net/quic/crypto/crypto_handshake_message.cc - platform/external/chromium_org - Git at Google

 // Copyright (c) 2013 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/quic/crypto/crypto_handshake_message.h"

 #include "base/strings/stringprintf.h"
 #include "base/strings/string_number_conversions.h"
 #include "net/quic/crypto/crypto_framer.h"
 #include "net/quic/crypto/crypto_protocol.h"
 #include "net/quic/quic_socket_address_coder.h"
 #include "net/quic/quic_utils.h"

 using base::StringPiece;
 using base::StringPrintf;
 using std::string;
 using std::vector;

 namespace net {

 CryptoHandshakeMessage::CryptoHandshakeMessage()
     : tag_(0),
       minimum_size_(0) {}

 CryptoHandshakeMessage::CryptoHandshakeMessage(
     const CryptoHandshakeMessage& other)
     : tag_(other.tag_),
       tag_value_map_(other.tag_value_map_),
       minimum_size_(other.minimum_size_) {
   // Don't copy serialized_. scoped_ptr doesn't have a copy constructor.
   // The new object can lazily reconstruct serialized_.
 }

 CryptoHandshakeMessage::~CryptoHandshakeMessage() {}

 CryptoHandshakeMessage& CryptoHandshakeMessage::operator=(
     const CryptoHandshakeMessage& other) {
   tag_ = other.tag_;
   tag_value_map_ = other.tag_value_map_;
   // Don't copy serialized_. scoped_ptr doesn't have an assignment operator.
   // However, invalidate serialized_.
   serialized_.reset();
   minimum_size_ = other.minimum_size_;
   return *this;
 }

 void CryptoHandshakeMessage::Clear() {
   tag_ = 0;
   tag_value_map_.clear();
   minimum_size_ = 0;
   serialized_.reset();
 }

 const QuicData& CryptoHandshakeMessage::GetSerialized() const {
   if (!serialized_.get()) {
     serialized_.reset(CryptoFramer::ConstructHandshakeMessage(*this));
   }
   return *serialized_.get();
 }

 void CryptoHandshakeMessage::MarkDirty() {
   serialized_.reset();
 }

 void CryptoHandshakeMessage::SetTaglist(QuicTag tag, ...) {
   // Warning, if sizeof(QuicTag) > sizeof(int) then this function will break
   // because the terminating 0 will only be promoted to int.
   COMPILE_ASSERT(sizeof(QuicTag) <= sizeof(int),
                  crypto_tag_may_not_be_larger_than_int_or_varargs_will_break);

   vector<QuicTag> tags;
   va_list ap;

   va_start(ap, tag);
   for (;;) {
     QuicTag list_item = va_arg(ap, QuicTag);
     if (list_item == 0) {
       break;
     }
     tags.push_back(list_item);
   }

   // Because of the way that we keep tags in memory, we can copy the contents
   // of the vector and get the correct bytes in wire format. See
   // crypto_protocol.h. This assumes that the system is little-endian.
   SetVector(tag, tags);

   va_end(ap);
 }

 void CryptoHandshakeMessage::SetStringPiece(QuicTag tag, StringPiece value) {
   tag_value_map_[tag] = value.as_string();
 }

 void CryptoHandshakeMessage::Erase(QuicTag tag) {
   tag_value_map_.erase(tag);
 }

 QuicErrorCode CryptoHandshakeMessage::GetTaglist(QuicTag tag,
                                                  const QuicTag** out_tags,
                                                  size_t* out_len) const {
   QuicTagValueMap::const_iterator it = tag_value_map_.find(tag);
   QuicErrorCode ret = QUIC_NO_ERROR;

   if (it == tag_value_map_.end()) {
     ret = QUIC_CRYPTO_MESSAGE_PARAMETER_NOT_FOUND;
   } else if (it->second.size() % sizeof(QuicTag) != 0) {
     ret = QUIC_INVALID_CRYPTO_MESSAGE_PARAMETER;
   }

   if (ret != QUIC_NO_ERROR) {
     *out_tags = NULL;
     *out_len = 0;
     return ret;
   }

