quic/core/quic_data_reader.cc - quiche - 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/third_party/quiche/src/quic/core/quic_data_reader.h"

 #include "net/third_party/quiche/src/quic/core/quic_packets.h"
 #include "net/third_party/quiche/src/quic/core/quic_utils.h"
 #include "net/third_party/quiche/src/quic/platform/api/quic_bug_tracker.h"
 #include "net/third_party/quiche/src/quic/platform/api/quic_flags.h"
 #include "net/third_party/quiche/src/quic/platform/api/quic_str_cat.h"

 namespace quic {

 QuicDataReader::QuicDataReader(QuicStringPiece data)
     : QuicDataReader(data.data(), data.length(), NETWORK_BYTE_ORDER) {}

 QuicDataReader::QuicDataReader(const char* data, const size_t len)
     : QuicDataReader(data, len, NETWORK_BYTE_ORDER) {}

 QuicDataReader::QuicDataReader(const char* data,
                                const size_t len,
                                Endianness endianness)
     : data_(data), len_(len), pos_(0), endianness_(endianness) {}

 bool QuicDataReader::ReadUInt8(uint8_t* result) {
   return ReadBytes(result, sizeof(*result));
 }

 bool QuicDataReader::ReadUInt16(uint16_t* result) {
   if (!ReadBytes(result, sizeof(*result))) {
     return false;
   }
   if (endianness_ == NETWORK_BYTE_ORDER) {
     *result = QuicEndian::NetToHost16(*result);
   }
   return true;
 }

 bool QuicDataReader::ReadUInt32(uint32_t* result) {
   if (!ReadBytes(result, sizeof(*result))) {
     return false;
   }
   if (endianness_ == NETWORK_BYTE_ORDER) {
     *result = QuicEndian::NetToHost32(*result);
   }
   return true;
 }

 bool QuicDataReader::ReadUInt64(uint64_t* result) {
   if (!ReadBytes(result, sizeof(*result))) {
     return false;
   }
   if (endianness_ == NETWORK_BYTE_ORDER) {
     *result = QuicEndian::NetToHost64(*result);
   }
   return true;
 }

 bool QuicDataReader::ReadBytesToUInt64(size_t num_bytes, uint64_t* result) {
   *result = 0u;
   if (num_bytes > sizeof(*result)) {
     return false;
   }
   if (endianness_ == HOST_BYTE_ORDER) {
     return ReadBytes(result, num_bytes);
   }

   if (!ReadBytes(reinterpret_cast<char*>(result) + sizeof(*result) - num_bytes,
                  num_bytes)) {
     return false;
   }
   *result = QuicEndian::NetToHost64(*result);
   return true;
 }

 bool QuicDataReader::ReadUFloat16(uint64_t* result) {
   uint16_t value;
   if (!ReadUInt16(&value)) {
     return false;
   }

   *result = value;
   if (*result < (1 << kUFloat16MantissaEffectiveBits)) {
     // Fast path: either the value is denormalized (no hidden bit), or
     // normalized (hidden bit set, exponent offset by one) with exponent zero.
     // Zero exponent offset by one sets the bit exactly where the hidden bit is.
     // So in both cases the value encodes itself.
     return true;
   }

   uint16_t exponent =
       value >> kUFloat16MantissaBits;  // No sign extend on uint!
   // After the fast pass, the exponent is at least one (offset by one).
   // Un-offset the exponent.
   --exponent;
   DCHECK_GE(exponent, 1);
   DCHECK_LE(exponent, kUFloat16MaxExponent);
   // Here we need to clear the exponent and set the hidden bit. We have already
   // decremented the exponent, so when we subtract it, it leaves behind the
   // hidden bit.
   *result -= exponent << kUFloat16MantissaBits;
   *result <<= exponent;
   DCHECK_GE(*result,
             static_cast<uint64_t>(1 << kUFloat16MantissaEffectiveBits));
   DCHECK_LE(*result, kUFloat16MaxValue);
   return true;
 }

 bool QuicDataReader::ReadStringPiece16(QuicStringPiece* result) {
   // Read resultant length.
   uint16_t result_len;
   if (!ReadUInt16(&result_len)) {
     // OnFailure() already called.
     return false;
   }

   return ReadStringPiece(result, result_len);
 }

 bool QuicDataReader::ReadStringPiece(QuicStringPiece* result, size_t size) {
   // Make sure that we have enough data to read.
   if (!CanRead(size)) {
     OnFailure();
     return false;
   }

   // Set result.
   *result = QuicStringPiece(data_ + pos_, size);

