest_ip)); if (target_mapped == PXREMAP_MAPPED) { sum += chksum_update_32((u32_t *)&oiph->dest, ip4_addr_get_u32(&target_ip)); } sum = FOLD_U32T(sum); IPH_CHKSUM_SET(oiph, ~sum); /* rewrite outer IP header */ sum = (u16_t)~IPH_CHKSUM(iph); sum += chksum_update_32((u32_t *)&iph->dest, ip4_addr_get_u32(&guest_ip)); if (error_mapped == PXREMAP_MAPPED) { sum += chksum_update_32((u32_t *)&iph->src, ip4_addr_get_u32(&error_ip)); } else { IPH_TTL_SET(iph, IPH_TTL(iph) - 1); sum += PP_NTOHS(~0x0100); } sum = FOLD_U32T(sum); IPH_CHKSUM_SET(iph, ~sum); pxping_pmgr_forward_inbound(pxping, iplen); } /** * Process incoming ICMPv6 message for the host. * NB: we will get a lot of spam here and have to sift through it. */ static void pxping_pmgr_icmp6(struct pxping *pxping) { #ifndef RT_OS_WINDOWS struct msghdr mh; ssize_t nread; #else WSAMSG mh; DWORD nread; #endif IOVEC iov[1]; static u8_t cmsgbuf[128]; struct cmsghdr *cmh; struct sockaddr_in6 sin6; socklen_t salen = sizeof(sin6); struct icmp6_echo_hdr *icmph; struct in6_pktinfo *pktinfo; int hopl, tclass; int status; /* * Reads from raw IPv6 sockets deliver only the payload. Full * headers are available via recvmsg(2)/cmsg(3). */ IOVEC_SET_BASE(iov[0], pollmgr_udpbuf); IOVEC_SET_LEN(iov[0], sizeof(pollmgr_udpbuf)); memset(&mh, 0, sizeof(mh)); #ifndef RT_OS_WINDOWS mh.msg_name = &sin6; mh.msg_namelen = sizeof(sin6); mh.msg_iov = iov; mh.msg_iovlen = 1; mh.msg_control = cmsgbuf; mh.msg_controllen = sizeof(cmsgbuf); mh.msg_flags = 0; nread = recvmsg(pxping->sock6, &mh, 0); if (nread < 0) { DPRINTF(("%s: %R[sockerr]\n", __func__, SOCKERRNO())); return; } #else /* RT_OS_WINDOWS */ mh.name = (LPSOCKADDR)&sin6; mh.namelen = sizeof(sin6); mh.lpBuffers = iov; mh.dwBufferCount = 1; mh.Control.buf = cmsgbuf; mh.Control.len = sizeof(cmsgbuf); mh.dwFlags = 0; status = (*pxping->pfWSARecvMsg6)(pxping->sock6, &mh, &nread, NULL, NULL); if (status == SOCKET_ERROR) { DPRINTF2(("%s: error %d\n", __func__, WSAGetLastError())); return; } #endif icmph = (struct icmp6_echo_hdr *)pollmgr_udpbuf; DPRINTF2(("%s: %RTnaipv6 ICMPv6: ", __func__, &sin6.sin6_addr)); if (icmph->type == ICMP6_TYPE_EREP) { DPRINTF2(("echo reply %04x %u\n", (unsigned int)icmph->id, (unsigned int)icmph->seqno)); } else { /* XXX */ if (icmph->type == ICMP6_TYPE_EREQ) { DPRINTF2(("echo request %04x %u\n", (unsigned int)icmph->id, (unsigned int)icmph->seqno)); } else if (icmph->type == ICMP6_TYPE_DUR) { DPRINTF2(("destination unreachable\n")); } else if (icmph->type == ICMP6_TYPE_PTB) { DPRINTF2(("packet too big\n")); } else if (icmph->type == ICMP6_TYPE_TE) { DPRINTF2(("time exceeded\n")); } else if (icmph->type == ICMP6_TYPE_PP) { DPRINTF2(("parameter problem\n")); } else { DPRINTF2(("type %d len %u\n", icmph->type, (unsigned int)nread)); } if (icmph->type >= ICMP6_TYPE_EREQ) { return; /* informational message */ } } pktinfo = NULL; hopl = -1; tclass = -1; for (cmh = CMSG_FIRSTHDR(&mh); cmh != NULL; cmh = CMSG_NXTHDR(&mh, cmh)) { if (cmh->cmsg_len == 