net/dns/dns_query.cc - chromium/src.git - Git at Google

 // 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_query.h"

 #include <utility>

 #include "base/big_endian.h"
 #include "base/logging.h"
 #include "base/memory/ptr_util.h"
 #include "base/numerics/safe_conversions.h"
 #include "base/optional.h"
 #include "base/sys_byteorder.h"
 #include "net/base/io_buffer.h"
 #include "net/dns/dns_util.h"
 #include "net/dns/public/dns_protocol.h"
 #include "net/dns/record_rdata.h"

 namespace net {

 namespace {

 const size_t kHeaderSize = sizeof(dns_protocol::Header);

 // Size of the fixed part of an OPT RR:
 // https://tools.ietf.org/html/rfc6891#section-6.1.2
 static const size_t kOptRRFixedSize = 11;

 // https://tools.ietf.org/html/rfc6891#section-6.2.5
 // TODO(robpercival): Determine a good value for this programmatically.
 const uint16_t kMaxUdpPayloadSize = 4096;

 size_t QuestionSize(size_t qname_size) {
   // QNAME + QTYPE + QCLASS
   return qname_size + sizeof(uint16_t) + sizeof(uint16_t);
 }

 // Buffer size of Opt record for |rdata| (does not include Opt record or RData
 // added for padding).
 size_t OptRecordSize(const OptRecordRdata* rdata) {
   return rdata == nullptr ? 0 : kOptRRFixedSize + rdata->buf().size();
 }

 // Padding size includes Opt header for the padding.  Does not include OptRecord
 // header (kOptRRFixedSize) even when added just for padding.
 size_t DeterminePaddingSize(size_t unpadded_size,
                             DnsQuery::PaddingStrategy padding_strategy) {
   switch (padding_strategy) {
     case DnsQuery::PaddingStrategy::NONE:
       return 0;
     case DnsQuery::PaddingStrategy::BLOCK_LENGTH_128:
       size_t padding_size = OptRecordRdata::Opt::kHeaderSize;
       size_t remainder = (padding_size + unpadded_size) % 128;
       padding_size += (128 - remainder) % 128;
       DCHECK_EQ((unpadded_size + padding_size) % 128, 0u);
       return padding_size;
   }
 }

 base::Optional<OptRecordRdata> AddPaddingIfNecessary(
     const OptRecordRdata* opt_rdata,
     DnsQuery::PaddingStrategy padding_strategy,
     size_t no_opt_buffer_size) {
   // If no input OPT record rdata and no padding, no OPT record rdata needed.
   if (!opt_rdata && padding_strategy == DnsQuery::PaddingStrategy::NONE)
     return base::nullopt;

   OptRecordRdata merged_opt_rdata;
   if (opt_rdata)
     merged_opt_rdata.AddOpts(*opt_rdata);

   size_t unpadded_size = no_opt_buffer_size + OptRecordSize(&merged_opt_rdata);
   size_t padding_size = DeterminePaddingSize(unpadded_size, padding_strategy);

   if (padding_size > 0) {
     // |opt_rdata| must not already contain padding if DnsQuery is to add
     // padding.
     DCHECK(!merged_opt_rdata.ContainsOptCode(dns_protocol::kEdnsPadding));
     // OPT header is the minimum amount of padding.
     DCHECK(padding_size >= OptRecordRdata::Opt::kHeaderSize);

     merged_opt_rdata.AddOpt(OptRecordRdata::Opt(
         dns_protocol::kEdnsPadding,
         std::string(padding_size - OptRecordRdata::Opt::kHeaderSize, 0)));
   }

   return merged_opt_rdata;
 }

 }  // namespace

 // DNS query consists of a 12-byte header followed by a question section.
 // For details, see RFC 1035 section 4.1.1.  This header template sets RD
 // bit, which directs the name server to pursue query recursively, and sets
 // the QDCOUNT to 1, meaning the question section has a single entry.
 DnsQuery::DnsQuery(uint16_t id,
                    const base::StringPiece& qname,
                    uint16_t qtype,
                    const OptRecordRdata* opt_rdata,
                    PaddingStrategy padding_strategy)
     : qname_size_(qname.size()) {
   DCHECK(!DNSDomainToString(qname).empty());

