internal/quic/crypto_stream.go - net - Git at Google

 // Copyright 2023 The Go Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 //go:build go1.21

 package quic

 // "Implementations MUST support buffering at least 4096 bytes of data
 // received in out-of-order CRYPTO frames."
 // https://www.rfc-editor.org/rfc/rfc9000.html#section-7.5-2
 //
 // 4096 is too small for real-world cases, however, so we allow more.
 const cryptoBufferSize = 1 << 20

 // A cryptoStream is the stream of data passed in CRYPTO frames.
 // There is one cryptoStream per packet number space.
 type cryptoStream struct {
 	// CRYPTO data received from the peer.
 	in    pipe
 	inset rangeset[int64] // bytes received

 	// CRYPTO data queued for transmission to the peer.
 	out       pipe
 	outunsent rangeset[int64] // bytes in need of sending
 	outacked  rangeset[int64] // bytes acked by peer
 }

 // handleCrypto processes data received in a CRYPTO frame.
 func (s *cryptoStream) handleCrypto(off int64, b []byte, f func([]byte) error) error {
 	end := off + int64(len(b))
 	if end-s.inset.min() > cryptoBufferSize {
 		return localTransportError(errCryptoBufferExceeded)
 	}
 	s.inset.add(off, end)
 	if off == s.in.start {
 		// Fast path: This is the next chunk of data in the stream,
 		// so just handle it immediately.
 		if err := f(b); err != nil {
 			return err
 		}
 		s.in.discardBefore(end)
 	} else {
 		// This is either data we've already processed,
 		// data we can't process yet, or a mix of both.
 		s.in.writeAt(b, off)
 	}
 	// s.in.start is the next byte in sequence.
 	// If it's in s.inset, we have bytes to provide.
 	// If it isn't, we don't--we're either out of data,
 	// or only have data that comes after the next byte.
 	if !s.inset.contains(s.in.start) {
 		return nil
 	}
 	// size is the size of the first contiguous chunk of bytes
 	// that have not been processed yet.
 	size := int(s.inset[0].end - s.in.start)
 	if size <= 0 {
 		return nil
 	}
 	err := s.in.read(s.in.start, size, f)
 	s.in.discardBefore(s.inset[0].end)
 	return err
 }

 // write queues data for sending to the peer.
 // It does not block or limit the amount of buffered data.
 // QUIC connections don't communicate the amount of CRYPTO data they are willing to buffer,
 // so we send what we have and the peer can close the connection if it is too much.
 func (s *cryptoStream) write(b []byte) {
 	start := s.out.end
 	s.out.writeAt(b, start)
 	s.outunsent.add(start, s.out.end)
 }

 // ackOrLoss reports that an CRYPTO frame sent by us has been acknowledged by the peer, or lost.
 func (s *cryptoStream) ackOrLoss(start, end int64, fate packetFate) {
 	switch fate {
 	case packetAcked:
 		s.outacked.add(start, end)
 		s.outunsent.sub(start, end)
 		// If this ack is for data at the start of the send buffer, we can now discard it.
 		if s.outacked.contains(s.out.start) {
 			s.out.discardBefore(s.outacked[0].end)
 		}
 	case packetLost:
 		// Mark everything lost, but not previously acked, as needing retransmission.
 		// We do this by adding all the lost bytes to outunsent, and then
 		// removing everything already acked.
 		s.outunsent.add(start, end)
 		for _, a := range s.outacked {
 			s.outunsent.sub(a.start, a.end)
 		}
 	}
 }

 // dataToSend reports what data should be sent in CRYPTO frames to the peer.
 // It calls f with each range of data to send.
 // f uses sendData to get the bytes to send, and returns the number of bytes sent.
 // dataToSend calls f until no data is left, or f returns 0.
 //
 // This function is unusually indirect (why not just return a []byte,
 // or implement io.Reader?).
 //
 // Returning a []byte to the caller either requires that we store the
 // data to send contiguously (which we don't), allocate a temporary buffer
 // and copy into it (inefficient), or return less data than we have available
 // (requires complexity to avoid unnecessarily breaking data across frames).
 //
 // Accepting a []byte from the caller (io.Reader) makes packet construction
 // difficult. Since CRYPTO data is encoded with a varint length prefix, the
 // location of the data depends on the length of the data. (We could hardcode
 // a 2-byte length, of course.)
 //
 // Instead, we tell the caller how much data is, the caller figures out where
 // to put it (and possibly decides that it doesn't have space for this data
 // in the packet after all), and the caller then makes a separate call to
 // copy the data it wants into position.
 func (s *cryptoStream) dataToSend(pto bool, f func(off, size int64) (sent int64)) {
 	for {
 		off, size := dataToSend(s.out, s.outunsent, s.outacked, pto)
 		if size == 0 {
 			return
 		}
 		n := f(off, size)
 		if n == 0 || pto {
 			return
 		}
 	}
 }

