#include "dnsd.hpp" #include /* getaddrinfo, getnameinfo */ #include /* exit */ #include /* memset */ #include #include #include /* close */ #include #include #include #include "logger.hpp" // FIXME: make configurable #define SERVER "8.8.8.8" #define PORT 53 struct sockaddr * resolveHost(const char *url) { char *sUrl = strdup(url); struct dns_query dnsQuery; dnsQuery.length = 12; dnsQuery.url = sUrl; dnsQuery.reqType = 0x01; // dnsQuery.request = { 0xDB, 0x42, 0x01, 0x00, 0x00, 0x01, 0x00, 0x00, 0x00, // 0x00, 0x00, 0x00 }; dnsQuery.request[0] = 0xDB; dnsQuery.request[1] = 0x42; dnsQuery.request[2] = 0x01; dnsQuery.request[3] = 0x00; dnsQuery.request[4] = 0x00; dnsQuery.request[5] = 0x01; dnsQuery.request[6] = 0x00; dnsQuery.request[7] = 0x00; dnsQuery.request[8] = 0x00; dnsQuery.request[9] = 0x00; dnsQuery.request[10] = 0x00; dnsQuery.request[11] = 0x00; char *word; unsigned int i; llarp::LogDebug("Asking DNS server %s about %s\n", SERVER, url); // dnsQuery.reqType = 0x01; word = strtok(sUrl, "."); while(word) { llarp::LogDebug("parsing hostname: \"%s\" is %zu characters\n", word, strlen(word)); dnsQuery.request[dnsQuery.length++] = strlen(word); for(i = 0; i < strlen(word); i++) { dnsQuery.request[dnsQuery.length++] = word[i]; } word = strtok(NULL, "."); } dnsQuery.request[dnsQuery.length++] = 0x00; // End of the host name dnsQuery.request[dnsQuery.length++] = 0x00; // 0x0001 - Query is a Type A query (host address) dnsQuery.request[dnsQuery.length++] = dnsQuery.reqType; dnsQuery.request[dnsQuery.length++] = 0x00; // 0x0001 - Query is class IN (Internet address) dnsQuery.request[dnsQuery.length++] = 0x01; struct sockaddr_in addr; // int socket; ssize_t ret; int rcode; socklen_t size; int ip = 0; int length; unsigned char buffer[DNC_BUF_SIZE]; // unsigned char tempBuf[3]; uint16_t QDCOUNT; // No. of items in Question Section uint16_t ANCOUNT; // No. of items in Answer Section uint16_t NSCOUNT; // No. of items in Authority Section uint16_t ARCOUNT; // No. of items in Additional Section uint16_t QCLASS; // Specifies the class of the query uint16_t ATYPE; // Specifies the meaning of the data in the RDATA field uint16_t ACLASS; // Specifies the class of the data in the RDATA field uint32_t TTL; // The number of seconds the results can be cached uint16_t RDLENGTH; // The length of the RDATA field uint16_t MSGID; int sockfd; sockfd = socket(AF_INET, SOCK_DGRAM, 0); if(sockfd < 0) { llarp::LogWarn("Error creating socket!\n"); return nullptr; } // socket = sockfd; memset(&addr, 0, sizeof(addr)); addr.sin_family = AF_INET; addr.sin_addr.s_addr = inet_addr(SERVER); addr.sin_port = htons(PORT); size = sizeof(addr); // hexdump("sending packet", &dnsQuery.request, dnsQuery.length); ret = sendto(sockfd, dnsQuery.request, dnsQuery.length, 0, (struct sockaddr *)&addr, size); if(ret < 0) { llarp::LogWarn("Error Sending Request"); return nullptr; } // printf("Sent\n"); memset(&buffer, 0, DNC_BUF_SIZE); ret = recvfrom(sockfd, buffer, DNC_BUF_SIZE, 0, (struct sockaddr *)&addr, &size); if(ret < 0) { llarp::LogWarn("Error Receiving Response"); return nullptr; } // hexdump("received packet", &buffer, ret); close(sockfd); rcode = (buffer[3] & 0x0F); // tempBuf[0] = buffer[4]; // tempBuf[1] = buffer[5]; // tempBuf[2] = '\0'; // printf("%0x %0x %0x %0x\n", buffer[4], buffer[5], tempBuf[0], tempBuf[1]); // QDCOUNT = (uint16_t) strtol(tempBuf, NULL, 16); QDCOUNT = (uint16_t)buffer[4] * 