   // Iterate.
   pos_ += size;

   return true;
 }

 bool QuicDataReader::ReadConnectionId(QuicConnectionId* connection_id,
                                       uint8_t length) {
   if (length > kQuicMaxConnectionIdAllVersionsLength) {
     QUIC_BUG << "Attempted to read connection ID with length too high "
              << static_cast<int>(length);
     return false;
   }
   if (length == 0) {
     connection_id->set_length(0);
     return true;
   }

   if (BytesRemaining() < length) {
     return false;
   }

   connection_id->set_length(length);
   const bool ok =
       ReadBytes(connection_id->mutable_data(), connection_id->length());
   DCHECK(ok);
   return ok;
 }

 bool QuicDataReader::ReadLengthPrefixedConnectionId(
     QuicConnectionId* connection_id) {
   uint8_t connection_id_length;
   if (!ReadUInt8(&connection_id_length)) {
     return false;
   }
   if (connection_id_length > kQuicMaxConnectionIdAllVersionsLength) {
     return false;
   }
   return ReadConnectionId(connection_id, connection_id_length);
 }

 bool QuicDataReader::ReadTag(uint32_t* tag) {
   return ReadBytes(tag, sizeof(*tag));
 }

 QuicStringPiece QuicDataReader::ReadRemainingPayload() {
   QuicStringPiece payload = PeekRemainingPayload();
   pos_ = len_;
   return payload;
 }

 QuicStringPiece QuicDataReader::PeekRemainingPayload() const {
   return QuicStringPiece(data_ + pos_, len_ - pos_);
 }

 QuicStringPiece QuicDataReader::FullPayload() const {
   return QuicStringPiece(data_, len_);
 }

 bool QuicDataReader::ReadBytes(void* result, size_t size) {
   // Make sure that we have enough data to read.
   if (!CanRead(size)) {
     OnFailure();
     return false;
   }

   // Read into result.
   memcpy(result, data_ + pos_, size);

   // Iterate.
   pos_ += size;

   return true;
 }

 bool QuicDataReader::Seek(size_t size) {
   if (!CanRead(size)) {
     OnFailure();
     return false;
   }
   pos_ += size;
   return true;
 }

 bool QuicDataReader::IsDoneReading() const {
   return len_ == pos_;
 }

 QuicVariableLengthIntegerLength QuicDataReader::PeekVarInt62Length() {
   DCHECK_EQ(endianness_, NETWORK_BYTE_ORDER);
   const unsigned char* next =
       reinterpret_cast<const unsigned char*>(data_ + pos_);
   if (BytesRemaining() == 0) {
     return VARIABLE_LENGTH_INTEGER_LENGTH_0;
   }
   return static_cast<QuicVariableLengthIntegerLength>(
       1 << ((*next & 0b11000000) >> 6));
 }

 size_t QuicDataReader::BytesRemaining() const {
   return len_ - pos_;
 }

 bool QuicDataReader::TruncateRemaining(size_t truncation_length) {
   if (truncation_length > BytesRemaining()) {
     return false;
   }
   len_ = pos_ + truncation_length;
   return true;
 }

 bool QuicDataReader::CanRead(size_t bytes) const {
   return bytes <= (len_ - pos_);
 }

 void QuicDataReader::OnFailure() {
   // Set our iterator to the end of the buffer so that further reads fail
   // immediately.
   pos_ = len_;
 }

 uint8_t QuicDataReader::PeekByte() const {
   if (pos_ >= len_) {
     QUIC_BUG << "Reading is done, cannot peek next byte. Tried to read pos = "
              << pos_ << " buffer length = " << len_;
     return 0;
   }
   return data_[pos_];
 }

 // Read an IETF/QUIC formatted 62-bit Variable Length Integer.
 //
 // Performance notes
 //
 // Measurements and experiments showed that unrolling the four cases
 // like this and dereferencing next_ as we do (*(next_+n) --- and then
 // doing a single pos_+=x at the end) gains about 10% over making a
 // loop and dereferencing next_ such as *(next_++)
 //
 // Using a register for pos_ was not helpful.
 //
 // Branches are ordered to increase the likelihood of the first being
 // taken.
 //
 // Low-level optimization is useful here because this function will be
 // called frequently, leading to outsize benefits.
 bool QuicDataReader::ReadVarInt62(uint64_t* result) {
   DCHECK_EQ(endianness_, NETWORK_BYTE_ORDER);