 // sendData fills b with data to send to the peer, starting at off,
 // and marks the data as sent. The caller must have already ascertained
 // that there is data to send in this region using dataToSend.
 func (s *cryptoStream) sendData(off int64, b []byte) {
 	s.out.copy(off, b)
 	s.outunsent.sub(off, off+int64(len(b)))
 }
	// Copyright 2023 The Go Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	//go:build go1.21

	package quic

	// "Implementations MUST support buffering at least 4096 bytes of data
	// received in out-of-order CRYPTO frames."
	// https://www.rfc-editor.org/rfc/rfc9000.html#section-7.5-2
	//
	// 4096 is too small for real-world cases, however, so we allow more.
	const cryptoBufferSize = 1 << 20

	// A cryptoStream is the stream of data passed in CRYPTO frames.
	// There is one cryptoStream per packet number space.
	type cryptoStream struct {
	// CRYPTO data received from the peer.
	in pipe
	inset rangeset[int64] // bytes received

	// CRYPTO data queued for transmission to the peer.
	out pipe
	outunsent rangeset[int64] // bytes in need of sending
	outacked rangeset[int64] // bytes acked by peer
	}

	// handleCrypto processes data received in a CRYPTO frame.
	func (s *cryptoStream) handleCrypto(off int64, b []byte, f func([]byte) error) error {
	end := off + int64(len(b))
	if end-s.inset.min() > cryptoBufferSize {
	return localTransportError(errCryptoBufferExceeded)
	}
	s.inset.add(off, end)
	if off == s.in.start {
	// Fast path: This is the next chunk of data in the stream,
	// so just handle it immediately.
	if err := f(b); err != nil {
	return err
	}
	s.in.discardBefore(end)
	} else {
	// This is either data we've already processed,
	// data we can't process yet, or a mix of both.
	s.in.writeAt(b, off)
	}
	// s.in.start is the next byte in sequence.
	// If it's in s.inset, we have bytes to provide.
	// If it isn't, we don't--we're either out of data,
	// or only have data that comes after the next byte.
	if !s.inset.contains(s.in.start) {
	return nil
	}
	// size is the size of the first contiguous chunk of bytes
	// that have not been processed yet.
	size := int(s.inset[0].end - s.in.start)
	if size <= 0 {
	return nil
	}
	err := s.in.read(s.in.start, size, f)
	s.in.discardBefore(s.inset[0].end)
	return err
	}

	// write queues data for sending to the peer.
	// It does not block or limit the amount of buffered data.
	// QUIC connections don't communicate the amount of CRYPTO data they are willing to buffer,
	// so we send what we have and the peer can close the connection if it is too much.
	func (s *cryptoStream) write(b []byte) {
	start := s.out.end
	s.out.writeAt(b, start)
	s.outunsent.add(start, s.out.end)
	}

	// ackOrLoss reports that an CRYPTO frame sent by us has been acknowledged by the peer, or lost.
	func (s *cryptoStream) ackOrLoss(start, end int64, fate packetFate) {
	switch fate {
	case packetAcked:
	s.outacked.add(start, end)
	s.outunsent.sub(start, end)
	// If this ack is for data at the start of the send buffer, we can now discard it.
	if s.outacked.contains(s.out.start) {
	s.out.discardBefore(s.outacked[0].end)
	}
	case packetLost:
	// Mark everything lost, but not previously acked, as needing retransmission.
	// We do this by adding all the lost bytes to outunsent, and then
	// removing everything already acked.
	s.outunsent.add(start, end)
	for _, a := range s.outacked {
	s.outunsent.sub(a.start, a.end)
	}
	}
	}

	// dataToSend reports what data should be sent in CRYPTO frames to the peer.
	// It calls f with each range of data to send.
	// f uses sendData to get the bytes to send, and returns the number of bytes sent.
	// dataToSend calls f until no data is left, or f returns 0.
	//
	// This function is unusually indirect (why not just return a []byte,
	// or implement io.Reader?).
	//
	// Returning a []byte to the caller either requires that we store the
	// data to send contiguously (which we don't), allocate a temporary buffer
	// and copy into it (inefficient), or return less data than we have available
	// (requires complexity to avoid unnecessarily breaking data across frames).
	//
	// Accepting a []byte from the caller (io.Reader) makes packet construction
	// difficult. Since CRYPTO data is encoded with a varint length prefix, the
	// location of the data depends on the length of the data. (We could hardcode
	// a 2-byte length, of course.)
	//
	// Instead, we tell the caller how much data is, the caller figures out where
	// to put it (and possibly decides that it doesn't have space for this data
	// in the packet after all), and the caller then makes a separate call to
	// copy the data it wants into position.
	func (s *cryptoStream) dataToSend(pto bool, f func(off, size int64) (sent int64)) {
	for {
	off, size := dataToSend(s.out, s.outunsent, s.outacked, pto)
	if size == 0 {
	return
	}
	n := f(off, size)
	if n == 0 \|\| pto {
	return
	}
	}
	}

	// sendData fills b with data to send to the peer, starting at off,
	// and marks the data as sent. The caller must have already ascertained
	// that there is data to send in this region using dataToSend.
	func (s *cryptoStream) sendData(off int64, b []byte) {
	s.out.copy(off, b)
	s.outunsent.sub(off, off+int64(len(b)))
	}