0x100 + buffer[5]; llarp::LogDebug("entries in question section: %u\n", QDCOUNT); ANCOUNT = (uint16_t)buffer[6] * 0x100 + buffer[7]; llarp::LogDebug("records in answer section: %u\n", ANCOUNT); NSCOUNT = (uint16_t)buffer[8] * 0x100 + buffer[9]; llarp::LogDebug("name server resource record count: %u\n", NSCOUNT); ARCOUNT = (uint16_t)buffer[10] * 0x100 + buffer[11]; llarp::LogDebug("additional records count: %u\n", ARCOUNT); llarp::LogDebug("query type: %u\n", dnsQuery.reqType); QCLASS = (uint16_t)dnsQuery.request[dnsQuery.length - 2] * 0x100 + dnsQuery.request[dnsQuery.length - 1]; llarp::LogDebug("query class: %u\n", QCLASS); length = dnsQuery.length + 1; // to skip 0xc00c ATYPE = (uint16_t)buffer[length + 1] * 0x100 + buffer[length + 2]; llarp::LogDebug("answer type: %u\n", ATYPE); ACLASS = (uint16_t)buffer[length + 3] * 0x100 + buffer[length + 4]; llarp::LogDebug("answer class: %u\n", ACLASS); TTL = (uint32_t)buffer[length + 5] * 0x1000000 + buffer[length + 6] * 0x10000 + buffer[length + 7] * 0x100 + buffer[length + 8]; llarp::LogDebug("seconds to cache: %u\n", TTL); RDLENGTH = (uint16_t)buffer[length + 9] * 0x100 + buffer[length + 10]; llarp::LogDebug("bytes in answer: %u\n", RDLENGTH); MSGID = (uint16_t)buffer[0] * 0x100 + buffer[1]; llarp::LogDebug("answer msg id: %u\n", MSGID); if(rcode == 2) { llarp::LogWarn("nameserver %s returned SERVFAIL:\n", SERVER); llarp::LogWarn( " the name server was unable to process this query due to a\n " "problem with the name server.\n"); return nullptr; } else if(rcode == 3) { llarp::LogWarn("nameserver %s returned NXDOMAIN for %s:\n", SERVER, dnsQuery.url); llarp::LogWarn( " the domain name referenced in the query does not exist\n"); return nullptr; } /* search for and print IPv4 addresses */ if(dnsQuery.reqType == 0x01) { llarp::LogDebug("DNS server's answer is: (type#=%u):", ATYPE); // printf("IPv4 address(es) for %s:\n", dnsQuery.url); for(i = 0; i < ret; i++) { if(buffer[i] == 0xC0 && buffer[i + 3] == 0x01) { ip++; i += 12; /* ! += buf[i+1]; */ llarp::LogDebug(" %u.%u.%u.%u\n", buffer[i], buffer[i + 1], buffer[i + 2], buffer[i + 3]); struct sockaddr *g_addr = new sockaddr; g_addr->sa_family = AF_INET; // g_addr->sa_len = sizeof(in_addr); struct in_addr *addr = &((struct sockaddr_in *)g_addr)->sin_addr; unsigned char *ip; // have ip point to s_addr ip = (unsigned char *)&(addr->s_addr); ip[0] = buffer[i + 0]; ip[1] = buffer[i + 1]; ip[2] = buffer[i + 2]; ip[3] = buffer[i + 3]; return g_addr; } } if(!ip) { llarp::LogWarn(" No IPv4 address found in the DNS response!\n"); return nullptr; } } return nullptr; } void llarp_handle_dnsclient_recvfrom(struct llarp_udp_io *udp, const struct sockaddr *saddr, const void *buf, ssize_t sz) { struct dns_client_request *request = (struct dns_client_request *)udp->user; if(!request) { llarp::LogError( "User data to DNS Client response not a dns_client_request"); // we can't call back the hook return; } // it's corrupt by here... // dns_request *server_request = (dns_request *)request->user; // unsigned char buffer[DNC_BUF_SIZE]; unsigned char *buffer = (unsigned char *)buf; // memset(&buffer, 0, DNC_BUF_SIZE); // ret = recvfrom(sockfd, buffer, BUF_SIZE, 0, (struct sockaddr*)&addr, // &size); if(sz < 0) { llarp::LogWarn("Error Receiving DNS Client Response"); request->resolved(request, nullptr); return; } // hexdump("received packet", &buffer, ret); llarp_ev_close_udp(udp); uint16_t