   size_t remaining = BytesRemaining();
   const unsigned char* next =
       reinterpret_cast<const unsigned char*>(data_ + pos_);
   if (remaining != 0) {
     switch (*next & 0xc0) {
       case 0xc0:
         // Leading 0b11...... is 8 byte encoding
         if (remaining >= 8) {
           *result = (static_cast<uint64_t>((*(next)) & 0x3f) << 56) +
                     (static_cast<uint64_t>(*(next + 1)) << 48) +
                     (static_cast<uint64_t>(*(next + 2)) << 40) +
                     (static_cast<uint64_t>(*(next + 3)) << 32) +
                     (static_cast<uint64_t>(*(next + 4)) << 24) +
                     (static_cast<uint64_t>(*(next + 5)) << 16) +
                     (static_cast<uint64_t>(*(next + 6)) << 8) +
                     (static_cast<uint64_t>(*(next + 7)) << 0);
           pos_ += 8;
           return true;
         }
         return false;

       case 0x80:
         // Leading 0b10...... is 4 byte encoding
         if (remaining >= 4) {
           *result = (((*(next)) & 0x3f) << 24) + (((*(next + 1)) << 16)) +
                     (((*(next + 2)) << 8)) + (((*(next + 3)) << 0));
           pos_ += 4;
           return true;
         }
         return false;

       case 0x40:
         // Leading 0b01...... is 2 byte encoding
         if (remaining >= 2) {
           *result = (((*(next)) & 0x3f) << 8) + (*(next + 1));
           pos_ += 2;
           return true;
         }
         return false;

       case 0x00:
         // Leading 0b00...... is 1 byte encoding
         *result = (*next) & 0x3f;
         pos_++;
         return true;
     }
   }
   return false;
 }

 bool QuicDataReader::ReadVarIntU32(uint32_t* result) {
   uint64_t temp_uint64;
   // TODO(fkastenholz): We should disambiguate read-errors from
   // value errors.
   if (!this->ReadVarInt62(&temp_uint64)) {
     return false;
   }
   if (temp_uint64 > kMaxQuicStreamId) {
     return false;
   }
   *result = static_cast<uint32_t>(temp_uint64);
   return true;
 }

 std::string QuicDataReader::DebugString() const {
   return QuicStrCat(" { length: ", len_, ", position: ", pos_, " }");
 }

 #undef ENDPOINT  // undef for jumbo builds
 }  // namespace quic
	// 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/third_party/quiche/src/quic/core/quic_data_reader.h"

	#include "net/third_party/quiche/src/quic/core/quic_packets.h"
	#include "net/third_party/quiche/src/quic/core/quic_utils.h"
	#include "net/third_party/quiche/src/quic/platform/api/quic_bug_tracker.h"
	#include "net/third_party/quiche/src/quic/platform/api/quic_flags.h"
	#include "net/third_party/quiche/src/quic/platform/api/quic_str_cat.h"

	namespace quic {

	QuicDataReader::QuicDataReader(QuicStringPiece data)
	: QuicDataReader(data.data(), data.length(), NETWORK_BYTE_ORDER) {}

	QuicDataReader::QuicDataReader(const char* data, const size_t len)
	: QuicDataReader(data, len, NETWORK_BYTE_ORDER) {}

	QuicDataReader::QuicDataReader(const char* data,
	const size_t len,
	Endianness endianness)
	: data_(data), len_(len), pos_(0), endianness_(endianness) {}

	bool QuicDataReader::ReadUInt8(uint8_t* result) {
	return ReadBytes(result, sizeof(*result));
	}

	bool QuicDataReader::ReadUInt16(uint16_t* result) {
	if (!ReadBytes(result, sizeof(*result))) {
	return false;
	}
	if (endianness_ == NETWORK_BYTE_ORDER) {
	result = QuicEndian::NetToHost16(result);
	}
	return true;
	}

	bool QuicDataReader::ReadUInt32(uint32_t* result) {
	if (!ReadBytes(result, sizeof(*result))) {
	return false;
	}
	if (endianness_ == NETWORK_BYTE_ORDER) {
	result = QuicEndian::NetToHost32(result);
	}
	return true;
	}

	bool QuicDataReader::ReadUInt64(uint64_t* result) {
	if (!ReadBytes(result, sizeof(*result))) {
	return false;
	}
	if (endianness_ == NETWORK_BYTE_ORDER) {
	result = QuicEndian::NetToHost64(result);
	}
	return true;
	}

	bool QuicDataReader::ReadBytesToUInt64(size_t num_bytes, uint64_t* result) {
	*result = 0u;
	if (num_bytes > sizeof(*result)) {
	return false;
	}
	if (endianness_ == HOST_BYTE_ORDER) {
	return ReadBytes(result, num_bytes);
	}

	if (!ReadBytes(reinterpret_cast<char>(result) + sizeof(result) - num_bytes,
	num_bytes)) {
	return false;
	}
	result = QuicEndian::NetToHost64(result);
	return true;
	}

	bool QuicDataReader::ReadUFloat16(uint64_t* result) {
	uint16_t value;
	if (!ReadUInt16(&value)) {
	return false;
	}