   size_t buffer_size = kHeaderSize + QuestionSize(qname_size_);
   base::Optional<OptRecordRdata> merged_opt_rdata =
       AddPaddingIfNecessary(opt_rdata, padding_strategy, buffer_size);
   if (merged_opt_rdata)
     buffer_size += OptRecordSize(&merged_opt_rdata.value());

   io_buffer_ = base::MakeRefCounted<IOBufferWithSize>(buffer_size);

   header_ = reinterpret_cast<dns_protocol::Header*>(io_buffer_->data());
   *header_ = {};
   header_->id = base::HostToNet16(id);
   header_->flags = base::HostToNet16(dns_protocol::kFlagRD);
   header_->qdcount = base::HostToNet16(1);

   // Write question section after the header.
   base::BigEndianWriter writer(io_buffer_->data() + kHeaderSize,
                                io_buffer_->size() - kHeaderSize);
   writer.WriteBytes(qname.data(), qname.size());
   writer.WriteU16(qtype);
   writer.WriteU16(dns_protocol::kClassIN);

   if (merged_opt_rdata) {
     DCHECK(!merged_opt_rdata.value().opts().empty());

     header_->arcount = base::HostToNet16(1);
     // Write OPT pseudo-resource record.
     writer.WriteU8(0);                       // empty domain name (root domain)
     writer.WriteU16(OptRecordRdata::kType);  // type
     writer.WriteU16(kMaxUdpPayloadSize);     // class
     // ttl (next 3 fields)
     writer.WriteU8(0);  // rcode does not apply to requests
     writer.WriteU8(0);  // version
     // TODO(robpercival): Set "DNSSEC OK" flag if/when DNSSEC is supported:
     // https://tools.ietf.org/html/rfc3225#section-3
     writer.WriteU16(0);  // flags

     // rdata
     writer.WriteU16(merged_opt_rdata.value().buf().size());  // rdata length
     writer.WriteBytes(merged_opt_rdata.value().buf().data(),
                       merged_opt_rdata.value().buf().size());
   }
 }

 DnsQuery::DnsQuery(scoped_refptr<IOBufferWithSize> buffer)
     : io_buffer_(std::move(buffer)) {}

 DnsQuery::~DnsQuery() = default;

 std::unique_ptr<DnsQuery> DnsQuery::CloneWithNewId(uint16_t id) const {
   return base::WrapUnique(new DnsQuery(*this, id));
 }

 bool DnsQuery::Parse(size_t valid_bytes) {
   if (io_buffer_ == nullptr || io_buffer_->data() == nullptr) {
     return false;
   }
   CHECK(valid_bytes <= base::checked_cast<size_t>(io_buffer_->size()));
   // We should only parse the query once if the query is constructed from a raw
   // buffer. If we have constructed the query from data or the query is already
   // parsed after constructed from a raw buffer, |header_| is not null.
   DCHECK(header_ == nullptr);
   base::BigEndianReader reader(io_buffer_->data(), valid_bytes);
   dns_protocol::Header header;
   if (!ReadHeader(&reader, &header)) {
     return false;
   }
   if (header.flags & dns_protocol::kFlagResponse) {
     return false;
   }
   if (header.qdcount > 1) {
     VLOG(1) << "Not supporting parsing a DNS query with multiple questions.";
     return false;
   }
   std::string qname;
   if (!ReadName(&reader, &qname)) {
     return false;
   }
   uint16_t qtype;
   uint16_t qclass;
   if (!reader.ReadU16(&qtype) || !reader.ReadU16(&qclass) ||
       qclass != dns_protocol::kClassIN) {
     return false;
   }
   // |io_buffer_| now contains the raw packet of a valid DNS query, we just
   // need to properly initialize |qname_size_| and |header_|.
   qname_size_ = qname.size();
   header_ = reinterpret_cast<dns_protocol::Header*>(io_buffer_->data());
   return true;
 }

 uint16_t DnsQuery::id() const {
   return base::NetToHost16(header_->id);
 }

 base::StringPiece DnsQuery::qname() const {
   return base::StringPiece(io_buffer_->data() + kHeaderSize, qname_size_);
 }

