// Package xinput is the X client API for the XInputExtension extension. package xinput // This file is automatically generated from xinput.xml. Edit at your peril! import ( "github.com/BurntSushi/xgb" "github.com/BurntSushi/xgb/xproto" ) // Init must be called before using the XInputExtension extension. func Init(c *xgb.Conn) error { reply, err := xproto.QueryExtension(c, 15, "XInputExtension").Reply() switch { case err != nil: return err case !reply.Present: return xgb.Errorf("No extension named XInputExtension could be found on on the server.") } xgb.ExtLock.Lock() c.Extensions["XInputExtension"] = reply.MajorOpcode for evNum, fun := range xgb.NewExtEventFuncs["XInputExtension"] { xgb.NewEventFuncs[int(reply.FirstEvent)+evNum] = fun } for errNum, fun := range xgb.NewExtErrorFuncs["XInputExtension"] { xgb.NewErrorFuncs[int(reply.FirstError)+errNum] = fun } xgb.ExtLock.Unlock() return nil } func init() { xgb.NewExtEventFuncs["XInputExtension"] = make(map[int]xgb.NewEventFun) xgb.NewExtErrorFuncs["XInputExtension"] = make(map[int]xgb.NewErrorFun) } type AxisInfo struct { Resolution uint32 Minimum int32 Maximum int32 } // AxisInfoRead reads a byte slice into a AxisInfo value. func AxisInfoRead(buf []byte, v *AxisInfo) int { b := 0 v.Resolution = xgb.Get32(buf[b:]) b += 4 v.Minimum = int32(xgb.Get32(buf[b:])) b += 4 v.Maximum = int32(xgb.Get32(buf[b:])) b += 4 return b } // AxisInfoReadList reads a byte slice into a list of AxisInfo values. func AxisInfoReadList(buf []byte, dest []AxisInfo) int { b := 0 for i := 0; i < len(dest); i++ { dest[i] = AxisInfo{} b += AxisInfoRead(buf[b:], &dest[i]) } return xgb.Pad(b) } // Bytes writes a AxisInfo value to a byte slice. func (v AxisInfo) Bytes() []byte { buf := make([]byte, 12) b := 0 xgb.Put32(buf[b:], v.Resolution) b += 4 xgb.Put32(buf[b:], uint32(v.Minimum)) b += 4 xgb.Put32(buf[b:], uint32(v.Maximum)) b += 4 return buf } // AxisInfoListBytes writes a list of AxisInfo values to a byte slice. func AxisInfoListBytes(buf []byte, list []AxisInfo) int { b := 0 var structBytes []byte for _, item := range list { structBytes = item.Bytes() copy(buf[b:], structBytes) b += len(structBytes) } return xgb.Pad(b) } type BellFeedbackCtl struct { ClassId byte Id byte Len uint16 Percent int8 // padding: 3 bytes Pitch int16 Duration int16 } // BellFeedbackCtlRead reads a byte slice into a BellFeedbackCtl value. func BellFeedbackCtlRead(buf []byte, v *BellFeedbackCtl) int { b := 0 v.ClassId = buf[b] b += 1 v.Id = buf[b] b += 1 v.Len = xgb.Get16(buf[b:]) b += 2 v.Percent = int8(buf[b]) b += 1 b += 3 // padding v.Pitch = int16(xgb.Get16(buf[b:])) b += 2 v.Duration = int16(xgb.Get16(buf[b:])) b += 2 return b } // BellFeedbackCtlReadList reads a byte slice into a list of BellFeedbackCtl values. func BellFeedbackCtlReadList(buf []byte, dest []BellFeedbackCtl) int { b := 0 for i := 0; i < len(dest); i++ { dest[i] = BellFeedbackCtl{} b += BellFeedbackCtlRead(buf[b:], &dest[i]) } return xgb.Pad(b) } // Bytes writes a BellFeedbackCtl value to a byte slice. func (v BellFeedbackCtl) Bytes() []byte { buf := make([]byte, 12) b := 0 buf[b] = v.ClassId b += 1 buf[b] = v.Id b += 1 xgb.Put16(buf[b:], v.Len) b += 2 buf[b] = byte(v.Percent) b += 1 b += 3 // padding xgb.Put16(buf[b:], uint16(v.Pitch)) b += 2 xgb.Put16(buf[b:], uint16(v.Duration)) b += 2 return buf } // BellFeedbackCtlListBytes writes a list of BellFeedbackCtl values to a byte slice. func BellFeedbackCtlListBytes(buf []byte, list []BellFeedbackCtl) int { b := 0 var structBytes []byte for _, item := range list { structBytes = item.Bytes() copy(buf[b:], structBytes) b += len(structBytes) } return xgb.Pad(b) } type BellFeedbackState struct { ClassId byte Id byte Len uint16 Percent byte // padding: 3 bytes Pitch uint16 Duration uint16 } // BellFeedbackStateRead reads a byte slice into a BellFeedbackState value. func BellFeedbackStateRead(buf []byte, v *BellFeedbackState) int { b := 0 v.ClassId = buf[b] b += 1 v.Id = buf[b] b += 1 v.Len = xgb.Get16(buf[b:]) b += 2 v.Percent = buf[b] b += 1 b += 3 // padding v.Pitch = xgb.Get16(buf[b:]) b += 2 v.Duration = xgb.Get16(buf[b:]) b += 2 return b } // BellFeedbackStateReadList reads a byte slice into a list of BellFeedbackState values. func BellFeedbackStateReadList(buf []byte, dest []BellFeedbackState) int { b := 0 for i := 0; i < len(dest); i++ { dest[i] = BellFeedbackState{} b += BellFeedbackStateRead(buf[b:], &dest[i]) } return xgb.Pad(b) } // Bytes writes a BellFeedbackState value to a byte slice. func (v BellFeedbackState) Bytes() []byte { buf := make([]byte, 12) b := 0 buf[b] = v.ClassId b += 1 buf[b] = v.Id b += 1 xgb.Put16(buf[b:], v.Len) b += 2 buf[b] = v.Percent b += 1 b += 3 // padding xgb.Put16(buf[b:], v.Pitch) b += 2 xgb.Put16(buf[b:], v.Duration) b += 2 return buf } // BellFeedbackStateListBytes writes a list of BellFeedbackState values to a byte slice. func BellFeedbackStateListBytes(buf []byte, list []BellFeedbackState) int { b := 0 var structBytes []byte for _, item := range list { structBytes = item.Bytes() copy(buf[b:], structBytes) b += len(structBytes) } return xgb.Pad(b) } type ButtonInfo struct { ClassId byte Len byte NumButtons uint16 } // ButtonInfoRead reads a byte slice into a ButtonInfo value. func ButtonInfoRead(buf []byte, v *ButtonInfo) int { b := 0 v.ClassId = buf[b] b += 1 v.Len = buf[b] b += 1 v.NumButtons = xgb.Get16(buf[b:]) b += 2 return b } // ButtonInfoReadList reads a byte slice into a list of ButtonInfo values. func ButtonInfoReadList(buf []byte, dest []ButtonInfo) int { b := 0 for i := 0; i < len(dest); i++ { dest[i] = ButtonInfo{} b += ButtonInfoRead(buf[b:], &dest[i]) } return xgb.Pad(b) } // Bytes writes a ButtonInfo value to a byte slice. func (v ButtonInfo) Bytes() []byte { buf := make([]byte, 4) b := 0 buf[b] = v.ClassId b += 1 buf[b] = v.Len b += 1 xgb.Put16(buf[b:], v.NumButtons) b += 2 return buf } // ButtonInfoListBytes writes a list of ButtonInfo values to a byte slice. func ButtonInfoListBytes(buf []byte, list []ButtonInfo) int { b := 0 var structBytes []byte for _, item := range list { structBytes = item.Bytes() copy(buf[b:], structBytes) b += len(structBytes) } return xgb.Pad(b) } type ButtonState struct { ClassId byte Len byte NumButtons byte // padding: 1 bytes Buttons []byte // size: 32 } // ButtonStateRead reads a byte slice into a ButtonState value. func ButtonStateRead(buf []byte, v *ButtonState) int { b := 0 v.ClassId = buf[b] b += 1 v.Len = buf[b] b += 1 v.NumButtons = buf[b] b += 1 b += 1 // padding v.Buttons = make([]byte, 32) copy(v.Buttons[:32], buf[b:]) b += xgb.Pad(int(32)) return b } // ButtonStateReadList reads a byte slice into a list of ButtonState values. func ButtonStateReadList(buf []byte, dest []ButtonState) int { b := 0 for i := 0; i < len(dest); i++ { dest[i] = ButtonState{} b += ButtonStateRead(buf[b:], &dest[i]) } return xgb.Pad(b) } // Bytes writes a ButtonState value to a byte slice. func (v ButtonState) Bytes() []byte { buf := make([]byte, 36) b := 0 buf[b] = v.ClassId b += 1 buf[b] = v.Len b += 1 buf[b] = v.NumButtons b += 1 b += 1 // padding copy(buf[b:], v.Buttons[:32]) b += xgb.Pad(int(32)) return buf } // ButtonStateListBytes writes a list of ButtonState values to a byte slice. func ButtonStateListBytes(buf []byte, list []ButtonState) int { b := 0 var structBytes []byte for _, item := range list { structBytes = item.Bytes() copy(buf[b:], structBytes) b += len(structBytes) } return xgb.Pad(b) } // ButtonStateListSize computes the size (bytes) of a list of ButtonState values. func ButtonStateListSize(list []ButtonState) int { size := 0 for _ = range list { size += 36 } return size } // ChangeDeviceNotify is the event number for a ChangeDeviceNotifyEvent. const ChangeDeviceNotify = 12 type ChangeDeviceNotifyEvent struct { Sequence uint16 DeviceId byte Time xproto.Timestamp Request byte // padding: 23 bytes } // ChangeDeviceNotifyEventNew constructs a ChangeDeviceNotifyEvent value that implements xgb.Event from a byte slice. func ChangeDeviceNotifyEventNew(buf []byte) xgb.Event { v := ChangeDeviceNotifyEvent{} b := 1 // don't read event number v.DeviceId = buf[b] b += 1 v.Sequence = xgb.Get16(buf[b:]) b += 2 v.Time = xproto.Timestamp(xgb.Get32(buf[b:])) b += 4 v.Request = buf[b] b += 1 b += 23 // padding return v } // Bytes writes a ChangeDeviceNotifyEvent value to a byte slice. func (v ChangeDeviceNotifyEvent) Bytes() []byte { buf := make([]byte, 32) b := 0 // write event number buf[b] = 12 b += 1 buf[b] = v.DeviceId b += 1 b += 2 // skip sequence number xgb.Put32(buf[b:], uint32(v.Time)) b += 4 buf[b] = v.Request b += 1 b += 23 // padding return buf } // SequenceId returns the sequence id attached to the ChangeDeviceNotify event. // Events without a sequence number (KeymapNotify) return 0. // This is mostly used internally. func (v ChangeDeviceNotifyEvent) SequenceId() uint16 { return v.Sequence } // String is a rudimentary string representation of ChangeDeviceNotifyEvent. func (v ChangeDeviceNotifyEvent) String() string { fieldVals := make([]string, 0, 4) fieldVals = append(fieldVals, xgb.Sprintf("Sequence: %d", v.Sequence)) fieldVals = append(fieldVals, xgb.Sprintf("DeviceId: %d", v.DeviceId)) fieldVals = append(fieldVals, xgb.Sprintf("Time: %d", v.Time)) fieldVals = append(fieldVals, xgb.Sprintf("Request: %d", v.Request)) return "ChangeDeviceNotify {" + xgb.StringsJoin(fieldVals, ", ") + "}" } func init() { xgb.NewExtEventFuncs["XInputExtension"][12] = ChangeDeviceNotifyEventNew } // BadClass is the error number for a BadClass. const BadClass = 4 type ClassError struct { Sequence uint16 NiceName string } // ClassErrorNew constructs a ClassError value that implements xgb.Error from a byte slice. func ClassErrorNew(buf []byte) xgb.Error { v := ClassError{} v.NiceName = "Class" b := 1 // skip error determinant b += 1 // don't read error number v.Sequence = xgb.Get16(buf[b:]) b += 2 return v } // SequenceId returns the sequence id attached to the BadClass error. // This is mostly used internally. func (err ClassError) SequenceId() uint16 { return err.Sequence } // BadId returns the 'BadValue' number if one exists for the BadClass error. If no bad value exists, 0 is returned. func (err ClassError) BadId() uint32 { return 0 } // Error returns a rudimentary string representation of the BadClass error. func (err ClassError) Error() string { fieldVals := make([]string, 0, 0) fieldVals = append(fieldVals, "NiceName: "+err.NiceName) fieldVals = append(fieldVals, xgb.Sprintf("Sequence: %d", err.Sequence)) return "BadClass {" + xgb.StringsJoin(fieldVals, ", ") + "}" } func init() { xgb.NewExtErrorFuncs["XInputExtension"][4] = ClassErrorNew } // BadDevice is the error number for a BadDevice. const BadDevice = 0 type DeviceError struct { Sequence uint16 NiceName string } // DeviceErrorNew constructs a DeviceError value that implements xgb.Error from a byte slice. func DeviceErrorNew(buf []byte) xgb.Error { v := DeviceError{} v.NiceName = "Device" b := 1 // skip error determinant b += 1 // don't read error number v.Sequence = xgb.Get16(buf[b:]) b += 2 return v } // SequenceId returns the sequence id attached to the BadDevice error. // This is mostly used internally. func (err DeviceError) SequenceId() uint16 { return err.Sequence } // BadId returns the 'BadValue' number if one exists for the BadDevice error. If no bad value exists, 0 is returned. func (err DeviceError) BadId() uint32 { return 0 } // Error returns a rudimentary string representation of the BadDevice error. func (err DeviceError) Error() string { fieldVals := make([]string, 0, 0) fieldVals = append(fieldVals, "NiceName: "+err.NiceName) fieldVals = append(fieldVals, xgb.Sprintf("Sequence: %d", err.Sequence)) return "BadDevice {" + xgb.StringsJoin(fieldVals, ", ") + "}" } func init() { xgb.NewExtErrorFuncs["XInputExtension"][0] = DeviceErrorNew } type DeviceAbsAreaCtrl struct { ControlId uint16 Len uint16 OffsetX uint32 OffsetY uint32 Width int32 Height int32 Screen int32 Following uint32 } // DeviceAbsAreaCtrlRead reads a byte slice into a DeviceAbsAreaCtrl value. func DeviceAbsAreaCtrlRead(buf []byte, v *DeviceAbsAreaCtrl) int { b := 0 v.ControlId = xgb.Get16(buf[b:]) b += 2 v.Len = xgb.Get16(buf[b:]) b += 2 v.OffsetX = xgb.Get32(buf[b:]) b += 4 v.OffsetY = xgb.Get32(buf[b:]) b += 4 v.Width = int32(xgb.Get32(buf[b:])) b += 4 v.Height = int32(xgb.Get32(buf[b:])) b += 4 v.Screen = int32(xgb.Get32(buf[b:])) b += 4 v.Following = xgb.Get32(buf[b:]) b += 4 return b } // DeviceAbsAreaCtrlReadList reads a byte slice into a list of DeviceAbsAreaCtrl values. func DeviceAbsAreaCtrlReadList(buf []byte, dest []DeviceAbsAreaCtrl) int { b := 0 for i := 0; i < len(dest); i++ { dest[i] = DeviceAbsAreaCtrl{} b += DeviceAbsAreaCtrlRead(buf[b:], &dest[i]) } return xgb.Pad(b) } // Bytes writes a DeviceAbsAreaCtrl value to a byte slice. func (v DeviceAbsAreaCtrl) Bytes() []byte { buf := make([]byte, 28) b := 0 xgb.Put16(buf[b:], v.ControlId) b += 2 xgb.Put16(buf[b:], v.Len) b += 2 xgb.Put32(buf[b:], v.OffsetX) b += 4 xgb.Put32(buf[b:], v.OffsetY) b += 4 xgb.Put32(buf[b:], uint32(v.Width)) b += 4 xgb.Put32(buf[b:], uint32(v.Height)) b += 4 xgb.Put32(buf[b:], uint32(v.Screen)) b += 4 xgb.Put32(buf[b:], v.Following) b += 4 return buf } // DeviceAbsAreaCtrlListBytes writes a list of DeviceAbsAreaCtrl values to a byte slice. func DeviceAbsAreaCtrlListBytes(buf []byte, list []DeviceAbsAreaCtrl) int { b := 0 var structBytes []byte for _, item := range list { structBytes = item.Bytes() copy(buf[b:], structBytes) b += len(structBytes) } return xgb.Pad(b) } type DeviceAbsAreaState struct { ControlId uint16 Len uint16 OffsetX uint32 OffsetY uint32 Width uint32 Height uint32 Screen uint32 Following uint32 } // DeviceAbsAreaStateRead reads a byte slice into a DeviceAbsAreaState value. func DeviceAbsAreaStateRead(buf []byte, v *DeviceAbsAreaState) int { b := 0 v.ControlId = xgb.Get16(buf[b:]) b += 2 v.Len = xgb.Get16(buf[b:]) b += 2 v.OffsetX = xgb.Get32(buf[b:]) b += 4 v.OffsetY = xgb.Get32(buf[b:]) b += 4 v.Width = xgb.Get32(buf[b:]) b += 4 v.Height = xgb.Get32(buf[b:]) b += 4 v.Screen = xgb.Get32(buf[b:]) b += 4 v.Following = xgb.Get32(buf[b:]) b += 4 return b } // DeviceAbsAreaStateReadList reads a byte slice into a list of DeviceAbsAreaState values. func DeviceAbsAreaStateReadList(buf []byte, dest []DeviceAbsAreaState) int { b := 0 for i := 0; i < len(dest); i++ { dest[i] = DeviceAbsAreaState{} b += DeviceAbsAreaStateRead(buf[b:], &dest[i]) } return xgb.Pad(b) } // Bytes writes a DeviceAbsAreaState value to a byte slice. func (v DeviceAbsAreaState) Bytes() []byte { buf := make([]byte, 28) b := 0 xgb.Put16(buf[b:], v.ControlId) b += 2 xgb.Put16(buf[b:], v.Len) b += 2 xgb.Put32(buf[b:], v.OffsetX) b += 4 xgb.Put32(buf[b:], v.OffsetY) b += 4 xgb.Put32(buf[b:], v.Width) b += 4 xgb.Put32(buf[b:], v.Height) b += 4 xgb.Put32(buf[b:], v.Screen) b += 4 xgb.Put32(buf[b:], v.Following) b += 4 return buf } // DeviceAbsAreaStateListBytes writes a list of DeviceAbsAreaState values to a byte slice. func DeviceAbsAreaStateListBytes(buf []byte, list []DeviceAbsAreaState) int { b := 0 var structBytes []byte for _, item := range list { structBytes = item.Bytes() copy(buf[b:], structBytes) b += len(structBytes) } return xgb.Pad(b) } type DeviceAbsCalibCtl struct { ControlId uint16 Len uint16 MinX int32 MaxX int32 MinY int32 MaxY int32 FlipX uint32 FlipY uint32 Rotation uint32 ButtonThreshold uint32 } // DeviceAbsCalibCtlRead reads a byte slice into a DeviceAbsCalibCtl value. func DeviceAbsCalibCtlRead(buf []byte, v *DeviceAbsCalibCtl) int { b := 0 v.ControlId = xgb.Get16(buf[b:]) b += 2 v.Len = xgb.Get16(buf[b:]) b += 2 v.MinX = int32(xgb.Get32(buf[b:])) b += 4 v.MaxX = int32(xgb.Get32(buf[b:])) b += 4 v.MinY = int32(xgb.Get32(buf[b:])) b += 4 v.MaxY = int32(xgb.Get32(buf[b:])) b += 4 v.FlipX = xgb.Get32(buf[b:]) b += 4 v.FlipY = xgb.Get32(buf[b:]) b += 4 v.Rotation = xgb.Get32(buf[b:]) b += 4 v.ButtonThreshold = xgb.Get32(buf[b:]) b += 4 return b } // DeviceAbsCalibCtlReadList reads a byte slice into a list of DeviceAbsCalibCtl values. func DeviceAbsCalibCtlReadList(buf []byte, dest []DeviceAbsCalibCtl) int { b := 0 for i := 0; i < len(dest); i++ { dest[i] = DeviceAbsCalibCtl{} b += DeviceAbsCalibCtlRead(buf[b:], &dest[i]) } return xgb.Pad(b) } // Bytes writes a DeviceAbsCalibCtl value to a byte slice. func (v DeviceAbsCalibCtl) Bytes() []byte { buf := make([]byte, 36) b := 0 xgb.Put16(buf[b:], v.ControlId) b += 2 xgb.Put16(buf[b:], v.Len) b += 2 xgb.Put32(buf[b:], uint32(v.MinX)) b += 4 xgb.Put32(buf[b:], uint32(v.MaxX)) b += 4 xgb.Put32(buf[b:], uint32(v.MinY)) b += 4 xgb.Put32(buf[b:], uint32(v.MaxY)) b += 4 xgb.Put32(buf[b:], v.FlipX) b += 4 xgb.Put32(buf[b:], v.FlipY) b += 4 xgb.Put32(buf[b:], v.Rotation) b += 4 xgb.Put32(buf[b:], v.ButtonThreshold) b += 4 return buf } // DeviceAbsCalibCtlListBytes writes a list of DeviceAbsCalibCtl values to a byte slice. func DeviceAbsCalibCtlListBytes(buf []byte, list []DeviceAbsCalibCtl) int { b := 0 var structBytes []byte for _, item := range list { structBytes = item.Bytes() copy(buf[b:], structBytes) b += len(structBytes) } return xgb.Pad(b) } type DeviceAbsCalibState struct { ControlId uint16 Len uint16 MinX int32 MaxX int32 MinY int32 MaxY int32 FlipX uint32 FlipY uint32 Rotation uint32 ButtonThreshold uint32 } // DeviceAbsCalibStateRead reads a byte slice into a DeviceAbsCalibState value. func DeviceAbsCalibStateRead(buf []byte, v *DeviceAbsCalibState) int { b := 0 v.ControlId = xgb.Get16(buf[b:]) b += 2 v.Len = xgb.Get16(buf[b:]) b += 2 v.MinX = int32(xgb.Get32(buf[b:])) b += 4 v.MaxX = int32(xgb.Get32(buf[b:])) b += 4 v.MinY = int32(xgb.Get32(buf[b:])) b += 4 v.MaxY = int32(xgb.Get32(buf[b:])) b += 4 v.FlipX = xgb.Get32(buf[b:]) b += 4 v.FlipY = xgb.Get32(buf[b:]) b += 4 v.Rotation = xgb.Get32(buf[b:]) b += 4 v.ButtonThreshold = xgb.Get32(buf[b:]) b += 4 return