   *out_tags = reinterpret_cast<const QuicTag*>(it->second.data());
   *out_len = it->second.size() / sizeof(QuicTag);
   return ret;
 }

 bool CryptoHandshakeMessage::GetStringPiece(QuicTag tag,
                                             StringPiece* out) const {
   QuicTagValueMap::const_iterator it = tag_value_map_.find(tag);
   if (it == tag_value_map_.end()) {
     return false;
   }
   *out = it->second;
   return true;
 }

 QuicErrorCode CryptoHandshakeMessage::GetNthValue24(QuicTag tag,
                                                     unsigned index,
                                                     StringPiece* out) const {
   StringPiece value;
   if (!GetStringPiece(tag, &value)) {
     return QUIC_CRYPTO_MESSAGE_PARAMETER_NOT_FOUND;
   }

   for (unsigned i = 0;; i++) {
     if (value.empty()) {
       return QUIC_CRYPTO_MESSAGE_INDEX_NOT_FOUND;
     }
     if (value.size() < 3) {
       return QUIC_INVALID_CRYPTO_MESSAGE_PARAMETER;
     }

     const unsigned char* data =
         reinterpret_cast<const unsigned char*>(value.data());
     size_t size = static_cast<size_t>(data[0]) |
                   (static_cast<size_t>(data[1]) << 8) |
                   (static_cast<size_t>(data[2]) << 16);
     value.remove_prefix(3);

     if (value.size() < size) {
       return QUIC_INVALID_CRYPTO_MESSAGE_PARAMETER;
     }

     if (i == index) {
       *out = StringPiece(value.data(), size);
       return QUIC_NO_ERROR;
     }

     value.remove_prefix(size);
   }
 }

 QuicErrorCode CryptoHandshakeMessage::GetUint16(QuicTag tag,
                                                 uint16* out) const {
   return GetPOD(tag, out, sizeof(uint16));
 }

 QuicErrorCode CryptoHandshakeMessage::GetUint32(QuicTag tag,
                                                 uint32* out) const {
   return GetPOD(tag, out, sizeof(uint32));
 }

 QuicErrorCode CryptoHandshakeMessage::GetUint64(QuicTag tag,
                                                 uint64* out) const {
   return GetPOD(tag, out, sizeof(uint64));
 }

 size_t CryptoHandshakeMessage::size() const {
   size_t ret = sizeof(QuicTag) +
                sizeof(uint16) /* number of entries */ +
                sizeof(uint16) /* padding */;
   ret += (sizeof(QuicTag) + sizeof(uint32) /* end offset */) *
          tag_value_map_.size();
   for (QuicTagValueMap::const_iterator i = tag_value_map_.begin();
        i != tag_value_map_.end(); ++i) {
     ret += i->second.size();
   }

   return ret;
 }

 void CryptoHandshakeMessage::set_minimum_size(size_t min_bytes) {
   if (min_bytes == minimum_size_) {
     return;
   }
   serialized_.reset();
   minimum_size_ = min_bytes;
 }

 size_t CryptoHandshakeMessage::minimum_size() const {
   return minimum_size_;
 }

 string CryptoHandshakeMessage::DebugString() const {
   return DebugStringInternal(0);
 }

 QuicErrorCode CryptoHandshakeMessage::GetPOD(
     QuicTag tag, void* out, size_t len) const {
   QuicTagValueMap::const_iterator it = tag_value_map_.find(tag);
   QuicErrorCode ret = QUIC_NO_ERROR;

   if (it == tag_value_map_.end()) {
     ret = QUIC_CRYPTO_MESSAGE_PARAMETER_NOT_FOUND;
   } else if (it->second.size() != len) {
     ret = QUIC_INVALID_CRYPTO_MESSAGE_PARAMETER;
   }

   if (ret != QUIC_NO_ERROR) {
     memset(out, 0, len);
     return ret;
   }

   memcpy(out, it->second.data(), len);
   return ret;
 }

 string CryptoHandshakeMessage::DebugStringInternal(size_t indent) const {
   string ret = string(2 * indent, ' ') + QuicUtils::TagToString(tag_) + "<\n";
   ++indent;
   for (QuicTagValueMap::const_iterator it = tag_value_map_.begin();
        it != tag_value_map_.end(); ++it) {
     ret += string(2 * indent, ' ') + QuicUtils::TagToString(it->first) + ": ";

