Nicolas Borla
/
BBR_1Ebene
BBR 1 Ebene
mbed-os/features/netsocket/nsapi_dns.cpp
- Committer:
- borlanic
- Date:
- 2018-05-14
- Revision:
- 0:fbdae7e6d805
File content as of revision 0:fbdae7e6d805:
/* nsapi_dns.cpp * Original work Copyright (c) 2013 Henry Leinen (henry[dot]leinen [at] online [dot] de) * Modified work Copyright (c) 2015 ARM Limited * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include "nsapi_dns.h" #include "netsocket/UDPSocket.h" #include <string.h> #include <stdlib.h> #include <stdio.h> #define CLASS_IN 1 #define RR_A 1 #define RR_AAAA 28 // DNS options #define DNS_BUFFER_SIZE 512 #define DNS_TIMEOUT 5000 #define DNS_SERVERS_SIZE 5 nsapi_addr_t dns_servers[DNS_SERVERS_SIZE] = { {NSAPI_IPv4, {8, 8, 8, 8}}, // Google {NSAPI_IPv4, {209, 244, 0, 3}}, // Level 3 {NSAPI_IPv4, {84, 200, 69, 80}}, // DNS.WATCH {NSAPI_IPv6, {0x20,0x01, 0x48,0x60, 0x48,0x60, 0,0, // Google 0,0, 0,0, 0,0, 0x88,0x88}}, {NSAPI_IPv6, {0x20,0x01, 0x16,0x08, 0,0x10, 0,0x25, // DNS.WATCH 0,0, 0,0, 0x1c,0x04, 0xb1,0x2f}}, }; // DNS server configuration extern "C" nsapi_error_t nsapi_dns_add_server(nsapi_addr_t addr) { memmove(&dns_servers[1], &dns_servers[0], (DNS_SERVERS_SIZE-1)*sizeof(nsapi_addr_t)); dns_servers[0] = addr; return NSAPI_ERROR_OK; } // DNS packet parsing static void dns_append_byte(uint8_t **p, uint8_t byte) { *(*p)++ = byte; } static void dns_append_word(uint8_t **p, uint16_t word) { dns_append_byte(p, 0xff & (word >> 8)); dns_append_byte(p, 0xff & (word >> 0)); } static void dns_append_name(uint8_t **p, const char *name, uint8_t len) { dns_append_byte(p, len); memcpy(*p, name, len); *p += len; } static uint8_t dns_scan_byte(const uint8_t **p) { return *(*p)++; } static uint16_t dns_scan_word(const uint8_t **p) { uint16_t a = dns_scan_byte(p); uint16_t b = dns_scan_byte(p); return (a << 8) | b; } static void dns_append_question(uint8_t **p, const char *host, nsapi_version_t version) { // fill the header dns_append_word(p, 1); // id = 1 dns_append_word(p, 0x0100); // flags = recursion required dns_append_word(p, 1); // qdcount = 1 dns_append_word(p, 0); // ancount = 0 dns_append_word(p, 0); // nscount = 0 dns_append_word(p, 0); // arcount = 0 // fill out the question names while (host[0]) { size_t label_len = strcspn(host, "."); dns_append_name(p, host, label_len); host += label_len + (host[label_len] == '.'); } dns_append_byte(p, 0); // fill out question footer if (version != NSAPI_IPv6) { dns_append_word(p, RR_A); // qtype = ipv4 } else { dns_append_word(p, RR_AAAA); // qtype = ipv6 } dns_append_word(p, CLASS_IN); } static int dns_scan_response(const uint8_t **p, nsapi_addr_t *addr, unsigned addr_count) { // scan header uint16_t id = dns_scan_word(p); uint16_t flags = dns_scan_word(p); bool qr = 0x1 & (flags >> 15); uint8_t opcode = 0xf & (flags >> 11); uint8_t rcode = 0xf & (flags >> 0); uint16_t qdcount = dns_scan_word(p); // qdcount uint16_t ancount = dns_scan_word(p); // ancount dns_scan_word(p); // nscount dns_scan_word(p); // arcount // verify header is response to query if (!