	*result = value;
	if (*result < (1 << kUFloat16MantissaEffectiveBits)) {
	// Fast path: either the value is denormalized (no hidden bit), or
	// normalized (hidden bit set, exponent offset by one) with exponent zero.
	// Zero exponent offset by one sets the bit exactly where the hidden bit is.
	// So in both cases the value encodes itself.
	return true;
	}

	uint16_t exponent =
	value >> kUFloat16MantissaBits; // No sign extend on uint!
	// After the fast pass, the exponent is at least one (offset by one).
	// Un-offset the exponent.
	--exponent;
	DCHECK_GE(exponent, 1);
	DCHECK_LE(exponent, kUFloat16MaxExponent);
	// Here we need to clear the exponent and set the hidden bit. We have already
	// decremented the exponent, so when we subtract it, it leaves behind the
	// hidden bit.
	*result -= exponent << kUFloat16MantissaBits;
	*result <<= exponent;
	DCHECK_GE(*result,
	static_cast<uint64_t>(1 << kUFloat16MantissaEffectiveBits));
	DCHECK_LE(*result, kUFloat16MaxValue);
	return true;
	}

	bool QuicDataReader::ReadStringPiece16(QuicStringPiece* result) {
	// Read resultant length.
	uint16_t result_len;
	if (!ReadUInt16(&result_len)) {
	// OnFailure() already called.
	return false;
	}

	return ReadStringPiece(result, result_len);
	}

	bool QuicDataReader::ReadStringPiece(QuicStringPiece* result, size_t size) {
	// Make sure that we have enough data to read.
	if (!CanRead(size)) {
	OnFailure();
	return false;
	}

	// Set result.
	*result = QuicStringPiece(data_ + pos_, size);

	// Iterate.
	pos_ += size;

	return true;
	}

	bool QuicDataReader::ReadConnectionId(QuicConnectionId* connection_id,
	uint8_t length) {
	if (length > kQuicMaxConnectionIdAllVersionsLength) {
	QUIC_BUG << "Attempted to read connection ID with length too high "
	<< static_cast<int>(length);
	return false;
	}
	if (length == 0) {
	connection_id->set_length(0);
	return true;
	}

	if (BytesRemaining() < length) {
	return false;
	}

	connection_id->set_length(length);
	const bool ok =
	ReadBytes(connection_id->mutable_data(), connection_id->length());
	DCHECK(ok);
	return ok;
	}

	bool QuicDataReader::ReadLengthPrefixedConnectionId(
	QuicConnectionId* connection_id) {
	uint8_t connection_id_length;
	if (!ReadUInt8(&connection_id_length)) {
	return false;
	}
	if (connection_id_length > kQuicMaxConnectionIdAllVersionsLength) {
	return false;
	}
	return ReadConnectionId(connection_id, connection_id_length);
	}

	bool QuicDataReader::ReadTag(uint32_t* tag) {
	return ReadBytes(tag, sizeof(*tag));
	}

	QuicStringPiece QuicDataReader::ReadRemainingPayload() {
	QuicStringPiece payload = PeekRemainingPayload();
	pos_ = len_;
	return payload;
	}

	QuicStringPiece QuicDataReader::PeekRemainingPayload() const {
	return QuicStringPiece(data_ + pos_, len_ - pos_);
	}

	QuicStringPiece QuicDataReader::FullPayload() const {
	return QuicStringPiece(data_, len_);
	}

	bool QuicDataReader::ReadBytes(void* result, size_t size) {
	// Make sure that we have enough data to read.
	if (!CanRead(size)) {
	OnFailure();
	return false;
	}

	// Read into result.
	memcpy(result, data_ + pos_, size);

