/* vim: set expandtab ts=4 sw=4: */ /* * You may redistribute this program and/or modify it under the terms of * the GNU General Public License as published by the Free Software Foundation, * either version 3 of the License, 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, see . */ #include "rust/cjdns_sys/Rffi.h" #include "benc/StringList.h" #include "interface/UDPInterface.h" #include "wire/Message.h" #include "util/events/UDPAddrIface.h" #include "util/GlobalConfig.h" #include "wire/Error.h" #include #include #define ArrayList_TYPE struct Sockaddr #define ArrayList_NAME Sockaddr #include "util/ArrayList.h" struct UDPInterface_pvt { struct UDPInterface pub; struct Log* log; struct Allocator* allocator; struct Allocator* bcastAddrAlloc; struct ArrayList_Sockaddr* bcastAddrs; struct Allocator* bcastIfaceAlloc; struct StringList* bcastIfaces; struct UDPAddrIface* commIf; struct UDPAddrIface* bcastIf; struct GlobalConfig* globalConf; struct Iface commSock; struct Iface bcastSock; uint16_t beaconPort_be; uint16_t commPort_be; Identity }; static struct Sockaddr* mkBcastAddr( uint16_t beaconPort_be, const Rffi_NetworkInterface* iface, struct Allocator* alloc) { uint32_t addr; memcpy(&addr, iface->address.octets, 4); uint32_t nmAddr; memcpy(&nmAddr, iface->address.netmask, 4); struct sockaddr_in bcast4 = { .sin_family = AF_INET, .sin_port = beaconPort_be, .sin_addr = { .s_addr = ( addr & nmAddr ) | ~nmAddr } }; return Sockaddr_fromNative(&bcast4, sizeof(struct sockaddr_in), alloc); } static int updateBcastAddrs(struct UDPInterface_pvt* ctx) { bool all = false; for (int i = 0; ctx->bcastIfaces && i < ctx->bcastIfaces->length; i++) { String* iface = StringList_get(ctx->bcastIfaces, i); if (String_equals(iface, String_CONST("all"))) { all = true; } } struct Allocator* tmpAlloc = Allocator_child(ctx->allocator); const Rffi_NetworkInterface* interfaces; int count = Rffi_interface_addresses(&interfaces, tmpAlloc); if (ctx->bcastAddrAlloc) { Allocator_free(ctx->bcastAddrAlloc); } struct Allocator* alloc = ctx->bcastAddrAlloc = Allocator_child(ctx->allocator); ctx->bcastAddrs = ArrayList_Sockaddr_new(alloc); String* tunDev = GlobalConfig_getTunName(ctx->globalConf); for (int i = 0; i < count; i++) { if (interfaces[i].is_internal) { continue; } if (interfaces[i].address.is_ipv6) { continue; } if (tunDev && !CString_strncmp(interfaces[i].name, tunDev->bytes, tunDev->len)) { continue; } struct Sockaddr* addr = mkBcastAddr(ctx->beaconPort_be, &interfaces[i], alloc); if (!all) { String* addrStr = String_new(Sockaddr_print(addr, alloc), alloc); bool found = false; for (int j = 0; ctx->bcastIfaces && j < ctx->bcastIfaces->length; j++) { String* iface = StringList_get(ctx->bcastIfaces, j); if (String_equals(iface, addrStr)) { found = true; } if (CString_strncmp(iface->bytes, interfaces[i].name, iface->len)) { found = true; } } if (!found) { continue; } } ArrayList_Sockaddr_add(ctx->bcastAddrs, addr); } Allocator_free(tmpAlloc); return 0; } static Iface_DEFUN sendPacket(struct Message* m, struct Iface* iface) { struct UDPInterface_pvt* ctx = Identity_containerOf(iface, struct UDPInterface_pvt, pub.generic.iface); Assert_true(Message_getLength(m) > Sockaddr_OVERHEAD); struct Sockaddr* sa = (struct Sockaddr*) m->msgbytes; Assert_true(Message_getLength(m) > sa->addrLen); // Regular traffic if (!