/* 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 "crypto/Key.h" #include "io/FileWriter.h" #include "memory/MallocAllocator.h" #include "memory/Allocator.h" #include "util/Base32.h" #include "util/Checksum.h" #include "util/log/WriterLog.h" #include "test/TestFramework.h" #include "net/Ducttape_pvt.h" #include "wire/Headers.h" #include "wire/Ethernet.h" #include "interface/tuntap/TUNMessageType.h" #include "util/Hex.h" #include "util/events/Time.h" #include "util/events/Timeout.h" #include "dht/dhtcore/NodeStore.h" #include #define TUNC 3 #define TUNB 2 #define TUNA 1 static uint8_t incomingTunC(struct Message* msg, struct Interface* iface) { Assert_true(TUNMessageType_pop(msg, NULL) == Ethernet_TYPE_IP6); Message_shift(msg, -Headers_IP6Header_SIZE, NULL); printf("Message from TUN in node C [%s] [%d]\n", msg->bytes, msg->length); *((int*)iface->senderContext) = TUNC; return 0; } static uint8_t incomingTunB(struct Message* msg, struct Interface* iface) { Assert_true(TUNMessageType_pop(msg, NULL) == Ethernet_TYPE_IP6); Message_shift(msg, -Headers_IP6Header_SIZE, NULL); printf("Message from TUN in node B [%s]\n", msg->bytes); *((int*)iface->senderContext) = TUNB; return 0; } static uint8_t incomingTunA(struct Message* msg, struct Interface* iface) { Assert_true(TUNMessageType_pop(msg, NULL) == Ethernet_TYPE_IP6); Message_shift(msg, -Headers_IP6Header_SIZE, NULL); uint8_t buff[1024]; Hex_encode(buff, 1024, msg->bytes, msg->length); printf("Message from TUN in node A [%s] [%d] [%s]\n", msg->bytes, msg->length, buff); *((int*)iface->senderContext) = TUNA; return 0; } struct ThreeNodes; typedef void (RunTest)(struct ThreeNodes* ctx); struct ThreeNodes { struct Interface tunIfC; struct TestFramework* nodeC; struct Interface tunIfB; struct TestFramework* nodeB; struct Interface tunIfA; struct TestFramework* nodeA; int messageFrom; struct Timeout* checkLinkageTimeout; struct Log* logger; struct EventBase* base; #define ThreeNodes_state_AB_COMPLETE 1 #define ThreeNodes_state_CB_COMPLETE 2 int state; uint64_t startTime; RunTest* runTest; Identity }; static void notLinkedYet(struct ThreeNodes* ctx) { uint64_t now = Time_currentTimeMilliseconds(ctx->base); if ((now - ctx->startTime) > 5000) { Assert_failure("three nodes failed to link in 5 seconds"); } } static void checkLinkage(void* vThreeNodes) { struct ThreeNodes* ctx = Identity_check((struct ThreeNodes*) vThreeNodes); if (ctx->nodeA->nodeStore->nodeCount < 1) { notLinkedYet(ctx); return; } if (ctx->state < ThreeNodes_state_AB_COMPLETE) { ctx->state = ThreeNodes_state_AB_COMPLETE; Log_debug(ctx->logger, "Link A and B complete"); } if (ctx->nodeC->nodeStore->nodeCount < 1) { notLinkedYet(ctx); return; } if (ctx->state < ThreeNodes_state_CB_COMPLETE) { ctx->state = ThreeNodes_state_CB_COMPLETE; Log_debug(ctx->logger, "Link C and B complete"); } if (ctx->nodeB->nodeStore->nodeCount < 2) { notLinkedYet(ctx); return; } Log_debug(ctx->logger, "Link C with B and A complete"); Log_debug(ctx->logger, "\n\nSetup Complete\n\n"); Timeout_clearTimeout(ctx->checkLinkageTimeout); ctx->runTest(ctx); } static void start(struct Allocator* alloc, struct Log* logger, struct EventBase* base, struct Random* rand, RunTest* runTest) { struct TestFramework* a = TestFramework_setUp("\xad\x7e\xa3\x26\xaa\x01\x94\x0a\x25\xbc\x9e\x01\x26\x22\xdb\x69" "\x4f\xd9\xb4\x17\x7c\xf3\xf8\x91\x16\xf3\xcf\xe8\x5c\x80\xe1\x4a", alloc, base, rand, logger); //"publicKey": "kmzm4w0kj9bswd5qmx74nu7kusv5pj40vcsmp781j6xxgpd59z00.k", //"ipv6": "fc41:94b5:0925:7ba9:3959:11ab:a006:367a", struct TestFramework* b = TestFramework_setUp("\xea\x8d\x34\x04\xa9\x7c\xe4\xf9\xca\x7e\x24\xe6\xf1\x85\xb9\x3f" "\x01\x37\xb7\xa1\xf5\x2c\xce\xc0\x2c\xae\x03\xf1\x83\x38\x13\x24", alloc, base, rand, logger); // This address was found by brute force for one which falls between A and C without being // closer in either direction (XOR is bidirectional address space distance) // ipv6: fc2e:3273:644e:426f:283d:e3c7:c87c:41c1 struct TestFramework* c = TestFramework_setUp("\xd8\x54\x3e\x70\xb9\xae\x7c\x41\xbc\x18\xa4\x9a\x9c\xee\xca\x9c" "\xdc\x45\x01\x96\x6b\xbd\x7e\x76\xcf\x3a\x9f\xbc\x12\xed\x8b\xb4", alloc, base, rand, logger); //"publicKey": "vz21tg07061s8v9mckrvgtfds7j2u5lst8cwl6nqhp81njrh5wg0.k", //"ipv6": "fc1f:5b96:e1c5:625d:afde:2523:a7fa:383a", Log_debug(a->logger, "Linking A and B"); TestFramework_linkNodes(b, a); Log_debug(a->logger, "Linking B and C"); TestFramework_linkNodes(c, b); struct ThreeNodes* out = Allocator_calloc(alloc, sizeof(struct ThreeNodes), 1); Identity_set(out); out->tunIfC.allocator = alloc; out->tunIfB.allocator = alloc; out->tunIfA.allocator = alloc; out->tunIfC.sendMessage = incomingTunC; out->tunIfB.sendMessage = incomingTunB; out->tunIfA.sendMessage = incomingTunA; out->tunIfC.senderContext = &out->messageFrom; out->tunIfB.senderContext = &out->messageFrom; out->tunIfA.senderContext = &out->messageFrom; out->nodeC = c; out->nodeB = b; out->nodeA = a; out->logger = logger; out->checkLinkageTimeout = Timeout_setInterval(checkLinkage, out, 1, base, alloc); out->base = base; out->startTime = Time_currentTimeMilliseconds(base); out->runTest = runTest; Ducttape_setUserInterface(c->ducttape, &out->tunIfC); Ducttape_setUserInterface(b->ducttape, &out->tunIfB); Ducttape_setUserInterface(a->ducttape, &out->tunIfA); Log_debug(a->logger, "Waiting for nodes to link asynchronously..."); } static void sendMessage(struct ThreeNodes* tn, char* message, struct TestFramework* from, struct TestFramework* to) { struct Message* msg; Message_STACK(msg, 64, 512); Bits_memcpy(msg->bytes, message, CString_strlen(message) + 1); msg->length = CString_strlen(message) + 1; TestFramework_craftIPHeader(msg, from->ip, to->ip); msg = Message_clone(msg, from->alloc); struct Interface* fromIf; if (from == tn->nodeA) { fromIf = &tn->tunIfA; } else if (from == tn->nodeB) { fromIf = &tn->tunIfB; } else if (from == tn->nodeC) { fromIf = &tn->tunIfC; } else { Assert_true(false); } TUNMessageType_push(msg, Ethernet_TYPE_IP6, NULL); fromIf->receiveMessage(msg, fromIf); if (to == tn->nodeA) { Assert_true(tn->messageFrom == TUNA); } else if (to == tn->nodeB) { Assert_true(tn->messageFrom == TUNB); } else if (to == tn->nodeC) { Assert_true(tn->messageFrom == TUNC); } else { Assert_true(false); } TestFramework_assertLastMessageUnaltered(tn->nodeA); TestFramework_assertLastMessageUnaltered(tn->nodeB); TestFramework_assertLastMessageUnaltered(tn->nodeC); tn->messageFrom = 0; } static void runTest(struct ThreeNodes* tn) { sendMessage(tn, "Hello World!", tn->nodeA, tn->nodeC); sendMessage(tn, "Hello cjdns!", tn->nodeC, tn->nodeA); sendMessage(tn, "send", tn->nodeA, tn->nodeC); sendMessage(tn, "a", tn->nodeC, tn->nodeA); sendMessage(tn, "few", tn->nodeA, tn->nodeC); sendMessage(tn, "packets", tn->nodeC, tn->nodeA); sendMessage(tn, "to", tn->nodeA, tn->nodeC); sendMessage(tn, "make", tn->nodeC, tn->nodeA); sendMessage(tn, "sure", tn->nodeA, tn->nodeC); sendMessage(tn, "the", tn->nodeC, tn->nodeA); sendMessage(tn, "cryptoauth", tn->nodeA, tn->nodeC); sendMessage(tn, "can", tn->nodeC, tn->nodeA); sendMessage(tn, "establish", tn->nodeA, tn->nodeC); Log_debug(tn->logger, "\n\nTest passed, shutting down\n\n"); EventBase_endLoop(tn->base); } /** Check if nodes A and C can communicate via B without A knowing that C exists. */ int main() { struct Allocator* alloc = MallocAllocator_new(1<<22); struct Writer* logwriter = FileWriter_new(stdout, alloc); struct Log* logger = WriterLog_new(logwriter, alloc); struct Random* rand = Random_new(alloc, logger, NULL); struct EventBase* base = EventBase_new(alloc); start(alloc, logger, base, rand, runTest); EventBase_beginLoop(base); Allocator_free(alloc); return 0; }