1 /*
2 * Copyright (C) 2016 The Android Open Source Project
3 *
4 * Licensed under the Apache License, Version 2.0 (the "License");
5 * you may not use this file except in compliance with the License.
6 * You may obtain a copy of the License at
7 *
8 * http://www.apache.org/licenses/LICENSE-2.0
9 *
10 * Unless required by applicable law or agreed to in writing, software
11 * distributed under the License is distributed on an "AS IS" BASIS,
12 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
13 * See the License for the specific language governing permissions and
14 * limitations under the License.
15 */
16
17 #include "dns_responder.h"
18
19 #include <arpa/inet.h>
20 #include <fcntl.h>
21 #include <netdb.h>
22 #include <stdarg.h>
23 #include <stdlib.h>
24 #include <string.h>
25 #include <sys/epoll.h>
26 #include <sys/eventfd.h>
27 #include <sys/socket.h>
28 #include <sys/types.h>
29 #include <unistd.h>
30
31 #include <chrono>
32 #include <iostream>
33 #include <set>
34 #include <vector>
35
36 #define LOG_TAG "DNSResponder"
37 #include <android-base/logging.h>
38 #include <android-base/strings.h>
39 #include <netdutils/InternetAddresses.h>
40 #include <netdutils/Slice.h>
41 #include <netdutils/SocketOption.h>
42
43 using android::netdutils::enableSockopt;
44 using android::netdutils::ScopedAddrinfo;
45 using android::netdutils::Slice;
46
47 namespace test {
48
errno2str()49 std::string errno2str() {
50 char error_msg[512] = {0};
51 // It actually calls __gnu_strerror_r() which returns the type |char*| rather than |int|.
52 // PLOG is an option though it requires lots of changes from ALOGx() to LOG(x).
53 return strerror_r(errno, error_msg, sizeof(error_msg));
54 }
55
str2hex(const char * buffer,size_t len)56 std::string str2hex(const char* buffer, size_t len) {
57 std::string str(len * 2, '\0');
58 for (size_t i = 0; i < len; ++i) {
59 static const char* hex = "0123456789ABCDEF";
60 uint8_t c = buffer[i];
61 str[i * 2] = hex[c >> 4];
62 str[i * 2 + 1] = hex[c & 0x0F];
63 }
64 return str;
65 }
66
addr2str(const sockaddr * sa,socklen_t sa_len)67 std::string addr2str(const sockaddr* sa, socklen_t sa_len) {
68 char host_str[NI_MAXHOST] = {0};
69 int rv = getnameinfo(sa, sa_len, host_str, sizeof(host_str), nullptr, 0, NI_NUMERICHOST);
70 if (rv == 0) return std::string(host_str);
71 return std::string();
72 }
73
74 /* DNS struct helpers */
75
dnstype2str(unsigned dnstype)76 const char* dnstype2str(unsigned dnstype) {
77 static std::unordered_map<unsigned, const char*> kTypeStrs = {
78 {ns_type::ns_t_a, "A"},
79 {ns_type::ns_t_ns, "NS"},
80 {ns_type::ns_t_md, "MD"},
81 {ns_type::ns_t_mf, "MF"},
82 {ns_type::ns_t_cname, "CNAME"},
83 {ns_type::ns_t_soa, "SOA"},
84 {ns_type::ns_t_mb, "MB"},
85 {ns_type::ns_t_mb, "MG"},
86 {ns_type::ns_t_mr, "MR"},
87 {ns_type::ns_t_null, "NULL"},
88 {ns_type::ns_t_wks, "WKS"},
89 {ns_type::ns_t_ptr, "PTR"},
90 {ns_type::ns_t_hinfo, "HINFO"},
91 {ns_type::ns_t_minfo, "MINFO"},
92 {ns_type::ns_t_mx, "MX"},
93 {ns_type::ns_t_txt, "TXT"},
94 {ns_type::ns_t_rp, "RP"},
95 {ns_type::ns_t_afsdb, "AFSDB"},
96 {ns_type::ns_t_x25, "X25"},
97 {ns_type::ns_t_isdn, "ISDN"},
98 {ns_type::ns_t_rt, "RT"},
99 {ns_type::ns_t_nsap, "NSAP"},
100 {ns_type::ns_t_nsap_ptr, "NSAP-PTR"},
101 {ns_type::ns_t_sig, "SIG"},
102 {ns_type::ns_t_key, "KEY"},
103 {ns_type::ns_t_px, "PX"},
104 {ns_type::ns_t_gpos, "GPOS"},
105 {ns_type::ns_t_aaaa, "AAAA"},
106 {ns_type::ns_t_loc, "LOC"},
107 {ns_type::ns_t_nxt, "NXT"},
108 {ns_type::ns_t_eid, "EID"},
109 {ns_type::ns_t_nimloc, "NIMLOC"},
110 {ns_type::ns_t_srv, "SRV"},
111 {ns_type::ns_t_naptr, "NAPTR"},
112 {ns_type::ns_t_kx, "KX"},
113 {ns_type::ns_t_cert, "CERT"},
114 {ns_type::ns_t_a6, "A6"},
115 {ns_type::ns_t_dname, "DNAME"},
116 {ns_type::ns_t_sink, "SINK"},
117 {ns_type::ns_t_opt, "OPT"},
118 {ns_type::ns_t_apl, "APL"},
119 {ns_type::ns_t_tkey, "TKEY"},
120 {ns_type::ns_t_tsig, "TSIG"},
121 {ns_type::ns_t_ixfr, "IXFR"},
122 {ns_type::ns_t_axfr, "AXFR"},
123 {ns_type::ns_t_mailb, "MAILB"},
124 {ns_type::ns_t_maila, "MAILA"},
125 {ns_type::ns_t_any, "ANY"},
126 {ns_type::ns_t_zxfr, "ZXFR"},
127 };
128 auto it = kTypeStrs.find(dnstype);
129 static const char* kUnknownStr{"UNKNOWN"};
130 if (it == kTypeStrs.end()) return kUnknownStr;
131 return it->second;
132 }
133
dnsclass2str(unsigned dnsclass)134 const char* dnsclass2str(unsigned dnsclass) {
135 static std::unordered_map<unsigned, const char*> kClassStrs = {
136 {ns_class::ns_c_in, "Internet"}, {2, "CSNet"},
137 {ns_class::ns_c_chaos, "ChaosNet"}, {ns_class::ns_c_hs, "Hesiod"},
138 {ns_class::ns_c_none, "none"}, {ns_class::ns_c_any, "any"}};
139 auto it = kClassStrs.find(dnsclass);
140 static const char* kUnknownStr{"UNKNOWN"};
141 if (it == kClassStrs.end()) return kUnknownStr;
142 return it->second;
143 }
144
dnsproto2str(int protocol)145 const char* dnsproto2str(int protocol) {
146 switch (protocol) {
147 case IPPROTO_TCP:
148 return "TCP";
149 case IPPROTO_UDP:
150 return "UDP";
151 default:
152 return "UNKNOWN";
153 }
154 }
155
read(const char * buffer,const char * buffer_end)156 const char* DNSName::read(const char* buffer, const char* buffer_end) {
157 const char* cur = buffer;
158 bool last = false;
159 do {
160 cur = parseField(cur, buffer_end, &last);
161 if (cur == nullptr) {
162 LOG(ERROR) << "parsing failed at line " << __LINE__;
163 return nullptr;
164 }
165 } while (!last);
166 return cur;
167 }
168
write(char * buffer,const char * buffer_end) const169 char* DNSName::write(char* buffer, const char* buffer_end) const {
170 char* buffer_cur = buffer;
171 for (size_t pos = 0; pos < name.size();) {
172 size_t dot_pos = name.find('.', pos);
173 if (dot_pos == std::string::npos) {
174 // Sanity check, should never happen unless parseField is broken.
