// Copyright (c) 2012 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include "net/dns/dns_response.h" #include #include "base/big_endian.h" #include "base/strings/string_util.h" #include "base/sys_byteorder.h" #include "net/base/address_list.h" #include "net/base/io_buffer.h" #include "net/base/ip_address.h" #include "net/base/net_errors.h" #include "net/dns/dns_protocol.h" #include "net/dns/dns_query.h" #include "net/dns/dns_util.h" namespace net { namespace { const size_t kHeaderSize = sizeof(dns_protocol::Header); const uint8_t kRcodeMask = 0xf; } // namespace DnsResourceRecord::DnsResourceRecord() = default; DnsResourceRecord::~DnsResourceRecord() = default; DnsRecordParser::DnsRecordParser() : packet_(NULL), length_(0), cur_(0) { } DnsRecordParser::DnsRecordParser(const void* packet, size_t length, size_t offset) : packet_(reinterpret_cast(packet)), length_(length), cur_(packet_ + offset) { DCHECK_LE(offset, length); } unsigned DnsRecordParser::ReadName(const void* const vpos, std::string* out) const { const char* const pos = reinterpret_cast(vpos); DCHECK(packet_); DCHECK_LE(packet_, pos); DCHECK_LE(pos, packet_ + length_); const char* p = pos; const char* end = packet_ + length_; // Count number of seen bytes to detect loops. unsigned seen = 0; // Remember how many bytes were consumed before first jump. unsigned consumed = 0; if (pos >= end) return 0; if (out) { out->clear(); out->reserve(dns_protocol::kMaxNameLength); } for (;;) { // The first two bits of the length give the type of the length. It's // either a direct length or a pointer to the remainder of the name. switch (*p & dns_protocol::kLabelMask) { case dns_protocol::kLabelPointer: { if (p + sizeof(uint16_t) > end) return 0; if (consumed == 0) { consumed = p - pos + sizeof(uint16_t); if (!out) return consumed; // If name is not stored, that's all we need. } seen += sizeof(uint16_t); // If seen the whole packet, then we must be in a loop. if (seen > length_) return 0; uint16_t offset; base::ReadBigEndian(p, &offset); offset &= dns_protocol::kOffsetMask; p = packet_ + offset; if (p >= end) return 0; break; } case dns_protocol::kLabelDirect: { uint8_t label_len = *p; ++p; // Note: root domain (".") is NOT included. if (label_len == 0) { if (consumed == 0) { consumed = p - pos; } // else we set |consumed| before first jump return consumed; } if (p + label_len >= end) return 0; // Truncated or missing label. if (out) { if (!out->empty()) out->append("."); out->append(p, label_len); } p += label_len; seen += 1 + label_len; break; } default: // unhandled label type return 0; } } } bool DnsRecordParser::ReadRecord(DnsResourceRecord* out) { DCHECK(packet_); size_t consumed = ReadName(cur_, &out->name); if (!consumed) return false; base::BigEndianReader reader(cur_ + consumed, packet_ + length_ - (cur_ + consumed)); uint16_t rdlen; if (reader.ReadU16(&out->type) && reader.ReadU16(&out->klass) && reader.ReadU32(&out->ttl) && reader.ReadU16(&rdlen) && reader.ReadPiece(&out->rdata, rdlen)) { cur_ = reader.ptr(); return true; } return false; } bool DnsRecordParser::SkipQuestion() { size_t consumed = ReadName(cur_, NULL); if (!consumed) return false; const char* next = cur_ + consumed + 2 * sizeof(uint16_t); // QTYPE + QCLASS if (next > packet_ + length_) return false; cur_ = next; return true; } DnsResponse::DnsResponse() : io_buffer_(new IOBuffer(dns_protocol::kMaxUDPSize + 1)), io_buffer_size_(dns_protocol::kMaxUDPSize + 1) {} DnsResponse::DnsResponse(IOBuffer* buffer, size_t size) : io_buffer_(buffer), io_buffer_size_(size) {} DnsResponse::DnsResponse(size_t length) : io_buffer_(new IOBuffer(length)), io_buffer_size_(length) {} DnsResponse::DnsResponse(const void* data, size_t length, size_t answer_offset) : io_buffer_(new IOBufferWithSize(length)), io_buffer_size_(length), parser_(io_buffer_->data(), length, answer_offset) { DCHECK(data); memcpy(io_buffer_->data(), data, length); } DnsResponse::~DnsResponse() = default; bool DnsResponse::InitParse(size_t nbytes, const DnsQuery& query) { // Response includes query, it should be at least that size. if (nbytes < static_cast(query.io_buffer()->size()) || nbytes >= io_buffer_size_) { return false; } // Match the query id. if (base::NetToHost16(header()->id) != query.id()) return false; // Match question count. if (base::NetToHost16(header()->qdcount) != 1) return false; // Match the question section. const base::StringPiece question = query.question(); if (question != base::StringPiece(io_buffer_->data() + kHeaderSize, question.size())) { return false; } // Construct