	// Iterate.
	pos_ += size;

	return true;
	}

	bool QuicDataReader::Seek(size_t size) {
	if (!CanRead(size)) {
	OnFailure();
	return false;
	}
	pos_ += size;
	return true;
	}

	bool QuicDataReader::IsDoneReading() const {
	return len_ == pos_;
	}

	QuicVariableLengthIntegerLength QuicDataReader::PeekVarInt62Length() {
	DCHECK_EQ(endianness_, NETWORK_BYTE_ORDER);
	const unsigned char* next =
	reinterpret_cast<const unsigned char*>(data_ + pos_);
	if (BytesRemaining() == 0) {
	return VARIABLE_LENGTH_INTEGER_LENGTH_0;
	}
	return static_cast<QuicVariableLengthIntegerLength>(
	1 << ((*next & 0b11000000) >> 6));
	}

	size_t QuicDataReader::BytesRemaining() const {
	return len_ - pos_;
	}

	bool QuicDataReader::TruncateRemaining(size_t truncation_length) {
	if (truncation_length > BytesRemaining()) {
	return false;
	}
	len_ = pos_ + truncation_length;
	return true;
	}

	bool QuicDataReader::CanRead(size_t bytes) const {
	return bytes <= (len_ - pos_);
	}

	void QuicDataReader::OnFailure() {
	// Set our iterator to the end of the buffer so that further reads fail
	// immediately.
	pos_ = len_;
	}

	uint8_t QuicDataReader::PeekByte() const {
	if (pos_ >= len_) {
	QUIC_BUG << "Reading is done, cannot peek next byte. Tried to read pos = "
	<< pos_ << " buffer length = " << len_;
	return 0;
	}
	return data_[pos_];
	}

	// Read an IETF/QUIC formatted 62-bit Variable Length Integer.
	//
	// Performance notes
	//
	// Measurements and experiments showed that unrolling the four cases
	// like this and dereferencing next_ as we do (*(next_+n) --- and then
	// doing a single pos_+=x at the end) gains about 10% over making a
	// loop and dereferencing next_ such as *(next_++)
	//
	// Using a register for pos_ was not helpful.
	//
	// Branches are ordered to increase the likelihood of the first being
	// taken.
	//
	// Low-level optimization is useful here because this function will be
	// called frequently, leading to outsize benefits.
	bool QuicDataReader::ReadVarInt62(uint64_t* result) {
	DCHECK_EQ(endianness_, NETWORK_BYTE_ORDER);

	size_t remaining = BytesRemaining();
	const unsigned char* next =
	reinterpret_cast<const unsigned char*>(data_ + pos_);
	if (remaining != 0) {
	switch (*next & 0xc0) {
	case 0xc0:
	// Leading 0b11...... is 8 byte encoding
	if (remaining >= 8) {
	result = (static_cast<uint64_t>(((next)) & 0x3f) << 56) +
	(static_cast<uint64_t>(*(next + 1)) << 48) +
	(static_cast<uint64_t>(*(next + 2)) << 40) +
	(static_cast<uint64_t>(*(next + 3)) << 32) +
	(static_cast<uint64_t>(*(next + 4)) << 24) +
	(static_cast<uint64_t>(*(next + 5)) << 16) +
	(static_cast<uint64_t>(*(next + 6)) << 8) +
	(static_cast<uint64_t>(*(next + 7)) << 0);
	pos_ += 8;
	return true;
	}
	return false;

	case 0x80:
	// Leading 0b10...... is 4 byte encoding
	if (remaining >= 4) {
	result = ((((next)) & 0x3f) << 24) + (((*(next + 1)) << 16)) +
	((((next + 2)) << 8)) + ((((next + 3)) << 0));
	pos_ += 4;
	return true;
	}
	return false;

	case 0x40:
	// Leading 0b01...... is 2 byte encoding
	if (remaining >= 2) {
	result = ((((next)) & 0x3f) << 8) + (*(next + 1));
	pos_ += 2;
	return true;
	}
	return false;

	case 0x00:
	// Leading 0b00...... is 1 byte encoding
	result = (next) & 0x3f;
	pos_++;
	return true;
	}
	}
	return false;
	}

	bool QuicDataReader::ReadVarIntU32(uint32_t* result) {
	uint64_t temp_uint64;
	// TODO(fkastenholz): We should disambiguate read-errors from
	// value errors.
	if (!this->ReadVarInt62(&temp_uint64)) {
	return false;
	}
	if (temp_uint64 > kMaxQuicStreamId) {
	return false;
	}
	*result = static_cast<uint32_t>(temp_uint64);
	return true;
	}

	std::string QuicDataReader::DebugString() const {
	return QuicStrCat(" { length: ", len_, ", position: ", pos_, " }");
	}

	#undef ENDPOINT // undef for jumbo builds
	} // namespace quic