175 LOG(ERROR) << "logic error: all names are expected to end with a '.'";
176 return nullptr;
177 }
178 const size_t len = dot_pos - pos;
179 if (len >= 256) {
180 LOG(ERROR) << "name component '" << name.substr(pos, dot_pos - pos) << "' is " << len
181 << " long, but max is 255";
182 return nullptr;
183 }
184 if (buffer_cur + sizeof(uint8_t) + len > buffer_end) {
185 LOG(ERROR) << "buffer overflow at line " << __LINE__;
186 return nullptr;
187 }
188 *buffer_cur++ = len;
189 buffer_cur = std::copy(std::next(name.begin(), pos), std::next(name.begin(), dot_pos),
190 buffer_cur);
191 pos = dot_pos + 1;
192 }
193 // Write final zero.
194 *buffer_cur++ = 0;
195 return buffer_cur;
196 }
197
parseField(const char * buffer,const char * buffer_end,bool * last)198 const char* DNSName::parseField(const char* buffer, const char* buffer_end, bool* last) {
199 if (buffer + sizeof(uint8_t) > buffer_end) {
200 LOG(ERROR) << "parsing failed at line " << __LINE__;
201 return nullptr;
202 }
203 unsigned field_type = *buffer >> 6;
204 unsigned ofs = *buffer & 0x3F;
205 const char* cur = buffer + sizeof(uint8_t);
206 if (field_type == 0) {
207 // length + name component
208 if (ofs == 0) {
209 *last = true;
210 return cur;
211 }
212 if (cur + ofs > buffer_end) {
213 LOG(ERROR) << "parsing failed at line " << __LINE__;
214 return nullptr;
215 }
216 name.append(cur, ofs);
217 name.push_back('.');
218 return cur + ofs;
219 } else if (field_type == 3) {
220 LOG(ERROR) << "name compression not implemented";
221 return nullptr;
222 }
223 LOG(ERROR) << "invalid name field type";
224 return nullptr;
225 }
226
read(const char * buffer,const char * buffer_end)227 const char* DNSQuestion::read(const char* buffer, const char* buffer_end) {
228 const char* cur = qname.read(buffer, buffer_end);
229 if (cur == nullptr) {
230 LOG(ERROR) << "parsing failed at line " << __LINE__;
231 return nullptr;
232 }
233 if (cur + 2 * sizeof(uint16_t) > buffer_end) {
234 LOG(ERROR) << "parsing failed at line " << __LINE__;
235 return nullptr;
236 }
237 qtype = ntohs(*reinterpret_cast<const uint16_t*>(cur));
238 qclass = ntohs(*reinterpret_cast<const uint16_t*>(cur + sizeof(uint16_t)));
239 return cur + 2 * sizeof(uint16_t);
240 }
241
write(char * buffer,const char * buffer_end) const242 char* DNSQuestion::write(char* buffer, const char* buffer_end) const {
243 char* buffer_cur = qname.write(buffer, buffer_end);
244 if (buffer_cur == nullptr) return nullptr;
245 if (buffer_cur + 2 * sizeof(uint16_t) > buffer_end) {
246 LOG(ERROR) << "buffer overflow on line " << __LINE__;
247 return nullptr;
248 }
249 *reinterpret_cast<uint16_t*>(buffer_cur) = htons(qtype);
250 *reinterpret_cast<uint16_t*>(buffer_cur + sizeof(uint16_t)) = htons(qclass);
251 return buffer_cur + 2 * sizeof(uint16_t);
252 }
253
toString() const254 std::string DNSQuestion::toString() const {
255 char buffer[4096];
256 int len = snprintf(buffer, sizeof(buffer), "Q<%s,%s,%s>", qname.name.c_str(),
257 dnstype2str(qtype), dnsclass2str(qclass));
258 return std::string(buffer, len);
259 }
260
read(const char * buffer,const char * buffer_end)261 const char* DNSRecord::read(const char* buffer, const char* buffer_end) {
262 const char* cur = name.read(buffer, buffer_end);
263 if (cur == nullptr) {
264 LOG(ERROR) << "parsing failed at line " << __LINE__;
265 return nullptr;
266 }
267 unsigned rdlen = 0;
268 cur = readIntFields(cur, buffer_end, &rdlen);
269 if (cur == nullptr) {
270 LOG(ERROR) << "parsing failed at line " << __LINE__;
271 return nullptr;
272 }
273 if (cur + rdlen > buffer_end) {
274 LOG(ERROR) << "parsing failed at line " << __LINE__;
275 return nullptr;
276 }
277 rdata.assign(cur, cur + rdlen);
278 return cur + rdlen;
279 }
280
write(char * buffer,const char * buffer_end) const281 char* DNSRecord::write(char* buffer, const char* buffer_end) const {
282 char* buffer_cur = name.write(buffer, buffer_end);
283 if (buffer_cur == nullptr) return nullptr;
284 buffer_cur = writeIntFields(rdata.size(), buffer_cur, buffer_end);
285 if (buffer_cur == nullptr) return nullptr;
286 if (buffer_cur + rdata.size() > buffer_end) {
287 LOG(ERROR) << "buffer overflow on line " << __LINE__;
288 return nullptr;
289 }
290 return std::copy(rdata.begin(), rdata.end(), buffer_cur);
291 }
292
toString() const293 std::string DNSRecord::toString() const {
294 char buffer[4096];
295 int len = snprintf(buffer, sizeof(buffer), "R<%s,%s,%s>", name.name.c_str(), dnstype2str(rtype),
296 dnsclass2str(rclass));
297 return std::string(buffer, len);
298 }
299
readIntFields(const char * buffer,const char * buffer_end,unsigned * rdlen)300 const char* DNSRecord::readIntFields(const char* buffer, const char* buffer_end, unsigned* rdlen) {
301 if (buffer + sizeof(IntFields) > buffer_end) {
302 LOG(ERROR) << "parsing failed at line " << __LINE__;
303 return nullptr;
304 }
305 const auto& intfields = *reinterpret_cast<const IntFields*>(buffer);
306 rtype = ntohs(intfields.rtype);
307 rclass = ntohs(intfields.rclass);
308 ttl = ntohl(intfields.ttl);
309 *rdlen = ntohs(intfields.rdlen);
310 return buffer + sizeof(IntFields);
311 }
312
writeIntFields(unsigned rdlen,char * buffer,const char * buffer_end) const313 char* DNSRecord::writeIntFields(unsigned rdlen, char* buffer, const char* buffer_end) const {