b } // DeviceAbsCalibStateReadList reads a byte slice into a list of DeviceAbsCalibState values. func DeviceAbsCalibStateReadList(buf []byte, dest []DeviceAbsCalibState) int { b := 0 for i := 0; i < len(dest); i++ { dest[i] = DeviceAbsCalibState{} b += DeviceAbsCalibStateRead(buf[b:], &dest[i]) } return xgb.Pad(b) } // Bytes writes a DeviceAbsCalibState value to a byte slice. func (v DeviceAbsCalibState) Bytes() []byte { buf := make([]byte, 36) b := 0 xgb.Put16(buf[b:], v.ControlId) b += 2 xgb.Put16(buf[b:], v.Len) b += 2 xgb.Put32(buf[b:], uint32(v.MinX)) b += 4 xgb.Put32(buf[b:], uint32(v.MaxX)) b += 4 xgb.Put32(buf[b:], uint32(v.MinY)) b += 4 xgb.Put32(buf[b:], uint32(v.MaxY)) b += 4 xgb.Put32(buf[b:], v.FlipX) b += 4 xgb.Put32(buf[b:], v.FlipY) b += 4 xgb.Put32(buf[b:], v.Rotation) b += 4 xgb.Put32(buf[b:], v.ButtonThreshold) b += 4 return buf } // DeviceAbsCalibStateListBytes writes a list of DeviceAbsCalibState values to a byte slice. func DeviceAbsCalibStateListBytes(buf []byte, list []DeviceAbsCalibState) int { b := 0 var structBytes []byte for _, item := range list { structBytes = item.Bytes() copy(buf[b:], structBytes) b += len(structBytes) } return xgb.Pad(b) } // BadDeviceBusy is the error number for a BadDeviceBusy. const BadDeviceBusy = 3 type DeviceBusyError struct { Sequence uint16 NiceName string } // DeviceBusyErrorNew constructs a DeviceBusyError value that implements xgb.Error from a byte slice. func DeviceBusyErrorNew(buf []byte) xgb.Error { v := DeviceBusyError{} v.NiceName = "DeviceBusy" b := 1 // skip error determinant b += 1 // don't read error number v.Sequence = xgb.Get16(buf[b:]) b += 2 return v } // SequenceId returns the sequence id attached to the BadDeviceBusy error. // This is mostly used internally. func (err DeviceBusyError) SequenceId() uint16 { return err.Sequence } // BadId returns the 'BadValue' number if one exists for the BadDeviceBusy error. If no bad value exists, 0 is returned. func (err DeviceBusyError) BadId() uint32 { return 0 } // Error returns a rudimentary string representation of the BadDeviceBusy error. func (err DeviceBusyError) Error() string { fieldVals := make([]string, 0, 0) fieldVals = append(fieldVals, "NiceName: "+err.NiceName) fieldVals = append(fieldVals, xgb.Sprintf("Sequence: %d", err.Sequence)) return "BadDeviceBusy {" + xgb.StringsJoin(fieldVals, ", ") + "}" } func init() { xgb.NewExtErrorFuncs["XInputExtension"][3] = DeviceBusyErrorNew } // DeviceButtonPress is the event number for a DeviceButtonPressEvent. const DeviceButtonPress = 3 type DeviceButtonPressEvent DeviceKeyPressEvent // DeviceButtonPressEventNew constructs a DeviceButtonPressEvent value that implements xgb.Event from a byte slice. func DeviceButtonPressEventNew(buf []byte) xgb.Event { return DeviceButtonPressEvent(DeviceKeyPressEventNew(buf).(DeviceKeyPressEvent)) } // Bytes writes a DeviceButtonPressEvent value to a byte slice. func (v DeviceButtonPressEvent) Bytes() []byte { return DeviceKeyPressEvent(v).Bytes() } // SequenceId returns the sequence id attached to the DeviceButtonPress event. // Events without a sequence number (KeymapNotify) return 0. // This is mostly used internally. func (v DeviceButtonPressEvent) SequenceId() uint16 { return v.Sequence } func (v DeviceButtonPressEvent) String() string { fieldVals := make([]string, 0, 12) fieldVals = append(fieldVals, xgb.Sprintf("Sequence: %d", v.Sequence)) fieldVals = append(fieldVals, xgb.Sprintf("Detail: %d", v.Detail)) fieldVals = append(fieldVals, xgb.Sprintf("Time: %d", v.Time)) fieldVals = append(fieldVals, xgb.Sprintf("Root: %d", v.Root)) fieldVals = append(fieldVals, xgb.Sprintf("Event: %d", v.Event)) fieldVals = append(fieldVals, xgb.Sprintf("Child: %d", v.Child)) fieldVals = append(fieldVals, xgb.Sprintf("RootX: %d", v.RootX)) fieldVals = append(fieldVals, xgb.Sprintf("RootY: %d", v.RootY)) fieldVals = append(fieldVals, xgb.Sprintf("EventX: %d", v.EventX)) fieldVals = append(fieldVals, xgb.Sprintf("EventY: %d", v.EventY)) fieldVals = append(fieldVals, xgb.Sprintf("State: %d", v.State)) fieldVals = append(fieldVals, xgb.Sprintf("SameScreen: %t", v.SameScreen)) fieldVals = append(fieldVals, xgb.Sprintf("DeviceId: %d", v.DeviceId)) return "DeviceButtonPress {" + xgb.StringsJoin(fieldVals, ", ") + "}" } func init() { xgb.NewExtEventFuncs["XInputExtension"][3] = DeviceButtonPressEventNew } // DeviceButtonRelease is the event number for a DeviceButtonReleaseEvent. const DeviceButtonRelease = 4 type DeviceButtonReleaseEvent DeviceKeyPressEvent // DeviceButtonReleaseEventNew constructs a DeviceButtonReleaseEvent value that implements xgb.Event from a byte slice. func DeviceButtonReleaseEventNew(buf []byte) xgb.Event { return DeviceButtonReleaseEvent(DeviceKeyPressEventNew(buf).(DeviceKeyPressEvent)) } // Bytes writes a DeviceButtonReleaseEvent value to a byte slice. func (v DeviceButtonReleaseEvent) Bytes() []byte { return DeviceKeyPressEvent(v).Bytes() } // SequenceId returns the sequence id attached to the DeviceButtonRelease event. // Events without a sequence number (KeymapNotify) return 0. // This is mostly used internally. func (v DeviceButtonReleaseEvent) SequenceId() uint16 { return v.Sequence } func (v DeviceButtonReleaseEvent) String() string { fieldVals := make([]string, 0, 12) fieldVals = append(fieldVals, xgb.Sprintf("Sequence: %d", v.Sequence)) fieldVals = append(fieldVals, xgb.Sprintf("Detail: %d", v.Detail)) fieldVals = append(fieldVals, xgb.Sprintf("Time: %d", v.Time)) fieldVals = append(fieldVals, xgb.Sprintf("Root: %d", v.Root)) fieldVals = append(fieldVals, xgb.Sprintf("Event: %d", v.Event)) fieldVals = append(fieldVals, xgb.Sprintf("Child: %d", v.Child)) fieldVals = append(fieldVals, xgb.Sprintf("RootX: %d", v.RootX)) fieldVals = append(fieldVals, xgb.Sprintf("RootY: %d", v.RootY)) fieldVals = append(fieldVals, xgb.Sprintf("EventX: %d", v.EventX)) fieldVals = append(fieldVals, xgb.Sprintf("EventY: %d", v.EventY)) fieldVals = append(fieldVals, xgb.Sprintf("State: %d", v.State)) fieldVals = append(fieldVals, xgb.Sprintf("SameScreen: %t", v.SameScreen)) fieldVals = append(fieldVals, xgb.Sprintf("DeviceId: %d", v.DeviceId)) return "DeviceButtonRelease {" + xgb.StringsJoin(fieldVals, ", ") + "}" } func init() { xgb.NewExtEventFuncs["XInputExtension"][4] = DeviceButtonReleaseEventNew } // DeviceButtonStateNotify is the event number for a DeviceButtonStateNotifyEvent. const DeviceButtonStateNotify = 14 type DeviceButtonStateNotifyEvent struct { Sequence uint16 DeviceId byte Buttons []byte // size: 28 } // DeviceButtonStateNotifyEventNew constructs a DeviceButtonStateNotifyEvent value that implements xgb.Event from a byte slice. func DeviceButtonStateNotifyEventNew(buf []byte) xgb.Event { v := DeviceButtonStateNotifyEvent{} b := 1 // don't read event number v.DeviceId = buf[b] b += 1 v.Sequence = xgb.Get16(buf[b:]) b += 2 v.Buttons = make([]byte, 28) copy(v.Buttons[:28], buf[b:]) b += xgb.Pad(int(28)) return v } // Bytes writes a DeviceButtonStateNotifyEvent value to a byte slice. func (v DeviceButtonStateNotifyEvent) Bytes() []byte { buf := make([]byte, 32) b := 0 // write event number buf[b] = 14 b += 1 buf[b] = v.DeviceId b += 1 b += 2 // skip sequence number copy(buf[b:], v.Buttons[:28]) b += xgb.Pad(int(28)) return buf } // SequenceId returns the sequence id attached to the DeviceButtonStateNotify event. // Events without a sequence number (KeymapNotify) return 0. // This is mostly used internally. func (v DeviceButtonStateNotifyEvent) SequenceId() uint16 { return v.Sequence } // String is a rudimentary string representation of DeviceButtonStateNotifyEvent. func (v DeviceButtonStateNotifyEvent) String() string { fieldVals := make([]string, 0, 2) fieldVals = append(fieldVals, xgb.Sprintf("Sequence: %d", v.Sequence)) fieldVals = append(fieldVals, xgb.Sprintf("DeviceId: %d", v.DeviceId)) return "DeviceButtonStateNotify {" + xgb.StringsJoin(fieldVals, ", ") + "}" } func init() { xgb.NewExtEventFuncs["XInputExtension"][14] = DeviceButtonStateNotifyEventNew } type DeviceCoreCtrl struct { ControlId uint16 Len uint16 Status byte // padding: 3 bytes } // DeviceCoreCtrlRead reads a byte slice into a DeviceCoreCtrl value. func DeviceCoreCtrlRead(buf []byte, v *DeviceCoreCtrl) int { b := 0 v.ControlId = xgb.Get16(buf[b:]) b += 2 v.Len = xgb.Get16(buf[b:]) b += 2 v.Status = buf[b] b += 1 b += 3 // padding return b } // DeviceCoreCtrlReadList reads a byte slice into a list of DeviceCoreCtrl values. func DeviceCoreCtrlReadList(buf []byte, dest []DeviceCoreCtrl) int { b := 0 for i := 0; i < len(dest); i++ { dest[i] = DeviceCoreCtrl{} b += DeviceCoreCtrlRead(buf[b:], &dest[i]) } return xgb.Pad(b) } // Bytes writes a DeviceCoreCtrl value to a byte slice. func (v DeviceCoreCtrl) Bytes() []byte { buf := make([]byte, 8) b := 0 xgb.Put16(buf[b:], v.ControlId) b += 2 xgb.Put16(buf[b:], v.Len) b += 2 buf[b] = v.Status b += 1 b += 3 // padding return buf } // DeviceCoreCtrlListBytes writes a list of DeviceCoreCtrl values to a byte slice. func DeviceCoreCtrlListBytes(buf []byte, list []DeviceCoreCtrl) int { b := 0 var structBytes []byte for _, item := range list { structBytes = item.Bytes() copy(buf[b:], structBytes) b += len(structBytes) } return xgb.Pad(b) } type DeviceCoreState struct { ControlId uint16 Len uint16 Status byte Iscore byte // padding: 2 bytes } // DeviceCoreStateRead reads a byte slice into a DeviceCoreState value. func DeviceCoreStateRead(buf []byte, v *DeviceCoreState) int { b := 0 v.ControlId = xgb.Get16(buf[b:]) b += 2 v.Len = xgb.Get16(buf[b:]) b += 2 v.Status = buf[b] b += 1 v.Iscore = buf[b] b += 1 b += 2 // padding return b } // DeviceCoreStateReadList reads a byte slice into a list of DeviceCoreState values. func DeviceCoreStateReadList(buf []byte, dest []DeviceCoreState) int { b := 0 for i := 0; i < len(dest); i++ { dest[i] = DeviceCoreState{} b += DeviceCoreStateRead(buf[b:], &dest[i]) } return xgb.Pad(b) } // Bytes writes a DeviceCoreState value to a byte slice. func (v DeviceCoreState) Bytes() []byte { buf := make([]byte, 8) b := 0 xgb.Put16(buf[b:], v.ControlId) b += 2 xgb.Put16(buf[b:], v.Len) b += 2 buf[b] = v.Status b += 1 buf[b] = v.Iscore b += 1 b += 2 // padding return buf } // DeviceCoreStateListBytes writes a list of DeviceCoreState values to a byte slice. func DeviceCoreStateListBytes(buf []byte, list []DeviceCoreState) int { b := 0 var structBytes []byte for _, item := range list { structBytes = item.Bytes() copy(buf[b:], structBytes) b += len(structBytes) } return xgb.Pad(b) } type DeviceCtl struct { ControlId uint16 Len uint16 } // DeviceCtlRead reads a byte slice into a DeviceCtl value. func DeviceCtlRead(buf []byte, v *DeviceCtl) int { b := 0 v.ControlId = xgb.Get16(buf[b:]) b += 2 v.Len = xgb.Get16(buf[b:]) b += 2 return b } // DeviceCtlReadList reads a byte slice into a list of DeviceCtl values. func DeviceCtlReadList(buf []byte, dest []DeviceCtl) int { b := 0 for i := 0; i < len(dest); i++ { dest[i] = DeviceCtl{} b += DeviceCtlRead(buf[b:], &dest[i]) } return xgb.Pad(b) } // Bytes writes a DeviceCtl value to a byte slice. func (v DeviceCtl) Bytes() []byte { buf := make([]byte, 4) b := 0 xgb.Put16(buf[b:], v.ControlId) b += 2 xgb.Put16(buf[b:], v.Len) b += 2 return buf } // DeviceCtlListBytes writes a list of DeviceCtl values to a byte slice. func DeviceCtlListBytes(buf []byte, list []DeviceCtl) int { b := 0 var structBytes []byte for _, item := range list { structBytes = item.Bytes() copy(buf[b:], structBytes) b += len(structBytes) } return xgb.Pad(b) } type DeviceEnableCtrl struct { ControlId uint16 Len uint16 Enable byte // padding: 3 bytes } // DeviceEnableCtrlRead reads a byte slice into a DeviceEnableCtrl value. func DeviceEnableCtrlRead(buf []byte, v *DeviceEnableCtrl) int { b := 0 v.ControlId = xgb.Get16(buf[b:]) b += 2 v.Len = xgb.Get16(buf[b:]) b += 2 v.Enable = buf[b] b += 1 b += 3 // padding return b } // DeviceEnableCtrlReadList reads a byte slice into a list of DeviceEnableCtrl values. func DeviceEnableCtrlReadList(buf []byte, dest []DeviceEnableCtrl) int { b := 0 for i := 0; i < len(dest); i++ { dest[i] = DeviceEnableCtrl{} b += DeviceEnableCtrlRead(buf[b:], &dest[i]) } return xgb.Pad(b) } // Bytes writes a DeviceEnableCtrl value to a byte slice. func (v DeviceEnableCtrl) Bytes() []byte { buf := make([]byte, 8) b := 0 xgb.Put16(buf[b:], v.ControlId) b += 2 xgb.Put16(buf[b:], v.Len) b += 2 buf[b] = v.Enable b += 1 b += 3 // padding return buf } // DeviceEnableCtrlListBytes writes a list of DeviceEnableCtrl values to a byte slice. func DeviceEnableCtrlListBytes(buf []byte, list []DeviceEnableCtrl) int { b := 0 var structBytes []byte for _, item := range list { structBytes = item.Bytes() copy(buf[b:], structBytes) b += len(structBytes) } return xgb.Pad(b) } type DeviceEnableState struct { ControlId uint16 Len uint16 Enable byte // padding: 3 bytes } // DeviceEnableStateRead reads a byte slice into a DeviceEnableState value. func DeviceEnableStateRead(buf []byte, v *DeviceEnableState) int { b := 0 v.ControlId = xgb.Get16(buf[b:]) b += 2 v.Len = xgb.Get16(buf[b:]) b += 2 v.Enable = buf[b] b += 1 b += 3 // padding return b } // DeviceEnableStateReadList reads a byte slice into a list of DeviceEnableState values. func DeviceEnableStateReadList(buf []byte, dest []DeviceEnableState) int { b := 0 for i := 0; i < len(dest); i++ { dest[i] = DeviceEnableState{} b += DeviceEnableStateRead(buf[b:], &dest[i]) } return xgb.Pad(b) } // Bytes writes a DeviceEnableState value to a byte slice. func (v DeviceEnableState) Bytes() []byte { buf := make([]byte, 8) b := 0 xgb.Put16(buf[b:], v.ControlId) b += 2 xgb.Put16(buf[b:], v.Len) b += 2 buf[b] = v.Enable b += 1 b += 3 // padding return buf } // DeviceEnableStateListBytes writes a list of DeviceEnableState values to a byte slice. func DeviceEnableStateListBytes(buf []byte, list []DeviceEnableState) int { b := 0 var structBytes []byte for _, item := range list { structBytes = item.Bytes() copy(buf[b:], structBytes) b += len(structBytes) } return xgb.Pad(b) } type DeviceInfo struct { DeviceType xproto.Atom DeviceId byte NumClassInfo byte DeviceUse byte // padding: 1 bytes } // DeviceInfoRead reads a byte slice into a DeviceInfo value. func DeviceInfoRead(buf []byte, v *DeviceInfo) int { b := 0 v.DeviceType = xproto.Atom(xgb.Get32(buf[b:])) b += 4 v.DeviceId = buf[b] b += 1 v.NumClassInfo = buf[b] b += 1 v.DeviceUse = buf[b] b += 1 b += 1 // padding return b } // DeviceInfoReadList reads a byte slice into a list of DeviceInfo values. func DeviceInfoReadList(buf []byte, dest []DeviceInfo) int { b := 0 for i := 0; i < len(dest); i++ { dest[i] = DeviceInfo{} b += DeviceInfoRead(buf[b:], &dest[i]) } return xgb.Pad(b) } // Bytes writes a DeviceInfo value to a byte slice. func (v DeviceInfo) Bytes() []byte { buf := make([]byte, 8) b := 0 xgb.Put32(buf[b:], uint32(v.DeviceType)) b += 4 buf[b] = v.DeviceId b += 1 buf[b] = v.NumClassInfo b += 1 buf[b] = v.DeviceUse b += 1 b += 1 // padding return buf } // DeviceInfoListBytes writes a list of DeviceInfo values to a byte slice. func DeviceInfoListBytes(buf []byte, list []DeviceInfo) int { b := 0 var structBytes []byte for _, item := range list { structBytes = item.Bytes() copy(buf[b:], structBytes) b += len(structBytes) } return xgb.Pad(b) } const ( DeviceInputModeAsyncThisDevice = 0 DeviceInputModeSyncThisDevice = 1 DeviceInputModeReplayThisDevice = 2 DeviceInputModeAsyncOtherDevices = 3 DeviceInputModeAsyncAll = 4 DeviceInputModeSyncAll = 5 ) // DeviceKeyPress is the event number for a DeviceKeyPressEvent. const DeviceKeyPress = 1 type DeviceKeyPressEvent struct { Sequence uint16 Detail byte Time xproto.Timestamp Root xproto.Window Event xproto.Window Child xproto.Window RootX int16 RootY int16 EventX int16 EventY int16 State uint16 SameScreen bool DeviceId byte } // DeviceKeyPressEventNew constructs a DeviceKeyPressEvent value that implements xgb.Event from a byte slice. func DeviceKeyPressEventNew(buf []byte) xgb.Event { v := DeviceKeyPressEvent{} b := 1 // don't read event number v.Detail = buf[b] b += 1 v.Sequence = xgb.Get16(buf[b:]) b += 2 v.Time = xproto.Timestamp(xgb.Get32(buf[b:])) b += 4 v.Root = xproto.Window(xgb.Get32(buf[b:])) b += 4 v.Event = xproto.Window(xgb.Get32(buf[b:])) b += 4 v.Child = xproto.Window(xgb.Get32(buf[b:])) b += 4 v.RootX = int16(xgb.Get16(buf[b:])) b += 2 v.RootY = int16(xgb.Get16(buf[b:])) b += 2 v.EventX = int16(xgb.Get16(buf[b:])) b += 2 v.EventY = int16(xgb.Get16(buf[b:])) b += 2 v.State = xgb.Get16(buf[b:]) b += 2 if buf[b] == 1 { v.SameScreen = true } else { v.SameScreen = false } b += 1 v.DeviceId = buf[b] b += 1 return v } // Bytes writes a DeviceKeyPressEvent value to a byte slice. func (v DeviceKeyPressEvent) Bytes() []byte { buf := make([]byte, 32) b := 0 // write event number buf[b] = 1 b += 1 buf[b] = v.Detail b += 1 b += 2 // skip sequence number xgb.Put32(buf[b:], uint32(v.Time)) b += 4 xgb.Put32(buf[b:], uint32(v.Root)) b += 4 xgb.Put32(buf[b:], uint32(v.Event)) b += 4 xgb.Put32(buf[b:], uint32(v.Child)) b += 4 xgb.Put16(buf[b:], uint16(v.RootX)) b += 2 xgb.Put16(buf[b:], uint16(v.RootY)) b += 2 xgb.Put16(buf[b:], uint16(v.EventX)) b += 2 xgb.Put16(buf[b:], uint16(v.EventY)) b += 2 xgb.Put16(buf[b:], v.State) b += 2 if v.SameScreen { buf[b] = 1 } else { buf[b] = 0 } b += 1 buf[b] = v.DeviceId b += 1 return buf } // SequenceId returns the sequence id attached to the DeviceKeyPress event. // Events without a sequence number (KeymapNotify) return 0. // This is mostly used internally. func (v DeviceKeyPressEvent) SequenceId() uint16 { return v.Sequence } // String is a rudimentary string representation of DeviceKeyPressEvent. func (v DeviceKeyPressEvent) String() string { fieldVals := make([]string, 0, 12) fieldVals = append(fieldVals, xgb.Sprintf("Sequence: %d", v.Sequence)) fieldVals = append(fieldVals, xgb.Sprintf("Detail: %d", v.Detail)) fieldVals = append(fieldVals, xgb.Sprintf("Time: %d", v.Time)) fieldVals = append(fieldVals, xgb.Sprintf("Root: %d", v.Root)) fieldVals = append(fieldVals, xgb.Sprintf("Event: %d", v.Event)) fieldVals = append(fieldVals, xgb.Sprintf("Child: %d", v.Child)) fieldVals = append(fieldVals, xgb.Sprintf("RootX: %d", v.RootX)) fieldVals = append(fieldVals, xgb.Sprintf("RootY: %d", v.RootY)) fieldVals = append(fieldVals, xgb.Sprintf("EventX: %d", v.EventX)) fieldVals = append(fieldVals, xgb.Sprintf("EventY: %d", v.EventY)) fieldVals = append(fieldVals, xgb.Sprintf("State: %d", v.State)) fieldVals = append(fieldVals, xgb.Sprintf("SameScreen: %t", v.SameScreen)) fieldVals = append(fieldVals, xgb.Sprintf("DeviceId: %d", v.DeviceId)) return "DeviceKeyPress {" + xgb.StringsJoin(fieldVals, ", ") + "}" } func init() { xgb.NewExtEventFuncs["XInputExtension"][1] = DeviceKeyPressEventNew } // DeviceKeyRelease is the event number for a DeviceKeyReleaseEvent. const DeviceKeyRelease = 2 type DeviceKeyReleaseEvent DeviceKeyPressEvent // DeviceKeyReleaseEventNew constructs a DeviceKeyReleaseEvent value that implements xgb.Event from a byte slice. func DeviceKeyReleaseEventNew(buf []byte) xgb.Event { return DeviceKeyReleaseEvent(DeviceKeyPressEventNew(buf).