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// 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.
#ifndef QUICHE_QUIC_CORE_QUIC_CRYPTO_STREAM_H_
#define QUICHE_QUIC_CORE_QUIC_CRYPTO_STREAM_H_
#include <array>
#include <cstddef>
#include <string>
#include "absl/strings/string_view.h"
#include "third_party/boringssl/src/include/openssl/ssl.h"
#include "quic/core/crypto/crypto_framer.h"
#include "quic/core/crypto/crypto_utils.h"
#include "quic/core/quic_config.h"
#include "quic/core/quic_packets.h"
#include "quic/core/quic_stream.h"
#include "quic/core/quic_types.h"
#include "quic/platform/api/quic_export.h"
namespace quic {
class QuicSession;
// Crypto handshake messages in QUIC take place over a reserved stream with the
// id 1. Each endpoint (client and server) will allocate an instance of a
// subclass of QuicCryptoStream to send and receive handshake messages. (In the
// normal 1-RTT handshake, the client will send a client hello, CHLO, message.
// The server will receive this message and respond with a server hello message,
// SHLO. At this point both sides will have established a crypto context they
// can use to send encrypted messages.
//
// For more details:
// https://docs.google.com/document/d/1g5nIXAIkN_Y-7XJW5K45IblHd_L2f5LTaDUDwvZ5L6g/edit?usp=sharing
class QUIC_EXPORT_PRIVATE QuicCryptoStream : public QuicStream {
public:
explicit QuicCryptoStream(QuicSession* session);
QuicCryptoStream(const QuicCryptoStream&) = delete;
QuicCryptoStream& operator=(const QuicCryptoStream&) = delete;
~QuicCryptoStream() override;
// Returns the per-packet framing overhead associated with sending a
// handshake message for |version|.
static QuicByteCount CryptoMessageFramingOverhead(
QuicTransportVersion version,
QuicConnectionId connection_id);
// QuicStream implementation
void OnStreamFrame(const QuicStreamFrame& frame) override;
void OnDataAvailable() override;
// Called when a CRYPTO frame is received.
void OnCryptoFrame(const QuicCryptoFrame& frame);
// Called when a CRYPTO frame is ACKed.
bool OnCryptoFrameAcked(const QuicCryptoFrame& frame,
QuicTime::Delta ack_delay_time);
void OnStreamReset(const QuicRstStreamFrame& frame) override;
// Performs key extraction to derive a new secret of |result_len| bytes
// dependent on |label|, |context|, and the stream's negotiated subkey secret.
// Returns false if the handshake has not been confirmed or the parameters are
// invalid (e.g. |label| contains null bytes); returns true on success.
bool ExportKeyingMaterial(absl::string_view label,
absl::string_view context,
size_t result_len,
std::string* result) const;
// Writes |data| to the QuicStream at level |level|.
virtual void WriteCryptoData(EncryptionLevel level, absl::string_view data);
// Returns the ssl_early_data_reason_t describing why 0-RTT was accepted or
// rejected. Note that the value returned by this function may vary during the
// handshake. Once |one_rtt_keys_available| returns true, the value returned
// by this function will not change for the rest of the lifetime of the
// QuicCryptoStream.
virtual ssl_early_data_reason_t EarlyDataReason() const = 0;
// Returns true once an encrypter has been set for the connection.
virtual bool encryption_established() const = 0;
// Returns true once the crypto handshake has completed.
virtual bool one_rtt_keys_available() const = 0;
// Returns the parameters negotiated in the crypto handshake.
virtual const QuicCryptoNegotiatedParameters& crypto_negotiated_params()
const = 0;
// Provides the message parser to use when data is received on this stream.
virtual CryptoMessageParser* crypto_message_parser() = 0;
// Called when a packet of encryption |level| has been successfully decrypted.
virtual void OnPacketDecrypted(EncryptionLevel level) = 0;
// Called when a 1RTT packet has been acknowledged.
virtual void OnOneRttPacketAcknowledged() = 0;
// Called when a packet of ENCRYPTION_HANDSHAKE gets sent.
virtual void OnHandshakePacketSent() = 0;
// Called when a handshake done frame has been received.
virtual void OnHandshakeDoneReceived() = 0;
// Called when a new token frame has been received.
virtual void OnNewTokenReceived(absl::string_view token) = 0;
// Called to get an address token.
virtual std::string GetAddressToken() const = 0;
// Called to validate |token|.
virtual bool ValidateAddressToken(absl::string_view token) const = 0;
// Returns current handshake state.
virtual HandshakeState GetHandshakeState() const = 0;
// Called to provide the server-side application state that must be checked
// when performing a 0-RTT TLS resumption.
//
// On a client, this may be called at any time; 0-RTT tickets will not be
// cached until this function is called. When a 0-RTT resumption is attempted,
// QuicSession::SetApplicationState will be called with the state provided by
// a call to this function on a previous connection.
