package pixelflut import ( "bufio" "encoding/hex" "image" "image/color" "log" "math/rand" "net" "sync" "github.com/SpeckiJ/Hochwasser/render" ) // Flut asynchronously sends the given image to pixelflut server at `address` // using `conns` connections. Pixels are sent column wise, unless `shuffle` // is set. Stops when stop is closed. // @cleanup: use FlutTask{} as arg func Flut(img *image.NRGBA, position image.Point, shuffle, rgbsplit, randoffset, recreateConns bool, address string, conns int, stop chan bool, wg *sync.WaitGroup) { var cmds commands if rgbsplit { // do a RGB split of white imgmod := render.ImgColorFilter(img, color.NRGBA{0xff, 0xff, 0xff, 0xff}, color.NRGBA{0xff, 0, 0, 0xff}) cmds = append(cmds, commandsFromImage(imgmod, image.Pt(position.X-10, position.Y-10))...) imgmod = render.ImgColorFilter(img, color.NRGBA{0xff, 0xff, 0xff, 0xff}, color.NRGBA{0, 0xff, 0, 0xff}) cmds = append(cmds, commandsFromImage(imgmod, image.Pt(position.X+10, position.Y))...) imgmod = render.ImgColorFilter(img, color.NRGBA{0xff, 0xff, 0xff, 0xff}, color.NRGBA{0, 0, 0xff, 0xff}) cmds = append(cmds, commandsFromImage(imgmod, image.Pt(position.X-10, position.Y+10))...) cmds = append(cmds, commandsFromImage(img, position)...) } else { cmds = commandsFromImage(img, position) } if shuffle { cmds.Shuffle() } var messages [][]byte var maxX, maxY int if randoffset { maxX, maxY = CanvasSize(address) messages = cmds.Chunk(1) // each connection should send the full img } else { messages = cmds.Chunk(conns) } bombWg := sync.WaitGroup{} for i := 0; i < conns; i++ { msg := messages[0] if len(messages) > i { msg = messages[i] } bombWg.Add(1) if randoffset { msg = append(OffsetCmd( rand.Intn(maxX-img.Bounds().Canon().Dx()), rand.Intn(maxY-img.Bounds().Canon().Dy()), ), msg...) } go bombAddress(msg, address, stop, &bombWg) } bombWg.Wait() if wg != nil { wg.Done() } } // CanvasSize returns the size of the canvas as returned by the server func CanvasSize(address string) (int, int) { conn, err := net.Dial("tcp", address) if err != nil { log.Fatal(err) } defer conn.Close() conn.Write([]byte("SIZE\n")) reader := bufio.NewReader(conn) res, err := reader.ReadSlice('\n') if err != nil { log.Fatal(err) } return parseXY(res[5:]) } // FetchImage asynchronously uses `conns` to fetch pixels within `bounds` from // a pixelflut server at `address`, and writes them into the returned Image. func FetchImage(bounds image.Rectangle, address string, conns int, stop chan bool) (img *image.NRGBA) { img = image.NewNRGBA(bounds) cmds := cmdsFetchImage(bounds).Chunk(conns) for i := 0; i < conns; i++ { conn, err := net.Dial("tcp", address) if err != nil { log.Fatal(err) } go readPixels(img, conn, stop) go bombConn(cmds[i], conn, stop) } return img } func readPixels(target *image.NRGBA, conn net.Conn, stop chan bool) { reader := bufio.NewReader(conn) col := make([]byte, 3) for { select { case <-stop: return default: res, err := reader.ReadSlice('\n') if err != nil { log.Fatal(err) } // parse response ("PX \n") colorStart := len(res) - 7 x, y := parseXY(res[3 : colorStart-1]) hex.Decode(col, res[colorStart:len(res)-1]) target.SetNRGBA(x, y, color.NRGBA{col[0], col[1], col[2], 255}) } } } func parseXY(xy []byte) (int, int) { last := len(xy) - 1 yStart := last - 1 // y is at least one char long for ; yStart >= 0; yStart-- { if xy[yStart] == ' ' { break } } x := asciiToInt(xy[:yStart]) y := asciiToInt(xy[yStart+1 : last]) return x, y } func asciiToInt(buf []byte) (v int) { for _, c := range buf { v = v*10 + int(c-'0') } return v }