314 if (buffer + sizeof(IntFields) > buffer_end) {
315 LOG(ERROR) << "buffer overflow on line " << __LINE__;
316 return nullptr;
317 }
318 auto& intfields = *reinterpret_cast<IntFields*>(buffer);
319 intfields.rtype = htons(rtype);
320 intfields.rclass = htons(rclass);
321 intfields.ttl = htonl(ttl);
322 intfields.rdlen = htons(rdlen);
323 return buffer + sizeof(IntFields);
324 }
325
read(const char * buffer,const char * buffer_end)326 const char* DNSHeader::read(const char* buffer, const char* buffer_end) {
327 unsigned qdcount;
328 unsigned ancount;
329 unsigned nscount;
330 unsigned arcount;
331 const char* cur = readHeader(buffer, buffer_end, &qdcount, &ancount, &nscount, &arcount);
332 if (cur == nullptr) {
333 LOG(ERROR) << "parsing failed at line " << __LINE__;
334 return nullptr;
335 }
336 if (qdcount) {
337 questions.resize(qdcount);
338 for (unsigned i = 0; i < qdcount; ++i) {
339 cur = questions[i].read(cur, buffer_end);
340 if (cur == nullptr) {
341 LOG(ERROR) << "parsing failed at line " << __LINE__;
342 return nullptr;
343 }
344 }
345 }
346 if (ancount) {
347 answers.resize(ancount);
348 for (unsigned i = 0; i < ancount; ++i) {
349 cur = answers[i].read(cur, buffer_end);
350 if (cur == nullptr) {
351 LOG(ERROR) << "parsing failed at line " << __LINE__;
352 return nullptr;
353 }
354 }
355 }
356 if (nscount) {
357 authorities.resize(nscount);
358 for (unsigned i = 0; i < nscount; ++i) {
359 cur = authorities[i].read(cur, buffer_end);
360 if (cur == nullptr) {
361 LOG(ERROR) << "parsing failed at line " << __LINE__;
362 return nullptr;
363 }
364 }
365 }
366 if (arcount) {
367 additionals.resize(arcount);
368 for (unsigned i = 0; i < arcount; ++i) {
369 cur = additionals[i].read(cur, buffer_end);
370 if (cur == nullptr) {
371 LOG(ERROR) << "parsing failed at line " << __LINE__;
372 return nullptr;
373 }
374 }
375 }
376 return cur;
377 }
378
write(char * buffer,const char * buffer_end) const379 char* DNSHeader::write(char* buffer, const char* buffer_end) const {
380 if (buffer + sizeof(Header) > buffer_end) {
381 LOG(ERROR) << "buffer overflow on line " << __LINE__;
382 return nullptr;
383 }
384 Header& header = *reinterpret_cast<Header*>(buffer);
385 // bytes 0-1
386 header.id = htons(id);
387 // byte 2: 7:qr, 3-6:opcode, 2:aa, 1:tr, 0:rd
388 header.flags0 = (qr << 7) | (opcode << 3) | (aa << 2) | (tr << 1) | rd;
389 // byte 3: 7:ra, 6:zero, 5:ad, 4:cd, 0-3:rcode
390 // Fake behavior: if the query set the "ad" bit, set it in the response too.
391 // In a real server, this should be set only if the data is authentic and the
392 // query contained an "ad" bit or DNSSEC extensions.
393 header.flags1 = (ad << 5) | rcode;
394 // rest of header
395 header.qdcount = htons(questions.size());
396 header.ancount = htons(answers.size());
397 header.nscount = htons(authorities.size());
398 header.arcount = htons(additionals.size());
399 char* buffer_cur = buffer + sizeof(Header);
400 for (const DNSQuestion& question : questions) {
401 buffer_cur = question.write(buffer_cur, buffer_end);
402 if (buffer_cur == nullptr) return nullptr;
403 }
404 for (const DNSRecord& answer : answers) {
405 buffer_cur = answer.write(buffer_cur, buffer_end);
406 if (buffer_cur == nullptr) return nullptr;
407 }
408 for (const DNSRecord& authority : authorities) {
409 buffer_cur = authority.write(buffer_cur, buffer_end);
410 if (buffer_cur == nullptr) return nullptr;
411 }
412 for (const DNSRecord& additional : additionals) {
413 buffer_cur = additional.write(buffer_cur, buffer_end);
414 if (buffer_cur == nullptr) return nullptr;
415 }
416 return buffer_cur;
417 }
418
419 // TODO: convert all callers to this interface, then delete the old one.
write(std::vector<uint8_t> * out) const420 bool DNSHeader::write(std::vector<uint8_t>* out) const {
421 char buffer[4096];
422 char* end = this->write(buffer, buffer + sizeof buffer);
423 if (end == nullptr) return false;
424 out->insert(out->end(), buffer, end);
425 return true;
426 }
427
toString() const428 std::string DNSHeader::toString() const {
429 // TODO
430 return std::string();
431 }
432
readHeader(const char * buffer,const char * buffer_end,unsigned * qdcount,unsigned * ancount,unsigned * nscount,unsigned * arcount)433 const char* DNSHeader::readHeader(const char* buffer, const char* buffer_end, unsigned* qdcount,
434 unsigned* ancount, unsigned* nscount, unsigned* arcount) {
435 if (buffer + sizeof(Header) > buffer_end) return nullptr;
436 const auto& header = *reinterpret_cast<const Header*>(buffer);
437 // bytes 0-1
438 id = ntohs(header.id);
439 // byte 2: 7:qr, 3-6:opcode, 2:aa, 1:tr, 0:rd
440 qr = header.flags0 >> 7;
441 opcode = (header.flags0 >> 3) & 0x0F;
442 aa = (header.flags0 >> 2) & 1;
443 tr = (header.flags0 >> 1) & 1;
444 rd = header.flags0 & 1;
445 // byte 3: 7:ra, 6:zero, 5:ad, 4:cd, 0-3:rcode
446 ra = header.flags1 >> 7;
447 ad = (header.flags1 >> 5) & 1;
448 rcode = header.flags1 & 0xF;
449 // rest of header
450 *qdcount = ntohs(header.qdcount);
451 *ancount = ntohs(header.ancount);
452 *nscount = ntohs(header.nscount);
453 *arcount = ntohs(header.arcount);
454 return buffer + sizeof(Header);
455 }
456
457 /* DNS responder */
458
