package ray import ( "context" "io" "sync" "time" "v2ray.com/core/common" "v2ray.com/core/common/buf" "v2ray.com/core/common/platform" "v2ray.com/core/common/signal" ) // NewRay creates a new Ray for direct traffic transport. func NewRay(ctx context.Context) Ray { return &directRay{ Input: NewStream(ctx), Output: NewStream(ctx), } } type directRay struct { Input *Stream Output *Stream } func (v *directRay) OutboundInput() InputStream { return v.Input } func (v *directRay) OutboundOutput() OutputStream { return v.Output } func (v *directRay) InboundInput() OutputStream { return v.Input } func (v *directRay) InboundOutput() InputStream { return v.Output } var streamSizeLimit uint64 = 10 * 1024 * 1024 func init() { const raySizeEnvKey = "v2ray.ray.buffer.size" size := platform.EnvFlag{ Name: raySizeEnvKey, AltName: platform.NormalizeEnvName(raySizeEnvKey), }.GetValueAsInt(10) streamSizeLimit = uint64(size) * 1024 * 1024 } // Stream is a sequential container for data in bytes. type Stream struct { access sync.RWMutex data buf.MultiBuffer size uint64 ctx context.Context readSignal *signal.Notifier writeSignal *signal.Notifier close bool err bool } // NewStream creates a new Stream. func NewStream(ctx context.Context) *Stream { return &Stream{ ctx: ctx, readSignal: signal.NewNotifier(), writeSignal: signal.NewNotifier(), size: 0, } } func (s *Stream) getData() (buf.MultiBuffer, error) { s.access.Lock() defer s.access.Unlock() if s.data != nil { mb := s.data s.data = nil s.size = 0 return mb, nil } if s.close { return nil, io.EOF } if s.err { return nil, io.ErrClosedPipe } return nil, nil } // Peek fills in the given buffer with data from head of the Stream. func (s *Stream) Peek(b *buf.Buffer) { s.access.RLock() defer s.access.RUnlock() common.Must(b.Reset(func(data []byte) (int, error) { return s.data.Copy(data), nil })) } // ReadMultiBuffer reads data from the Stream. func (s *Stream) ReadMultiBuffer() (buf.MultiBuffer, error) { for { mb, err := s.getData() if err != nil { return nil, err } if mb != nil { s.readSignal.Signal() return mb, nil } select { case <-s.ctx.Done(): return nil, io.EOF case <-s.writeSignal.Wait(): } } } // ReadTimeout reads from the Stream with a specified timeout. func (s *Stream) ReadTimeout(timeout time.Duration) (buf.MultiBuffer, error) { for { mb, err := s.getData() if err != nil { return nil, err } if mb != nil { s.readSignal.Signal() return mb, nil } select { case <-s.ctx.Done(): return nil, io.EOF case <-time.After(timeout): return nil, buf.ErrReadTimeout case <-s.writeSignal.Wait(): } } } // Size returns the number of bytes hold in the Stream. func (s *Stream) Size() uint64 { s.access.RLock() defer s.access.RUnlock() return s.size } // waitForStreamSize waits until the Stream has room for more data, or any error happens. func (s *Stream) waitForStreamSize() error { if streamSizeLimit == 0 { return nil } for s.Size() >= streamSizeLimit { select { case <-s.ctx.Done(): return io.ErrClosedPipe case <-s.readSignal.Wait(): if s.err || s.close { return io.ErrClosedPipe } } } return nil } // WriteMultiBuffer writes more data into the Stream. func (s *Stream) WriteMultiBuffer(data buf.MultiBuffer) error { if data.IsEmpty() { return nil } if err := s.waitForStreamSize(); err != nil { data.Release() return err } s.access.Lock() defer s.access.Unlock() if s.err || s.close { data.Release() return io.ErrClosedPipe } if s.data == nil { s.data = buf.NewMultiBufferCap(128) } s.data.AppendMulti(data) s.size += uint64(data.Len()) s.writeSignal.Signal() return nil } // Close closes the stream for writing. Read() still works until EOF. func (s *Stream) Close() { s.access.Lock() s.close = true s.readSignal.Signal() s.writeSignal.Signal() s.access.Unlock() } // CloseError closes the Stream with error. Read() will return an error afterwards. func (s *Stream) CloseError() { s.access.Lock() s.err = true if s.data != nil { s.data.Release() s.data = nil s.size = 0 } s.readSignal.Signal() s.writeSignal.Signal() s.access.Unlock() }