 uint16_t DnsQuery::qtype() const {
   uint16_t type;
   base::ReadBigEndian<uint16_t>(io_buffer_->data() + kHeaderSize + qname_size_,
                                 &type);
   return type;
 }

 base::StringPiece DnsQuery::question() const {
   return base::StringPiece(io_buffer_->data() + kHeaderSize,
                            QuestionSize(qname_size_));
 }

 size_t DnsQuery::question_size() const {
   return QuestionSize(qname_size_);
 }

 void DnsQuery::set_flags(uint16_t flags) {
   header_->flags = flags;
 }

 DnsQuery::DnsQuery(const DnsQuery& orig, uint16_t id) {
   qname_size_ = orig.qname_size_;
   io_buffer_ = base::MakeRefCounted<IOBufferWithSize>(orig.io_buffer()->size());
   memcpy(io_buffer_.get()->data(), orig.io_buffer()->data(),
          io_buffer_.get()->size());
   header_ = reinterpret_cast<dns_protocol::Header*>(io_buffer_->data());
   header_->id = base::HostToNet16(id);
 }

 bool DnsQuery::ReadHeader(base::BigEndianReader* reader,
                           dns_protocol::Header* header) {
   return (
       reader->ReadU16(&header->id) && reader->ReadU16(&header->flags) &&
       reader->ReadU16(&header->qdcount) && reader->ReadU16(&header->ancount) &&
       reader->ReadU16(&header->nscount) && reader->ReadU16(&header->arcount));
 }

 bool DnsQuery::ReadName(base::BigEndianReader* reader, std::string* out) {
   DCHECK(out != nullptr);
   out->clear();
   out->reserve(dns_protocol::kMaxNameLength);
   uint8_t label_length;
   if (!reader->ReadU8(&label_length)) {
     return false;
   }
   out->append(reinterpret_cast<char*>(&label_length), 1);
   while (label_length) {
     base::StringPiece label;
     if (!reader->ReadPiece(&label, label_length)) {
       return false;
     }
     out->append(label.data(), label.size());
     if (!reader->ReadU8(&label_length)) {
       return false;
     }
     out->append(reinterpret_cast<char*>(&label_length), 1);
   }
   return true;
 }

 }  // namespace net
	// 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_query.h"

	#include <utility>

	#include "base/big_endian.h"
	#include "base/logging.h"
	#include "base/memory/ptr_util.h"
	#include "base/numerics/safe_conversions.h"
	#include "base/optional.h"
	#include "base/sys_byteorder.h"
	#include "net/base/io_buffer.h"
	#include "net/dns/dns_util.h"
	#include "net/dns/public/dns_protocol.h"
	#include "net/dns/record_rdata.h"

	namespace net {

	namespace {

	const size_t kHeaderSize = sizeof(dns_protocol::Header);

	// Size of the fixed part of an OPT RR:
	// https://tools.ietf.org/html/rfc6891#section-6.1.2
	static const size_t kOptRRFixedSize = 11;

	// https://tools.ietf.org/html/rfc6891#section-6.2.5
	// TODO(robpercival): Determine a good value for this programmatically.
	const uint16_t kMaxUdpPayloadSize = 4096;

	size_t QuestionSize(size_t qname_size) {
	// QNAME + QTYPE + QCLASS
	return qname_size + sizeof(uint16_t) + sizeof(uint16_t);
	}

	// Buffer size of Opt record for \|rdata\| (does not include Opt record or RData
	// added for padding).
	size_t OptRecordSize(const OptRecordRdata* rdata) {
	return rdata == nullptr ? 0 : kOptRRFixedSize + rdata->buf().size();
	}

	// Padding size includes Opt header for the padding. Does not include OptRecord
	// header (kOptRRFixedSize) even when added just for padding.
	size_t DeterminePaddingSize(size_t unpadded_size,
	DnsQuery::PaddingStrategy padding_strategy) {
	switch (padding_strategy) {
	case DnsQuery::PaddingStrategy::NONE:
	return 0;
	case DnsQuery::PaddingStrategy::BLOCK_LENGTH_128:
	size_t padding_size = OptRecordRdata::Opt::kHeaderSize;
	size_t remainder = (padding_size + unpadded_size) % 128;
	padding_size += (128 - remainder) % 128;
	DCHECK_EQ((unpadded_size + padding_size) % 128, 0u);
	return padding_size;
	}
	}

	base::Optional<OptRecordRdata> AddPaddingIfNecessary(
	const OptRecordRdata* opt_rdata,
	DnsQuery::PaddingStrategy padding_strategy,
	size_t no_opt_buffer_size) {
	// If no input OPT record rdata and no padding, no OPT record rdata needed.
	if (!opt_rdata && padding_strategy == DnsQuery::PaddingStrategy::NONE)
	return base::nullopt;