DNSResponder(std::string listen_address,std::string listen_service,ns_rcode error_rcode,MappingType mapping_type)459 DNSResponder::DNSResponder(std::string listen_address, std::string listen_service,
460 ns_rcode error_rcode, MappingType mapping_type)
461 : listen_address_(std::move(listen_address)),
462 listen_service_(std::move(listen_service)),
463 error_rcode_(error_rcode),
464 mapping_type_(mapping_type) {}
465
~DNSResponder()466 DNSResponder::~DNSResponder() {
467 stopServer();
468 }
469
addMapping(const std::string & name,ns_type type,const std::string & addr)470 void DNSResponder::addMapping(const std::string& name, ns_type type, const std::string& addr) {
471 std::lock_guard lock(mappings_mutex_);
472 mappings_[{name, type}] = addr;
473 }
474
addMappingDnsHeader(const std::string & name,ns_type type,const DNSHeader & header)475 void DNSResponder::addMappingDnsHeader(const std::string& name, ns_type type,
476 const DNSHeader& header) {
477 std::lock_guard lock(mappings_mutex_);
478 dnsheader_mappings_[{name, type}] = header;
479 }
480
addMappingBinaryPacket(const std::vector<uint8_t> & query,const std::vector<uint8_t> & response)481 void DNSResponder::addMappingBinaryPacket(const std::vector<uint8_t>& query,
482 const std::vector<uint8_t>& response) {
483 std::lock_guard lock(mappings_mutex_);
484 packet_mappings_[query] = response;
485 }
486
removeMapping(const std::string & name,ns_type type)487 void DNSResponder::removeMapping(const std::string& name, ns_type type) {
488 std::lock_guard lock(mappings_mutex_);
489 if (!mappings_.erase({name, type})) {
490 LOG(ERROR) << "Cannot remove mapping from (" << name << ", " << dnstype2str(type)
491 << "), not present in registered mappings";
492 }
493 }
494
removeMappingDnsHeader(const std::string & name,ns_type type)495 void DNSResponder::removeMappingDnsHeader(const std::string& name, ns_type type) {
496 std::lock_guard lock(mappings_mutex_);
497 if (!dnsheader_mappings_.erase({name, type})) {
498 LOG(ERROR) << "Cannot remove mapping from (" << name << ", " << dnstype2str(type)
499 << "), not present in registered DnsHeader mappings";
500 }
501 }
502
removeMappingBinaryPacket(const std::vector<uint8_t> & query)503 void DNSResponder::removeMappingBinaryPacket(const std::vector<uint8_t>& query) {
504 std::lock_guard lock(mappings_mutex_);
505 if (!packet_mappings_.erase(query)) {
506 LOG(ERROR) << "Cannot remove mapping, not present in registered BinaryPacket mappings";
507 LOG(INFO) << "Hex dump:";
508 LOG(INFO) << android::netdutils::toHex(
509 Slice(const_cast<uint8_t*>(query.data()), query.size()), 32);
510 }
511 }
512
513 // Set response probability on all supported protocols.
setResponseProbability(double response_probability)514 void DNSResponder::setResponseProbability(double response_probability) {
515 setResponseProbability(response_probability, IPPROTO_TCP);
516 setResponseProbability(response_probability, IPPROTO_UDP);
517 }
518
setResponseDelayMs(unsigned timeMs)519 void DNSResponder::setResponseDelayMs(unsigned timeMs) {
520 response_delayed_ms_ = timeMs;
521 }
522
523 // Set response probability on specific protocol. It's caller's duty to ensure that the |protocol|
524 // can be supported by DNSResponder.
setResponseProbability(double response_probability,int protocol)525 void DNSResponder::setResponseProbability(double response_probability, int protocol) {
526 switch (protocol) {
527 case IPPROTO_TCP:
528 response_probability_tcp_ = response_probability;
529 break;
530 case IPPROTO_UDP:
531 response_probability_udp_ = response_probability;
532 break;
533 default:
534 LOG(FATAL) << "Unsupported protocol " << protocol; // abort() by log level FATAL
535 }
536 }
537
getResponseProbability(int protocol) const538 double DNSResponder::getResponseProbability(int protocol) const {
539 switch (protocol) {
540 case IPPROTO_TCP:
541 return response_probability_tcp_;
542 case IPPROTO_UDP:
543 return response_probability_udp_;
544 default:
545 LOG(FATAL) << "Unsupported protocol " << protocol; // abort() by log level FATAL
546 // unreachable
547 return -1;
548 }
549 }
550
setEdns(Edns edns)551 void DNSResponder::setEdns(Edns edns) {
552 edns_ = edns;
553 }
554
setTtl(unsigned ttl)555 void DNSResponder::setTtl(unsigned ttl) {
556 answer_record_ttl_sec_ = ttl;
557 }
558
running() const559 bool DNSResponder::running() const {
560 return (udp_socket_.ok()) && (tcp_socket_.ok());
561 }
562
startServer()563 bool DNSResponder::startServer() {
564 if (running()) {
565 LOG(ERROR) << "server already running";
566 return false;
567 }
568
569 // Create UDP, TCP socket
570 if (udp_socket_ = createListeningSocket(SOCK_DGRAM); udp_socket_.get() < 0) {
571 PLOG(ERROR) << "failed to create UDP socket";
572 return false;
573 }
574
575 if (tcp_socket_ = createListeningSocket(SOCK_STREAM); tcp_socket_.get() < 0) {
576 PLOG(ERROR) << "failed to create TCP socket";
577 return false;
578 }
579
580 if (listen(tcp_socket_.get(), 1) < 0) {
581 PLOG(ERROR) << "failed to listen TCP socket";
582 return false;
583 }
584
585 // Set up eventfd socket.
586 event_fd_.reset(eventfd(0, EFD_NONBLOCK | EFD_CLOEXEC));
587 if (event_fd_.get() == -1) {
588 PLOG(ERROR) << "failed to create eventfd";
589 return false;
590 }
591
592 // Set up epoll socket.
