func main() { _, err := gc.Init() if err != nil { log.Fatal(err) } defer gc.End() // create a new pad of 50 rows and 200 columns... var pad *gc.Pad pad, err = gc.NewPad(50, 200) if err != nil { log.Fatal(err) } // ...and fill it with some characters for x := 0; x < 50; x++ { pad.MovePrint(x, x, "This is a pad.") } // Refresh the pad to show only a portion of the pad. Understanding // what these coordinates mean can be a bit tricky. The first two // coordinates are the position in the pad, in this case 0,5 (remember // the coordinates in ncurses are y,x). The second set of numbers are the // coordinates on the screen on which to display the content, so row 5, // column 10. The last set of numbers tell how high and how wide the // rectangle to displayed should be, in this case 15 rows long and 25 // columns wide. pad.Refresh(0, 5, 5, 10, 15, 25) pad.GetChar() }
func genStarfield(pl, pc int) *gc.Pad { pad, err := gc.NewPad(pl, pc) if err != nil { log.Fatal(err) } stars := int(float64(pc*pl) * density) planets := int(float64(pc*pl) * planet_density) for i := 0; i < stars; i++ { y, x := rand.Intn(pl), rand.Intn(pc) c := int16(rand.Intn(4) + 1) pad.AttrOn(gc.A_BOLD | gc.ColorPair(c)) pad.MovePrint(y, x, ".") pad.AttrOff(gc.A_BOLD | gc.ColorPair(c)) } for i := 0; i < planets; i++ { y, x := rand.Intn(pl), rand.Intn(pc) c := int16(rand.Intn(2) + 5) pad.ColorOn(c) if i%2 == 0 { pad.MoveAddChar(y, x, 'O') } pad.MoveAddChar(y, x, 'o') pad.ColorOff(c) } return pad }