     bool done = false;
     switch (it->first) {
       case kICSL:
       case kIFCW:
       case kCFCW:
       case kSFCW:
       case kIRTT:
       case kKATO:
       case kMSPC:
       case kSWND:
         // uint32 value
         if (it->second.size() == 4) {
           uint32 value;
           memcpy(&value, it->second.data(), sizeof(value));
           ret += base::UintToString(value);
           done = true;
         }
         break;
       case kKEXS:
       case kAEAD:
       case kCGST:
       case kCOPT:
       case kLOSS:
       case kPDMD:
       case kVER:
         // tag lists
         if (it->second.size() % sizeof(QuicTag) == 0) {
           for (size_t j = 0; j < it->second.size(); j += sizeof(QuicTag)) {
             QuicTag tag;
             memcpy(&tag, it->second.data() + j, sizeof(tag));
             if (j > 0) {
               ret += ",";
             }
             ret += "'" + QuicUtils::TagToString(tag) + "'";
           }
           done = true;
         }
         break;
       case kCADR:
         // IP address and port
         if (!it->second.empty()) {
           QuicSocketAddressCoder decoder;
           if (decoder.Decode(it->second.data(), it->second.size())) {
             ret += IPAddressToStringWithPort(decoder.ip(), decoder.port());
             done = true;
           }
         }
         break;
       case kSCFG:
         // nested messages.
         if (!it->second.empty()) {
           scoped_ptr<CryptoHandshakeMessage> msg(
               CryptoFramer::ParseMessage(it->second));
           if (msg.get()) {
             ret += "\n";
             ret += msg->DebugStringInternal(indent + 1);

             done = true;
           }
         }
         break;
       case kPAD:
         ret += StringPrintf("(%d bytes of padding)",
                             static_cast<int>(it->second.size()));
         done = true;
         break;
       case kUAID:
         ret += it->second;
         done = true;
         break;
     }

     if (!done) {
       // If there's no specific format for this tag, or the value is invalid,
       // then just use hex.
       ret += "0x" + base::HexEncode(it->second.data(), it->second.size());
     }
     ret += "\n";
   }
   --indent;
   ret += string(2 * indent, ' ') + ">";
   return ret;
 }

 }  // namespace net
	// Copyright (c) 2013 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/quic/crypto/crypto_handshake_message.h"

	#include "base/strings/stringprintf.h"
	#include "base/strings/string_number_conversions.h"
	#include "net/quic/crypto/crypto_framer.h"
	#include "net/quic/crypto/crypto_protocol.h"
	#include "net/quic/quic_socket_address_coder.h"
	#include "net/quic/quic_utils.h"

	using base::StringPiece;
	using base::StringPrintf;
	using std::string;
	using std::vector;

	namespace net {

	CryptoHandshakeMessage::CryptoHandshakeMessage()
	: tag_(0),
	minimum_size_(0) {}

	CryptoHandshakeMessage::CryptoHandshakeMessage(
	const CryptoHandshakeMessage& other)
	: tag_(other.tag_),
	tag_value_map_(other.tag_value_map_),
	minimum_size_(other.minimum_size_) {
	// Don't copy serialized_. scoped_ptr doesn't have a copy constructor.
	// The new object can lazily reconstruct serialized_.
	}

	CryptoHandshakeMessage::~CryptoHandshakeMessage() {}

	CryptoHandshakeMessage& CryptoHandshakeMessage::operator=(
	const CryptoHandshakeMessage& other) {
	tag_ = other.tag_;
	tag_value_map_ = other.tag_value_map_;
	// Don't copy serialized_. scoped_ptr doesn't have an assignment operator.
	// However, invalidate serialized_.
	serialized_.reset();
	minimum_size_ = other.minimum_size_;
	return *this;
	}

	void CryptoHandshakeMessage::Clear() {
	tag_ = 0;
	tag_value_map_.clear();
	minimum_size_ = 0;
	serialized_.reset();
	}

	const QuicData& CryptoHandshakeMessage::GetSerialized() const {
	if (!serialized_.get()) {
	serialized_.reset(CryptoFramer::ConstructHandshakeMessage(*this));
	}
	return *serialized_.get();
	}