the parser. parser_ = DnsRecordParser(io_buffer_->data(), nbytes, kHeaderSize + question.size()); return true; } bool DnsResponse::InitParseWithoutQuery(size_t nbytes) { if (nbytes < kHeaderSize || nbytes >= io_buffer_size_) { return false; } parser_ = DnsRecordParser(io_buffer_->data(), nbytes, kHeaderSize); unsigned qdcount = base::NetToHost16(header()->qdcount); for (unsigned i = 0; i < qdcount; ++i) { if (!parser_.SkipQuestion()) { parser_ = DnsRecordParser(); // Make parser invalid again. return false; } } return true; } bool DnsResponse::IsValid() const { return parser_.IsValid(); } uint16_t DnsResponse::flags() const { DCHECK(parser_.IsValid()); return base::NetToHost16(header()->flags) & ~(kRcodeMask); } uint8_t DnsResponse::rcode() const { DCHECK(parser_.IsValid()); return base::NetToHost16(header()->flags) & kRcodeMask; } unsigned DnsResponse::answer_count() const { DCHECK(parser_.IsValid()); return base::NetToHost16(header()->ancount); } unsigned DnsResponse::additional_answer_count() const { DCHECK(parser_.IsValid()); return base::NetToHost16(header()->arcount); } base::StringPiece DnsResponse::qname() const { DCHECK(parser_.IsValid()); // The response is HEADER QNAME QTYPE QCLASS ANSWER. // |parser_| is positioned at the beginning of ANSWER, so the end of QNAME is // two uint16_ts before it. const size_t qname_size = parser_.GetOffset() - 2 * sizeof(uint16_t) - kHeaderSize; return base::StringPiece(io_buffer_->data() + kHeaderSize, qname_size); } uint16_t DnsResponse::qtype() const { DCHECK(parser_.IsValid()); // QTYPE starts where QNAME ends. const size_t type_offset = parser_.GetOffset() - 2 * sizeof(uint16_t); uint16_t type; base::ReadBigEndian(io_buffer_->data() + type_offset, &type); return type; } std::string DnsResponse::GetDottedName() const { return DNSDomainToString(qname()); } DnsRecordParser DnsResponse::Parser() const { DCHECK(parser_.IsValid()); // Return a copy of the parser. return parser_; } const dns_protocol::Header* DnsResponse::header() const { return reinterpret_cast(io_buffer_->data()); } DnsResponse::Result DnsResponse::ParseToAddressList( AddressList* addr_list, base::TimeDelta* ttl) const { DCHECK(IsValid()); // DnsTransaction already verified that |response| matches the issued query. // We still need to determine if there is a valid chain of CNAMEs from the // query name to the RR owner name. // We err on the side of caution with the assumption that if we are too picky, // we can always fall back to the system getaddrinfo. // Expected owner of record. No trailing dot. std::string expected_name = GetDottedName(); uint16_t expected_type = qtype(); DCHECK(expected_type == dns_protocol::kTypeA || expected_type == dns_protocol::kTypeAAAA); size_t expected_size = (expected_type == dns_protocol::kTypeAAAA) ? IPAddress::kIPv6AddressSize : IPAddress::kIPv4AddressSize; uint32_t ttl_sec = std::numeric_limits::max(); IPAddressList ip_addresses; DnsRecordParser parser = Parser(); DnsResourceRecord record; unsigned ancount = answer_count(); for (unsigned i = 0; i < ancount; ++i) { if (!parser.ReadRecord(&record)) return DNS_MALFORMED_RESPONSE; if (record.type == dns_protocol::kTypeCNAME) { // Following the CNAME chain, only if no addresses seen. if (!ip_addresses.empty()) return DNS_CNAME_AFTER_ADDRESS; if (!base::EqualsCaseInsensitiveASCII(record.name, expected_name)) return DNS_NAME_MISMATCH; if (record.rdata.size() != parser.ReadName(record.rdata.begin(), &expected_name)) return DNS_MALFORMED_CNAME; ttl_sec = std::min(ttl_sec, record.ttl); } else if (record.type == expected_type) { if (record.rdata.size() != expected_size) return DNS_SIZE_MISMATCH; if (!base::EqualsCaseInsensitiveASCII(record.name, expected_name)) return DNS_NAME_MISMATCH; ttl_sec = std::min(ttl_sec, record.ttl); ip_addresses.push_back( IPAddress(reinterpret_cast(record.rdata.data()), record.rdata.length())); } } // NXDOMAIN or NODATA cases respectively. if (rcode() == dns_protocol::kRcodeNXDOMAIN || (ancount == 0 && rcode() == dns_protocol::kRcodeNOERROR)) { unsigned nscount = base::NetToHost16(header()->nscount); for (unsigned i = 0; i < nscount; ++i) { if (parser.ReadRecord(&record) && record.type == dns_protocol::kTypeSOA) ttl_sec = std::min(ttl_sec, record.ttl); } } // getcanonname in eglibc returns the first owner name of an A or AAAA RR. // If the response passed all the checks so far, then |expected_name| is it. *addr_list = AddressList::CreateFromIPAddressList(ip_addresses, expected_name); *ttl = base::TimeDelta::FromSeconds(ttl_sec); return DNS_PARSE_OK; } } // namespace net