593 epoll_fd_.reset(epoll_create1(EPOLL_CLOEXEC));
594 if (epoll_fd_.get() < 0) {
595 PLOG(ERROR) << "epoll_create1() failed on fd";
596 return false;
597 }
598
599 LOG(INFO) << "adding UDP socket to epoll";
600 if (!addFd(udp_socket_.get(), EPOLLIN)) {
601 LOG(ERROR) << "failed to add the UDP socket to epoll";
602 return false;
603 }
604
605 LOG(INFO) << "adding TCP socket to epoll";
606 if (!addFd(tcp_socket_.get(), EPOLLIN)) {
607 LOG(ERROR) << "failed to add the TCP socket to epoll";
608 return false;
609 }
610
611 LOG(INFO) << "adding eventfd to epoll";
612 if (!addFd(event_fd_.get(), EPOLLIN)) {
613 LOG(ERROR) << "failed to add the eventfd to epoll";
614 return false;
615 }
616
617 {
618 std::lock_guard lock(update_mutex_);
619 handler_thread_ = std::thread(&DNSResponder::requestHandler, this);
620 }
621 LOG(INFO) << "server started successfully";
622 return true;
623 }
624
stopServer()625 bool DNSResponder::stopServer() {
626 std::lock_guard lock(update_mutex_);
627 if (!running()) {
628 LOG(ERROR) << "server not running";
629 return false;
630 }
631 LOG(INFO) << "stopping server";
632 if (!sendToEventFd()) {
633 return false;
634 }
635 handler_thread_.join();
636 epoll_fd_.reset();
637 event_fd_.reset();
638 udp_socket_.reset();
639 tcp_socket_.reset();
640 LOG(INFO) << "server stopped successfully";
641 return true;
642 }
643
queries() const644 std::vector<DNSResponder::QueryInfo> DNSResponder::queries() const {
645 std::lock_guard lock(queries_mutex_);
646 return queries_;
647 }
648
dumpQueries() const649 std::string DNSResponder::dumpQueries() const {
650 std::lock_guard lock(queries_mutex_);
651 std::string out;
652
653 for (const auto& q : queries_) {
654 out += "{\"" + q.name + "\", " + std::to_string(q.type) + "\", " +
655 dnsproto2str(q.protocol) + "} ";
656 }
657 return out;
658 }
659
clearQueries()660 void DNSResponder::clearQueries() {
661 std::lock_guard lock(queries_mutex_);
662 queries_.clear();
663 }
664
hasOptPseudoRR(DNSHeader * header) const665 bool DNSResponder::hasOptPseudoRR(DNSHeader* header) const {
666 if (header->additionals.empty()) return false;
667
668 // OPT RR may be placed anywhere within the additional section. See RFC 6891 section 6.1.1.
669 auto found = std::find_if(header->additionals.begin(), header->additionals.end(),
670 [](const auto& a) { return a.rtype == ns_type::ns_t_opt; });
671 return found != header->additionals.end();
672 }
673
requestHandler()674 void DNSResponder::requestHandler() {
675 epoll_event evs[EPOLL_MAX_EVENTS];
676 while (true) {
677 int n = epoll_wait(epoll_fd_.get(), evs, EPOLL_MAX_EVENTS, -1);
678 if (n <= 0) {
679 PLOG(ERROR) << "epoll_wait() failed, n=" << n;
680 return;
681 }
682
683 for (int i = 0; i < n; i++) {
684 const int fd = evs[i].data.fd;
685 const uint32_t events = evs[i].events;
686 if (fd == event_fd_.get() && (events & (EPOLLIN | EPOLLERR))) {
687 handleEventFd();
688 return;
689 } else if (fd == udp_socket_.get() && (events & (EPOLLIN | EPOLLERR))) {
690 handleQuery(IPPROTO_UDP);
691 } else if (fd == tcp_socket_.get() && (events & (EPOLLIN | EPOLLERR))) {
692 handleQuery(IPPROTO_TCP);
693 } else {
694 LOG(WARNING) << "unexpected epoll events " << events << " on fd " << fd;
695 }
696 }
697 }
698 }
699
handleDNSRequest(const char * buffer,ssize_t len,int protocol,char * response,size_t * response_len) const700 bool DNSResponder::handleDNSRequest(const char* buffer, ssize_t len, int protocol, char* response,
701 size_t* response_len) const {
702 LOG(DEBUG) << "request: '" << str2hex(buffer, len) << "', on " << dnsproto2str(protocol);
703 const char* buffer_end = buffer + len;
704 DNSHeader header;
705 const char* cur = header.read(buffer, buffer_end);
706 // TODO(imaipi): for now, unparsable messages are silently dropped, fix.
707 if (cur == nullptr) {
708 LOG(ERROR) << "failed to parse query";
709 return false;
710 }
711 if (header.qr) {
712 LOG(ERROR) << "response received instead of a query";
713 return false;
714 }
715 if (header.opcode != ns_opcode::ns_o_query) {
716 LOG(INFO) << "unsupported request opcode received";
717 return makeErrorResponse(&header, ns_rcode::ns_r_notimpl, response, response_len);
718 }
719 if (header.questions.empty()) {
720 LOG(INFO) << "no questions present";
721 return makeErrorResponse(&header, ns_rcode::ns_r_formerr, response, response_len);
722 }
723 if (!header.answers.empty()) {
724 LOG(INFO) << "already " << header.answers.size() << " answers present in query";
725 return makeErrorResponse(&header, ns_rcode::ns_r_formerr, response, response_len);
726 }
727
728 if (edns_ == Edns::FORMERR_UNCOND) {
729 LOG(INFO) << "force to return RCODE FORMERR";
730 return makeErrorResponse(&header, ns_rcode::ns_r_formerr, response, response_len);
731 }
732
733 if (!header.additionals.empty() && edns_ != Edns::ON) {
734 LOG(INFO) << "DNS request has an additional section (assumed EDNS). Simulating an ancient "
735 "(pre-EDNS) server, and returning "
736 << (edns_ == Edns::FORMERR_ON_EDNS ? "RCODE FORMERR." : "no response.");
737 if (edns_ == Edns::FORMERR_ON_EDNS) {
738 return makeErrorResponse(&header, ns_rcode::ns_r_formerr, response, response_len);
739 }
740 // No response.
741 return false;
742 }
743 {
744 std::lock_guard lock(queries_mutex_);
745 for (const DNSQuestion& question : header.questions) {
746 queries_.push_back({question.qname.name, ns_type(question.qtype), protocol});
747 }
748 }
749 // Ignore requests with the preset probability.
750 auto constexpr bound = std::numeric_limits<unsigned>::max();
751 if (arc4random_uniform(bound) > bound * getResponseProbability(protocol)) {
752 if (error_rcode_ < 0) {
753 LOG(ERROR) << "Returning no response";
754 return false;
755 } else {
756 LOG(INFO) << "returning RCODE " << static_cast<int>(error_rcode_)
757 << " in accordance with probability distribution";
758 return makeErrorResponse(&header, error_rcode_, response, response_len);
759 }
760 }
761
762 // Make the response. The query has been read into |header| which is used to build and return
763 // the response as well.
764 return makeResponse(&header, protocol, response, response_len);
765 }
766
addAnswerRecords(const DNSQuestion & question,std::vector<DNSRecord> * answers) const767 bool DNSResponder::addAnswerRecords(const DNSQuestion& question,
768 std::vector<DNSRecord>* answers) const {
769 std::lock_guard guard(mappings_mutex_);
770 std::string rname = question.qname.name;
771 std::vector<int> rtypes;
772
773 if (question.qtype == ns_type::ns_t_a || question.qtype == ns_type::ns_t_aaaa ||
774 question.qtype == ns_type::ns_t_ptr)
775 rtypes.push_back(ns_type::ns_t_cname);
776 rtypes.push_back(question.qtype);
777 for (int rtype : rtypes) {
778 std::set<std::string> cnames_Loop;
779 std::unordered_map<QueryKey, std::string, QueryKeyHash>::const_iterator it;
780 while ((it = mappings_.find(QueryKey(rname, rtype))) != mappings_.end()) {
781 if (rtype == ns_type::ns_t_cname) {
782 // When detect CNAME infinite loops by cnames_Loop, it won't save the duplicate one.