//
// On a server, this function must be called before commencing the handshake,
// otherwise 0-RTT tickets will not be issued. On subsequent connections,
// 0-RTT will be rejected if the data passed into this function does not match
// the data passed in on the connection where the 0-RTT ticket was issued.
virtual void SetServerApplicationStateForResumption(
std::unique_ptr<ApplicationState> state) = 0;
// Returns the maximum number of bytes that can be buffered at a particular
// encryption level |level|.
virtual size_t BufferSizeLimitForLevel(EncryptionLevel level) const;
// Returns whether the implementation supports key update.
virtual bool KeyUpdateSupportedLocally() const = 0;
// Called to generate a decrypter for the next key phase. Each call should
// generate the key for phase n+1.
virtual std::unique_ptr<QuicDecrypter>
AdvanceKeysAndCreateCurrentOneRttDecrypter() = 0;
// Called to generate an encrypter for the same key phase of the last
// decrypter returned by AdvanceKeysAndCreateCurrentOneRttDecrypter().
virtual std::unique_ptr<QuicEncrypter> CreateCurrentOneRttEncrypter() = 0;
// Called to cancel retransmission of unencrypted crypto stream data.
void NeuterUnencryptedStreamData();
// Called to cancel retransmission of data of encryption |level|.
void NeuterStreamDataOfEncryptionLevel(EncryptionLevel level);
// Override to record the encryption level of consumed data.
void OnStreamDataConsumed(QuicByteCount bytes_consumed) override;
// Returns whether there are any bytes pending retransmission in CRYPTO
// frames.
virtual bool HasPendingCryptoRetransmission() const;
// Writes any pending CRYPTO frame retransmissions.
void WritePendingCryptoRetransmission();
// Override to retransmit lost crypto data with the appropriate encryption
// level.
void WritePendingRetransmission() override;
// Override to send unacked crypto data with the appropriate encryption level.
bool RetransmitStreamData(QuicStreamOffset offset,
QuicByteCount data_length,
bool fin,
TransmissionType type) override;
// Sends stream retransmission data at |encryption_level|.
QuicConsumedData RetransmitStreamDataAtLevel(
QuicStreamOffset retransmission_offset,
QuicByteCount retransmission_length,
EncryptionLevel encryption_level,
TransmissionType type);
// Returns the number of bytes of handshake data that have been received from
// the peer in either CRYPTO or STREAM frames.
uint64_t crypto_bytes_read() const;
// Returns the number of bytes of handshake data that have been received from
// the peer in CRYPTO frames at a particular encryption level.
QuicByteCount BytesReadOnLevel(EncryptionLevel level) const;
// Writes |data_length| of data of a crypto frame to |writer|. The data
// written is from the send buffer for encryption level |level| and starts at
// |offset|.
bool WriteCryptoFrame(EncryptionLevel level,
QuicStreamOffset offset,
QuicByteCount data_length,
QuicDataWriter* writer);
// Called when data from a CRYPTO frame is considered lost. The lost data is
// identified by the encryption level, offset, and length in |crypto_frame|.
void OnCryptoFrameLost(QuicCryptoFrame* crypto_frame);
// Called to retransmit any outstanding data in the range indicated by the
// encryption level, offset, and length in |crypto_frame|.
void RetransmitData(QuicCryptoFrame* crypto_frame, TransmissionType type);
// Called to write buffered crypto frames.
void WriteBufferedCryptoFrames();
// Returns true if there is buffered crypto frames.
bool HasBufferedCryptoFrames() const;
// Returns true if any portion of the data at encryption level |level|
// starting at |offset| for |length| bytes is outstanding.
bool IsFrameOutstanding(EncryptionLevel level,
size_t offset,
size_t length) const;
// Returns true if the crypto handshake is still waiting for acks of sent
// data, and false if all data has been acked.
bool IsWaitingForAcks() const;
private:
// Data sent and received in CRYPTO frames is sent at multiple encryption
// levels. Some of the state for the single logical crypto stream is split
// across encryption levels, and a CryptoSubstream is used to manage that
// state for a particular encryption level.
struct QUIC_EXPORT_PRIVATE CryptoSubstream {
CryptoSubstream(QuicCryptoStream* crypto_stream, EncryptionLevel);
QuicStreamSequencer sequencer;
QuicStreamSendBuffer send_buffer;
};
// Helper method for OnDataAvailable. Calls CryptoMessageParser::ProcessInput
// with the data available in |sequencer| and |level|, and marks the data
// passed to ProcessInput as consumed.
void OnDataAvailableInSequencer(QuicStreamSequencer* sequencer,
EncryptionLevel level);
// Consumed data according to encryption levels.
// TODO(fayang): This is not needed once switching from QUIC crypto to
// TLS 1.3, which never encrypts crypto data.
QuicIntervalSet<QuicStreamOffset> bytes_consumed_[NUM_ENCRYPTION_LEVELS];
// Keeps state for data sent/received in CRYPTO frames at each encryption
// level.
std::array<CryptoSubstream, NUM_ENCRYPTION_LEVELS> substreams_;
};
} // namespace quic
#endif // QUICHE_QUIC_CORE_QUIC_CRYPTO_STREAM_H_