package vnc import ( "encoding/binary" "fmt" "image" ) //var _ draw.Drawer = (*ServerConn)(nil) //var _ draw.Image = (*ServerConn)(nil) // Color represents a single color in a color map. type Color struct { pf *PixelFormat cm *ColorMap cmIndex uint32 // Only valid if pf.TrueColor is false. R, G, B uint16 } type ColorMap [256]Color // NewColor returns a new Color object. func NewColor(pf *PixelFormat, cm *ColorMap) *Color { return &Color{ pf: pf, cm: cm, } } // Rectangle represents a rectangle of pixel data. type Rectangle struct { X, Y uint16 Width, Height uint16 EncType EncodingType Enc Encoding } func NewRectangle() *Rectangle { return &Rectangle{} } // Marshal implements the Marshaler interface. func (c *Color) Marshal() ([]byte, error) { order := c.pf.order() pixel := c.cmIndex if c.pf.TrueColor == 1 { pixel = uint32(c.R) << c.pf.RedShift pixel |= uint32(c.G) << c.pf.GreenShift pixel |= uint32(c.B) << c.pf.BlueShift } var bytes []byte switch c.pf.BPP { case 8: bytes = make([]byte, 1) bytes[0] = byte(pixel) case 16: bytes = make([]byte, 2) order.PutUint16(bytes, uint16(pixel)) case 32: bytes = make([]byte, 4) order.PutUint32(bytes, pixel) } return bytes, nil } // Unmarshal implements the Unmarshaler interface. func (c *Color) Unmarshal(data []byte) error { if len(data) == 0 { return nil } order := c.pf.order() var pixel uint32 switch c.pf.BPP { case 8: pixel = uint32(data[0]) case 16: pixel = uint32(order.Uint16(data)) case 32: pixel = order.Uint32(data) } if c.pf.TrueColor == 1 { c.R = uint16((pixel >> c.pf.RedShift) & uint32(c.pf.RedMax)) c.G = uint16((pixel >> c.pf.GreenShift) & uint32(c.pf.GreenMax)) c.B = uint16((pixel >> c.pf.BlueShift) & uint32(c.pf.BlueMax)) } else { *c = c.cm[pixel] c.cmIndex = pixel } return nil } func colorsToImage(x, y, width, height uint16, colors []Color) *image.RGBA64 { rect := image.Rect(int(x), int(y), int(x+width), int(y+height)) rgba := image.NewRGBA64(rect) a := uint16(1) for i, color := range colors { rgba.Pix[4*i+0] = uint8(color.R >> 8) rgba.Pix[4*i+1] = uint8(color.R) rgba.Pix[4*i+2] = uint8(color.G >> 8) rgba.Pix[4*i+3] = uint8(color.G) rgba.Pix[4*i+4] = uint8(color.B >> 8) rgba.Pix[4*i+5] = uint8(color.B) rgba.Pix[4*i+6] = uint8(a >> 8) rgba.Pix[4*i+7] = uint8(a) } return rgba } // Marshal implements the Marshaler interface. func (r *Rectangle) Write(c Conn) error { if err := binary.Write(c, binary.BigEndian, r.X); err != nil { return err } if err := binary.Write(c, binary.BigEndian, r.Y); err != nil { return err } if err := binary.Write(c, binary.BigEndian, r.Width); err != nil { return err } if err := binary.Write(c, binary.BigEndian, r.Height); err != nil { return err } if err := binary.Write(c, binary.BigEndian, r.EncType); err != nil { return err } if err := r.Enc.Write(c, r); err != nil { return err } return c.Flush() } func (r *Rectangle) Read(c Conn) error { fmt.Printf("qqq\n") var err error if err = binary.Read(c, binary.BigEndian, &r.X); err != nil { return err } if err = binary.Read(c, binary.BigEndian, &r.Y); err != nil { return err } if err = binary.Read(c, binary.BigEndian, &r.Width); err != nil { return err } if err = binary.Read(c, binary.BigEndian, &r.Height); err != nil { return err } if err = binary.Read(c, binary.BigEndian, &r.EncType); err != nil { return err } fmt.Printf("rrrr %#+v\n", r) switch r.EncType { case EncRaw: r.Enc = &RawEncoding{} } return r.Enc.Read(c, r) } // Area returns the total area in pixels of the Rectangle. func (r *Rectangle) Area() int { return int(r.Width) * int(r.Height) }