// PhyiscalHeads returns the list of heads in a physical ordering.
// Namely, left to right then top to bottom. (Defined by (X, Y).)
// Xinerama must have been initialized, otherwise the xinerama.QueryScreens
// request will panic.
// PhysicalHeads also checks to make sure each rectangle has a unique (x, y)
// tuple, so as not to return the geometry of cloned displays.
// (At present moment, xgbutil initializes Xinerama automatically during
// initial connection.)
func PhysicalHeads(xu *xgbutil.XUtil) (Heads, error) {
xinfo, err := xinerama.QueryScreens(xu.Conn()).Reply()
if err != nil {
return nil, err
}
hds := make(Heads, 0)
for _, info := range xinfo.ScreenInfo {
head := xrect.New(int(info.XOrg), int(info.YOrg),
int(info.Width), int(info.Height))
// Maybe Xinerama is enabled, but we have cloned displays...
unique := true
for _, h := range hds {
if h.X() == head.X() && h.Y() == head.Y() {
unique = false
break
}
}
if unique {
hds = append(hds, head)
}
}
sort.Sort(hds)
return hds, nil
}
func (ms Monitors) Init(e *Euclid, x XHandle) (bool, bool) {
var rr, xn bool
c := x.Conn()
err := randr.Init(c)
if err == nil && ms.Update(e, x, false, false, false) {
rr = true
randr.SelectInputChecked(c, x.Root(), randr.NotifyMaskScreenChange)
} else {
rr = false
err = xinerama.Init(c)
if err == nil {
xia, err := xinerama.IsActive(c).Reply()
if xia != nil && err == nil {
xn = true
xsq, _ := xinerama.QueryScreens(c).Reply()
xsi := xsq.ScreenInfo
for i := 0; i < len(xsi); i++ {
info := xsi[i]
rect := xproto.Rectangle{info.XOrg, info.YOrg, info.Width, info.Height}
ms.Add(e, x, rect)
}
} else {
s := x.Screen()
rect := xproto.Rectangle{0, 0, s.WidthInPixels, s.HeightInPixels}
ms.Add(e, x, rect)
}
}
}
return rr, xn
}
func initScreens() {
xine, err := xinerama.QueryScreens(xConn).Reply()
if err != nil {
log.Fatal(err)
}
if len(xine.ScreenInfo) > 0 {
screens = make([]*screen, len(xine.ScreenInfo))
for i, si := range xine.ScreenInfo {
screens[i] = &screen{
rect: xp.Rectangle{
X: si.XOrg,
Y: si.YOrg,
Width: si.Width - 1,
Height: si.Height - 1,
},
}
}
} else {
screens = make([]*screen, 1)
screens[0] = &screen{
rect: xp.Rectangle{
X: 0,
Y: 0,
Width: desktopWidth - 1,
Height: desktopHeight - 1,
},
}
}
for _, s := range screens {
k := newWorkspace(s.rect, dummyWorkspace.link[prev])
s.workspace, k.screen = k, s
}
}
func main() {
X, err := xgb.NewConn()
if err != nil {
log.Fatal(err)
}
// Initialize the Xinerama extension.
// The appropriate 'Init' function must be run for *every*
// extension before any of its requests can be used.
err = xinerama.Init(X)
if err != nil {
log.Fatal(err)
}
// Issue a request to get the screen information.
reply, err := xinerama.QueryScreens(X).Reply()
if err != nil {
log.Fatal(err)
}
// reply.Number is the number of active heads, while reply.ScreenInfo
// is a slice of XineramaScreenInfo containing the rectangle geometry
// of each head.
fmt.Printf("Number of heads: %d\n", reply.Number)
for i, screen := range reply.ScreenInfo {
fmt.Printf("%d :: X: %d, Y: %d, Width: %d, Height: %d\n",
i, screen.XOrg, screen.YOrg, screen.Width, screen.Height)
}
}
func Load(c *xgb.Conn) error {
err := xinerama.Init(c)
if err != nil {
return err
}
reply, err := xinerama.QueryScreens(c).Reply()
if err != nil {
return err
}
count = reply.Number
for _, scr := range reply.ScreenInfo {
sizes = append(sizes, types.Geometry{int32(scr.XOrg), int32(scr.YOrg),
int32(scr.Width), int32(scr.Height)})
}
return nil
}