(id == 1 && qr && opcode == 0 && rcode == 0)) { return 0; } // skip questions for (int i = 0; i < qdcount; i++) { while (true) { uint8_t len = dns_scan_byte(p); if (len == 0) { break; } *p += len; } dns_scan_word(p); // qtype dns_scan_word(p); // qclass } // scan each response unsigned count = 0; for (int i = 0; i < ancount && count < addr_count; i++) { while (true) { uint8_t len = dns_scan_byte(p); if (len == 0) { break; } else if (len & 0xc0) { // this is link dns_scan_byte(p); break; } *p += len; } uint16_t rtype = dns_scan_word(p); // rtype uint16_t rclass = dns_scan_word(p); // rclass *p += 4; // ttl uint16_t rdlength = dns_scan_word(p); // rdlength if (rtype == RR_A && rclass == CLASS_IN && rdlength == NSAPI_IPv4_BYTES) { // accept A record addr->version = NSAPI_IPv4; for (int i = 0; i < NSAPI_IPv4_BYTES; i++) { addr->bytes[i] = dns_scan_byte(p); } addr += 1; count += 1; } else if (rtype == RR_AAAA && rclass == CLASS_IN && rdlength == NSAPI_IPv6_BYTES) { // accept AAAA record addr->version = NSAPI_IPv6; for (int i = 0; i < NSAPI_IPv6_BYTES; i++) { addr->bytes[i] = dns_scan_byte(p); } addr += 1; count += 1; } else { // skip unrecognized records *p += rdlength; } } return count; } // core query function static nsapi_size_or_error_t nsapi_dns_query_multiple(NetworkStack *stack, const char *host, nsapi_addr_t *addr, unsigned addr_count, nsapi_version_t version) { // check for valid host name int host_len = host ? strlen(host) : 0; if (host_len > 128 || host_len == 0) { return NSAPI_ERROR_PARAMETER; } // create a udp socket UDPSocket socket; int err = socket.open(stack); if (err) { return err; } socket.set_timeout(DNS_TIMEOUT); // create network packet uint8_t * const packet = (uint8_t *)malloc(DNS_BUFFER_SIZE); if (!packet) { return NSAPI_ERROR_NO_MEMORY; } nsapi_size_or_error_t result = NSAPI_ERROR_DNS_FAILURE; // check against each dns server for (unsigned i = 0; i < DNS_SERVERS_SIZE; i++) { // send the question uint8_t *question = packet; dns_append_question(&question, host, version); err = socket.sendto(SocketAddress(dns_servers[i], 53), packet, question - packet); // send may fail for various reasons, including wrong address type - move on if (err < 0) { continue; } // recv the response err = socket.recvfrom(NULL, packet, DNS_BUFFER_SIZE); if (err == NSAPI_ERROR_WOULD_BLOCK) { continue; } else if (err < 0) { result = err; break; } const uint8_t *response = packet; int count = dns_scan_response(&response, addr, addr_count); if (count > 0) { result = count; } /* The DNS response is final, no need to check other servers */ break; } // clean up packet free(packet); // clean up udp err = socket.close(); if (err) { return err; } // return result return result; } // convenience functions for other forms of queries extern "C" nsapi_size_or_error_t nsapi_dns_query_multiple(nsapi_stack_t *stack, const char *host, nsapi_addr_t *addr, nsapi_size_t addr_count, nsapi_version_t version) { NetworkStack *nstack = nsapi_create_stack(stack); return nsapi_dns_query_multiple(nstack, host, addr, addr_count, version); } nsapi_size_or_error_t nsapi_dns_query_multiple(NetworkStack *stack, const char *host, SocketAddress *addresses, nsapi_size_t addr_count, nsapi_version_t version) { nsapi_addr_t *addrs = new nsapi_addr_t[addr_count]; nsapi_size_or_error_t result = nsapi_dns_query_multiple(stack, host, addrs, addr_count, version); if (result > 0) { for (int i = 0; i < result; i++) { addresses[i].set_addr(addrs[i]); } } delete[] addrs; return result; } extern "C" nsapi_error_t nsapi_dns_query(nsapi_stack_t *stack, const char *host, nsapi_addr_t *addr, nsapi_version_t version) { NetworkStack *nstack = nsapi_create_stack(stack); nsapi_size_or_error_t result = nsapi_dns_query_multiple(nstack, host, addr, 1, version); return (nsapi_error_t)((result > 0) ? 0 : result); } nsapi_error_t nsapi_dns_query(NetworkStack *stack, const char *host, SocketAddress *address, nsapi_version_t version) { nsapi_addr_t addr; nsapi_size_or_error_t result = nsapi_dns_query_multiple(stack, host, &addr, 1, version); address->set_addr(addr); return (nsapi_error_t)((result > 0) ? 0 : result); }