(DeviceKeyPressEvent)) } // Bytes writes a DeviceKeyReleaseEvent value to a byte slice. func (v DeviceKeyReleaseEvent) Bytes() []byte { return DeviceKeyPressEvent(v).Bytes() } // SequenceId returns the sequence id attached to the DeviceKeyRelease event. // Events without a sequence number (KeymapNotify) return 0. // This is mostly used internally. func (v DeviceKeyReleaseEvent) SequenceId() uint16 { return v.Sequence } func (v DeviceKeyReleaseEvent) String() string { fieldVals := make([]string, 0, 12) fieldVals = append(fieldVals, xgb.Sprintf("Sequence: %d", v.Sequence)) fieldVals = append(fieldVals, xgb.Sprintf("Detail: %d", v.Detail)) fieldVals = append(fieldVals, xgb.Sprintf("Time: %d", v.Time)) fieldVals = append(fieldVals, xgb.Sprintf("Root: %d", v.Root)) fieldVals = append(fieldVals, xgb.Sprintf("Event: %d", v.Event)) fieldVals = append(fieldVals, xgb.Sprintf("Child: %d", v.Child)) fieldVals = append(fieldVals, xgb.Sprintf("RootX: %d", v.RootX)) fieldVals = append(fieldVals, xgb.Sprintf("RootY: %d", v.RootY)) fieldVals = append(fieldVals, xgb.Sprintf("EventX: %d", v.EventX)) fieldVals = append(fieldVals, xgb.Sprintf("EventY: %d", v.EventY)) fieldVals = append(fieldVals, xgb.Sprintf("State: %d", v.State)) fieldVals = append(fieldVals, xgb.Sprintf("SameScreen: %t", v.SameScreen)) fieldVals = append(fieldVals, xgb.Sprintf("DeviceId: %d", v.DeviceId)) return "DeviceKeyRelease {" + xgb.StringsJoin(fieldVals, ", ") + "}" } func init() { xgb.NewExtEventFuncs["XInputExtension"][2] = DeviceKeyReleaseEventNew } // DeviceKeyStateNotify is the event number for a DeviceKeyStateNotifyEvent. const DeviceKeyStateNotify = 13 type DeviceKeyStateNotifyEvent struct { Sequence uint16 DeviceId byte Keys []byte // size: 28 } // DeviceKeyStateNotifyEventNew constructs a DeviceKeyStateNotifyEvent value that implements xgb.Event from a byte slice. func DeviceKeyStateNotifyEventNew(buf []byte) xgb.Event { v := DeviceKeyStateNotifyEvent{} b := 1 // don't read event number v.DeviceId = buf[b] b += 1 v.Sequence = xgb.Get16(buf[b:]) b += 2 v.Keys = make([]byte, 28) copy(v.Keys[:28], buf[b:]) b += xgb.Pad(int(28)) return v } // Bytes writes a DeviceKeyStateNotifyEvent value to a byte slice. func (v DeviceKeyStateNotifyEvent) Bytes() []byte { buf := make([]byte, 32) b := 0 // write event number buf[b] = 13 b += 1 buf[b] = v.DeviceId b += 1 b += 2 // skip sequence number copy(buf[b:], v.Keys[:28]) b += xgb.Pad(int(28)) return buf } // SequenceId returns the sequence id attached to the DeviceKeyStateNotify event. // Events without a sequence number (KeymapNotify) return 0. // This is mostly used internally. func (v DeviceKeyStateNotifyEvent) SequenceId() uint16 { return v.Sequence } // String is a rudimentary string representation of DeviceKeyStateNotifyEvent. func (v DeviceKeyStateNotifyEvent) String() string { fieldVals := make([]string, 0, 2) fieldVals = append(fieldVals, xgb.Sprintf("Sequence: %d", v.Sequence)) fieldVals = append(fieldVals, xgb.Sprintf("DeviceId: %d", v.DeviceId)) return "DeviceKeyStateNotify {" + xgb.StringsJoin(fieldVals, ", ") + "}" } func init() { xgb.NewExtEventFuncs["XInputExtension"][13] = DeviceKeyStateNotifyEventNew } // DeviceMappingNotify is the event number for a DeviceMappingNotifyEvent. const DeviceMappingNotify = 11 type DeviceMappingNotifyEvent struct { Sequence uint16 DeviceId byte Request byte FirstKeycode KeyCode Count byte // padding: 1 bytes Time xproto.Timestamp // padding: 20 bytes } // DeviceMappingNotifyEventNew constructs a DeviceMappingNotifyEvent value that implements xgb.Event from a byte slice. func DeviceMappingNotifyEventNew(buf []byte) xgb.Event { v := DeviceMappingNotifyEvent{} b := 1 // don't read event number v.DeviceId = buf[b] b += 1 v.Sequence = xgb.Get16(buf[b:]) b += 2 v.Request = buf[b] b += 1 v.FirstKeycode = KeyCode(buf[b]) b += 1 v.Count = buf[b] b += 1 b += 1 // padding v.Time = xproto.Timestamp(xgb.Get32(buf[b:])) b += 4 b += 20 // padding return v } // Bytes writes a DeviceMappingNotifyEvent value to a byte slice. func (v DeviceMappingNotifyEvent) Bytes() []byte { buf := make([]byte, 32) b := 0 // write event number buf[b] = 11 b += 1 buf[b] = v.DeviceId b += 1 b += 2 // skip sequence number buf[b] = v.Request b += 1 buf[b] = byte(v.FirstKeycode) b += 1 buf[b] = v.Count b += 1 b += 1 // padding xgb.Put32(buf[b:], uint32(v.Time)) b += 4 b += 20 // padding return buf } // SequenceId returns the sequence id attached to the DeviceMappingNotify event. // Events without a sequence number (KeymapNotify) return 0. // This is mostly used internally. func (v DeviceMappingNotifyEvent) SequenceId() uint16 { return v.Sequence } // String is a rudimentary string representation of DeviceMappingNotifyEvent. func (v DeviceMappingNotifyEvent) String() string { fieldVals := make([]string, 0, 7) fieldVals = append(fieldVals, xgb.Sprintf("Sequence: %d", v.Sequence)) fieldVals = append(fieldVals, xgb.Sprintf("DeviceId: %d", v.DeviceId)) fieldVals = append(fieldVals, xgb.Sprintf("Request: %d", v.Request)) fieldVals = append(fieldVals, xgb.Sprintf("FirstKeycode: %d", v.FirstKeycode)) fieldVals = append(fieldVals, xgb.Sprintf("Count: %d", v.Count)) fieldVals = append(fieldVals, xgb.Sprintf("Time: %d", v.Time)) return "DeviceMappingNotify {" + xgb.StringsJoin(fieldVals, ", ") + "}" } func init() { xgb.NewExtEventFuncs["XInputExtension"][11] = DeviceMappingNotifyEventNew } // DeviceMotionNotify is the event number for a DeviceMotionNotifyEvent. const DeviceMotionNotify = 5 type DeviceMotionNotifyEvent DeviceKeyPressEvent // DeviceMotionNotifyEventNew constructs a DeviceMotionNotifyEvent value that implements xgb.Event from a byte slice. func DeviceMotionNotifyEventNew(buf []byte) xgb.Event { return DeviceMotionNotifyEvent(DeviceKeyPressEventNew(buf).(DeviceKeyPressEvent)) } // Bytes writes a DeviceMotionNotifyEvent value to a byte slice. func (v DeviceMotionNotifyEvent) Bytes() []byte { return DeviceKeyPressEvent(v).Bytes() } // SequenceId returns the sequence id attached to the DeviceMotionNotify event. // Events without a sequence number (KeymapNotify) return 0. // This is mostly used internally. func (v DeviceMotionNotifyEvent) SequenceId() uint16 { return v.Sequence } func (v DeviceMotionNotifyEvent) String() string { fieldVals := make([]string, 0, 12) fieldVals = append(fieldVals, xgb.Sprintf("Sequence: %d", v.Sequence)) fieldVals = append(fieldVals, xgb.Sprintf("Detail: %d", v.Detail)) fieldVals = append(fieldVals, xgb.Sprintf("Time: %d", v.Time)) fieldVals = append(fieldVals, xgb.Sprintf("Root: %d", v.Root)) fieldVals = append(fieldVals, xgb.Sprintf("Event: %d", v.Event)) fieldVals = append(fieldVals, xgb.Sprintf("Child: %d", v.Child)) fieldVals = append(fieldVals, xgb.Sprintf("RootX: %d", v.RootX)) fieldVals = append(fieldVals, xgb.Sprintf("RootY: %d", v.RootY)) fieldVals = append(fieldVals, xgb.Sprintf("EventX: %d", v.EventX)) fieldVals = append(fieldVals, xgb.Sprintf("EventY: %d", v.EventY)) fieldVals = append(fieldVals, xgb.Sprintf("State: %d", v.State)) fieldVals = append(fieldVals, xgb.Sprintf("SameScreen: %t", v.SameScreen)) fieldVals = append(fieldVals, xgb.Sprintf("DeviceId: %d", v.DeviceId)) return "DeviceMotionNotify {" + xgb.StringsJoin(fieldVals, ", ") + "}" } func init() { xgb.NewExtEventFuncs["XInputExtension"][5] = DeviceMotionNotifyEventNew } // DevicePresenceNotify is the event number for a DevicePresenceNotifyEvent. const DevicePresenceNotify = 15 type DevicePresenceNotifyEvent struct { Sequence uint16 // padding: 1 bytes Time xproto.Timestamp Devchange byte DeviceId byte Control uint16 // padding: 20 bytes } // DevicePresenceNotifyEventNew constructs a DevicePresenceNotifyEvent value that implements xgb.Event from a byte slice. func DevicePresenceNotifyEventNew(buf []byte) xgb.Event { v := DevicePresenceNotifyEvent{} b := 1 // don't read event number b += 1 // padding v.Sequence = xgb.Get16(buf[b:]) b += 2 v.Time = xproto.Timestamp(xgb.Get32(buf[b:])) b += 4 v.Devchange = buf[b] b += 1 v.DeviceId = buf[b] b += 1 v.Control = xgb.Get16(buf[b:]) b += 2 b += 20 // padding return v } // Bytes writes a DevicePresenceNotifyEvent value to a byte slice. func (v DevicePresenceNotifyEvent) Bytes() []byte { buf := make([]byte, 32) b := 0 // write event number buf[b] = 15 b += 1 b += 1 // padding b += 2 // skip sequence number xgb.Put32(buf[b:], uint32(v.Time)) b += 4 buf[b] = v.Devchange b += 1 buf[b] = v.DeviceId b += 1 xgb.Put16(buf[b:], v.Control) b += 2 b += 20 // padding return buf } // SequenceId returns the sequence id attached to the DevicePresenceNotify event. // Events without a sequence number (KeymapNotify) return 0. // This is mostly used internally. func (v DevicePresenceNotifyEvent) SequenceId() uint16 { return v.Sequence } // String is a rudimentary string representation of DevicePresenceNotifyEvent. func (v DevicePresenceNotifyEvent) String() string { fieldVals := make([]string, 0, 6) fieldVals = append(fieldVals, xgb.Sprintf("Sequence: %d", v.Sequence)) fieldVals = append(fieldVals, xgb.Sprintf("Time: %d", v.Time)) fieldVals = append(fieldVals, xgb.Sprintf("Devchange: %d", v.Devchange)) fieldVals = append(fieldVals, xgb.Sprintf("DeviceId: %d", v.DeviceId)) fieldVals = append(fieldVals, xgb.Sprintf("Control: %d", v.Control)) return "DevicePresenceNotify {" + xgb.StringsJoin(fieldVals, ", ") + "}" } func init() { xgb.NewExtEventFuncs["XInputExtension"][15] = DevicePresenceNotifyEventNew } type DeviceResolutionCtl struct { ControlId uint16 Len uint16 FirstValuator byte NumValuators byte ResolutionValues []uint32 // size: xgb.Pad((int(NumValuators) * 4)) } // DeviceResolutionCtlRead reads a byte slice into a DeviceResolutionCtl value. func DeviceResolutionCtlRead(buf []byte, v *DeviceResolutionCtl) int { b := 0 v.ControlId = xgb.Get16(buf[b:]) b += 2 v.Len = xgb.Get16(buf[b:]) b += 2 v.FirstValuator = buf[b] b += 1 v.NumValuators = buf[b] b += 1 v.ResolutionValues = make([]uint32, v.NumValuators) for i := 0; i < int(v.NumValuators); i++ { v.ResolutionValues[i] = xgb.Get32(buf[b:]) b += 4 } b = xgb.Pad(b) return b } // DeviceResolutionCtlReadList reads a byte slice into a list of DeviceResolutionCtl values. func DeviceResolutionCtlReadList(buf []byte, dest []DeviceResolutionCtl) int { b := 0 for i := 0; i < len(dest); i++ { dest[i] = DeviceResolutionCtl{} b += DeviceResolutionCtlRead(buf[b:], &dest[i]) } return xgb.Pad(b) } // Bytes writes a DeviceResolutionCtl value to a byte slice. func (v DeviceResolutionCtl) Bytes() []byte { buf := make([]byte, (6 + xgb.Pad((int(v.NumValuators) * 4)))) b := 0 xgb.Put16(buf[b:], v.ControlId) b += 2 xgb.Put16(buf[b:], v.Len) b += 2 buf[b] = v.FirstValuator b += 1 buf[b] = v.NumValuators b += 1 for i := 0; i < int(v.NumValuators); i++ { xgb.Put32(buf[b:], v.ResolutionValues[i]) b += 4 } b = xgb.Pad(b) return buf } // DeviceResolutionCtlListBytes writes a list of DeviceResolutionCtl values to a byte slice. func DeviceResolutionCtlListBytes(buf []byte, list []DeviceResolutionCtl) int { b := 0 var structBytes []byte for _, item := range list { structBytes = item.Bytes() copy(buf[b:], structBytes) b += len(structBytes) } return xgb.Pad(b) } // DeviceResolutionCtlListSize computes the size (bytes) of a list of DeviceResolutionCtl values. func DeviceResolutionCtlListSize(list []DeviceResolutionCtl) int { size := 0 for _, item := range list { size += (6 + xgb.Pad((int(item.NumValuators) * 4))) } return size } type DeviceResolutionState struct { ControlId uint16 Len uint16 NumValuators uint32 ResolutionValues []uint32 // size: xgb.Pad((int(NumValuators) * 4)) ResolutionMin []uint32 // size: xgb.Pad((int(NumValuators) * 4)) ResolutionMax []uint32 // size: xgb.Pad((int(NumValuators) * 4)) } // DeviceResolutionStateRead reads a byte slice into a DeviceResolutionState value. func DeviceResolutionStateRead(buf []byte, v *DeviceResolutionState) int { b := 0 v.ControlId = xgb.Get16(buf[b:]) b += 2 v.Len = xgb.Get16(buf[b:]) b += 2 v.NumValuators = xgb.Get32(buf[b:]) b += 4 v.ResolutionValues = make([]uint32, v.NumValuators) for i := 0; i < int(v.NumValuators); i++ { v.ResolutionValues[i] = xgb.Get32(buf[b:]) b += 4 } b = xgb.Pad(b) v.ResolutionMin = make([]uint32, v.NumValuators) for i := 0; i < int(v.NumValuators); i++ { v.ResolutionMin[i] = xgb.Get32(buf[b:]) b += 4 } b = xgb.Pad(b) v.ResolutionMax = make([]uint32, v.NumValuators) for i := 0; i < int(v.NumValuators); i++ { v.ResolutionMax[i] = xgb.Get32(buf[b:]) b += 4 } b = xgb.Pad(b) return b } // DeviceResolutionStateReadList reads a byte slice into a list of DeviceResolutionState values. func DeviceResolutionStateReadList(buf []byte, dest []DeviceResolutionState) int { b := 0 for i := 0; i < len(dest); i++ { dest[i] = DeviceResolutionState{} b += DeviceResolutionStateRead(buf[b:], &dest[i]) } return xgb.Pad(b) } // Bytes writes a DeviceResolutionState value to a byte slice. func (v DeviceResolutionState) Bytes() []byte { buf := make([]byte, (((8 + xgb.Pad((int(v.NumValuators) * 4))) + xgb.Pad((int(v.NumValuators) * 4))) + xgb.Pad((int(v.NumValuators) * 4)))) b := 0 xgb.Put16(buf[b:], v.ControlId) b += 2 xgb.Put16(buf[b:], v.Len) b += 2 xgb.Put32(buf[b:], v.NumValuators) b += 4 for i := 0; i < int(v.NumValuators); i++ { xgb.Put32(buf[b:], v.ResolutionValues[i]) b += 4 } b = xgb.Pad(b) for i := 0; i < int(v.NumValuators); i++ { xgb.Put32(buf[b:], v.ResolutionMin[i]) b += 4 } b = xgb.Pad(b) for i := 0; i < int(v.NumValuators); i++ { xgb.Put32(buf[b:], v.ResolutionMax[i]) b += 4 } b = xgb.Pad(b) return buf } // DeviceResolutionStateListBytes writes a list of DeviceResolutionState values to a byte slice. func DeviceResolutionStateListBytes(buf []byte, list []DeviceResolutionState) int { b := 0 var structBytes []byte for _, item := range list { structBytes = item.Bytes() copy(buf[b:], structBytes) b += len(structBytes) } return xgb.Pad(b) } // DeviceResolutionStateListSize computes the size (bytes) of a list of DeviceResolutionState values. func DeviceResolutionStateListSize(list []DeviceResolutionState) int { size := 0 for _, item := range list { size += (((8 + xgb.Pad((int(item.NumValuators) * 4))) + xgb.Pad((int(item.NumValuators) * 4))) + xgb.Pad((int(item.NumValuators) * 4))) } return size } type DeviceState struct { ControlId uint16 Len uint16 } // DeviceStateRead reads a byte slice into a DeviceState value. func DeviceStateRead(buf []byte, v *DeviceState) int { b := 0 v.ControlId = xgb.Get16(buf[b:]) b += 2 v.Len = xgb.Get16(buf[b:]) b += 2 return b } // DeviceStateReadList reads a byte slice into a list of DeviceState values. func DeviceStateReadList(buf []byte, dest []DeviceState) int { b := 0 for i := 0; i < len(dest); i++ { dest[i] = DeviceState{} b += DeviceStateRead(buf[b:], &dest[i]) } return xgb.Pad(b) } // Bytes writes a DeviceState value to a byte slice. func (v DeviceState) Bytes() []byte { buf := make([]byte, 4) b := 0 xgb.Put16(buf[b:], v.ControlId) b += 2 xgb.Put16(buf[b:], v.Len) b += 2 return buf } // DeviceStateListBytes writes a list of DeviceState values to a byte slice. func DeviceStateListBytes(buf []byte, list []DeviceState) int { b := 0 var structBytes []byte for _, item := range list { structBytes = item.Bytes() copy(buf[b:], structBytes) b += len(structBytes) } return xgb.Pad(b) } // DeviceStateNotify is the event number for a DeviceStateNotifyEvent. const DeviceStateNotify = 10 type DeviceStateNotifyEvent struct { Sequence uint16 DeviceId byte Time xproto.Timestamp NumKeys byte NumButtons byte NumValuators byte ClassesReported byte Buttons []byte // size: 4 Keys []byte // size: 4 Valuators []uint32 // size: 12 } // DeviceStateNotifyEventNew constructs a DeviceStateNotifyEvent value that implements xgb.Event from a byte slice. func DeviceStateNotifyEventNew(buf []byte) xgb.Event { v := DeviceStateNotifyEvent{} b := 1 // don't read event number v.DeviceId = buf[b] b += 1 v.Sequence = xgb.Get16(buf[b:]) b += 2 v.Time = xproto.Timestamp(xgb.Get32(buf[b:])) b += 4 v.NumKeys = buf[b] b += 1 v.NumButtons = buf[b] b += 1 v.NumValuators = buf[b] b += 1 v.ClassesReported = buf[b] b += 1 v.Buttons = make([]byte, 4) copy(v.Buttons[:4], buf[b:]) b += xgb.Pad(int(4)) v.Keys = make([]byte, 4) copy(v.Keys[:4], buf[b:]) b += xgb.Pad(int(4)) v.Valuators = make([]uint32, 3) for i := 0; i < int(3); i++ { v.Valuators[i] = xgb.Get32(buf[b:]) b += 4 } b = xgb.Pad(b) return v } // Bytes writes a DeviceStateNotifyEvent value to a byte slice. func (v DeviceStateNotifyEvent) Bytes() []byte { buf := make([]byte, 32) b := 0 // write event number buf[b] = 10 b += 1 buf[b] = v.DeviceId b += 1 b += 2 // skip sequence number xgb.Put32(buf[b:], uint32(v.Time)) b += 4 buf[b] = v.NumKeys