	OptRecordRdata merged_opt_rdata;
	if (opt_rdata)
	merged_opt_rdata.AddOpts(*opt_rdata);

	size_t unpadded_size = no_opt_buffer_size + OptRecordSize(&merged_opt_rdata);
	size_t padding_size = DeterminePaddingSize(unpadded_size, padding_strategy);

	if (padding_size > 0) {
	// \|opt_rdata\| must not already contain padding if DnsQuery is to add
	// padding.
	DCHECK(!merged_opt_rdata.ContainsOptCode(dns_protocol::kEdnsPadding));
	// OPT header is the minimum amount of padding.
	DCHECK(padding_size >= OptRecordRdata::Opt::kHeaderSize);

	merged_opt_rdata.AddOpt(OptRecordRdata::Opt(
	dns_protocol::kEdnsPadding,
	std::string(padding_size - OptRecordRdata::Opt::kHeaderSize, 0)));
	}

	return merged_opt_rdata;
	}

	} // namespace

	// DNS query consists of a 12-byte header followed by a question section.
	// For details, see RFC 1035 section 4.1.1. This header template sets RD
	// bit, which directs the name server to pursue query recursively, and sets
	// the QDCOUNT to 1, meaning the question section has a single entry.
	DnsQuery::DnsQuery(uint16_t id,
	const base::StringPiece& qname,
	uint16_t qtype,
	const OptRecordRdata* opt_rdata,
	PaddingStrategy padding_strategy)
	: qname_size_(qname.size()) {
	DCHECK(!DNSDomainToString(qname).empty());

	size_t buffer_size = kHeaderSize + QuestionSize(qname_size_);
	base::Optional<OptRecordRdata> merged_opt_rdata =
	AddPaddingIfNecessary(opt_rdata, padding_strategy, buffer_size);
	if (merged_opt_rdata)
	buffer_size += OptRecordSize(&merged_opt_rdata.value());

	io_buffer_ = base::MakeRefCounted<IOBufferWithSize>(buffer_size);

	header_ = reinterpret_cast<dns_protocol::Header*>(io_buffer_->data());
	*header_ = {};
	header_->id = base::HostToNet16(id);
	header_->flags = base::HostToNet16(dns_protocol::kFlagRD);
	header_->qdcount = base::HostToNet16(1);

	// Write question section after the header.
	base::BigEndianWriter writer(io_buffer_->data() + kHeaderSize,
	io_buffer_->size() - kHeaderSize);
	writer.WriteBytes(qname.data(), qname.size());
	writer.WriteU16(qtype);
	writer.WriteU16(dns_protocol::kClassIN);

	if (merged_opt_rdata) {
	DCHECK(!merged_opt_rdata.value().opts().empty());

	header_->arcount = base::HostToNet16(1);
	// Write OPT pseudo-resource record.
	writer.WriteU8(0); // empty domain name (root domain)
	writer.WriteU16(OptRecordRdata::kType); // type
	writer.WriteU16(kMaxUdpPayloadSize); // class
	// ttl (next 3 fields)
	writer.WriteU8(0); // rcode does not apply to requests
	writer.WriteU8(0); // version
	// TODO(robpercival): Set "DNSSEC OK" flag if/when DNSSEC is supported:
	// https://tools.ietf.org/html/rfc3225#section-3
	writer.WriteU16(0); // flags

	// rdata
	writer.WriteU16(merged_opt_rdata.value().buf().size()); // rdata length
	writer.WriteBytes(merged_opt_rdata.value().buf().data(),
	merged_opt_rdata.value().buf().size());
	}
	}

	DnsQuery::DnsQuery(scoped_refptr<IOBufferWithSize> buffer)
	: io_buffer_(std::move(buffer)) {}