	void CryptoHandshakeMessage::MarkDirty() {
	serialized_.reset();
	}

	void CryptoHandshakeMessage::SetTaglist(QuicTag tag, ...) {
	// Warning, if sizeof(QuicTag) > sizeof(int) then this function will break
	// because the terminating 0 will only be promoted to int.
	COMPILE_ASSERT(sizeof(QuicTag) <= sizeof(int),
	crypto_tag_may_not_be_larger_than_int_or_varargs_will_break);

	vector<QuicTag> tags;
	va_list ap;

	va_start(ap, tag);
	for (;;) {
	QuicTag list_item = va_arg(ap, QuicTag);
	if (list_item == 0) {
	break;
	}
	tags.push_back(list_item);
	}

	// Because of the way that we keep tags in memory, we can copy the contents
	// of the vector and get the correct bytes in wire format. See
	// crypto_protocol.h. This assumes that the system is little-endian.
	SetVector(tag, tags);

	va_end(ap);
	}

	void CryptoHandshakeMessage::SetStringPiece(QuicTag tag, StringPiece value) {
	tag_value_map_[tag] = value.as_string();
	}

	void CryptoHandshakeMessage::Erase(QuicTag tag) {
	tag_value_map_.erase(tag);
	}

	QuicErrorCode CryptoHandshakeMessage::GetTaglist(QuicTag tag,
	const QuicTag** out_tags,
	size_t* out_len) const {
	QuicTagValueMap::const_iterator it = tag_value_map_.find(tag);
	QuicErrorCode ret = QUIC_NO_ERROR;

	if (it == tag_value_map_.end()) {
	ret = QUIC_CRYPTO_MESSAGE_PARAMETER_NOT_FOUND;
	} else if (it->second.size() % sizeof(QuicTag) != 0) {
	ret = QUIC_INVALID_CRYPTO_MESSAGE_PARAMETER;
	}

	if (ret != QUIC_NO_ERROR) {
	*out_tags = NULL;
	*out_len = 0;
	return ret;
	}

	out_tags = reinterpret_cast<const QuicTag>(it->second.data());
	*out_len = it->second.size() / sizeof(QuicTag);
	return ret;
	}

	bool CryptoHandshakeMessage::GetStringPiece(QuicTag tag,
	StringPiece* out) const {
	QuicTagValueMap::const_iterator it = tag_value_map_.find(tag);
	if (it == tag_value_map_.end()) {
	return false;
	}
	*out = it->second;
	return true;
	}

	QuicErrorCode CryptoHandshakeMessage::GetNthValue24(QuicTag tag,
	unsigned index,
	StringPiece* out) const {
	StringPiece value;
	if (!GetStringPiece(tag, &value)) {
	return QUIC_CRYPTO_MESSAGE_PARAMETER_NOT_FOUND;
	}

	for (unsigned i = 0;; i++) {
	if (value.empty()) {
	return QUIC_CRYPTO_MESSAGE_INDEX_NOT_FOUND;
	}
	if (value.size() < 3) {
	return QUIC_INVALID_CRYPTO_MESSAGE_PARAMETER;
	}

	const unsigned char* data =
	reinterpret_cast<const unsigned char*>(value.data());
	size_t size = static_cast<size_t>(data[0]) \|
	(static_cast<size_t>(data[1]) << 8) \|
	(static_cast<size_t>(data[2]) << 16);
	value.remove_prefix(3);

	if (value.size() < size) {
	return QUIC_INVALID_CRYPTO_MESSAGE_PARAMETER;
	}

	if (i == index) {
	*out = StringPiece(value.data(), size);
	return QUIC_NO_ERROR;
	}

	value.remove_prefix(size);
	}
	}

	QuicErrorCode CryptoHandshakeMessage::GetUint16(QuicTag tag,
	uint16* out) const {
	return GetPOD(tag, out, sizeof(uint16));
	}

	QuicErrorCode CryptoHandshakeMessage::GetUint32(QuicTag tag,
	uint32* out) const {
	return GetPOD(tag, out, sizeof(uint32));
	}