b += 1 buf[b] = v.NumButtons b += 1 buf[b] = v.NumValuators b += 1 buf[b] = v.ClassesReported b += 1 copy(buf[b:], v.Buttons[:4]) b += xgb.Pad(int(4)) copy(buf[b:], v.Keys[:4]) b += xgb.Pad(int(4)) for i := 0; i < int(3); i++ { xgb.Put32(buf[b:], v.Valuators[i]) b += 4 } b = xgb.Pad(b) return buf } // SequenceId returns the sequence id attached to the DeviceStateNotify event. // Events without a sequence number (KeymapNotify) return 0. // This is mostly used internally. func (v DeviceStateNotifyEvent) SequenceId() uint16 { return v.Sequence } // String is a rudimentary string representation of DeviceStateNotifyEvent. func (v DeviceStateNotifyEvent) String() string { fieldVals := make([]string, 0, 9) fieldVals = append(fieldVals, xgb.Sprintf("Sequence: %d", v.Sequence)) fieldVals = append(fieldVals, xgb.Sprintf("DeviceId: %d", v.DeviceId)) fieldVals = append(fieldVals, xgb.Sprintf("Time: %d", v.Time)) fieldVals = append(fieldVals, xgb.Sprintf("NumKeys: %d", v.NumKeys)) fieldVals = append(fieldVals, xgb.Sprintf("NumButtons: %d", v.NumButtons)) fieldVals = append(fieldVals, xgb.Sprintf("NumValuators: %d", v.NumValuators)) fieldVals = append(fieldVals, xgb.Sprintf("ClassesReported: %d", v.ClassesReported)) return "DeviceStateNotify {" + xgb.StringsJoin(fieldVals, ", ") + "}" } func init() { xgb.NewExtEventFuncs["XInputExtension"][10] = DeviceStateNotifyEventNew } type DeviceTimeCoord struct { Time xproto.Timestamp } // DeviceTimeCoordRead reads a byte slice into a DeviceTimeCoord value. func DeviceTimeCoordRead(buf []byte, v *DeviceTimeCoord) int { b := 0 v.Time = xproto.Timestamp(xgb.Get32(buf[b:])) b += 4 return b } // DeviceTimeCoordReadList reads a byte slice into a list of DeviceTimeCoord values. func DeviceTimeCoordReadList(buf []byte, dest []DeviceTimeCoord) int { b := 0 for i := 0; i < len(dest); i++ { dest[i] = DeviceTimeCoord{} b += DeviceTimeCoordRead(buf[b:], &dest[i]) } return xgb.Pad(b) } // Bytes writes a DeviceTimeCoord value to a byte slice. func (v DeviceTimeCoord) Bytes() []byte { buf := make([]byte, 4) b := 0 xgb.Put32(buf[b:], uint32(v.Time)) b += 4 return buf } // DeviceTimeCoordListBytes writes a list of DeviceTimeCoord values to a byte slice. func DeviceTimeCoordListBytes(buf []byte, list []DeviceTimeCoord) int { b := 0 var structBytes []byte for _, item := range list { structBytes = item.Bytes() copy(buf[b:], structBytes) b += len(structBytes) } return xgb.Pad(b) } const ( DeviceUseIsXPointer = 0 DeviceUseIsXKeyboard = 1 DeviceUseIsXExtensionDevice = 2 DeviceUseIsXExtensionKeyboard = 3 DeviceUseIsXExtensionPointer = 4 ) // DeviceValuator is the event number for a DeviceValuatorEvent. const DeviceValuator = 0 type DeviceValuatorEvent struct { Sequence uint16 DeviceId byte DeviceState uint16 NumValuators byte FirstValuator byte Valuators []int32 // size: 24 } // DeviceValuatorEventNew constructs a DeviceValuatorEvent value that implements xgb.Event from a byte slice. func DeviceValuatorEventNew(buf []byte) xgb.Event { v := DeviceValuatorEvent{} b := 1 // don't read event number v.DeviceId = buf[b] b += 1 v.Sequence = xgb.Get16(buf[b:]) b += 2 v.DeviceState = xgb.Get16(buf[b:]) b += 2 v.NumValuators = buf[b] b += 1 v.FirstValuator = buf[b] b += 1 v.Valuators = make([]int32, 6) for i := 0; i < int(6); i++ { v.Valuators[i] = int32(xgb.Get32(buf[b:])) b += 4 } b = xgb.Pad(b) return v } // Bytes writes a DeviceValuatorEvent value to a byte slice. func (v DeviceValuatorEvent) Bytes() []byte { buf := make([]byte, 32) b := 0 // write event number buf[b] = 0 b += 1 buf[b] = v.DeviceId b += 1 b += 2 // skip sequence number xgb.Put16(buf[b:], v.DeviceState) b += 2 buf[b] = v.NumValuators b += 1 buf[b] = v.FirstValuator b += 1 for i := 0; i < int(6); i++ { xgb.Put32(buf[b:], uint32(v.Valuators[i])) b += 4 } b = xgb.Pad(b) return buf } // SequenceId returns the sequence id attached to the DeviceValuator event. // Events without a sequence number (KeymapNotify) return 0. // This is mostly used internally. func (v DeviceValuatorEvent) SequenceId() uint16 { return v.Sequence } // String is a rudimentary string representation of DeviceValuatorEvent. func (v DeviceValuatorEvent) String() string { fieldVals := make([]string, 0, 5) fieldVals = append(fieldVals, xgb.Sprintf("Sequence: %d", v.Sequence)) fieldVals = append(fieldVals, xgb.Sprintf("DeviceId: %d", v.DeviceId)) fieldVals = append(fieldVals, xgb.Sprintf("DeviceState: %d", v.DeviceState)) fieldVals = append(fieldVals, xgb.Sprintf("NumValuators: %d", v.NumValuators)) fieldVals = append(fieldVals, xgb.Sprintf("FirstValuator: %d", v.FirstValuator)) return "DeviceValuator {" + xgb.StringsJoin(fieldVals, ", ") + "}" } func init() { xgb.NewExtEventFuncs["XInputExtension"][0] = DeviceValuatorEventNew } // BadEvent is the error number for a BadEvent. const BadEvent = 1 type EventError struct { Sequence uint16 NiceName string } // EventErrorNew constructs a EventError value that implements xgb.Error from a byte slice. func EventErrorNew(buf []byte) xgb.Error { v := EventError{} v.NiceName = "Event" b := 1 // skip error determinant b += 1 // don't read error number v.Sequence = xgb.Get16(buf[b:]) b += 2 return v } // SequenceId returns the sequence id attached to the BadEvent error. // This is mostly used internally. func (err EventError) SequenceId() uint16 { return err.Sequence } // BadId returns the 'BadValue' number if one exists for the BadEvent error. If no bad value exists, 0 is returned. func (err EventError) BadId() uint32 { return 0 } // Error returns a rudimentary string representation of the BadEvent error. func (err EventError) Error() string { fieldVals := make([]string, 0, 0) fieldVals = append(fieldVals, "NiceName: "+err.NiceName) fieldVals = append(fieldVals, xgb.Sprintf("Sequence: %d", err.Sequence)) return "BadEvent {" + xgb.StringsJoin(fieldVals, ", ") + "}" } func init() { xgb.NewExtErrorFuncs["XInputExtension"][1] = EventErrorNew } type EventClass uint32 const ( FeedbackClassKeyboard = 0 FeedbackClassPointer = 1 FeedbackClassString = 2 FeedbackClassInteger = 3 FeedbackClassLed = 4 FeedbackClassBell = 5 ) type FeedbackCtl struct { ClassId byte Id byte Len uint16 } // FeedbackCtlRead reads a byte slice into a FeedbackCtl value. func FeedbackCtlRead(buf []byte, v *FeedbackCtl) int { b := 0 v.ClassId = buf[b] b += 1 v.Id = buf[b] b += 1 v.Len = xgb.Get16(buf[b:]) b += 2 return b } // FeedbackCtlReadList reads a byte slice into a list of FeedbackCtl values. func FeedbackCtlReadList(buf []byte, dest []FeedbackCtl) int { b := 0 for i := 0; i < len(dest); i++ { dest[i] = FeedbackCtl{} b += FeedbackCtlRead(buf[b:], &dest[i]) } return xgb.Pad(b) } // Bytes writes a FeedbackCtl value to a byte slice. func (v FeedbackCtl) Bytes() []byte { buf := make([]byte, 4) b := 0 buf[b] = v.ClassId b += 1 buf[b] = v.Id b += 1 xgb.Put16(buf[b:], v.Len) b += 2 return buf } // FeedbackCtlListBytes writes a list of FeedbackCtl values to a byte slice. func FeedbackCtlListBytes(buf []byte, list []FeedbackCtl) int { b := 0 var structBytes []byte for _, item := range list { structBytes = item.Bytes() copy(buf[b:], structBytes) b += len(structBytes) } return xgb.Pad(b) } type FeedbackState struct { ClassId byte Id byte Len uint16 } // FeedbackStateRead reads a byte slice into a FeedbackState value. func FeedbackStateRead(buf []byte, v *FeedbackState) int { b := 0 v.ClassId = buf[b] b += 1 v.Id = buf[b] b += 1 v.Len = xgb.Get16(buf[b:]) b += 2 return b } // FeedbackStateReadList reads a byte slice into a list of FeedbackState values. func FeedbackStateReadList(buf []byte, dest []FeedbackState) int { b := 0 for i := 0; i < len(dest); i++ { dest[i] = FeedbackState{} b += FeedbackStateRead(buf[b:], &dest[i]) } return xgb.Pad(b) } // Bytes writes a FeedbackState value to a byte slice. func (v FeedbackState) Bytes() []byte { buf := make([]byte, 4) b := 0 buf[b] = v.ClassId b += 1 buf[b] = v.Id b += 1 xgb.Put16(buf[b:], v.Len) b += 2 return buf } // FeedbackStateListBytes writes a list of FeedbackState values to a byte slice. func FeedbackStateListBytes(buf []byte, list []FeedbackState) int { b := 0 var structBytes []byte for _, item := range list { structBytes = item.Bytes() copy(buf[b:], structBytes) b += len(structBytes) } return xgb.Pad(b) } // FocusIn is the event number for a FocusInEvent. const FocusIn = 6 type FocusInEvent struct { Sequence uint16 Detail byte Time xproto.Timestamp Window xproto.Window Mode byte DeviceId byte // padding: 18 bytes } // FocusInEventNew constructs a FocusInEvent value that implements xgb.Event from a byte slice. func FocusInEventNew(buf []byte) xgb.Event { v := FocusInEvent{} b := 1 // don't read event number v.Detail = buf[b] b += 1 v.Sequence = xgb.Get16(buf[b:]) b += 2 v.Time = xproto.Timestamp(xgb.Get32(buf[b:])) b += 4 v.Window = xproto.Window(xgb.Get32(buf[b:])) b += 4 v.Mode = buf[b] b += 1 v.DeviceId = buf[b] b += 1 b += 18 // padding return v } // Bytes writes a FocusInEvent value to a byte slice. func (v FocusInEvent) Bytes() []byte { buf := make([]byte, 32) b := 0 // write event number buf[b] = 6 b += 1 buf[b] = v.Detail b += 1 b += 2 // skip sequence number xgb.Put32(buf[b:], uint32(v.Time)) b += 4 xgb.Put32(buf[b:], uint32(v.Window)) b += 4 buf[b] = v.Mode b += 1 buf[b] = v.DeviceId b += 1 b += 18 // padding return buf } // SequenceId returns the sequence id attached to the FocusIn event. // Events without a sequence number (KeymapNotify) return 0. // This is mostly used internally. func (v FocusInEvent) SequenceId() uint16 { return v.Sequence } // String is a rudimentary string representation of FocusInEvent. func (v FocusInEvent) String() string { fieldVals := make([]string, 0, 6) fieldVals = append(fieldVals, xgb.Sprintf("Sequence: %d", v.Sequence)) fieldVals = append(fieldVals, xgb.Sprintf("Detail: %d", v.Detail)) fieldVals = append(fieldVals, xgb.Sprintf("Time: %d", v.Time)) fieldVals = append(fieldVals, xgb.Sprintf("Window: %d", v.Window)) fieldVals = append(fieldVals, xgb.Sprintf("Mode: %d", v.Mode)) fieldVals = append(fieldVals, xgb.Sprintf("DeviceId: %d", v.DeviceId)) return "FocusIn {" + xgb.StringsJoin(fieldVals, ", ") + "}" } func init() { xgb.NewExtEventFuncs["XInputExtension"][6] = FocusInEventNew } // FocusOut is the event number for a FocusOutEvent. const FocusOut = 7 type FocusOutEvent FocusInEvent // FocusOutEventNew constructs a FocusOutEvent value that implements xgb.Event from a byte slice. func FocusOutEventNew(buf []byte) xgb.Event { return FocusOutEvent(FocusInEventNew(buf).(FocusInEvent)) } // Bytes writes a FocusOutEvent value to a byte slice. func (v FocusOutEvent) Bytes() []byte { return FocusInEvent(v).Bytes() } // SequenceId returns the sequence id attached to the FocusOut event. // Events without a sequence number (KeymapNotify) return 0. // This is mostly used internally. func (v FocusOutEvent) SequenceId() uint16 { return v.Sequence } func (v FocusOutEvent) String() string { fieldVals := make([]string, 0, 6) fieldVals = append(fieldVals, xgb.Sprintf("Sequence: %d", v.Sequence)) fieldVals = append(fieldVals, xgb.Sprintf("Detail: %d", v.Detail)) fieldVals = append(fieldVals, xgb.Sprintf("Time: %d", v.Time)) fieldVals = append(fieldVals, xgb.Sprintf("Window: %d", v.Window)) fieldVals = append(fieldVals, xgb.Sprintf("Mode: %d", v.Mode)) fieldVals = append(fieldVals, xgb.Sprintf("DeviceId: %d", v.DeviceId)) return "FocusOut {" + xgb.StringsJoin(fieldVals, ", ") + "}" } func init() { xgb.NewExtEventFuncs["XInputExtension"][7] = FocusOutEventNew } const ( InputClassKey = 0 InputClassButton = 1 InputClassValuator = 2 InputClassFeedback = 3 InputClassProximity = 4 InputClassFocus = 5 InputClassOther = 6 ) type InputClassInfo struct { ClassId byte EventTypeBase byte } // InputClassInfoRead reads a byte slice into a InputClassInfo value. func InputClassInfoRead(buf []byte, v *InputClassInfo) int { b := 0 v.ClassId = buf[b] b += 1 v.EventTypeBase = buf[b] b += 1 return b } // InputClassInfoReadList reads a byte slice into a list of InputClassInfo values. func InputClassInfoReadList(buf []byte, dest []InputClassInfo) int { b := 0 for i := 0; i < len(dest); i++ { dest[i] = InputClassInfo{} b += InputClassInfoRead(buf[b:], &dest[i]) } return xgb.Pad(b) } // Bytes writes a InputClassInfo value to a byte slice. func (v InputClassInfo) Bytes() []byte { buf := make([]byte, 2) b := 0 buf[b] = v.ClassId b += 1 buf[b] = v.EventTypeBase b += 1 return buf } // InputClassInfoListBytes writes a list of InputClassInfo values to a byte slice. func InputClassInfoListBytes(buf []byte, list []InputClassInfo) int { b := 0 var structBytes []byte for _, item := range list { structBytes = item.Bytes() copy(buf[b:], structBytes) b += len(structBytes) } return xgb.Pad(b) } type InputInfo struct { ClassId byte Len byte } // InputInfoRead reads a byte slice into a InputInfo value. func InputInfoRead(buf []byte, v *InputInfo) int { b := 0 v.ClassId = buf[b] b += 1 v.Len = buf[b] b += 1 return b } // InputInfoReadList reads a byte slice into a list of InputInfo values. func InputInfoReadList(buf []byte, dest []InputInfo) int { b := 0 for i := 0; i < len(dest); i++ { dest[i] = InputInfo{} b += InputInfoRead(buf[b:], &dest[i]) } return xgb.Pad(b) } // Bytes writes a InputInfo value to a byte slice. func (v InputInfo) Bytes() []byte { buf := make([]byte, 2) b := 0 buf[b] = v.ClassId b += 1 buf[b] = v.Len b += 1 return buf } // InputInfoListBytes writes a list of InputInfo values to a byte slice. func InputInfoListBytes(buf []byte, list []InputInfo) int { b := 0 var structBytes []byte for _, item := range list { structBytes = item.Bytes() copy(buf[b:], structBytes) b += len(structBytes) } return xgb.Pad(b) } type InputState struct { ClassId byte Len byte NumItems byte } // InputStateRead reads a byte slice into a InputState value. func InputStateRead(buf []byte, v *InputState) int { b := 0 v.ClassId = buf[b] b += 1 v.Len = buf[b] b += 1 v.NumItems = buf[b] b += 1 return b } // InputStateReadList reads a byte slice into a list of InputState values. func InputStateReadList(buf []byte, dest []InputState) int { b := 0 for i := 0; i < len(dest); i++ { dest[i] = InputState{} b += InputStateRead(buf[b:], &dest[i]) } return xgb.Pad(b) } // Bytes writes a InputState value to a byte slice. func (v InputState) Bytes() []byte { buf := make([]byte, 3) b := 0 buf[b] = v.ClassId b += 1 buf[b] = v.Len b += 1 buf[b] = v.NumItems b += 1 return buf } // InputStateListBytes writes a list of InputState values to a byte slice. func InputStateListBytes(buf []byte, list []InputState) int { b := 0 var structBytes []byte for _, item := range list { structBytes = item.Bytes() copy(buf[b:], structBytes) b += len(structBytes) } return xgb.Pad(b) } type IntegerFeedbackCtl struct { ClassId byte Id byte Len uint16 IntToDisplay int32 } // IntegerFeedbackCtlRead reads a byte slice into a IntegerFeedbackCtl value. func IntegerFeedbackCtlRead(buf []byte, v *IntegerFeedbackCtl) int { b := 0 v.ClassId = buf[b] b += 1 v.Id = buf[b] b += 1 v.Len = xgb.Get16(buf[b:]) b += 2 v.IntToDisplay = int32(xgb.Get32(buf[b:])) b += 4 return b } // IntegerFeedbackCtlReadList reads a byte slice into a list of IntegerFeedbackCtl values. func IntegerFeedbackCtlReadList(buf []byte, dest []IntegerFeedbackCtl) int { b := 0 for i := 0; i < len(dest); i++ { dest[i] = IntegerFeedbackCtl{} b += IntegerFeedbackCtlRead(buf[b:], &dest[i]) } return xgb.Pad(b) } // Bytes writes a IntegerFeedbackCtl value to a byte slice. func (v IntegerFeedbackCtl) Bytes() []byte { buf := make([]byte, 8) b := 0 buf[b] = v.ClassId b += 1 buf[b] = v.Id b += 1 xgb.Put16(buf[b:], v.Len) b += 2 xgb.Put32(buf[b:], uint32(v.IntToDisplay)) b += 4 return buf } // IntegerFeedbackCtlListBytes writes a list of IntegerFeedbackCtl values to a byte slice. func IntegerFeedbackCtlListBytes(buf []byte, list []IntegerFeedbackCtl) int { b := 0 var structBytes []byte for _, item := range list { structBytes = item.Bytes() copy(buf[b:], structBytes) b += len(structBytes) } return xgb.Pad(b) } type IntegerFeedbackState struct { ClassId byte Id byte Len uint16 Resolution uint32 MinValue int32 MaxValue int32 } // IntegerFeedbackStateRead reads a byte slice into a IntegerFeedbackState value. func IntegerFeedbackStateRead(buf []byte, v *IntegerFeedbackState) int { b := 0 v.ClassId = buf[b] b += 1 v.Id = buf[b] b += 1 v.Len = xgb.Get16(buf[b:]) b += 2 v.Resolution = xgb.Get32(buf[b:]) b += 4 v.MinValue = int32(xgb.Get32(buf[b:])) b += 4 v.MaxValue = int32(xgb.Get32(buf[b:])) b += 4 return b } // IntegerFeedbackStateReadList reads a byte slice into a list of IntegerFeedbackState values. func IntegerFeedbackStateReadList(buf []byte, dest []IntegerFeedbackState) int { b := 0 for i := 0; i < len(dest); i++ { dest[i] = IntegerFeedbackState{} b += IntegerFeedbackStateRead(buf[b:], &dest[i]) } return xgb.Pad(b) } // Bytes writes a IntegerFeedbackState value to a byte slice. func (v IntegerFeedbackState) Bytes() []byte { buf := make([]byte, 16) b := 0 buf[b] = v.ClassId b += 1 buf[b] = v.Id b += 1 xgb.Put16(buf[b:], v.Len) b += 2 xgb.Put32(buf[b:], v.Resolution) b += 4 xgb.Put32(buf[b:], uint32(v.MinValue)) b += 4 xgb.Put32(buf[b:], uint32(v.MaxValue)) b += 4 return buf } // IntegerFeedbackStateListBytes writes a list of IntegerFeedbackState values to a byte slice. func IntegerFeedbackStateListBytes(buf []byte, list []IntegerFeedbackState) int { b := 0 var structBytes []byte for _, item := range list { structBytes = item.Bytes() copy(buf[b:], structBytes) b += len(structBytes) } return xgb.Pad(b) } type KbdFeedbackCtl struct { ClassId byte Id byte Len uint16 Key KeyCode AutoRepeatMode byte KeyClickPercent int8 BellPercent int8 BellPitch int16 BellDuration int16 LedMask uint32 LedValues uint32 } // KbdFeedbackCtlRead reads a byte slice into a KbdFeedbackCtl value. func KbdFeedbackCtlRead(buf []byte, v *KbdFeedbackCtl) int { b := 0 v.ClassId = buf[b] b += 1 v.Id = buf[b] b += 1 v.Len = xgb.Get16(buf[b:]) b += 2 v.Key = KeyCode(buf[b]) b += 1 v.AutoRepeatMode = buf[b] b += 1 v.KeyClickPercent = int8(buf[b]) b += 1 v.BellPercent = int8(buf[b]) b += 1 v.BellPitch = int16(xgb.Get16(buf[b:])) b += 2 v.BellDuration = int16(xgb.Get16(buf[b:])) b += 2 v.LedMask = xgb.Get32(buf[b:]) b += 4 v.LedValues = xgb.Get32(buf[b:]) b += 4 return b } // KbdFeedbackCtlReadList reads a byte slice into a list of KbdFeedbackCtl values. func KbdFeedbackCtlReadList(buf []byte, dest []KbdFeedbackCtl) int { b := 0 for i := 0; i < len(dest); i++ { dest[i] = KbdFeedbackCtl{} b += KbdFeedbackCtlRead(buf[b:], &dest[i]) } return xgb.Pad(b) } // Bytes writes a KbdFeedbackCtl value to a byte slice. func (v KbdFeedbackCtl) Bytes() []byte { buf := make([]byte, 20) b := 0 buf[b] = v.ClassId b += 1 buf[b] = v.Id b += 1 xgb.Put16(buf[b:], v.Len) b += 2 buf[b] = byte(v.Key) b += 1 buf[b] = v.AutoRepeatMode b += 1 buf[b] = byte(v.KeyClickPercent) b += 1 buf[b] = byte(v.BellPercent) b += 1 xgb.Put16(buf[b:], uint16(v.BellPitch)) b += 2 xgb.Put16(buf[b:], uint16(v.BellDuration)) b += 2 xgb.Put32(buf[b:], v.LedMask) b += 4 xgb.Put32(buf[b:], v.LedValues) b += 4 return buf } // KbdFeedbackCtlListBytes writes a list of KbdFeedbackCtl values to a byte slice. func KbdFeedbackCtlListBytes(buf []byte, list []KbdFeedbackCtl) int { b := 0 var structBytes []byte for _, item := range list { structBytes = item.Bytes() copy(buf[b:], structBytes) b += len(structBytes) } return xgb.Pad(b) } type KbdFeedbackState struct { ClassId byte Id byte Len uint16 Pitch uint16 Duration uint16 LedMask uint32 LedValues uint32 GlobalAutoRepeat bool Click byte Percent byte // padding: 1 bytes AutoRepeats []byte // size: 32 } // KbdFeedbackStateRead reads a byte slice into a KbdFeedbackState value. func KbdFeedbackStateRead(buf []byte, v *KbdFeedbackState) int { b := 0 v.ClassId = buf[b] b += 1 v.Id = buf[b] b += 1 v.Len = xgb.Get16(buf[b:]) b += 2 v.Pitch = xgb.Get16(buf[b:]) b += 2 v.Duration = xgb.Get16(buf[b:]) b += 2 v.LedMask = xgb.Get32(buf[b:]) b += 4 v.LedValues = xgb.Get32(buf[b:]) b += 4 if buf[b] == 1 { v.GlobalAutoRepeat = true } else { v.GlobalAutoRepeat = false } b += 1 v.Click = buf[b] b += 1 v.Percent = buf[b] b += 1 b += 1 // padding v.AutoRepeats = make([]byte, 32) copy(v.AutoRepeats[:32], buf[b:]) b += xgb.Pad(int(32)) return b } // KbdFeedbackStateReadList reads a byte slice into a list of KbdFeedbackState values. func KbdFeedbackStateReadList(buf []byte, dest []KbdFeedbackState) int { b := 0 for i := 0; i < len(dest); i++ { dest[i] = KbdFeedbackState{} b += KbdFeedbackStateRead(buf[b:], &dest[i]) } return xgb.Pad(b) } // Bytes writes a KbdFeedbackState value to a byte slice. func (v KbdFeedbackState) Bytes() []byte { buf := make([]byte, 52) b := 0 buf[b] = v.ClassId b += 1 buf[b] = v.Id b += 1 xgb.Put16(buf[b:], v.Len) b += 2 xgb.Put16(buf[b:], v.Pitch) b += 2 xgb.Put16(buf[b:], v.Duration) b += 2 xgb.Put32(buf[b:], v.LedMask) b += 4 xgb.Put32(buf[b:], v.LedValues) b += 4 if v.GlobalAutoRepeat { buf[b] = 1 } else { buf[b] = 0 } b += 1 buf[b] = v.Click b += 1 buf[b] = v.Percent b += 1 b += 1 // padding copy(buf[b:], v.AutoRepeats[:32]) b += xgb.Pad(int(32)) return buf } // KbdFeedbackStateListBytes writes a list of KbdFeedbackState values to a byte slice. func KbdFeedbackStateListBytes(buf []byte, list []KbdFeedbackState) int { b := 0 var structBytes []byte for _, item := range list { structBytes = item.Bytes() copy(buf[b:], structBytes) b += len(structBytes) } return xgb.Pad(b) } // KbdFeedbackStateListSize computes the size (bytes) of a list of KbdFeedbackState values. func KbdFeedbackStateListSize(list []KbdFeedbackState) int { size := 0 for _ = range list { size += 52 } return size } type KeyCode byte type KeyInfo struct { ClassId byte Len byte MinKeycode KeyCode MaxKeycode KeyCode NumKeys uint16 // padding: 2 bytes } // KeyInfoRead reads a byte slice into a KeyInfo value. func KeyInfoRead(buf []byte, v *KeyInfo) int { b := 0 v.ClassId = buf[b] b += 1 v.Len = buf[b] b += 1 v.MinKeycode = KeyCode(buf[b]) b += 1 v.MaxKeycode = KeyCode(buf[b]) b += 1 v.NumKeys = xgb.Get16(buf[b:]) b += 2 b += 2 // padding return b } // KeyInfoReadList reads a byte slice into a list of KeyInfo values. func KeyInfoReadList(buf []byte, dest []KeyInfo) int { b := 0 for i := 0; i < len(dest); i++ { dest[i] = KeyInfo{} b += KeyInfoRead(buf[b:], &dest[i]) } return xgb.Pad(b) } // Bytes writes a KeyInfo value to a byte slice. func (v KeyInfo) Bytes() []byte { buf := make([]byte, 8) b := 0 buf[b] = v.ClassId b += 1 buf[b] = v.Len b += 1 buf[b] = byte(v.MinKeycode) b += 1 buf[b] = byte(v.MaxKeycode) b += 1 xgb.Put16(buf[b:], v.NumKeys) b += 2 b += 2 // padding return buf } // KeyInfoListBytes writes a list of KeyInfo values to a byte slice. func KeyInfoListBytes(buf []byte, list []KeyInfo) int { b := 0 var structBytes []byte for _, item := range list { structBytes = item.Bytes() copy(buf[b:], structBytes) b += len(structBytes) } return xgb.Pad(b) } type KeyState struct { ClassId byte Len byte NumKeys byte // padding: 1 bytes Keys []byte // size: 32 } // KeyStateRead reads a byte slice into a KeyState value. func KeyStateRead(buf []byte, v *KeyState) int { b := 0 v.ClassId = buf[b] b += 1 v.Len = buf[b] b += 1 v.NumKeys = buf[b] b += 1 b += 1 // padding v.Keys = make([]byte, 32) copy(v.Keys[:32], buf[b:]) b += xgb.Pad(int(32)) return b } // KeyStateReadList reads a byte slice into a list of KeyState values. func KeyStateReadList(buf []byte, dest []KeyState) int { b := 0 for i := 0; i < len(dest); i++ { dest[i] = KeyState{} b += KeyStateRead(buf[b:], &dest[i]) } return xgb.Pad(b) } // Bytes writes a KeyState value to a byte slice. func (v KeyState) Bytes() []byte { buf := make([]byte, 36) b := 0 buf[b] = v.ClassId b += 1 buf[b] = v.Len b += 1 buf[b] = v.NumKeys b += 1 b += 1 // padding copy(buf[b:], v.Keys[:32]) b += xgb.Pad(int(32)) return buf } // KeyStateListBytes writes a list of KeyState values to a byte slice. func KeyStateListBytes(buf []byte, list []KeyState) int { b := 0 var structBytes []byte for _, item := range list { structBytes = item.Bytes() copy(buf[b:], structBytes) b += len(structBytes) } return xgb.Pad(b) } // KeyStateListSize computes the size (bytes) of a list of KeyState values. func KeyStateListSize(list []KeyState) int { size := 0 for _ = range list { size += 36 } return size } type LedFeedbackCtl struct { ClassId byte Id byte Len uint16 LedMask uint32 LedValues uint32 } // LedFeedbackCtlRead reads a byte slice into a LedFeedbackCtl value. func LedFeedbackCtlRead(buf []byte, v *LedFeedbackCtl) int { b := 0 v.ClassId = buf[b] b += 1 v.Id = buf[b] b += 1 v.Len = xgb.Get16(buf[b:]) b += 2 v.LedMask = xgb.Get32(buf[b:]) b += 4 v.LedValues = xgb.Get32(buf[b:]) b += 4 return b } // LedFeedbackCtlReadList reads a byte slice into a list of LedFeedbackCtl values. func LedFeedbackCtlReadList(buf []byte, dest []LedFeedbackCtl) int { b := 0 for i := 0; i < len(dest); i++ { dest[i] = LedFeedbackCtl{} b += LedFeedbackCtlRead(buf[b:], &dest[i]) } return xgb.Pad(b) } // Bytes writes a LedFeedbackCtl value to a byte slice. func (v LedFeedbackCtl) Bytes() []byte { buf := make([]byte, 12) b := 0 buf[b] = v.ClassId b += 1 buf[b] = v.Id b += 1 xgb.Put16(buf[b:], v.Len) b += 2 xgb.Put32(buf[b:], v.LedMask) b += 4 xgb.Put32(buf[b:], v.LedValues) b += 4 return buf } // LedFeedbackCtlListBytes writes a list of LedFeedbackCtl values to a byte slice. func LedFeedbackCtlListBytes(buf []byte, list []LedFeedbackCtl) int { b := 0 var structBytes []byte for _, item := range list { structBytes = item.Bytes() copy(buf[b:], structBytes) b += len(structBytes) } return xgb.Pad(b) } type LedFeedbackState struct { ClassId byte Id byte Len uint16 LedMask uint32 LedValues uint32 } // LedFeedbackStateRead reads a byte slice into a LedFeedbackState value. func LedFeedbackStateRead(buf []byte, v *LedFeedbackState) int { b := 0 v.ClassId = buf[b] b += 1 v.Id = buf[b] b += 1 v.Len = xgb.Get16(buf[b:]) b += 2 v.LedMask = xgb.Get32(buf[b:]) b += 4 v.LedValues = xgb.Get32(buf[b:]) b += 4 return b } // LedFeedbackStateReadList reads a byte slice into a list of LedFeedbackState values. func LedFeedbackStateReadList(buf []byte, dest []LedFeedbackState) int { b := 0 for i := 0; i < len(dest); i++ { dest[i] = LedFeedbackState{} b += LedFeedbackStateRead(buf[b:], &dest[i]) } return xgb.Pad(b) } // Bytes writes a LedFeedbackState value to a byte slice. func (v LedFeedbackState) Bytes() []byte { buf := make([]byte, 12) b := 0 buf[b] = v.ClassId b += 1 buf[b] = v.Id b += 1 xgb.Put16(buf[b:], v.Len) b += 2 xgb.Put32(buf[b:], v.LedMask) b += 4 xgb.Put32(buf[b:], v.LedValues) b += 4 return buf } // LedFeedbackStateListBytes writes a list of LedFeedbackState values to a byte slice. func LedFeedbackStateListBytes(buf []byte, list []LedFeedbackState) int { b := 0 var structBytes []byte for _, item := range list { structBytes = item.Bytes() copy(buf[b:], structBytes) b += len(structBytes) } return xgb.Pad(b) } // BadMode is the error number for a BadMode. const BadMode = 2 type ModeError struct { Sequence uint16 NiceName string } // ModeErrorNew constructs a ModeError value that implements xgb.Error from a byte slice. func ModeErrorNew(buf []byte) xgb.Error { v := ModeError{} v.NiceName = "Mode" b := 1 // skip error determinant b += 1 // don't read error number v.Sequence = xgb.Get16(buf[b:]) b += 2 return v } // SequenceId returns the sequence id attached to the BadMode error. // This is mostly used internally. func (err ModeError) SequenceId() uint16 { return err.Sequence } // BadId returns the 'BadValue' number if one exists for the BadMode error. If no bad value exists, 0 is returned. func (err ModeError) BadId() uint32 { return 0 } // Error returns a rudimentary string representation of the BadMode error. func (err ModeError) Error() string { fieldVals := make([]string, 0, 0) fieldVals = append(fieldVals, "NiceName: "+err.NiceName) fieldVals = append(fieldVals, xgb.Sprintf("Sequence: %d", err.Sequence)) return "BadMode {" + xgb.StringsJoin(fieldVals, ", ") + "}" } func init() { xgb.NewExtErrorFuncs["XInputExtension"][2] = ModeErrorNew } const ( PropagateModeAddToList = 0 PropagateModeDeleteFromList = 1 ) // ProximityIn is the event number for a ProximityInEvent. const ProximityIn = 8 type ProximityInEvent DeviceKeyPressEvent // ProximityInEventNew constructs a ProximityInEvent value that implements xgb.Event from a byte slice. func ProximityInEventNew(buf []byte) xgb.Event { return ProximityInEvent(DeviceKeyPressEventNew(buf).(DeviceKeyPressEvent)) } // Bytes writes a ProximityInEvent value to a byte slice. func (v ProximityInEvent) Bytes() []byte { return DeviceKeyPressEvent(v).Bytes() } // SequenceId returns the sequence id attached to the ProximityIn event. // Events without a sequence number (KeymapNotify) return 0. // This is mostly used internally. func (v ProximityInEvent) SequenceId() uint16 { return v.Sequence } func (v ProximityInEvent) String() string { fieldVals := make([]string, 0, 12) fieldVals = append(fieldVals, xgb.Sprintf("Sequence: %d", v.Sequence)) fieldVals = append(fieldVals, xgb.Sprintf("Detail: %d", v.Detail)) fieldVals = append(fieldVals, xgb.Sprintf("Time: %d", v.Time)) fieldVals = append(fieldVals, xgb.Sprintf("Root: %d", v.Root)) fieldVals = append(fieldVals, xgb.Sprintf("Event: %d", v.Event)) fieldVals = append(fieldVals, xgb.Sprintf("Child: %d", v.Child)) fieldVals = append(fieldVals, xgb.Sprintf("RootX: %d", v.RootX)) fieldVals = append(fieldVals, xgb.Sprintf("RootY: %d", v.RootY)) fieldVals = append(fieldVals, xgb.Sprintf("EventX: %d", v.EventX)) fieldVals = append(fieldVals, xgb.Sprintf("EventY: %d", v.EventY)) fieldVals = append(fieldVals, xgb.Sprintf("State: %d", v.State)) fieldVals = append(fieldVals, xgb.Sprintf("SameScreen: %t", v.SameScreen)) fieldVals = append(fieldVals, xgb.Sprintf("DeviceId: %d", v.DeviceId)) return "ProximityIn {" + xgb.StringsJoin(fieldVals, ", ") + "}" } func init() { xgb.NewExtEventFuncs["XInputExtension"][8] = ProximityInEventNew } // ProximityOut is the event number for a ProximityOutEvent. const ProximityOut = 9 type ProximityOutEvent DeviceKeyPressEvent // ProximityOutEventNew constructs a ProximityOutEvent value that implements xgb.Event from a byte slice. func ProximityOutEventNew(buf []byte) xgb.Event { return ProximityOutEvent(DeviceKeyPressEventNew(buf).(DeviceKeyPressEvent)) } // Bytes writes a ProximityOutEvent value to a byte slice. func (v ProximityOutEvent) Bytes() []byte { return DeviceKeyPressEvent(v).Bytes() } // SequenceId returns the sequence id attached to the ProximityOut event. // Events without a sequence number (KeymapNotify) return 0. // This is mostly used internally. func (v ProximityOutEvent) SequenceId() uint16 { return v.Sequence } func (v ProximityOutEvent) String() string { fieldVals := make([]string, 0, 12) fieldVals = append(fieldVals, xgb.Sprintf("Sequence: %d", v.Sequence)) fieldVals = append(fieldVals, xgb.Sprintf("Detail: %d", v.Detail)) fieldVals = append(fieldVals, xgb.Sprintf("Time: %d", v.Time)) fieldVals = append(fieldVals, xgb.Sprintf("Root: %d", v.Root)) fieldVals = append(fieldVals, xgb.Sprintf("Event: %d", v.Event)) fieldVals = append(fieldVals, xgb.Sprintf("Child: %d", v.Child)) fieldVals = append(fieldVals, xgb.Sprintf("RootX: %d", v.RootX)) fieldVals = append(fieldVals, xgb.Sprintf("RootY: %d", v.RootY)) fieldVals = append(fieldVals, xgb.Sprintf("EventX: %d", v.EventX)) fieldVals = append(fieldVals, xgb.Sprintf("EventY: %d", v.EventY)) fieldVals = append(fieldVals, xgb.Sprintf("State: %d", v.State)) fieldVals = append(fieldVals, xgb.Sprintf("SameScreen: %t", v.SameScreen)) fieldVals = append(fieldVals, xgb.Sprintf("DeviceId: %d", v.DeviceId)) return "ProximityOut {" + xgb.StringsJoin(fieldVals, ", ") + "}" } func init() { xgb.NewExtEventFuncs["XInputExtension"][9] = ProximityOutEventNew } type PtrFeedbackCtl struct { ClassId byte Id byte Len uint16 // padding: 2 bytes Num int16 Denom int16 Threshold int16 } // PtrFeedbackCtlRead reads a byte slice into a PtrFeedbackCtl value. func PtrFeedbackCtlRead(buf []byte, v *PtrFeedbackCtl) int { b := 0 v.ClassId = buf[b] b += 1 v.Id = buf[b] b += 1 v.Len = xgb.Get16(buf[b:]) b += 2 b += 2 // padding v.Num = int16(xgb.Get16(buf[b:])) b += 2 v.Denom = int16(xgb.Get16(buf[b:])) b += 2 v.Threshold = int16(xgb.Get16(buf[b:])) b += 2 return b } // PtrFeedbackCtlReadList reads a byte slice into a list of PtrFeedbackCtl values. func PtrFeedbackCtlReadList(buf []byte, dest []PtrFeedbackCtl) int { b := 0 for i := 0; i < len(dest); i++ { dest[i] = PtrFeedbackCtl{} b += PtrFeedbackCtlRead(buf[b:], &dest[i]) } return xgb.Pad(b) } // Bytes writes a PtrFeedbackCtl value to a byte slice. func (v PtrFeedbackCtl) Bytes() []byte { buf := make([]byte, 12) b := 0 buf[b] = v.ClassId b += 1 buf[b] = v.Id b += 1 xgb.Put16(buf[b:], v.Len) b += 2 b += 2 // padding xgb.Put16(buf[b:], uint16(v.Num)) b += 2 xgb.Put16(buf[b:], uint16(v.Denom)) b += 2 xgb.Put16(buf[b:], uint16(v.Threshold)) b += 2 return buf } // PtrFeedbackCtlListBytes writes a list of PtrFeedbackCtl values to a byte slice. func PtrFeedbackCtlListBytes(buf []byte, list []PtrFeedbackCtl) int { b := 0 var structBytes []byte for _, item := range list { structBytes = item.Bytes() copy(buf[b:], structBytes) b += len(structBytes) } return xgb.Pad(b) } type PtrFeedbackState struct { ClassId byte Id byte Len uint16 // padding: 2 bytes AccelNum uint16 AccelDenom uint16 Threshold uint16 } // PtrFeedbackStateRead reads a byte slice into a PtrFeedbackState value. func PtrFeedbackStateRead(buf []byte, v *PtrFeedbackState) int { b := 0 v.ClassId = buf[b] b += 1 v.Id = buf[b] b += 1 v.Len = xgb.Get16(buf[b:]) b += 2 b += 2 // padding v.AccelNum = xgb.Get16(buf[b:]) b += 2 v.AccelDenom = xgb.Get16(buf[b:]) b += 2 v.Threshold = xgb.Get16(buf[b:]) b += 2 return b } // PtrFeedbackStateReadList reads a byte slice into a list of PtrFeedbackState values. func PtrFeedbackStateReadList(buf []byte, dest []PtrFeedbackState) int { b := 0 for i := 0; i < len(dest); i++ { dest[i] = PtrFeedbackState{} b += PtrFeedbackStateRead(buf[b:], &dest[i]) } return xgb.Pad(b) } // Bytes writes a PtrFeedbackState value to a byte slice. func (v PtrFeedbackState) Bytes() []byte { buf := make([]byte, 12) b := 0 buf[b] = v.ClassId b += 1 buf[b] = v.Id b += 1 xgb.Put16(buf[b:], v.Len) b += 2 b += 2 // padding xgb.Put16(buf[b:], v.AccelNum) b += 2 xgb.Put16(buf[b:], v.AccelDenom) b += 2 xgb.Put16(buf[b:], v.Threshold) b += 2 return buf } // PtrFeedbackStateListBytes writes a list of PtrFeedbackState values to a byte slice. func PtrFeedbackStateListBytes(buf []byte, list []PtrFeedbackState) int { b := 0 var structBytes []byte for _, item := range list { structBytes = item.Bytes() copy(buf[b:], structBytes) b += len(structBytes) } return xgb.Pad(b) } type StringFeedbackCtl struct { ClassId byte Id byte Len uint16 // padding: 2 bytes NumKeysyms uint16 Keysyms []xproto.Keysym // size: xgb.Pad((int(NumKeysyms) * 4)) } // StringFeedbackCtlRead reads a byte slice into a StringFeedbackCtl value. func StringFeedbackCtlRead(buf []byte, v *StringFeedbackCtl) int { b := 0 v.ClassId = buf[b] b += 1 v.Id = buf[b] b += 1 v.Len = xgb.Get16(buf[b:]) b += 2 b += 2 // padding v.NumKeysyms = xgb.Get16(buf[b:]) b += 2 v.Keysyms = make([]xproto.Keysym, v.NumKeysyms) for i := 0; i < int(v.NumKeysyms); i++ { v.Keysyms[i] = xproto.Keysym(xgb.Get32(buf[b:])) b += 4 } b = xgb.Pad(b) return b } // StringFeedbackCtlReadList reads a byte slice into a list of StringFeedbackCtl values. func StringFeedbackCtlReadList(buf []byte, dest []StringFeedbackCtl) int { b := 0 for i := 0; i < len(dest); i++ { dest[i] = StringFeedbackCtl{} b += StringFeedbackCtlRead(buf[b:], &dest[i]) } return xgb.Pad(b) } // Bytes writes a StringFeedbackCtl value to a byte slice. func (v StringFeedbackCtl) Bytes() []byte { buf := make([]byte, (8 + xgb.Pad((int(v.NumKeysyms) * 4)))) b := 0 buf[b] = v.ClassId b += 1 buf[b] = v.Id b += 1 xgb.Put16(buf[b:], v.Len) b += 2 b += 2 // padding xgb.Put16(buf[b:], v.NumKeysyms) b += 2 for i := 0; i < int(v.NumKeysyms); i++ { xgb.Put32(buf[b:], uint32(v.Keysyms[i])) b += 4 } b = xgb.Pad(b) return buf } // StringFeedbackCtlListBytes writes a list of StringFeedbackCtl values to a byte slice. func StringFeedbackCtlListBytes(buf []byte, list []StringFeedbackCtl) int { b := 0 var structBytes []byte for _, item := range list { structBytes = item.Bytes() copy(buf[b:], structBytes) b += len(structBytes) } return xgb.Pad(b) } // StringFeedbackCtlListSize computes the size (bytes) of a list of StringFeedbackCtl values. func StringFeedbackCtlListSize(list []StringFeedbackCtl) int { size := 0 for _, item := range list { size += (8 + xgb.Pad((int(item.NumKeysyms) * 4))) } return size } type StringFeedbackState struct { ClassId byte Id byte Len uint16 MaxSymbols uint16 NumKeysyms uint16 Keysyms []xproto.Keysym // size: xgb.Pad((int(NumKeysyms) * 4)) } // StringFeedbackStateRead reads a byte slice into a StringFeedbackState value. func StringFeedbackStateRead(buf []byte, v *StringFeedbackState) int { b := 0 v.ClassId = buf[b] b += 1 v.Id = buf[b] b += 1 v.Len = xgb.Get16(buf[b:]) b += 2 v.MaxSymbols = xgb.Get16(buf[b:]) b += 2 v.NumKeysyms = xgb.Get16(buf[b:]) b += 2 v.Keysyms = make([]xproto.Keysym, v.NumKeysyms) for i := 0; i < int(v.NumKeysyms); i++ { v.Keysyms[i] = xproto.Keysym(xgb.Get32(buf[b:])) b += 4 } b = xgb.Pad(b) return b } // StringFeedbackStateReadList reads a byte slice into a list of StringFeedbackState values. func StringFeedbackStateReadList(buf []byte, dest []StringFeedbackState) int { b := 0 for i := 0; i < len(dest); i++ { dest[i] = StringFeedbackState{} b += StringFeedbackStateRead(buf[b:], &dest[i]) } return xgb.Pad(b) } // Bytes writes a StringFeedbackState value to a byte slice. func (v StringFeedbackState) Bytes() []byte { buf := make([]byte, (8 + xgb.Pad((int(v.NumKeysyms) * 4)))) b := 0 buf[b] = v.ClassId b += 1 buf[b] = v.Id b += 1 xgb.Put16(buf[b:], v.Len) b += 2 xgb.Put16(buf[b:], v.MaxSymbols) b += 2 xgb.Put16(buf[b:], v.NumKeysyms) b += 2 for i := 0; i < int(v.NumKeysyms); i++ { xgb.Put32(buf[b:], uint32(v.Keysyms[i])) b += 4 } b = xgb.Pad(b) return buf } // StringFeedbackStateListBytes writes a list of StringFeedbackState values to a byte slice. func StringFeedbackStateListBytes(buf []byte, list []StringFeedbackState) int { b := 0 var structBytes []byte for _, item := range list { structBytes = item.Bytes() copy(buf[b:], structBytes) b += len(structBytes) } return xgb.Pad(b) } // StringFeedbackStateListSize computes the size (bytes) of a list of StringFeedbackState values. func StringFeedbackStateListSize(list []StringFeedbackState) int { size := 0 for _, item := range list { size += (8 + xgb.Pad((int(item.NumKeysyms) * 4))) } return size } type ValuatorInfo struct { ClassId byte Len byte AxesLen byte Mode byte MotionSize uint32 Axes []AxisInfo // size: xgb.Pad((int(AxesLen) * 12)) } // ValuatorInfoRead reads a byte slice into a ValuatorInfo value. func ValuatorInfoRead(buf []byte, v *ValuatorInfo) int { b := 0 v.ClassId = buf[b] b += 1 v.Len = buf[b] b += 1 v.AxesLen = buf[b] b += 1 v.Mode = buf[b] b += 1 v.MotionSize = xgb.Get32(buf[b:]) b += 4 v.Axes = make([]AxisInfo, v.AxesLen) b += AxisInfoReadList(buf[b:], v.Axes) return b } // ValuatorInfoReadList reads a byte slice into a list of ValuatorInfo values. func ValuatorInfoReadList(buf []byte, dest []ValuatorInfo) int { b := 0 for i := 0; i < len(dest); i++ { dest[i] = ValuatorInfo{} b += ValuatorInfoRead(buf[b:], &dest[i]) } return xgb.Pad(b) } // Bytes writes a ValuatorInfo value to a byte slice. func (v ValuatorInfo) Bytes() []byte { buf := make([]byte, (8 + xgb.Pad((int(v.AxesLen) * 12)))) b := 0 buf[b] = v.ClassId b += 1 buf[b] = v.Len b += 1 buf[b] = v.AxesLen b += 1 buf[b] = v.Mode b += 1 xgb.Put32(buf[b:], v.MotionSize) b += 4 b += AxisInfoListBytes(buf[b:], v.Axes) return buf } // ValuatorInfoListBytes writes a list of ValuatorInfo values to a byte slice. func ValuatorInfoListBytes(buf []byte, list []ValuatorInfo) int { b := 0 var structBytes []byte for _, item := range list { structBytes = item.Bytes() copy(buf[b:], structBytes) b += len(structBytes) } return xgb.Pad(b) } // ValuatorInfoListSize computes the size (bytes) of a list of ValuatorInfo values. func ValuatorInfoListSize(list []ValuatorInfo) int { size := 0 for _, item := range list { size += (8 + xgb.Pad((int(item.AxesLen) * 12))) } return size } const ( ValuatorModeRelative = 0 ValuatorModeAbsolute = 1 ) type ValuatorState struct { ClassId byte Len byte NumValuators byte Mode byte Valuators []uint32 // size: xgb.Pad((int(NumValuators) * 4)) } // ValuatorStateRead reads a byte slice into a ValuatorState value. func ValuatorStateRead(buf []byte, v *ValuatorState) int { b := 0 v.ClassId = buf[b] b += 1 v.Len = buf[b] b += 1 v.NumValuators = buf[b] b += 1 v.Mode = buf[b] b += 1 v.Valuators = make([]uint32, v.NumValuators) for i := 0; i < int(v.NumValuators); i++ { v.Valuators[i] = xgb.Get32(buf[b:]) b += 4 } b = xgb.Pad(b) return b } // ValuatorStateReadList reads a byte slice into a list of ValuatorState values. func ValuatorStateReadList(buf []byte, dest []ValuatorState) int { b := 0 for i := 0; i < len(dest); i++ { dest[i] = ValuatorState{} b += ValuatorStateRead(buf[b:], &dest[i]) } return xgb.Pad(b) } // Bytes writes a ValuatorState value to a byte slice. func (v ValuatorState) Bytes() []byte { buf := make([]byte, (4 + xgb.Pad((int(v.NumValuators) * 4)))) b := 0 buf[b] = v.ClassId b += 1 buf[b] = v.Len b += 1 buf[b] = v.NumValuators b += 1 buf[b] = v.Mode b += 1 for i := 0; i < int(v.NumValuators); i++ { xgb.Put32(buf[b:], v.Valuators[i]) b += 4 } b = xgb.Pad(b) return buf } // ValuatorStateListBytes writes a list of ValuatorState values to a byte slice. func ValuatorStateListBytes(buf []byte, list []ValuatorState) int { b := 0 var structBytes []byte for _, item := range list { structBytes = item.Bytes() copy(buf[b:], structBytes) b += len(structBytes) } return xgb.Pad(b) } // ValuatorStateListSize computes the size (bytes) of a list of ValuatorState values. func ValuatorStateListSize(list []ValuatorState) int { size := 0 for _, item := range list { size += (4 + xgb.Pad((int(item.NumValuators) * 4))) } return size } // Skipping definition for base type 'Bool' // Skipping definition for base type 'Byte' // Skipping definition for base type 'Card8' // Skipping definition for base type 'Char' // Skipping definition for base type 'Void' // Skipping definition for base type 'Double' // Skipping definition for base type 'Float' // Skipping definition for base type 'Int16' // Skipping definition for base type 'Int32' // Skipping definition for base type 'Int8' // Skipping definition for base type 'Card16' // Skipping definition for base type 'Card32' // AllowDeviceEventsCookie is a cookie used only for AllowDeviceEvents requests. type AllowDeviceEventsCookie struct { *xgb.Cookie } // AllowDeviceEvents sends an unchecked request. // If an error occurs, it can only be retrieved using xgb.WaitForEvent or xgb.PollForEvent. func AllowDeviceEvents(c *xgb.Conn, Time xproto.Timestamp, Mode byte, DeviceId byte) AllowDeviceEventsCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'AllowDeviceEvents' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(false, false) c.NewRequest(allowDeviceEventsRequest(c, Time, Mode, DeviceId), cookie) return AllowDeviceEventsCookie{cookie} } // AllowDeviceEventsChecked sends a checked request. // If an error occurs, it can be retrieved using AllowDeviceEventsCookie.Check() func AllowDeviceEventsChecked(c *xgb.Conn, Time xproto.Timestamp, Mode byte, DeviceId byte) AllowDeviceEventsCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'AllowDeviceEvents' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(true, false) c.NewRequest(allowDeviceEventsRequest(c, Time, Mode, DeviceId), cookie) return AllowDeviceEventsCookie{cookie} } // Check returns an error if one occurred for checked requests that are not expecting a reply. // This cannot be called for requests expecting a reply, nor for unchecked requests. func (cook AllowDeviceEventsCookie) Check() error { return cook.Cookie.Check() } // Write request to wire for AllowDeviceEvents // allowDeviceEventsRequest writes a AllowDeviceEvents request to a byte slice. func allowDeviceEventsRequest(c *xgb.Conn, Time xproto.Timestamp, Mode byte, DeviceId byte) []byte { size := 12 b := 0 buf := make([]byte, size) buf[b] = c.Extensions["XINPUTEXTENSION"] b += 1 buf[b] = 19 // request opcode b += 1 xgb.Put16(buf[b:], uint16(size/4)) // write request size in 4-byte units b += 2 xgb.Put32(buf[b:], uint32(Time)) b += 4 buf[b] = Mode b += 1 buf[b] = DeviceId b += 1 return buf } // ChangeDeviceDontPropagateListCookie is a cookie used only for ChangeDeviceDontPropagateList requests. type ChangeDeviceDontPropagateListCookie struct { *xgb.Cookie } // ChangeDeviceDontPropagateList sends an unchecked request. // If an error occurs, it can only be retrieved using xgb.WaitForEvent or xgb.PollForEvent. func ChangeDeviceDontPropagateList(c *xgb.Conn, Window xproto.Window, NumClasses uint16, Mode byte, Classes []EventClass) ChangeDeviceDontPropagateListCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'ChangeDeviceDontPropagateList' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(false, false) c.NewRequest(changeDeviceDontPropagateListRequest(c, Window, NumClasses, Mode, Classes), cookie) return ChangeDeviceDontPropagateListCookie{cookie} } // ChangeDeviceDontPropagateListChecked sends a checked request. // If an error occurs, it can be retrieved using ChangeDeviceDontPropagateListCookie.Check() func ChangeDeviceDontPropagateListChecked(c *xgb.Conn, Window xproto.Window, NumClasses uint16, Mode byte, Classes []EventClass) ChangeDeviceDontPropagateListCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'ChangeDeviceDontPropagateList' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(true, false) c.NewRequest(changeDeviceDontPropagateListRequest(c, Window, NumClasses, Mode, Classes), cookie) return ChangeDeviceDontPropagateListCookie{cookie} } // Check returns an error if one occurred for checked requests that are not expecting a reply. // This cannot be called for requests expecting a reply, nor for unchecked requests. func (cook ChangeDeviceDontPropagateListCookie) Check() error { return cook.Cookie.Check() } // Write request to wire for ChangeDeviceDontPropagateList // changeDeviceDontPropagateListRequest writes a ChangeDeviceDontPropagateList request to a byte slice. func changeDeviceDontPropagateListRequest(c *xgb.Conn, Window xproto.Window, NumClasses uint16, Mode byte, Classes []EventClass) []byte { size := xgb.Pad((12 + xgb.Pad((int(NumClasses) * 4)))) b := 0 buf := make([]byte, size) buf[b] = c.Extensions["XINPUTEXTENSION"] b += 1 buf[b] = 8 // request opcode b += 1 xgb.Put16(buf[b:], uint16(size/4)) // write request size in 4-byte units b += 2 xgb.Put32(buf[b:], uint32(Window)) b += 4 xgb.Put16(buf[b:], NumClasses) b += 2 buf[b] = Mode b += 1 b += 1 // padding for i := 0; i < int(NumClasses); i++ { xgb.Put32(buf[b:], uint32(Classes[i])) b += 4 } b = xgb.Pad(b) return buf } // ChangeDeviceKeyMappingCookie is a cookie used only for ChangeDeviceKeyMapping requests. type ChangeDeviceKeyMappingCookie struct { *xgb.Cookie } // ChangeDeviceKeyMapping sends an unchecked request. // If an error occurs, it can only be retrieved using xgb.WaitForEvent or xgb.PollForEvent. func ChangeDeviceKeyMapping(c *xgb.Conn, DeviceId byte, FirstKeycode KeyCode, KeysymsPerKeycode byte, KeycodeCount byte, Keysyms []xproto.Keysym) ChangeDeviceKeyMappingCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'ChangeDeviceKeyMapping' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(false, false) c.NewRequest(changeDeviceKeyMappingRequest(c, DeviceId, FirstKeycode, KeysymsPerKeycode, KeycodeCount, Keysyms), cookie) return ChangeDeviceKeyMappingCookie{cookie} } // ChangeDeviceKeyMappingChecked sends a checked request. // If an error occurs, it can be retrieved using ChangeDeviceKeyMappingCookie.Check() func ChangeDeviceKeyMappingChecked(c *xgb.Conn, DeviceId byte, FirstKeycode KeyCode, KeysymsPerKeycode byte, KeycodeCount byte, Keysyms []xproto.Keysym) ChangeDeviceKeyMappingCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'ChangeDeviceKeyMapping' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(true, false) c.NewRequest(changeDeviceKeyMappingRequest(c, DeviceId, FirstKeycode, KeysymsPerKeycode, KeycodeCount, Keysyms), cookie) return ChangeDeviceKeyMappingCookie{cookie} } // Check returns an error if one occurred for checked requests that are not expecting a reply. // This cannot be called for requests expecting a reply, nor for unchecked requests. func (cook ChangeDeviceKeyMappingCookie) Check() error { return cook.Cookie.Check() } // Write request to wire for ChangeDeviceKeyMapping // changeDeviceKeyMappingRequest writes a ChangeDeviceKeyMapping request to a byte slice. func changeDeviceKeyMappingRequest(c *xgb.Conn, DeviceId byte, FirstKeycode KeyCode, KeysymsPerKeycode byte, KeycodeCount byte, Keysyms []xproto.Keysym) []byte { size := xgb.Pad((8 + xgb.Pad(((int(KeycodeCount) * int(KeysymsPerKeycode)) * 4)))) b := 0 buf := make([]byte, size) buf[b] = c.Extensions["XINPUTEXTENSION"] b += 1 buf[b] = 25 // request opcode b += 1 xgb.Put16(buf[b:], uint16(size/4)) // write request size in 4-byte units b += 2 buf[b] = DeviceId b += 1 buf[b] = byte(FirstKeycode) b += 1 buf[b] = KeysymsPerKeycode b += 1 buf[b] = KeycodeCount b += 1 for i := 0; i < int((int(KeycodeCount) * int(KeysymsPerKeycode))); i++ { xgb.Put32(buf[b:], uint32(Keysyms[i])) b += 4 } b = xgb.Pad(b) return buf } // ChangeKeyboardDeviceCookie is a cookie used only for ChangeKeyboardDevice requests. type ChangeKeyboardDeviceCookie struct { *xgb.Cookie } // ChangeKeyboardDevice sends a checked request. // If an error occurs, it will be returned with the reply by calling ChangeKeyboardDeviceCookie.Reply() func ChangeKeyboardDevice(c *xgb.Conn, DeviceId byte) ChangeKeyboardDeviceCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'ChangeKeyboardDevice' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(true, true) c.NewRequest(changeKeyboardDeviceRequest(c, DeviceId), cookie) return ChangeKeyboardDeviceCookie{cookie} } // ChangeKeyboardDeviceUnchecked sends an unchecked request. // If an error occurs, it can only be retrieved using xgb.WaitForEvent or xgb.PollForEvent. func ChangeKeyboardDeviceUnchecked(c *xgb.Conn, DeviceId byte) ChangeKeyboardDeviceCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'ChangeKeyboardDevice' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(false, true) c.NewRequest(changeKeyboardDeviceRequest(c, DeviceId), cookie) return ChangeKeyboardDeviceCookie{cookie} } // ChangeKeyboardDeviceReply represents the data returned from a ChangeKeyboardDevice request. type ChangeKeyboardDeviceReply struct { Sequence uint16 // sequence number of the request for this reply Length uint32 // number of bytes in this reply // padding: 1 bytes Status byte // padding: 23 bytes } // Reply blocks and returns the reply data for a ChangeKeyboardDevice request. func (cook ChangeKeyboardDeviceCookie) Reply() (*ChangeKeyboardDeviceReply, error) { buf, err := cook.Cookie.Reply() if err != nil { return nil, err } if buf == nil { return nil, nil } return changeKeyboardDeviceReply(buf), nil } // changeKeyboardDeviceReply reads a byte slice into a ChangeKeyboardDeviceReply value. func changeKeyboardDeviceReply(buf []byte) *ChangeKeyboardDeviceReply { v := new(ChangeKeyboardDeviceReply) b := 1 // skip reply determinant b += 1 // padding v.Sequence = xgb.Get16(buf[b:]) b += 2 v.Length = xgb.Get32(buf[b:]) // 4-byte units b += 4 v.Status = buf[b] b += 1 b += 23 // padding return v } // Write request to wire for ChangeKeyboardDevice // changeKeyboardDeviceRequest writes a ChangeKeyboardDevice request to a byte slice. func changeKeyboardDeviceRequest(c *xgb.Conn, DeviceId byte) []byte { size := 8 b := 0 buf := make([]byte, size) buf[b] = c.Extensions["XINPUTEXTENSION"] b += 1 buf[b] = 11 // request opcode b += 1 xgb.Put16(buf[b:], uint16(size/4)) // write request size in 4-byte units b += 2 buf[b] = DeviceId b += 1 b += 3 // padding return buf } // ChangePointerDeviceCookie is a cookie used only for ChangePointerDevice requests. type ChangePointerDeviceCookie struct { *xgb.Cookie } // ChangePointerDevice sends a checked request. // If an error occurs, it will be returned with the reply by calling ChangePointerDeviceCookie.Reply() func ChangePointerDevice(c *xgb.Conn, XAxis byte, YAxis byte, DeviceId byte) ChangePointerDeviceCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'ChangePointerDevice' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(true, true) c.NewRequest(changePointerDeviceRequest(c, XAxis, YAxis, DeviceId), cookie) return ChangePointerDeviceCookie{cookie} } // ChangePointerDeviceUnchecked sends an unchecked request. // If an error occurs, it can only be retrieved using xgb.WaitForEvent or xgb.PollForEvent. func ChangePointerDeviceUnchecked(c *xgb.Conn, XAxis byte, YAxis byte, DeviceId byte) ChangePointerDeviceCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'ChangePointerDevice' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(false, true) c.NewRequest(changePointerDeviceRequest(c, XAxis, YAxis, DeviceId), cookie) return ChangePointerDeviceCookie{cookie} } // ChangePointerDeviceReply represents the data returned from a ChangePointerDevice request. type ChangePointerDeviceReply struct { Sequence uint16 // sequence number of the request for this reply Length uint32 // number of bytes in this reply // padding: 