(sa->flags & Sockaddr_flags_BCAST)) { return Iface_next(&ctx->commSock, m); } if (updateBcastAddrs(ctx)) { return Error(m, "updateBcastAddrs check logs"); } // bcast struct UDPInterface_BroadcastHeader hdr = { .fffffffc_be = Endian_hostToBigEndian32(0xfffffffc), .version = UDPInterface_CURRENT_VERSION, .zero = 0, .commPort_be = ctx->commPort_be }; Er_assert(Message_eshift(m, -sa->addrLen)); Er_assert(Message_epush(m, &hdr, UDPInterface_BroadcastHeader_SIZE)); for (int i = 0; i < ctx->bcastAddrs->length; i++) { struct Allocator* tmpAlloc = Allocator_child(ctx->allocator); struct Message* mm = Message_clone(m, tmpAlloc); struct Sockaddr* addr = ArrayList_Sockaddr_get(ctx->bcastAddrs, i); Er_assert(Message_epush(mm, addr, addr->addrLen)); Iface_send(&ctx->bcastSock, mm); Allocator_free(tmpAlloc); } return NULL; } static Iface_DEFUN fromCommSock(struct Message* m, struct Iface* iface) { struct UDPInterface_pvt* ctx = Identity_containerOf(iface, struct UDPInterface_pvt, commSock); return Iface_next(&ctx->pub.generic.iface, m); } static Iface_DEFUN fromBcastSock(struct Message* m, struct Iface* iface) { struct UDPInterface_pvt* ctx = Identity_containerOf(iface, struct UDPInterface_pvt, bcastSock); if (Message_getLength(m) < UDPInterface_BroadcastHeader_SIZE + Sockaddr_OVERHEAD) { Log_debug(ctx->log, "DROP runt bcast"); return Error(m, "RUNT bcast"); } struct Sockaddr_storage ss; Er_assert(Message_epop(m, &ss, Sockaddr_OVERHEAD)); if (Message_getLength(m) < UDPInterface_BroadcastHeader_SIZE + ss.addr.addrLen - Sockaddr_OVERHEAD) { Log_debug(ctx->log, "DROP runt bcast"); return Error(m, "RUNT bcast"); } Er_assert(Message_epop(m, &ss.nativeAddr, ss.addr.addrLen - Sockaddr_OVERHEAD)); struct UDPInterface_BroadcastHeader hdr; Er_assert(Message_epop(m, &hdr, UDPInterface_BroadcastHeader_SIZE)); if (hdr.fffffffc_be != Endian_hostToBigEndian32(0xfffffffc)) { Log_debug(ctx->log, "DROP bcast bad magic, expected 0xfffffffc got [%08x]", Endian_bigEndianToHost32(hdr.fffffffc_be)); return Error(m, "INVALID bcast, bad magic"); } if (hdr.version != UDPInterface_CURRENT_VERSION) { Log_debug(ctx->log, "DROP bcast bad version [%u]", hdr.version); return Error(m, "INVALID bcast, bad version"); } if (hdr.zero) { Log_debug(ctx->log, "DROP bcast malformed (zero not zero)"); return Error(m, "INVALID bcast, hdr.zero isn't 0"); } uint16_t commPort = Endian_bigEndianToHost16(hdr.commPort_be); // Fake that it came from the communication port Sockaddr_setPort(&ss.addr, commPort); ss.addr.flags |= Sockaddr_flags_BCAST; Er_assert(Message_epush(m, &ss.addr, ss.addr.addrLen)); return Iface_next(&ctx->pub.generic.iface, m); } Er_DEFUN(struct UDPInterface* UDPInterface_new(struct EventBase* eventBase, struct Sockaddr* bindAddr, uint16_t beaconPort, struct Allocator* alloc, struct Log* logger, struct GlobalConfig* globalConf)) { if (beaconPort && Sockaddr_getFamily(bindAddr) != Sockaddr_AF_INET) { Er_raise(alloc, "UDP broadcast only supported by ipv4."); } if (beaconPort && Sockaddr_getPort(bindAddr) == beaconPort) { Er_raise(alloc, "UDP broadcast port must be different from communication port."); } struct UDPAddrIface* uai = Er(UDPAddrIface_new(eventBase, bindAddr, alloc, logger)); uint16_t commPort = Sockaddr_getPort(uai->generic.addr); struct