0) break; if (cmh->cmsg_level == IPPROTO_IPV6 && cmh->cmsg_type == IPV6_HOPLIMIT && cmh->cmsg_len == CMSG_LEN(sizeof(int))) { hopl = *(int *)CMSG_DATA(cmh); DPRINTF2(("hoplimit = %d\n", hopl)); } if (cmh->cmsg_level == IPPROTO_IPV6 && cmh->cmsg_type == IPV6_PKTINFO && cmh->cmsg_len == CMSG_LEN(sizeof(struct in6_pktinfo))) { pktinfo = (struct in6_pktinfo *)CMSG_DATA(cmh); DPRINTF2(("pktinfo found\n")); } } if (pktinfo == NULL) { /* * ip6_output_if() doesn't do checksum for us so we need to * manually recompute it - for this we must know the * destination address of the pseudo-header that we will * rewrite with guest's address. (TODO: yeah, yeah, we can * compute it from scratch...) */ DPRINTF2(("%s: unable to get pktinfo\n", __func__)); return; } if (hopl < 0) { hopl = LWIP_ICMP6_HL; } if (icmph->type == ICMP6_TYPE_EREP) { pxping_pmgr_icmp6_echo(pxping, (ip6_addr_t *)&sin6.sin6_addr, (ip6_addr_t *)&pktinfo->ipi6_addr, hopl, tclass, (u16_t)nread); } else if (icmph->type < ICMP6_TYPE_EREQ) { pxping_pmgr_icmp6_error(pxping, (ip6_addr_t *)&sin6.sin6_addr, (ip6_addr_t *)&pktinfo->ipi6_addr, hopl, tclass, (u16_t)nread); } } /** * Check if this incoming ICMPv6 echo reply is for one of our pings * and forward it to the guest. */ static void pxping_pmgr_icmp6_echo(struct pxping *pxping, ip6_addr_t *src, ip6_addr_t *dst, int hopl, int tclass, u16_t icmplen) { struct icmp6_echo_hdr *icmph; ip6_addr_t guest_ip, target_ip; int mapped; struct ping_pcb *pcb; u16_t id, guest_id; u32_t sum; ip6_addr_copy(target_ip, *src); mapped = pxremap_inbound_ip6(&target_ip, &target_ip); if (mapped == PXREMAP_FAILED) { return; } else if (mapped == PXREMAP_ASIS) { if (hopl == 1) { DPRINTF2(("%s: dropping packet with ttl 1\n", __func__)); return; } --hopl; } icmph = (struct icmp6_echo_hdr *)pollmgr_udpbuf; id = icmph->id; sys_mutex_lock(&pxping->lock); pcb = pxping_pcb_for_reply(pxping, 1, ip6_2_ipX(&target_ip), id); if (pcb == NULL) { sys_mutex_unlock(&pxping->lock); DPRINTF2(("%s: no match\n", __func__)); return; } DPRINTF2(("%s: pcb %p\n", __func__, (void *)pcb)); /* save info before unlocking since pcb may expire */ ip6_addr_copy(guest_ip, *ipX_2_ip6(&pcb->src)); guest_id = pcb->guest_id; sys_mutex_unlock(&pxping->lock); /* rewrite ICMPv6 echo header */ sum = (u16_t)~icmph->chksum; sum += chksum_update_16(&icmph->id, guest_id); sum += chksum_delta_ipv6(dst, &guest_ip); /* pseudo */ if (mapped) { sum += chksum_delta_ipv6(src, &target_ip); /* pseudo */ } sum = FOLD_U32T(sum); icmph->chksum = ~sum; pxping_pmgr_forward_inbound6(pxping, &target_ip, /* echo reply src */ &guest_ip, /* echo reply dst */ hopl, tclass, icmplen); } /** * Check if this incoming ICMPv6 error is about one of our pings and * forward it to the guest. */ static void pxping_pmgr_icmp6_error(struct pxping *pxping, ip6_addr_t *src, ip6_addr_t *dst, int hopl, int tclass, u16_t icmplen) { struct icmp6_hdr *icmph; u8_t *bufptr; size_t buflen, hlen; int proto; struct ip6_hdr *oiph; struct icmp6_echo_hdr *oicmph; struct ping_pcb *pcb; ip6_addr_t guest_ip, target_ip, error_ip; int target_mapped, error_mapped; u16_t guest_id; u32_t sum; icmph = (struct icmp6_hdr *)pollmgr_udpbuf; /* * Inner IP datagram is not checked by the kernel and may be * anything, possibly malicious. */ oiph = NULL; oicmph = NULL; bufptr = pollmgr_udpbuf; buflen = icmplen; hlen = sizeof(*icmph); proto = IP6_NEXTH_ENCAPS; /* i.e. IPv6, lwIP's name is unfortuate */ for (;;) { if (hlen > buflen) { DPRINTF2(("truncated datagram inside ICMPv6 error message is too short\n")); return; } buflen -= hlen; bufptr += hlen; if (proto == IP6_NEXTH_ENCAPS && oiph == NULL) { /* outermost IPv6 */ oiph = (struct ip6_hdr *)bufptr; if (IP6H_V(oiph) != 6) { DPRINTF2(("%s: unexpected IP version %d\n", __func__, IP6H_V(oiph))); return; } proto = IP6H_NEXTH(oiph); hlen = IP6_HLEN; } else if (proto == IP6_NEXTH_ICMP6) { oicmph = (struct icmp6_echo_hdr *)bufptr; break; } else if (proto == IP6_NEXTH_ROUTING || proto == IP6_NEXTH_HOPBYHOP || proto == IP6_NEXTH_DESTOPTS) { proto = bufptr[0]; hlen = (bufptr[1] + 1) * 8; } else { DPRINTF2(("%s: stopping at protocol %d\n", __func__, proto)); break; } } if (oiph == NULL || oicmph == NULL) { return; } if (buflen < sizeof(*oicmph)) { DPRINTF2(("%s: original ICMPv6 is truncated too short\n", __func__)); return; } if (oicmph->type != ICMP6_TYPE_EREQ) { DPRINTF2(("%s: ignoring original ICMPv6 type %d\n", __func__, oicmph->type)); return; } ip6_addr_copy(target_ip, oiph->dest); /* inner (failed) */ target_mapped = pxremap_inbound_ip6(&target_ip, &target_ip); if (target_mapped == PXREMAP_FAILED) { return; } sys_mutex_lock(&pxping->lock); pcb = pxping_pcb_for_reply(pxping, 1, ip6_2_ipX(&target_ip), oicmph->id); if (pcb == NULL) { sys_mutex_unlock(&pxping->lock); DPRINTF2(("%s: no match\n", __func__)); return; } DPRINTF2(("%s: pcb %p\n", __func__, (void *)pcb)); /* save info before unlocking since pcb may expire */ ip6_addr_copy(guest_ip, *ipX_2_ip6(&pcb->src)); guest_id = pcb->guest_id; sys_mutex_unlock(&pxping->lock); /* * Rewrite inner and outer headers and forward to guest. Note * that IPv6 has no IP header checksum, but uses pseudo-header for * ICMPv6, so we update both in one go, adjusting ICMPv6 checksum * as we rewrite IP header. */ ip6_addr_copy(error_ip, *src); /* node that reports the error */ error_mapped = pxremap_inbound_ip6(&error_ip, &error_ip); if (error_mapped == PXREMAP_FAILED) { return; } if (error_mapped == PXREMAP_ASIS && hopl == 1) { DPRINTF2(("%s: dropping packet with ttl 1\n", __func__)); return; } /* rewrite inner ICMPv6 echo header and inner IPv6 header */ sum = (u16_t)~oicmph->chksum; sum += chksum_update_16(&oicmph->id, guest_id); sum += chksum_update_ipv6((ip6_addr_t *)&oiph->src, &guest_ip); if (target_mapped) { sum += chksum_delta_ipv6((ip6_addr_t *)&oiph->dest, &target_ip); } sum = FOLD_U32T(sum); oicmph->chksum = ~sum; /* rewrite outer ICMPv6 error header */ sum = (u16_t)~icmph->chksum; sum += chksum_delta_ipv6(dst, &guest_ip); /* pseudo */ if (error_mapped) { sum += chksum_delta_ipv6(src, &error_ip); /* pseudo */ } sum = FOLD_U32T(sum); icmph->chksum = ~sum; pxping_pmgr_forward_inbound6(pxping, &error_ip, /* error src */ &guest_ip, /* error dst */ hopl, tclass, icmplen); } /** * Hand off ICMP datagram to the lwip thread where it will be * forwarded to the guest. * * We no longer need ping_pcb. The pcb may get expired on the lwip * thread, but we have already patched necessary information into the * datagram. */ static void pxping_pmgr_forward_inbound(struct pxping *pxping, u16_t iplen) { struct pbuf *p; struct ping_msg *msg; err_t error; p = pbuf_alloc(PBUF_LINK, iplen, PBUF_RAM); if (p == NULL) { DPRINTF(("%s: pbuf_alloc(%d) failed\n", __func__, (unsigned int)iplen)); return; } error = pbuf_take(p, pollmgr_udpbuf, iplen); if (error != ERR_OK) { DPRINTF(("%s: pbuf_take(%d) failed\n", __func__, (unsigned int)iplen)); pbuf_free(p); return; } msg = (struct ping_msg *)malloc(sizeof(*msg)); if (msg == NULL) { pbuf_free(p); return; } msg->msg.type = TCPIP_MSG_CALLBACK_STATIC; msg->msg.sem = NULL; msg->msg.msg.cb.function = pxping_pcb_forward_inbound; msg->msg.msg.cb.ctx = (void *)msg; msg->pxping = pxping; msg->p = p; proxy_lwip_post(&msg->msg); } static void pxping_pcb_forward_inbound(void *arg) { struct ping_msg *msg = (struct ping_msg *)arg; err_t error; LWIP_ASSERT1(msg != NULL); LWIP_ASSERT1(msg->pxping != NULL); LWIP_ASSERT1(msg->p != NULL); error = ip_raw_output_if(msg->p, msg->pxping->netif); if (error != ERR_OK) { DPRINTF(("%s: ip_output_if: %s\n", __func__, proxy_lwip_strerr(error))); } pbuf_free(msg->p); free(msg); } static void pxping_pmgr_forward_inbound6(struct pxping *pxping, ip6_addr_t *src, ip6_addr_t *dst, u8_t hopl, u8_t tclass, u16_t icmplen) { struct pbuf *p; struct ping6_msg *msg; err_t error; p = pbuf_alloc(PBUF_IP, icmplen, PBUF_RAM); if (p == NULL) { DPRINTF(("%s: pbuf_alloc(%d) failed\n", __func__, (unsigned int)icmplen)); return; } error = pbuf_take(p, pollmgr_udpbuf, icmplen); if (error != ERR_OK) { DPRINTF(("%s: pbuf_take(%d) failed\n", __func__, (unsigned int)icmplen)); pbuf_free(p); return; } msg = (struct ping6_msg *)malloc(sizeof(*msg)); if (msg == NULL) { pbuf_free(p); return; } msg->msg.type = TCPIP_MSG_CALLBACK_STATIC; msg->msg.sem = NULL; msg->msg.msg.cb.function = pxping_pcb_forward_inbound6; msg->msg.msg.cb.ctx = (void *)msg; msg->pxping = pxping; msg->p = p; ip6_addr_copy(msg->src, *src); ip6_addr_copy(msg->dst, *dst); msg->hopl = hopl; msg->tclass = tclass; proxy_lwip_post(&msg->msg); } static void pxping_pcb_forward_inbound6(void *arg) { struct ping6_msg *msg = (struct ping6_msg *)arg; err_t error; LWIP_ASSERT1(msg != NULL); LWIP_ASSERT1(msg->pxping != NULL); LWIP_ASSERT1(msg->p != NULL); error = ip6_output_if(msg->p, &msg->src, &msg->dst, msg->hopl, msg->tclass, IP6_NEXTH_ICMP6, msg->pxping->netif); if (error != ERR_OK) { DPRINTF(("%s: ip6_output_if: %s\n", __func__, proxy_lwip_strerr(error))); } pbuf_free(msg->p); free(msg); }