783 // As following, the query will stop on loop3 by detecting the same cname.
784 // loop1.{"a.xxx.com", ns_type::ns_t_cname, "b.xxx.com"}(insert in answer record)
785 // loop2.{"b.xxx.com", ns_type::ns_t_cname, "a.xxx.com"}(insert in answer record)
786 // loop3.{"a.xxx.com", ns_type::ns_t_cname, "b.xxx.com"}(When the same cname record
787 // is found in cnames_Loop already, break the query loop.)
788 if (cnames_Loop.find(it->first.name) != cnames_Loop.end()) break;
789 cnames_Loop.insert(it->first.name);
790 }
791 DNSRecord record{
792 .name = {.name = it->first.name},
793 .rtype = it->first.type,
794 .rclass = ns_class::ns_c_in,
795 .ttl = answer_record_ttl_sec_, // seconds
796 };
797 if (!fillRdata(it->second, record)) return false;
798 answers->push_back(std::move(record));
799 if (rtype != ns_type::ns_t_cname) break;
800 rname = it->second;
801 }
802 }
803
804 if (answers->size() == 0) {
805 // TODO(imaipi): handle correctly
806 LOG(INFO) << "no mapping found for " << question.qname.name << " "
807 << dnstype2str(question.qtype) << ", lazily refusing to add an answer";
808 }
809
810 return true;
811 }
812
fillRdata(const std::string & rdatastr,DNSRecord & record)813 bool DNSResponder::fillRdata(const std::string& rdatastr, DNSRecord& record) {
814 if (record.rtype == ns_type::ns_t_a) {
815 record.rdata.resize(4);
816 if (inet_pton(AF_INET, rdatastr.c_str(), record.rdata.data()) != 1) {
817 LOG(ERROR) << "inet_pton(AF_INET, " << rdatastr << ") failed";
818 return false;
819 }
820 } else if (record.rtype == ns_type::ns_t_aaaa) {
821 record.rdata.resize(16);
822 if (inet_pton(AF_INET6, rdatastr.c_str(), record.rdata.data()) != 1) {
823 LOG(ERROR) << "inet_pton(AF_INET6, " << rdatastr << ") failed";
824 return false;
825 }
826 } else if ((record.rtype == ns_type::ns_t_ptr) || (record.rtype == ns_type::ns_t_cname) ||
827 (record.rtype == ns_type::ns_t_ns)) {
828 constexpr char delimiter = '.';
829 std::string name = rdatastr;
830 std::vector<char> rdata;
831
832 // Generating PTRDNAME field(section 3.3.12) or CNAME field(section 3.3.1) in rfc1035.
833 // The "name" should be an absolute domain name which ends in a dot.
834 if (name.back() != delimiter) {
835 LOG(ERROR) << "invalid absolute domain name";
836 return false;
837 }
838 name.pop_back(); // remove the dot in tail
839 for (const std::string& label : android::base::Split(name, {delimiter})) {
840 // The length of label is limited to 63 octets or less. See RFC 1035 section 3.1.
841 if (label.length() == 0 || label.length() > 63) {
842 LOG(ERROR) << "invalid label length";
843 return false;
844 }
845
846 rdata.push_back(label.length());
847 rdata.insert(rdata.end(), label.begin(), label.end());
848 }
849 rdata.push_back(0); // Length byte of zero terminates the label list
850
851 // The length of domain name is limited to 255 octets or less. See RFC 1035 section 3.1.
852 if (rdata.size() > 255) {
853 LOG(ERROR) << "invalid name length";
854 return false;
855 }
856 record.rdata = move(rdata);
857 } else {
858 LOG(ERROR) << "unhandled qtype " << dnstype2str(record.rtype);
859 return false;
860 }
861 return true;
862 }
863
writePacket(const DNSHeader * header,char * response,size_t * response_len) const864 bool DNSResponder::writePacket(const DNSHeader* header, char* response,
865 size_t* response_len) const {
866 char* response_cur = header->write(response, response + *response_len);
867 if (response_cur == nullptr) {
868 return false;
869 }
870 *response_len = response_cur - response;
871 return true;
872 }
873
makeErrorResponse(DNSHeader * header,ns_rcode rcode,char * response,size_t * response_len) const874 bool DNSResponder::makeErrorResponse(DNSHeader* header, ns_rcode rcode, char* response,
875 size_t* response_len) const {
876 header->answers.clear();
877 header->authorities.clear();
878 header->additionals.clear();
879 header->rcode = rcode;
880 header->qr = true;
881 return writePacket(header, response, response_len);
882 }
883
makeTruncatedResponse(DNSHeader * header,char * response,size_t * response_len) const884 bool DNSResponder::makeTruncatedResponse(DNSHeader* header, char* response,
885 size_t* response_len) const {
886 // Build a minimal response for non-EDNS response over UDP. Truncate all stub RRs in answer,
887 // authority and additional section. EDNS response truncation has not supported here yet
888 // because the EDNS response must have an OPT record. See RFC 6891 section 7.
889 header->answers.clear();
890 header->authorities.clear();
891 header->additionals.clear();
892 header->qr = true;
893 header->tr = true;
894 return writePacket(header, response, response_len);
895 }
896
makeResponse(DNSHeader * header,int protocol,char * response,size_t * response_len) const897 bool DNSResponder::makeResponse(DNSHeader* header, int protocol, char* response,
898 size_t* response_len) const {
899 char buffer[4096];
900 size_t buffer_len = sizeof(buffer);
901 bool ret;
902
903 switch (mapping_type_) {
904 case MappingType::DNS_HEADER:
905 ret = makeResponseFromDnsHeader(header, buffer, &buffer_len);
906 break;
907 case MappingType::BINARY_PACKET:
908 ret = makeResponseFromBinaryPacket(header, buffer, &buffer_len);
909 break;
910 case MappingType::ADDRESS_OR_HOSTNAME:
911 default:
912 ret = makeResponseFromAddressOrHostname(header, buffer, &buffer_len);
913 }
914
915 if (!ret) return false;
916
917 // Return truncated response if the built non-EDNS response size which is larger than 512 bytes
918 // will be responded over UDP. The truncated response implementation here just simply set up
919 // the TC bit and truncate all stub RRs in answer, authority and additional section. It is
920 // because the resolver will retry DNS query over TCP and use the full TCP response. See also
921 // RFC 1035 section 4.2.1 for UDP response truncation and RFC 6891 section 4.3 for EDNS larger
922 // response size capability.
923 // TODO: Perhaps keep the stub RRs as possible.
924 // TODO: Perhaps truncate the EDNS based response over UDP. See also RFC 6891 section 4.3,
925 // section 6.2.5 and section 7.