UDPInterface_pvt* context = Allocator_calloc(alloc, sizeof(struct UDPInterface_pvt), 1); Identity_set(context); context->log = logger; context->allocator = alloc; context->beaconPort_be = Endian_hostToBigEndian16(beaconPort); context->commPort_be = Endian_hostToBigEndian16(commPort); context->pub.generic.addr = uai->generic.addr; context->pub.generic.alloc = alloc; context->pub.generic.iface.send = sendPacket; context->commSock.send = fromCommSock; context->bcastSock.send = fromBcastSock; context->commIf = uai; context->globalConf = globalConf; Iface_plumb(&uai->generic.iface, &context->commSock); if (beaconPort) { struct Sockaddr* bcastAddr = Sockaddr_clone(bindAddr, alloc); Sockaddr_setPort(bcastAddr, beaconPort); struct UDPAddrIface* bcast = Er(UDPAddrIface_new(eventBase, bcastAddr, alloc, logger)); UDPAddrIface_setBroadcast(bcast, 1); Iface_plumb(&bcast->generic.iface, &context->bcastSock); context->bcastIf = bcast; } Er_ret(&context->pub); } Er_DEFUN(List* UDPInterface_listDevices(struct Allocator* alloc)) { const Rffi_NetworkInterface* interfaces; int count = Rffi_interface_addresses(&interfaces, alloc); List* out = List_new(alloc); for (int i = 0; i < count; i++) { if (interfaces[i].is_internal) { continue; } if (interfaces[i].address.is_ipv6) { continue; } List_addString(out, String_new(interfaces[i].name, alloc), alloc); } Er_ret(out); } void UDPInterface_setBroadcastDevices(struct UDPInterface* udpif, List* devices) { struct UDPInterface_pvt* ctx = Identity_check((struct UDPInterface_pvt*) udpif); if (ctx->bcastIfaceAlloc) { Allocator_free(ctx->bcastIfaceAlloc); } struct Allocator* alloc = ctx->bcastIfaceAlloc = Allocator_child(ctx->allocator); struct StringList* bcastIfaces = ctx->bcastIfaces = StringList_new(alloc); int len = List_size(devices); for (uint32_t i = 0; i < (unsigned) len; i++) { String* dev = List_getString(devices, i); StringList_add(bcastIfaces, String_clone(dev, alloc)); } } List* UDPInterface_getBroadcastDevices(struct UDPInterface* udpif, struct Allocator* alloc) { struct UDPInterface_pvt* ctx = Identity_check((struct UDPInterface_pvt*) udpif); List* out = List_new(alloc); for (int i = 0; ctx->bcastIfaces && i < ctx->bcastIfaces->length; i++) { List_addString(out, StringList_get(ctx->bcastIfaces, i), alloc); } return out; } List* UDPInterface_getBroadcastAddrs(struct UDPInterface* udpif, struct Allocator* alloc) { struct UDPInterface_pvt* ctx = Identity_check((struct UDPInterface_pvt*) udpif); List* out = List_new(alloc); if (updateBcastAddrs(ctx)) { // TODO(cjd): There should be some way to return the fact that there was an error return out; } for (int i = 0; i < ctx->bcastAddrs->length; i++) { char* addr = Sockaddr_print(ArrayList_Sockaddr_get(ctx->bcastAddrs, i), alloc); List_addStringC(out, addr, alloc); } return out; } int UDPInterface_setDSCP(struct UDPInterface* udpif, uint8_t dscp) { struct UDPInterface_pvt* ctx = Identity_check((struct UDPInterface_pvt*) udpif); int res = UDPAddrIface_setDSCP(ctx->commIf, dscp); if (res) { return res; } if (ctx->bcastIf) { return UDPAddrIface_setDSCP(ctx->bcastIf, dscp); } return 0; } int UDPInterface_getFd(struct UDPInterface* udpif) { struct UDPInterface_pvt* ctx = Identity_check((struct UDPInterface_pvt*) udpif); return UDPAddrIface_getFd(ctx->commIf); }