	DnsQuery::~DnsQuery() = default;

	std::unique_ptr<DnsQuery> DnsQuery::CloneWithNewId(uint16_t id) const {
	return base::WrapUnique(new DnsQuery(*this, id));
	}

	bool DnsQuery::Parse(size_t valid_bytes) {
	if (io_buffer_ == nullptr \|\| io_buffer_->data() == nullptr) {
	return false;
	}
	CHECK(valid_bytes <= base::checked_cast<size_t>(io_buffer_->size()));
	// We should only parse the query once if the query is constructed from a raw
	// buffer. If we have constructed the query from data or the query is already
	// parsed after constructed from a raw buffer, \|header_\| is not null.
	DCHECK(header_ == nullptr);
	base::BigEndianReader reader(io_buffer_->data(), valid_bytes);
	dns_protocol::Header header;
	if (!ReadHeader(&reader, &header)) {
	return false;
	}
	if (header.flags & dns_protocol::kFlagResponse) {
	return false;
	}
	if (header.qdcount > 1) {
	VLOG(1) << "Not supporting parsing a DNS query with multiple questions.";
	return false;
	}
	std::string qname;
	if (!ReadName(&reader, &qname)) {
	return false;
	}
	uint16_t qtype;
	uint16_t qclass;
	if (!reader.ReadU16(&qtype) \|\| !reader.ReadU16(&qclass) \|\|
	qclass != dns_protocol::kClassIN) {
	return false;
	}
	// \|io_buffer_\| now contains the raw packet of a valid DNS query, we just
	// need to properly initialize \|qname_size_\| and \|header_\|.
	qname_size_ = qname.size();
	header_ = reinterpret_cast<dns_protocol::Header*>(io_buffer_->data());
	return true;
	}

	uint16_t DnsQuery::id() const {
	return base::NetToHost16(header_->id);
	}

	base::StringPiece DnsQuery::qname() const {
	return base::StringPiece(io_buffer_->data() + kHeaderSize, qname_size_);
	}

	uint16_t DnsQuery::qtype() const {
	uint16_t type;
	base::ReadBigEndian<uint16_t>(io_buffer_->data() + kHeaderSize + qname_size_,
	&type);
	return type;
	}

	base::StringPiece DnsQuery::question() const {
	return base::StringPiece(io_buffer_->data() + kHeaderSize,
	QuestionSize(qname_size_));
	}

	size_t DnsQuery::question_size() const {
	return QuestionSize(qname_size_);
	}

	void DnsQuery::set_flags(uint16_t flags) {
	header_->flags = flags;
	}

	DnsQuery::DnsQuery(const DnsQuery& orig, uint16_t id) {
	qname_size_ = orig.qname_size_;
	io_buffer_ = base::MakeRefCounted<IOBufferWithSize>(orig.io_buffer()->size());
	memcpy(io_buffer_.get()->data(), orig.io_buffer()->data(),
	io_buffer_.get()->size());
	header_ = reinterpret_cast<dns_protocol::Header*>(io_buffer_->data());
	header_->id = base::HostToNet16(id);
	}

	bool DnsQuery::ReadHeader(base::BigEndianReader* reader,
	dns_protocol::Header* header) {
	return (
	reader->ReadU16(&header->id) && reader->ReadU16(&header->flags) &&
	reader->ReadU16(&header->qdcount) && reader->ReadU16(&header->ancount) &&
	reader->ReadU16(&header->nscount) && reader->ReadU16(&header->arcount));
	}

	bool DnsQuery::ReadName(base::BigEndianReader* reader, std::string* out) {
	DCHECK(out != nullptr);
	out->clear();
	out->reserve(dns_protocol::kMaxNameLength);
	uint8_t label_length;
	if (!reader->ReadU8(&label_length)) {
	return false;
	}
	out->append(reinterpret_cast<char*>(&label_length), 1);
	while (label_length) {
	base::StringPiece label;
	if (!reader->ReadPiece(&label, label_length)) {
	return false;
	}
	out->append(label.data(), label.size());
	if (!reader->ReadU8(&label_length)) {
	return false;
	}
	out->append(reinterpret_cast<char*>(&label_length), 1);
	}
	return true;
	}

	} // namespace net