	QuicErrorCode CryptoHandshakeMessage::GetUint64(QuicTag tag,
	uint64* out) const {
	return GetPOD(tag, out, sizeof(uint64));
	}

	size_t CryptoHandshakeMessage::size() const {
	size_t ret = sizeof(QuicTag) +
	sizeof(uint16) /* number of entries */ +
	sizeof(uint16) /* padding */;
	ret += (sizeof(QuicTag) + sizeof(uint32) /* end offset /)
	tag_value_map_.size();
	for (QuicTagValueMap::const_iterator i = tag_value_map_.begin();
	i != tag_value_map_.end(); ++i) {
	ret += i->second.size();
	}

	return ret;
	}

	void CryptoHandshakeMessage::set_minimum_size(size_t min_bytes) {
	if (min_bytes == minimum_size_) {
	return;
	}
	serialized_.reset();
	minimum_size_ = min_bytes;
	}

	size_t CryptoHandshakeMessage::minimum_size() const {
	return minimum_size_;
	}

	string CryptoHandshakeMessage::DebugString() const {
	return DebugStringInternal(0);
	}

	QuicErrorCode CryptoHandshakeMessage::GetPOD(
	QuicTag tag, void* out, size_t len) const {
	QuicTagValueMap::const_iterator it = tag_value_map_.find(tag);
	QuicErrorCode ret = QUIC_NO_ERROR;

	if (it == tag_value_map_.end()) {
	ret = QUIC_CRYPTO_MESSAGE_PARAMETER_NOT_FOUND;
	} else if (it->second.size() != len) {
	ret = QUIC_INVALID_CRYPTO_MESSAGE_PARAMETER;
	}

	if (ret != QUIC_NO_ERROR) {
	memset(out, 0, len);
	return ret;
	}

	memcpy(out, it->second.data(), len);
	return ret;
	}

	string CryptoHandshakeMessage::DebugStringInternal(size_t indent) const {
	string ret = string(2 * indent, ' ') + QuicUtils::TagToString(tag_) + "<\n";
	++indent;
	for (QuicTagValueMap::const_iterator it = tag_value_map_.begin();
	it != tag_value_map_.end(); ++it) {
	ret += string(2 * indent, ' ') + QuicUtils::TagToString(it->first) + ": ";

	bool done = false;
	switch (it->first) {
	case kICSL:
	case kIFCW:
	case kCFCW:
	case kSFCW:
	case kIRTT:
	case kKATO:
	case kMSPC:
	case kSWND:
	// uint32 value
	if (it->second.size() == 4) {
	uint32 value;
	memcpy(&value, it->second.data(), sizeof(value));
	ret += base::UintToString(value);
	done = true;
	}
	break;
	case kKEXS:
	case kAEAD:
	case kCGST:
	case kCOPT:
	case kLOSS:
	case kPDMD:
	case kVER:
	// tag lists
	if (it->second.size() % sizeof(QuicTag) == 0) {
	for (size_t j = 0; j < it->second.size(); j += sizeof(QuicTag)) {
	QuicTag tag;
	memcpy(&tag, it->second.data() + j, sizeof(tag));
	if (j > 0) {
	ret += ",";
	}
	ret += "'" + QuicUtils::TagToString(tag) + "'";
	}
	done = true;
	}
	break;
	case kCADR:
	// IP address and port
	if (!it->second.empty()) {
	QuicSocketAddressCoder decoder;
	if (decoder.Decode(it->second.data(), it->second.size())) {
	ret += IPAddressToStringWithPort(decoder.ip(), decoder.port());
	done = true;
	}
	}
	break;
	case kSCFG:
	// nested messages.
	if (!it->second.empty()) {
	scoped_ptr<CryptoHandshakeMessage> msg(
	CryptoFramer::ParseMessage(it->second));
	if (msg.get()) {
	ret += "\n";
	ret += msg->DebugStringInternal(indent + 1);

	done = true;
	}
	}
	break;
	case kPAD:
	ret += StringPrintf("(%d bytes of padding)",
	static_cast<int>(it->second.size()));
	done = true;
	break;
	case kUAID:
	ret += it->second;
	done = true;
	break;
	}

	if (!done) {
	// If there's no specific format for this tag, or the value is invalid,
	// then just use hex.
	ret += "0x" + base::HexEncode(it->second.data(), it->second.size());
	}
	ret += "\n";
	}
	--indent;
	ret += string(2 * indent, ' ') + ">";
	return ret;
	}

	} // namespace net