QDCOUNT; // No. of items in Question Section uint16_t ANCOUNT; // No. of items in Answer Section uint16_t NSCOUNT; // No. of items in Authority Section uint16_t ARCOUNT; // No. of items in Additional Section uint16_t QCLASS; // Specifies the class of the query uint16_t ATYPE; // Specifies the meaning of the data in the RDATA field uint16_t ACLASS; // Specifies the class of the data in the RDATA field uint32_t TTL; // The number of seconds the results can be cached uint16_t RDLENGTH; // The length of the RDATA field uint16_t MSGID; int rcode; int length; struct dns_query *dnsQuery = &request->query; rcode = (buffer[3] & 0x0F); // tempBuf[0] = buffer[4]; // tempBuf[1] = buffer[5]; // tempBuf[2] = '\0'; // printf("%0x %0x %0x %0x\n", buffer[4], buffer[5], tempBuf[0], tempBuf[1]); // QDCOUNT = (uint16_t) strtol(tempBuf, NULL, 16); QDCOUNT = (uint16_t)buffer[4] * 0x100 + buffer[5]; llarp::LogDebug("entries in question section: %u\n", QDCOUNT); ANCOUNT = (uint16_t)buffer[6] * 0x100 + buffer[7]; llarp::LogDebug("records in answer section: %u\n", ANCOUNT); NSCOUNT = (uint16_t)buffer[8] * 0x100 + buffer[9]; llarp::LogDebug("name server resource record count: %u\n", NSCOUNT); ARCOUNT = (uint16_t)buffer[10] * 0x100 + buffer[11]; llarp::LogDebug("additional records count: %u\n", ARCOUNT); llarp::LogDebug("query type: %u\n", dnsQuery->reqType); QCLASS = (uint16_t)dnsQuery->request[dnsQuery->length - 2] * 0x100 + dnsQuery->request[dnsQuery->length - 1]; llarp::LogDebug("query class: %u\n", QCLASS); length = dnsQuery->length + 1; // to skip 0xc00c ATYPE = (uint16_t)buffer[length + 1] * 0x100 + buffer[length + 2]; llarp::LogDebug("answer type: %u\n", ATYPE); ACLASS = (uint16_t)buffer[length + 3] * 0x100 + buffer[length + 4]; llarp::LogDebug("answer class: %u\n", ACLASS); TTL = (uint32_t)buffer[length + 5] * 0x1000000 + buffer[length + 6] * 0x10000 + buffer[length + 7] * 0x100 + buffer[length + 8]; llarp::LogDebug("seconds to cache: %u\n", TTL); RDLENGTH = (uint16_t)buffer[length + 9] * 0x100 + buffer[length + 10]; llarp::LogDebug("bytes in answer: %u\n", RDLENGTH); MSGID = (uint16_t)buffer[0] * 0x100 + buffer[1]; llarp::LogDebug("answer msg id: %u\n", MSGID); if(rcode == 2) { llarp::LogWarn("nameserver %s returned SERVFAIL:\n", SERVER); llarp::LogWarn( " the name server was unable to process this query due to a\n " "problem with the name server.\n"); request->resolved(request, nullptr); return; } else if(rcode == 3) { llarp::LogWarn("nameserver %s returned NXDOMAIN for %s:\n", SERVER, dnsQuery->url); llarp::LogWarn( " the domain name referenced in the query does not exist\n"); request->resolved(request, nullptr); return; } int ip = 0; /* search for and print IPv4 addresses */ if(dnsQuery->reqType == 0x01) { llarp::LogInfo("DNS server's answer is: (type#=%u):", ATYPE); printf("IPv4 address(es) for %s:\n", dnsQuery->url); for(unsigned int i = 0; i < sz; i++) { if(buffer[i] == 0xC0 && buffer[i + 3] == 0x01) { ip++; i += 12; /* ! += buf[i+1]; */ llarp::LogDebug(" %u.%u.%u.%u\n", buffer[i], buffer[i + 1], buffer[i + 2], buffer[i + 3]); struct sockaddr *g_addr = new sockaddr; g_addr->sa_family = AF_INET; // g_addr->sa_len = sizeof(in_addr); struct in_addr *addr = &((struct sockaddr_in *)g_addr)->sin_addr; unsigned char *ip; // have ip point to s_addr ip = (unsigned char *)&(addr->s_addr); ip[0] = buffer[i + 0]; ip[1] = buffer[i + 1]; ip[2] = buffer[i + 2]; ip[3] = buffer[i + 3]; // return g_addr; request->resolved(request, g_addr); return; } } if(!ip) { llarp::LogWarn(" No IPv4 address found in the DNS response!