926 if (protocol == IPPROTO_UDP && buffer_len > kMaximumUdpSize &&
927 !hasOptPseudoRR(header) /* non-EDNS */) {
928 LOG(INFO) << "Return truncated response because original response length " << buffer_len
929 << " is larger than " << kMaximumUdpSize << " bytes.";
930 return makeTruncatedResponse(header, response, response_len);
931 }
932
933 if (buffer_len > *response_len) {
934 LOG(ERROR) << "buffer overflow on line " << __LINE__;
935 return false;
936 }
937 memcpy(response, buffer, buffer_len);
938 *response_len = buffer_len;
939 return true;
940 }
941
makeResponseFromAddressOrHostname(DNSHeader * header,char * response,size_t * response_len) const942 bool DNSResponder::makeResponseFromAddressOrHostname(DNSHeader* header, char* response,
943 size_t* response_len) const {
944 for (const DNSQuestion& question : header->questions) {
945 if (question.qclass != ns_class::ns_c_in && question.qclass != ns_class::ns_c_any) {
946 LOG(INFO) << "unsupported question class " << question.qclass;
947 return makeErrorResponse(header, ns_rcode::ns_r_notimpl, response, response_len);
948 }
949
950 if (!addAnswerRecords(question, &header->answers)) {
951 return makeErrorResponse(header, ns_rcode::ns_r_servfail, response, response_len);
952 }
953 }
954 header->qr = true;
955 return writePacket(header, response, response_len);
956 }
957
makeResponseFromDnsHeader(DNSHeader * header,char * response,size_t * response_len) const958 bool DNSResponder::makeResponseFromDnsHeader(DNSHeader* header, char* response,
959 size_t* response_len) const {
960 std::lock_guard guard(mappings_mutex_);
961
962 // Support single question record only. It should be okay because res_mkquery() sets "qdcount"
963 // as one for the operation QUERY and handleDNSRequest() checks ns_opcode::ns_o_query before
964 // making a response. In other words, only need to handle the query which has single question
965 // section. See also res_mkquery() in system/netd/resolv/res_mkquery.cpp.
966 // TODO: Perhaps add support for multi-question records.
967 const std::vector<DNSQuestion>& questions = header->questions;
968 if (questions.size() != 1) {
969 LOG(INFO) << "unsupported question count " << questions.size();
970 return makeErrorResponse(header, ns_rcode::ns_r_notimpl, response, response_len);
971 }
972
973 if (questions[0].qclass != ns_class::ns_c_in && questions[0].qclass != ns_class::ns_c_any) {
974 LOG(INFO) << "unsupported question class " << questions[0].qclass;
975 return makeErrorResponse(header, ns_rcode::ns_r_notimpl, response, response_len);
976 }
977
978 const std::string name = questions[0].qname.name;
979 const int qtype = questions[0].qtype;
980 const auto it = dnsheader_mappings_.find(QueryKey(name, qtype));
981 if (it != dnsheader_mappings_.end()) {
982 // Store both "id" and "rd" which comes from query.
983 const unsigned id = header->id;
984 const bool rd = header->rd;
985
986 // Build a response from the registered DNSHeader mapping.
987 *header = it->second;
988 // Assign both "ID" and "RD" fields from query to response. See RFC 1035 section 4.1.1.
989 header->id = id;
990 header->rd = rd;
991 } else {
992 // TODO: handle correctly. See also TODO in addAnswerRecords().
993 LOG(INFO) << "no mapping found for " << name << " " << dnstype2str(qtype)
994 << ", couldn't build a response from DNSHeader mapping";
995
996 // Note that do nothing as makeResponseFromAddressOrHostname() if no mapping is found. It
997 // just changes the QR flag from query (0) to response (1) in the query. Then, send the
998 // modified query back as a response.
999 header->qr = true;
1000 }
1001 return writePacket(header, response, response_len);
1002 }
1003
makeResponseFromBinaryPacket(DNSHeader * header,char * response,size_t * response_len) const1004 bool DNSResponder::makeResponseFromBinaryPacket(DNSHeader* header, char* response,
1005 size_t* response_len) const {
1006 std::lock_guard guard(mappings_mutex_);
1007
1008 // Build a search key of mapping from the query.
1009 // TODO: Perhaps pass the query packet buffer directly from the caller.
1010 std::vector<uint8_t> queryKey;
1011 if (!header->write(&queryKey)) return false;
1012 // Clear ID field (byte 0-1) because it is not required by the mapping key.
1013 queryKey[0] = 0;
1014 queryKey[1] = 0;
1015
1016 const auto it = packet_mappings_.find(queryKey);
1017 if (it != packet_mappings_.end()) {
1018 if (it->second.size() > *response_len) {
1019 LOG(ERROR) << "buffer overflow on line " << __LINE__;
1020 return false;
1021 } else {
1022 std::copy(it->second.begin(), it->second.end(), response);
1023 // Leave the "RD" flag assignment for testing. The "RD" flag of the response keep
1024 // using the one from the raw packet mapping but the received query.
1025 // Assign "ID" field from query to response. See RFC 1035 section 4.1.1.
1026 reinterpret_cast<uint16_t*>(response)[0] = htons(header->id); // bytes 0-1: id
1027 *response_len = it->second.size();
1028 return true;
1029 }
1030 } else {
1031 // TODO: handle correctly. See also TODO in addAnswerRecords().
1032 // TODO: Perhaps dump packet content to indicate which query failed.
1033 LOG(INFO) << "no mapping found, couldn't build a response from BinaryPacket mapping";
1034 // Note that do nothing as makeResponseFromAddressOrHostname() if no mapping is found. It
1035 // just changes the QR flag from query (0) to response (1) in the query. Then, send the
1036 // modified query back as a response.
1037 header->qr = true;
1038 return writePacket(header, response, response_len);
1039 }
1040 }
1041
setDeferredResp(bool deferred_resp)1042 void DNSResponder::setDeferredResp(bool deferred_resp) {
1043 std::lock_guard<std::mutex> guard(cv_mutex_for_deferred_resp_);
1044 deferred_resp_ = deferred_resp;
1045 if (!deferred_resp_) {
1046 cv_for_deferred_resp_.notify_one();
1047 }
1048 }
1049
addFd(int fd,uint32_t events)1050 bool DNSResponder::addFd(int fd, uint32_t events) {
1051 epoll_event ev;
1052 ev.events = events;
1053 ev.data.fd = fd;
1054 if (epoll_ctl(epoll_fd_.get(), EPOLL_CTL_ADD, fd, &ev) < 0) {
1055 PLOG(ERROR) << "epoll_ctl() for socket " << fd << " failed";
1056 return false;
1057 }
1058 return true;
1059 }
1060
handleQuery(int protocol)1061 void DNSResponder::handleQuery(int protocol) {
1062 char buffer[4096];
1063 sockaddr_storage sa;
1064 socklen_t sa_len = sizeof(sa);
1065 ssize_t len = 0;
1066 android::base::unique_fd tcpFd;
1067 switch (protocol) {
1068 case IPPROTO_UDP:
1069 do {
1070 len = recvfrom(udp_socket_.get(), buffer, sizeof(buffer), 0, (sockaddr*)&sa,
1071 &sa_len);
1072 } while (len < 0 && (errno == EAGAIN || errno == EINTR));
1073 if (len <= 0) {
1074 PLOG(ERROR) << "recvfrom() failed, len=" << len;
1075 return;
1076 }
1077 break;
1078 case IPPROTO_TCP:
1079 tcpFd.reset(accept4(tcp_socket_.get(), reinterpret_cast<sockaddr*>(&sa), &sa_len,
1080 SOCK_CLOEXEC));
1081 if (tcpFd.get() < 0) {
1082 PLOG(ERROR) << "failed to accept client socket";
1083 return;
1084 }
1085 // Get the message length from two byte length field.