\n"); request->resolved(request, nullptr); return; } } } void build_dns_query(struct dns_query *dnsQuery) { dnsQuery->length = 12; // dnsQuery->url = sUrl; dnsQuery->reqType = 0x01; // dnsQuery.request = { 0xDB, 0x42, 0x01, 0x00, 0x00, 0x01, 0x00, 0x00, 0x00, // 0x00, 0x00, 0x00 }; dnsQuery->request[0] = 0xDB; dnsQuery->request[1] = 0x42; dnsQuery->request[2] = 0x01; dnsQuery->request[3] = 0x00; dnsQuery->request[4] = 0x00; dnsQuery->request[5] = 0x01; dnsQuery->request[6] = 0x00; dnsQuery->request[7] = 0x00; dnsQuery->request[8] = 0x00; dnsQuery->request[9] = 0x00; dnsQuery->request[10] = 0x00; dnsQuery->request[11] = 0x00; char *word; llarp::LogDebug("Asking DNS server %s about %s\n", SERVER, dnsQuery->url); char *strTemp = strdup(dnsQuery->url); word = strtok(strTemp, "."); while(word) { llarp::LogDebug("parsing hostname: \"%s\" is %zu characters\n", word, strlen(word)); dnsQuery->request[dnsQuery->length++] = strlen(word); for(unsigned int i = 0; i < strlen(word); i++) { dnsQuery->request[dnsQuery->length++] = word[i]; } word = strtok(NULL, "."); } dnsQuery->request[dnsQuery->length++] = 0x00; // End of the host name dnsQuery->request[dnsQuery->length++] = 0x00; // 0x0001 - Query is a Type A query (host address) dnsQuery->request[dnsQuery->length++] = dnsQuery->reqType; dnsQuery->request[dnsQuery->length++] = 0x00; // 0x0001 - Query is class IN (Internet address) dnsQuery->request[dnsQuery->length++] = 0x01; } bool llarp_dns_resolve(dns_client_request *request) { struct dns_query *dnsQuery = &request->query; build_dns_query(dnsQuery); struct sockaddr_in addr; // int socket; ssize_t ret; // socklen_t size; // unsigned char tempBuf[3]; memset(&addr, 0, sizeof(addr)); addr.sin_family = AF_INET; addr.sin_addr.s_addr = inet_addr(SERVER); addr.sin_port = htons(PORT); // size = sizeof(addr); llarp_udp_io *udp = (llarp_udp_io *)request->sock; // llarp::LogDebug("dns client set to use "); // XXX: udp user pointer should be set before binding to socket and once udp->user = request; // hexdump("sending packet", &dnsQuery.request, dnsQuery.length); // ret = sendto(sockfd, dnsQuery.request, dnsQuery.length, 0, (struct // sockaddr*)&addr, size); ret = llarp_ev_udp_sendto(udp, (sockaddr *)&addr, dnsQuery->request, dnsQuery->length); if(ret < 0) { llarp::LogWarn("Error Sending Request"); return false; } // dns_request *test = (dns_request *)request->user; // printf("Sent\n"); llarp::LogInfo("Request sent, awaiting response"); return true; } bool llarp_resolve_host(struct llarp_ev_loop *netloop, const char *url, resolve_dns_hook_func resolved, void *user) { struct sockaddr_in s_addr; s_addr.sin_family = AF_INET; s_addr.sin_addr.s_addr = inet_addr("0.0.0.0"); llarp_udp_io *udp = new llarp_udp_io; udp->tick = nullptr; udp->user = nullptr; udp->impl = nullptr; udp->parent = netloop; // add_udp will do this... // llarp::LogDebug("dns client set to use "); udp->recvfrom = &llarp_handle_dnsclient_recvfrom; if(llarp_ev_add_udp(netloop, udp, (sockaddr *)&s_addr) == -1) { llarp::LogError("failed to bind resolver to"); return false; } dns_client_request *request = new dns_client_request; request->sock = (void *)udp; request->user = user; request->query.url = strdup(url); request->resolved = resolved; llarp_dns_resolve(request); return true; }