1086 // See also RFC 1035, section 4.2.2 and RFC 7766, section 8
1087 uint8_t queryMessageLengthField[2];
1088 if (read(tcpFd.get(), &queryMessageLengthField, 2) != 2) {
1089 PLOG(ERROR) << "Not enough length field bytes";
1090 return;
1091 }
1092
1093 const uint16_t qlen = (queryMessageLengthField[0] << 8) | queryMessageLengthField[1];
1094 while (len < qlen) {
1095 ssize_t ret = read(tcpFd.get(), buffer + len, qlen - len);
1096 if (ret <= 0) {
1097 PLOG(ERROR) << "Error while reading query";
1098 return;
1099 }
1100 len += ret;
1101 }
1102 break;
1103 }
1104 LOG(DEBUG) << "read " << len << " bytes on " << dnsproto2str(protocol);
1105 std::lock_guard lock(cv_mutex_);
1106 char response[4096];
1107 size_t response_len = sizeof(response);
1108 // TODO: check whether sending malformed packets to DnsResponder
1109 if (handleDNSRequest(buffer, len, protocol, response, &response_len) && response_len > 0) {
1110 std::this_thread::sleep_for(std::chrono::milliseconds(response_delayed_ms_));
1111 // place wait_for after handleDNSRequest() so we can check the number of queries in
1112 // test case before it got responded.
1113 std::unique_lock guard(cv_mutex_for_deferred_resp_);
1114 cv_for_deferred_resp_.wait(
1115 guard, [this]() REQUIRES(cv_mutex_for_deferred_resp_) { return !deferred_resp_; });
1116 len = 0;
1117
1118 switch (protocol) {
1119 case IPPROTO_UDP:
1120 len = sendto(udp_socket_.get(), response, response_len, 0,
1121 reinterpret_cast<const sockaddr*>(&sa), sa_len);
1122 if (len < 0) {
1123 PLOG(ERROR) << "Failed to send response";
1124 }
1125 break;
1126 case IPPROTO_TCP:
1127 // Get the message length from two byte length field.
1128 // See also RFC 1035, section 4.2.2 and RFC 7766, section 8
1129 uint8_t responseMessageLengthField[2];
1130 responseMessageLengthField[0] = response_len >> 8;
1131 responseMessageLengthField[1] = response_len;
1132 if (write(tcpFd.get(), responseMessageLengthField, 2) != 2) {
1133 PLOG(ERROR) << "Failed to write response length field";
1134 break;
1135 }
1136 if (write(tcpFd.get(), response, response_len) !=
1137 static_cast<ssize_t>(response_len)) {
1138 PLOG(ERROR) << "Failed to write response";
1139 break;
1140 }
1141 len = response_len;
1142 break;
1143 }
1144 const std::string host_str = addr2str(reinterpret_cast<const sockaddr*>(&sa), sa_len);
1145 if (len > 0) {
1146 LOG(DEBUG) << "sent " << len << " bytes to " << host_str;
1147 } else {
1148 const char* method_str = (protocol == IPPROTO_TCP) ? "write()" : "sendto()";
1149 LOG(ERROR) << method_str << " failed for " << host_str;
1150 }
1151 // Test that the response is actually a correct DNS message.
1152 // TODO: Perhaps make DNS message validation to support name compression. Or it throws
1153 // a warning for a valid DNS message with name compression while the binary packet mapping
1154 // is used.
1155 const char* response_end = response + len;
1156 DNSHeader header;
1157 const char* cur = header.read(response, response_end);
1158 if (cur == nullptr) LOG(WARNING) << "response is flawed";
1159 } else {
1160 LOG(WARNING) << "not responding";
1161 }
1162 cv.notify_one();
1163 return;
1164 }
1165
sendToEventFd()1166 bool DNSResponder::sendToEventFd() {
1167 const uint64_t data = 1;
1168 if (const ssize_t rt = write(event_fd_.get(), &data, sizeof(data)); rt != sizeof(data)) {
1169 PLOG(ERROR) << "failed to write eventfd, rt=" << rt;
1170 return false;
1171 }
1172 return true;
1173 }
1174
handleEventFd()1175 void DNSResponder::handleEventFd() {
1176 int64_t data;
1177 if (const ssize_t rt = read(event_fd_.get(), &data, sizeof(data)); rt != sizeof(data)) {
1178 PLOG(INFO) << "ignore reading eventfd failed, rt=" << rt;
1179 }
1180 }
1181
createListeningSocket(int socket_type)1182 android::base::unique_fd DNSResponder::createListeningSocket(int socket_type) {
1183 addrinfo ai_hints{
1184 .ai_flags = AI_PASSIVE,
1185 .ai_family = AF_UNSPEC,
1186 .ai_socktype = socket_type,
1187 };
1188 addrinfo* ai_res = nullptr;
1189 const int rv =
1190 getaddrinfo(listen_address_.c_str(), listen_service_.c_str(), &ai_hints, &ai_res);
1191 ScopedAddrinfo ai_res_cleanup(ai_res);
1192 if (rv) {
1193 LOG(ERROR) << "getaddrinfo(" << listen_address_ << ", " << listen_service_
1194 << ") failed: " << gai_strerror(rv);
1195 return {};
1196 }
1197 for (const addrinfo* ai = ai_res; ai; ai = ai->ai_next) {
1198 android::base::unique_fd fd(
1199 socket(ai->ai_family, ai->ai_socktype | SOCK_NONBLOCK, ai->ai_protocol));
1200 if (fd.get() < 0) {
1201 PLOG(ERROR) << "ignore creating socket failed";
1202 continue;
1203 }
1204 enableSockopt(fd.get(), SOL_SOCKET, SO_REUSEPORT).ignoreError();
1205 enableSockopt(fd.get(), SOL_SOCKET, SO_REUSEADDR).ignoreError();
1206 const std::string host_str = addr2str(ai->ai_addr, ai->ai_addrlen);
1207 const char* socket_str = (socket_type == SOCK_STREAM) ? "TCP" : "UDP";
1208
1209 if (bind(fd.get(), ai->ai_addr, ai->ai_addrlen)) {
1210 PLOG(ERROR) << "failed to bind " << socket_str << " " << host_str << ":"
1211 << listen_service_;
1212 continue;
1213 }
1214 LOG(INFO) << "bound to " << socket_str << " " << host_str << ":" << listen_service_;
1215 return fd;
1216 }
1217 return {};
1218 }
1219
1220 } // namespace test
1221