1 bytes Status byte // padding: 23 bytes } // Reply blocks and returns the reply data for a ChangePointerDevice request. func (cook ChangePointerDeviceCookie) Reply() (*ChangePointerDeviceReply, error) { buf, err := cook.Cookie.Reply() if err != nil { return nil, err } if buf == nil { return nil, nil } return changePointerDeviceReply(buf), nil } // changePointerDeviceReply reads a byte slice into a ChangePointerDeviceReply value. func changePointerDeviceReply(buf []byte) *ChangePointerDeviceReply { v := new(ChangePointerDeviceReply) b := 1 // skip reply determinant b += 1 // padding v.Sequence = xgb.Get16(buf[b:]) b += 2 v.Length = xgb.Get32(buf[b:]) // 4-byte units b += 4 v.Status = buf[b] b += 1 b += 23 // padding return v } // Write request to wire for ChangePointerDevice // changePointerDeviceRequest writes a ChangePointerDevice request to a byte slice. func changePointerDeviceRequest(c *xgb.Conn, XAxis byte, YAxis byte, DeviceId byte) []byte { size := 8 b := 0 buf := make([]byte, size) buf[b] = c.Extensions["XINPUTEXTENSION"] b += 1 buf[b] = 12 // request opcode b += 1 xgb.Put16(buf[b:], uint16(size/4)) // write request size in 4-byte units b += 2 buf[b] = XAxis b += 1 buf[b] = YAxis b += 1 buf[b] = DeviceId b += 1 b += 1 // padding return buf } // CloseDeviceCookie is a cookie used only for CloseDevice requests. type CloseDeviceCookie struct { *xgb.Cookie } // CloseDevice sends an unchecked request. // If an error occurs, it can only be retrieved using xgb.WaitForEvent or xgb.PollForEvent. func CloseDevice(c *xgb.Conn, DeviceId byte) CloseDeviceCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'CloseDevice' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(false, false) c.NewRequest(closeDeviceRequest(c, DeviceId), cookie) return CloseDeviceCookie{cookie} } // CloseDeviceChecked sends a checked request. // If an error occurs, it can be retrieved using CloseDeviceCookie.Check() func CloseDeviceChecked(c *xgb.Conn, DeviceId byte) CloseDeviceCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'CloseDevice' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(true, false) c.NewRequest(closeDeviceRequest(c, DeviceId), cookie) return CloseDeviceCookie{cookie} } // Check returns an error if one occurred for checked requests that are not expecting a reply. // This cannot be called for requests expecting a reply, nor for unchecked requests. func (cook CloseDeviceCookie) Check() error { return cook.Cookie.Check() } // Write request to wire for CloseDevice // closeDeviceRequest writes a CloseDevice request to a byte slice. func closeDeviceRequest(c *xgb.Conn, DeviceId byte) []byte { size := 8 b := 0 buf := make([]byte, size) buf[b] = c.Extensions["XINPUTEXTENSION"] b += 1 buf[b] = 4 // request opcode b += 1 xgb.Put16(buf[b:], uint16(size/4)) // write request size in 4-byte units b += 2 buf[b] = DeviceId b += 1 b += 3 // padding return buf } // DeviceBellCookie is a cookie used only for DeviceBell requests. type DeviceBellCookie struct { *xgb.Cookie } // DeviceBell sends an unchecked request. // If an error occurs, it can only be retrieved using xgb.WaitForEvent or xgb.PollForEvent. func DeviceBell(c *xgb.Conn, DeviceId byte, FeedbackId byte, FeedbackClass byte, Percent int8) DeviceBellCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'DeviceBell' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(false, false) c.NewRequest(deviceBellRequest(c, DeviceId, FeedbackId, FeedbackClass, Percent), cookie) return DeviceBellCookie{cookie} } // DeviceBellChecked sends a checked request. // If an error occurs, it can be retrieved using DeviceBellCookie.Check() func DeviceBellChecked(c *xgb.Conn, DeviceId byte, FeedbackId byte, FeedbackClass byte, Percent int8) DeviceBellCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'DeviceBell' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(true, false) c.NewRequest(deviceBellRequest(c, DeviceId, FeedbackId, FeedbackClass, Percent), cookie) return DeviceBellCookie{cookie} } // Check returns an error if one occurred for checked requests that are not expecting a reply. // This cannot be called for requests expecting a reply, nor for unchecked requests. func (cook DeviceBellCookie) Check() error { return cook.Cookie.Check() } // Write request to wire for DeviceBell // deviceBellRequest writes a DeviceBell request to a byte slice. func deviceBellRequest(c *xgb.Conn, DeviceId byte, FeedbackId byte, FeedbackClass byte, Percent int8) []byte { size := 8 b := 0 buf := make([]byte, size) buf[b] = c.Extensions["XINPUTEXTENSION"] b += 1 buf[b] = 32 // request opcode b += 1 xgb.Put16(buf[b:], uint16(size/4)) // write request size in 4-byte units b += 2 buf[b] = DeviceId b += 1 buf[b] = FeedbackId b += 1 buf[b] = FeedbackClass b += 1 buf[b] = byte(Percent) b += 1 return buf } // GetDeviceButtonMappingCookie is a cookie used only for GetDeviceButtonMapping requests. type GetDeviceButtonMappingCookie struct { *xgb.Cookie } // GetDeviceButtonMapping sends a checked request. // If an error occurs, it will be returned with the reply by calling GetDeviceButtonMappingCookie.Reply() func GetDeviceButtonMapping(c *xgb.Conn, DeviceId byte) GetDeviceButtonMappingCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'GetDeviceButtonMapping' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(true, true) c.NewRequest(getDeviceButtonMappingRequest(c, DeviceId), cookie) return GetDeviceButtonMappingCookie{cookie} } // GetDeviceButtonMappingUnchecked sends an unchecked request. // If an error occurs, it can only be retrieved using xgb.WaitForEvent or xgb.PollForEvent. func GetDeviceButtonMappingUnchecked(c *xgb.Conn, DeviceId byte) GetDeviceButtonMappingCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'GetDeviceButtonMapping' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(false, true) c.NewRequest(getDeviceButtonMappingRequest(c, DeviceId), cookie) return GetDeviceButtonMappingCookie{cookie} } // GetDeviceButtonMappingReply represents the data returned from a GetDeviceButtonMapping request. type GetDeviceButtonMappingReply struct { Sequence uint16 // sequence number of the request for this reply Length uint32 // number of bytes in this reply // padding: 1 bytes MapSize byte // padding: 23 bytes Map []byte // size: xgb.Pad((int(MapSize) * 1)) } // Reply blocks and returns the reply data for a GetDeviceButtonMapping request. func (cook GetDeviceButtonMappingCookie) Reply() (*GetDeviceButtonMappingReply, error) { buf, err := cook.Cookie.Reply() if err != nil { return nil, err } if buf == nil { return nil, nil } return getDeviceButtonMappingReply(buf), nil } // getDeviceButtonMappingReply reads a byte slice into a GetDeviceButtonMappingReply value. func getDeviceButtonMappingReply(buf []byte) *GetDeviceButtonMappingReply { v := new(GetDeviceButtonMappingReply) b := 1 // skip reply determinant b += 1 // padding v.Sequence = xgb.Get16(buf[b:]) b += 2 v.Length = xgb.Get32(buf[b:]) // 4-byte units b += 4 v.MapSize = buf[b] b += 1 b += 23 // padding v.Map = make([]byte, v.MapSize) copy(v.Map[:v.MapSize], buf[b:]) b += xgb.Pad(int(v.MapSize)) return v } // Write request to wire for GetDeviceButtonMapping // getDeviceButtonMappingRequest writes a GetDeviceButtonMapping request to a byte slice. func getDeviceButtonMappingRequest(c *xgb.Conn, DeviceId byte) []byte { size := 8 b := 0 buf := make([]byte, size) buf[b] = c.Extensions["XINPUTEXTENSION"] b += 1 buf[b] = 28 // request opcode b += 1 xgb.Put16(buf[b:], uint16(size/4)) // write request size in 4-byte units b += 2 buf[b] = DeviceId b += 1 b += 3 // padding return buf } // GetDeviceControlCookie is a cookie used only for GetDeviceControl requests. type GetDeviceControlCookie struct { *xgb.Cookie } // GetDeviceControl sends a checked request. // If an error occurs, it will be returned with the reply by calling GetDeviceControlCookie.Reply() func GetDeviceControl(c *xgb.Conn, ControlId uint16, DeviceId byte) GetDeviceControlCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'GetDeviceControl' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(true, true) c.NewRequest(getDeviceControlRequest(c, ControlId, DeviceId), cookie) return GetDeviceControlCookie{cookie} } // GetDeviceControlUnchecked sends an unchecked request. // If an error occurs, it can only be retrieved using xgb.WaitForEvent or xgb.PollForEvent. func GetDeviceControlUnchecked(c *xgb.Conn, ControlId uint16, DeviceId byte) GetDeviceControlCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'GetDeviceControl' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(false, true) c.NewRequest(getDeviceControlRequest(c, ControlId, DeviceId), cookie) return GetDeviceControlCookie{cookie} } // GetDeviceControlReply represents the data returned from a GetDeviceControl request. type GetDeviceControlReply struct { Sequence uint16 // sequence number of the request for this reply Length uint32 // number of bytes in this reply // padding: 1 bytes Status byte // padding: 23 bytes } // Reply blocks and returns the reply data for a GetDeviceControl request. func (cook GetDeviceControlCookie) Reply() (*GetDeviceControlReply, error) { buf, err := cook.Cookie.Reply() if err != nil { return nil, err } if buf == nil { return nil, nil } return getDeviceControlReply(buf), nil } // getDeviceControlReply reads a byte slice into a GetDeviceControlReply value. func getDeviceControlReply(buf []byte) *GetDeviceControlReply { v := new(GetDeviceControlReply) b := 1 // skip reply determinant b += 1 // padding v.Sequence = xgb.Get16(buf[b:]) b += 2 v.Length = xgb.Get32(buf[b:]) // 4-byte units b += 4 v.Status = buf[b] b += 1 b += 23 // padding return v } // Write request to wire for GetDeviceControl // getDeviceControlRequest writes a GetDeviceControl request to a byte slice. func getDeviceControlRequest(c *xgb.Conn, ControlId uint16, DeviceId byte) []byte { size := 8 b := 0 buf := make([]byte, size) buf[b] = c.Extensions["XINPUTEXTENSION"] b += 1 buf[b] = 34 // request opcode b += 1 xgb.Put16(buf[b:], uint16(size/4)) // write request size in 4-byte units b += 2 xgb.Put16(buf[b:], ControlId) b += 2 buf[b] = DeviceId b += 1 b += 1 // padding return buf } // GetDeviceDontPropagateListCookie is a cookie used only for GetDeviceDontPropagateList requests. type GetDeviceDontPropagateListCookie struct { *xgb.Cookie } // GetDeviceDontPropagateList sends a checked request. // If an error occurs, it will be returned with the reply by calling GetDeviceDontPropagateListCookie.Reply() func GetDeviceDontPropagateList(c *xgb.Conn, Window xproto.Window) GetDeviceDontPropagateListCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'GetDeviceDontPropagateList' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(true, true) c.NewRequest(getDeviceDontPropagateListRequest(c, Window), cookie) return GetDeviceDontPropagateListCookie{cookie} } // GetDeviceDontPropagateListUnchecked sends an unchecked request. // If an error occurs, it can only be retrieved using xgb.WaitForEvent or xgb.PollForEvent. func GetDeviceDontPropagateListUnchecked(c *xgb.Conn, Window xproto.Window) GetDeviceDontPropagateListCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'GetDeviceDontPropagateList' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(false, true) c.NewRequest(getDeviceDontPropagateListRequest(c, Window), cookie) return GetDeviceDontPropagateListCookie{cookie} } // GetDeviceDontPropagateListReply represents the data returned from a GetDeviceDontPropagateList request. type GetDeviceDontPropagateListReply struct { Sequence uint16 // sequence number of the request for this reply Length uint32 // number of bytes in this reply // padding: 1 bytes NumClasses uint16 // padding: 22 bytes Classes []EventClass // size: xgb.Pad((int(NumClasses) * 4)) } // Reply blocks and returns the reply data for a GetDeviceDontPropagateList request. func (cook GetDeviceDontPropagateListCookie) Reply() (*GetDeviceDontPropagateListReply, error) { buf, err := cook.Cookie.Reply() if err != nil { return nil, err } if buf == nil { return nil, nil } return getDeviceDontPropagateListReply(buf), nil } // getDeviceDontPropagateListReply reads a byte slice into a GetDeviceDontPropagateListReply value. func getDeviceDontPropagateListReply(buf []byte) *GetDeviceDontPropagateListReply { v := new(GetDeviceDontPropagateListReply) b := 1 // skip reply determinant b += 1 // padding v.Sequence = xgb.Get16(buf[b:]) b += 2 v.Length = xgb.Get32(buf[b:]) // 4-byte units b += 4 v.NumClasses = xgb.Get16(buf[b:]) b += 2 b += 22 // padding v.Classes = make([]EventClass, v.NumClasses) for i := 0; i < int(v.NumClasses); i++ { v.Classes[i] = EventClass(xgb.Get32(buf[b:])) b += 4 } b = xgb.Pad(b) return v } // Write request to wire for GetDeviceDontPropagateList // getDeviceDontPropagateListRequest writes a GetDeviceDontPropagateList request to a byte slice. func getDeviceDontPropagateListRequest(c *xgb.Conn, Window xproto.Window) []byte { size := 8 b := 0 buf := make([]byte, size) buf[b] = c.Extensions["XINPUTEXTENSION"] b += 1 buf[b] = 9 // request opcode b += 1 xgb.Put16(buf[b:], uint16(size/4)) // write request size in 4-byte units b += 2 xgb.Put32(buf[b:], uint32(Window)) b += 4 return buf } // GetDeviceFocusCookie is a cookie used only for GetDeviceFocus requests. type GetDeviceFocusCookie struct { *xgb.Cookie } // GetDeviceFocus sends a checked request. // If an error occurs, it will be returned with the reply by calling GetDeviceFocusCookie.Reply() func GetDeviceFocus(c *xgb.Conn, DeviceId byte) GetDeviceFocusCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'GetDeviceFocus' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(true, true) c.NewRequest(getDeviceFocusRequest(c, DeviceId), cookie) return GetDeviceFocusCookie{cookie} } // GetDeviceFocusUnchecked sends an unchecked request. // If an error occurs, it can only be retrieved using xgb.WaitForEvent or xgb.PollForEvent. func GetDeviceFocusUnchecked(c *xgb.Conn, DeviceId byte) GetDeviceFocusCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'GetDeviceFocus' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(false, true) c.NewRequest(getDeviceFocusRequest(c, DeviceId), cookie) return GetDeviceFocusCookie{cookie} } // GetDeviceFocusReply represents the data returned from a GetDeviceFocus request. type GetDeviceFocusReply struct { Sequence uint16 // sequence number of the request for this reply Length uint32 // number of bytes in this reply // padding: 1 bytes Focus xproto.Window Time xproto.Timestamp RevertTo byte // padding: 15 bytes } // Reply blocks and returns the reply data for a GetDeviceFocus request. func (cook GetDeviceFocusCookie) Reply() (*GetDeviceFocusReply, error) { buf, err := cook.Cookie.Reply() if err != nil { return nil, err } if buf == nil { return nil, nil } return getDeviceFocusReply(buf), nil } // getDeviceFocusReply reads a byte slice into a GetDeviceFocusReply value. func getDeviceFocusReply(buf []byte) *GetDeviceFocusReply { v := new(GetDeviceFocusReply) b := 1 // skip reply determinant b += 1 // padding v.Sequence = xgb.Get16(buf[b:]) b += 2 v.Length = xgb.Get32(buf[b:]) // 4-byte units b += 4 v.Focus = xproto.Window(xgb.Get32(buf[b:])) b += 4 v.Time = xproto.Timestamp(xgb.Get32(buf[b:])) b += 4 v.RevertTo = buf[b] b += 1 b += 15 // padding return v } // Write request to wire for GetDeviceFocus // getDeviceFocusRequest writes a GetDeviceFocus request to a byte slice. func getDeviceFocusRequest(c *xgb.Conn, DeviceId byte) []byte { size := 8 b := 0 buf := make([]byte, size) buf[b] = c.Extensions["XINPUTEXTENSION"] b += 1 buf[b] = 20 // request opcode b += 1 xgb.Put16(buf[b:], uint16(size/4)) // write request size in 4-byte units b += 2 buf[b] = DeviceId b += 1 b += 3 // padding return buf } // GetDeviceKeyMappingCookie is a cookie used only for GetDeviceKeyMapping requests. type GetDeviceKeyMappingCookie struct { *xgb.Cookie } // GetDeviceKeyMapping sends a checked request. // If an error occurs, it will be returned with the reply by calling GetDeviceKeyMappingCookie.Reply() func GetDeviceKeyMapping(c *xgb.Conn, DeviceId byte, FirstKeycode KeyCode, Count byte) GetDeviceKeyMappingCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'GetDeviceKeyMapping' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(true, true) c.NewRequest(getDeviceKeyMappingRequest(c, DeviceId, FirstKeycode, Count), cookie) return GetDeviceKeyMappingCookie{cookie} } // GetDeviceKeyMappingUnchecked sends an unchecked request. // If an error occurs, it can only be retrieved using xgb.WaitForEvent or xgb.PollForEvent. func GetDeviceKeyMappingUnchecked(c *xgb.Conn, DeviceId byte, FirstKeycode KeyCode, Count byte) GetDeviceKeyMappingCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'GetDeviceKeyMapping' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(false, true) c.NewRequest(getDeviceKeyMappingRequest(c, DeviceId, FirstKeycode, Count), cookie) return GetDeviceKeyMappingCookie{cookie} } // GetDeviceKeyMappingReply represents the data returned from a GetDeviceKeyMapping request. type GetDeviceKeyMappingReply struct { Sequence uint16 // sequence number of the request for this reply Length uint32 // number of bytes in this reply // padding: 1 bytes KeysymsPerKeycode byte // padding: 23 bytes Keysyms []xproto.Keysym // size: xgb.Pad((int(Length) * 4)) } // Reply blocks and returns the reply data for a GetDeviceKeyMapping request. func (cook GetDeviceKeyMappingCookie) Reply() (*GetDeviceKeyMappingReply, error) { buf, err := cook.Cookie.Reply() if err != nil { return nil, err } if buf == nil { return nil, nil } return getDeviceKeyMappingReply(buf), nil } // getDeviceKeyMappingReply reads a byte slice into a GetDeviceKeyMappingReply value. func getDeviceKeyMappingReply(buf []byte) *GetDeviceKeyMappingReply { v := new(GetDeviceKeyMappingReply) b := 1 // skip reply determinant b += 1 // padding v.Sequence = xgb.Get16(buf[b:]) b += 2 v.Length = xgb.Get32(buf[b:]) // 4-byte units b += 4 v.KeysymsPerKeycode = buf[b] b += 1 b += 23 // padding v.Keysyms = make([]xproto.Keysym, v.Length) for i := 0; i < int(v.Length); i++ { v.Keysyms[i] = xproto.Keysym(xgb.Get32(buf[b:])) b += 4 } b = xgb.Pad(b) return v } // Write request to wire for GetDeviceKeyMapping // getDeviceKeyMappingRequest writes a GetDeviceKeyMapping request to a byte slice. func getDeviceKeyMappingRequest(c *xgb.Conn, DeviceId byte, FirstKeycode KeyCode, Count byte) []byte { size := 8 b := 0 buf := make([]byte, size) buf[b] = c.Extensions["XINPUTEXTENSION"] b += 1 buf[b] = 24 // request opcode b += 1 xgb.Put16(buf[b:], uint16(size/4)) // write request size in 4-byte units b += 2 buf[b] = DeviceId b += 1 buf[b] = byte(FirstKeycode) b += 1 buf[b] = Count b += 1 return buf } // GetDeviceModifierMappingCookie is a cookie used only for GetDeviceModifierMapping requests. type GetDeviceModifierMappingCookie struct { *xgb.Cookie } // GetDeviceModifierMapping sends a checked request. // If an error occurs, it will be returned with the reply by calling GetDeviceModifierMappingCookie.Reply() func GetDeviceModifierMapping(c *xgb.Conn, DeviceId byte) GetDeviceModifierMappingCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'GetDeviceModifierMapping' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(true, true) c.NewRequest(getDeviceModifierMappingRequest(c, DeviceId), cookie) return GetDeviceModifierMappingCookie{cookie} } // GetDeviceModifierMappingUnchecked sends an unchecked request. // If an error occurs, it can only be retrieved using xgb.WaitForEvent or xgb.PollForEvent. func GetDeviceModifierMappingUnchecked(c *xgb.Conn, DeviceId byte) GetDeviceModifierMappingCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'GetDeviceModifierMapping' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(false, true) c.NewRequest(getDeviceModifierMappingRequest(c, DeviceId), cookie) return GetDeviceModifierMappingCookie{cookie} } // GetDeviceModifierMappingReply represents the data returned from a GetDeviceModifierMapping request. type GetDeviceModifierMappingReply struct { Sequence uint16 // sequence number of the request for this reply Length uint32 // number of bytes in this reply // padding: 1 bytes KeycodesPerModifier byte // padding: 23 bytes Keymaps []byte // size: xgb.Pad(((int(KeycodesPerModifier) * 8) * 1)) } // Reply blocks and returns the reply data for a GetDeviceModifierMapping request. func (cook GetDeviceModifierMappingCookie) Reply() (*GetDeviceModifierMappingReply, error) { buf, err := cook.Cookie.Reply() if err != nil { return nil, err } if buf == nil { return nil, nil } return getDeviceModifierMappingReply(buf), nil } // getDeviceModifierMappingReply reads a byte slice into a GetDeviceModifierMappingReply value. func getDeviceModifierMappingReply(buf []byte) *GetDeviceModifierMappingReply { v := new(GetDeviceModifierMappingReply) b := 1 // skip reply determinant b += 1 // padding v.Sequence = xgb.Get16(buf[b:]) b += 2 v.Length = xgb.Get32(buf[b:]) // 4-byte units b += 4 v.KeycodesPerModifier = buf[b] b += 1 b += 23 // padding v.Keymaps = make([]byte, (int(v.KeycodesPerModifier) * 8)) copy(v.Keymaps[:(int(v.KeycodesPerModifier)*8)], buf[b:]) b += xgb.Pad(int((int(v.KeycodesPerModifier) * 8))) return v } // Write request to wire for GetDeviceModifierMapping // getDeviceModifierMappingRequest writes a GetDeviceModifierMapping request to a byte slice. func getDeviceModifierMappingRequest(c *xgb.Conn, DeviceId byte) []byte { size := 8 b := 0 buf := make([]byte, size) buf[b] = c.Extensions["XINPUTEXTENSION"] b += 1 buf[b] = 26 // request opcode b += 1 xgb.Put16(buf[b:], uint16(size/4)) // write request size in 4-byte units b += 2 buf[b] = DeviceId b += 1 b += 3 // padding return buf } // GetDeviceMotionEventsCookie is a cookie used only for GetDeviceMotionEvents requests. type GetDeviceMotionEventsCookie struct { *xgb.Cookie } // GetDeviceMotionEvents sends a checked request. // If an error occurs, it will be returned with the reply by calling GetDeviceMotionEventsCookie.Reply() func GetDeviceMotionEvents(c *xgb.Conn, Start xproto.Timestamp, Stop xproto.Timestamp, DeviceId byte) GetDeviceMotionEventsCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'GetDeviceMotionEvents' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(true, true) c.NewRequest(getDeviceMotionEventsRequest(c, Start, Stop, DeviceId), cookie) return GetDeviceMotionEventsCookie{cookie} } // GetDeviceMotionEventsUnchecked sends an unchecked request. // If an error occurs, it can only be retrieved using xgb.WaitForEvent or xgb.PollForEvent. func GetDeviceMotionEventsUnchecked(c *xgb.Conn, Start xproto.Timestamp, Stop xproto.Timestamp, DeviceId byte) GetDeviceMotionEventsCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'GetDeviceMotionEvents' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(false, true) c.NewRequest(getDeviceMotionEventsRequest(c, Start, Stop, DeviceId), cookie) return GetDeviceMotionEventsCookie{cookie} } // GetDeviceMotionEventsReply represents the data returned from a GetDeviceMotionEvents request. type GetDeviceMotionEventsReply struct { Sequence uint16 // sequence number of the request for this reply Length uint32 // number of bytes in this reply // padding: 1 bytes NumCoords uint32 NumAxes byte DeviceMode byte // padding: 18 bytes } // Reply blocks and returns the reply data for a GetDeviceMotionEvents request. func (cook GetDeviceMotionEventsCookie) Reply() (*GetDeviceMotionEventsReply, error) { buf, err := cook.Cookie.Reply() if err != nil { return nil, err } if buf == nil { return nil, nil } return getDeviceMotionEventsReply(buf), nil } // getDeviceMotionEventsReply reads a byte slice into a GetDeviceMotionEventsReply value. func getDeviceMotionEventsReply(buf []byte) *GetDeviceMotionEventsReply { v := new(GetDeviceMotionEventsReply) b := 1 // skip reply determinant b += 1 // padding v.Sequence = xgb.Get16(buf[b:]) b += 2 v.Length = xgb.Get32(buf[b:]) // 4-byte units b += 4 v.NumCoords = xgb.Get32(buf[b:]) b += 4 v.NumAxes = buf[b] b += 1 v.DeviceMode = buf[b] b += 1 b += 18 // padding return v } // Write request to wire for GetDeviceMotionEvents // getDeviceMotionEventsRequest writes a GetDeviceMotionEvents request to a byte slice. func getDeviceMotionEventsRequest(c *xgb.Conn, Start xproto.Timestamp, Stop xproto.Timestamp, DeviceId byte) []byte { size := 16 b := 0 buf := make([]byte, size) buf[b] = c.Extensions["XINPUTEXTENSION"] b += 1 buf[b] = 10 // request opcode b += 1 xgb.Put16(buf[b:], uint16(size/4)) // write request size in 4-byte units b += 2 xgb.Put32(buf[b:], uint32(Start)) b += 4 xgb.Put32(buf[b:], uint32(Stop)) b += 4 buf[b] = DeviceId b += 1 return buf } // GetExtensionVersionCookie is a cookie used only for GetExtensionVersion requests. type GetExtensionVersionCookie struct { *xgb.Cookie } // GetExtensionVersion sends a checked request. // If an error occurs, it will be returned with the reply by calling GetExtensionVersionCookie.Reply() func GetExtensionVersion(c *xgb.Conn, NameLen uint16, Name string) GetExtensionVersionCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'GetExtensionVersion' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(true, true) c.NewRequest(getExtensionVersionRequest(c, NameLen, Name), cookie) return GetExtensionVersionCookie{cookie} } // GetExtensionVersionUnchecked sends an unchecked request. // If an error occurs, it can only be retrieved using xgb.WaitForEvent or xgb.PollForEvent. func GetExtensionVersionUnchecked(c *xgb.Conn, NameLen uint16, Name string) GetExtensionVersionCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'GetExtensionVersion' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(false, true) c.NewRequest(getExtensionVersionRequest(c, NameLen, Name), cookie) return GetExtensionVersionCookie{cookie} } // GetExtensionVersionReply represents the data returned from a GetExtensionVersion request. type GetExtensionVersionReply struct { Sequence uint16 // sequence number of the request for this reply Length uint32 // number of bytes in this reply // padding: 1 bytes ServerMajor uint16 ServerMinor uint16 Present bool // padding: 19 bytes } // Reply blocks and returns the reply data for a GetExtensionVersion request. func (cook GetExtensionVersionCookie) Reply() (*GetExtensionVersionReply, error) { buf, err := cook.Cookie.Reply() if err != nil { return nil, err } if buf == nil { return nil, nil } return getExtensionVersionReply(buf), nil } // getExtensionVersionReply reads a byte slice into a GetExtensionVersionReply value. func getExtensionVersionReply(buf []byte) *GetExtensionVersionReply { v := new(GetExtensionVersionReply) b := 1 // skip reply determinant b += 1 // padding v.Sequence = xgb.Get16(buf[b:]) b += 2 v.Length = xgb.Get32(buf[b:]) // 4-byte units b += 4 v.ServerMajor = xgb.Get16(buf[b:]) b += 2 v.ServerMinor = xgb.Get16(buf[b:]) b += 2 if buf[b] == 1 { v.Present = true } else { v.Present = false } b += 1 b += 19 // padding return v } // Write request to wire for GetExtensionVersion // getExtensionVersionRequest writes a GetExtensionVersion request to a byte slice. func getExtensionVersionRequest(c *xgb.Conn, NameLen uint16, Name string) []byte { size := xgb.Pad((8 + xgb.Pad((int(NameLen) * 1)))) b := 0 buf := make([]byte, size) buf[b] = c.Extensions["XINPUTEXTENSION"] b += 1 buf[b] = 1 // request opcode b += 1 xgb.Put16(buf[b:], uint16(size/4)) // write request size in 4-byte units b += 2 xgb.Put16(buf[b:], NameLen) b += 2 b += 2 // padding copy(buf[b:], Name[:NameLen]) b += xgb.Pad(int(NameLen)) return buf } // GetFeedbackControlCookie is a cookie used only for GetFeedbackControl requests. type GetFeedbackControlCookie struct { *xgb.Cookie } // GetFeedbackControl sends a checked request. // If an error occurs, it will be returned with the reply by calling GetFeedbackControlCookie.Reply() func GetFeedbackControl(c *xgb.Conn, DeviceId byte) GetFeedbackControlCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'GetFeedbackControl' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(true, true) c.NewRequest(getFeedbackControlRequest(c, DeviceId), cookie) return GetFeedbackControlCookie{cookie} } // GetFeedbackControlUnchecked sends an unchecked request. // If an error occurs, it can only be retrieved using xgb.WaitForEvent or xgb.PollForEvent. func GetFeedbackControlUnchecked(c *xgb.Conn, DeviceId byte) GetFeedbackControlCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'GetFeedbackControl' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(false, true) c.NewRequest(getFeedbackControlRequest(c, DeviceId), cookie) return GetFeedbackControlCookie{cookie} } // GetFeedbackControlReply represents the data returned from a GetFeedbackControl request. type GetFeedbackControlReply struct { Sequence uint16 // sequence number of the request for this reply Length uint32 // number of bytes in this reply // padding: 1 bytes NumFeedback uint16 // padding: 22 bytes } // Reply blocks and returns the reply data for a GetFeedbackControl request. func (cook GetFeedbackControlCookie) Reply() (*GetFeedbackControlReply, error) { buf, err := cook.Cookie.Reply() if err != nil { return nil, err } if buf == nil { return nil, nil } return getFeedbackControlReply(buf), nil } // getFeedbackControlReply reads a byte slice into a GetFeedbackControlReply value. func getFeedbackControlReply(buf []byte) *GetFeedbackControlReply { v := new(GetFeedbackControlReply) b := 1 // skip reply determinant b += 1 // padding v.Sequence = xgb.Get16(buf[b:]) b += 2 v.Length = xgb.Get32(buf[b:]) // 4-byte units b += 4 v.NumFeedback = xgb.Get16(buf[b:]) b += 2 b += 22 // padding return v } // Write request to wire for GetFeedbackControl // getFeedbackControlRequest writes a GetFeedbackControl request to a byte slice. func getFeedbackControlRequest(c *xgb.Conn, DeviceId byte) []byte { size := 8 b := 0 buf := make([]byte, size) buf[b] = c.Extensions["XINPUTEXTENSION"] b += 1 buf[b] = 22 // request opcode b += 1 xgb.Put16(buf[b:], uint16(size/4)) // write request size in 4-byte units b += 2 buf[b] = DeviceId b += 1 b += 3 // padding return buf } // GetSelectedExtensionEventsCookie is a cookie used only for GetSelectedExtensionEvents requests. type GetSelectedExtensionEventsCookie struct { *xgb.Cookie } // GetSelectedExtensionEvents sends a checked request. // If an error occurs, it will be returned with the reply by calling GetSelectedExtensionEventsCookie.Reply() func GetSelectedExtensionEvents(c *xgb.Conn, Window xproto.Window) GetSelectedExtensionEventsCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'GetSelectedExtensionEvents' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(true, true) c.NewRequest(getSelectedExtensionEventsRequest(c, Window), cookie) return GetSelectedExtensionEventsCookie{cookie} } // GetSelectedExtensionEventsUnchecked sends an unchecked request. // If an error occurs, it can only be retrieved using xgb.WaitForEvent or xgb.PollForEvent. func GetSelectedExtensionEventsUnchecked(c *xgb.Conn, Window xproto.Window) GetSelectedExtensionEventsCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'GetSelectedExtensionEvents' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(false, true) c.NewRequest(getSelectedExtensionEventsRequest(c, Window), cookie) return GetSelectedExtensionEventsCookie{cookie} } // GetSelectedExtensionEventsReply represents the data returned from a GetSelectedExtensionEvents request. type GetSelectedExtensionEventsReply struct { Sequence uint16 // sequence number of the request for this reply Length uint32 // number of bytes in this reply // padding: 1 bytes NumThisClasses uint16 NumAllClasses uint16 // padding: 20 bytes ThisClasses []EventClass // size: xgb.Pad((int(NumThisClasses) * 4)) AllClasses []EventClass // size: xgb.Pad((int(NumAllClasses) * 4)) } // Reply blocks and returns the reply data for a GetSelectedExtensionEvents request. func (cook GetSelectedExtensionEventsCookie) Reply() (*GetSelectedExtensionEventsReply, error) { buf, err := cook.Cookie.Reply() if err != nil { return nil, err } if buf == nil { return nil, nil } return getSelectedExtensionEventsReply(buf), nil } // getSelectedExtensionEventsReply reads a byte slice into a GetSelectedExtensionEventsReply value. func getSelectedExtensionEventsReply(buf []byte) *GetSelectedExtensionEventsReply { v := new(GetSelectedExtensionEventsReply) b := 1 // skip reply determinant b += 1 // padding v.Sequence = xgb.Get16(buf[b:]) b += 2 v.Length = xgb.Get32(buf[b:]) // 4-byte units b += 4 v.NumThisClasses = xgb.Get16(buf[b:]) b += 2 v.NumAllClasses = xgb.Get16(buf[b:]) b += 2 b += 20 // padding v.ThisClasses = make([]EventClass, v.NumThisClasses) for i := 0; i < int(v.NumThisClasses); i++ { v.ThisClasses[i] = EventClass(xgb.Get32(buf[b:])) b += 4 } b = xgb.Pad(b) v.AllClasses = make([]EventClass, v.NumAllClasses) for i := 0; i < int(v.NumAllClasses); i++ { v.AllClasses[i] = EventClass(xgb.Get32(buf[b:])) b += 4 } b = xgb.Pad(b) return v } // Write request to wire for GetSelectedExtensionEvents // getSelectedExtensionEventsRequest writes a GetSelectedExtensionEvents request to a byte slice. func getSelectedExtensionEventsRequest(c *xgb.Conn, Window xproto.Window) []byte { size := 8 b := 0 buf := make([]byte, size) buf[b] = c.Extensions["XINPUTEXTENSION"] b += 1 buf[b] = 7 // request opcode b += 1 xgb.Put16(buf[b:], uint16(size/4)) // write request size in 4-byte units b += 2 xgb.Put32(buf[b:], uint32(Window)) b += 4 return buf } // GrabDeviceCookie is a cookie used only for GrabDevice requests. type GrabDeviceCookie struct { *xgb.Cookie } // GrabDevice sends a checked request. // If an error occurs, it will be returned with the reply by calling GrabDeviceCookie.Reply() func GrabDevice(c *xgb.Conn, GrabWindow xproto.Window, Time xproto.Timestamp, NumClasses uint16, ThisDeviceMode byte, OtherDeviceMode byte, OwnerEvents bool, DeviceId byte, Classes []EventClass) GrabDeviceCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'GrabDevice' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(true, true) c.NewRequest(grabDeviceRequest(c, GrabWindow, Time, NumClasses, ThisDeviceMode, OtherDeviceMode, OwnerEvents, DeviceId, Classes), cookie) return GrabDeviceCookie{cookie} } // GrabDeviceUnchecked sends an unchecked request. // If an error occurs, it can only be retrieved using xgb.WaitForEvent or xgb.PollForEvent. func GrabDeviceUnchecked(c *xgb.Conn, GrabWindow xproto.Window, Time xproto.Timestamp, NumClasses uint16, ThisDeviceMode byte, OtherDeviceMode byte, OwnerEvents bool, DeviceId byte, Classes []EventClass) GrabDeviceCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'GrabDevice' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(false, true) c.NewRequest(grabDeviceRequest(c, GrabWindow, Time, NumClasses, ThisDeviceMode, OtherDeviceMode, OwnerEvents, DeviceId, Classes), cookie) return GrabDeviceCookie{cookie} } // GrabDeviceReply represents the data returned from a GrabDevice request. type GrabDeviceReply struct { Sequence uint16 // sequence number of the request for this reply Length uint32 // number of bytes in this reply // padding: 1 bytes Status byte // padding: 23 bytes } // Reply blocks and returns the reply data for a GrabDevice request. func (cook GrabDeviceCookie) Reply() (*GrabDeviceReply, error) { buf, err := cook.Cookie.Reply() if err != nil { return nil, err } if buf == nil { return nil, nil } return grabDeviceReply(buf), nil } // grabDeviceReply reads a byte slice into a GrabDeviceReply value. func grabDeviceReply(buf []byte) *GrabDeviceReply { v := new(GrabDeviceReply) b := 1 // skip reply determinant b += 1 // padding v.Sequence = xgb.Get16(buf[b:]) b += 2 v.Length = xgb.Get32(buf[b:]) // 4-byte units b += 4 v.Status = buf[b] b += 1 b += 23 // padding return v } // Write request to wire for GrabDevice // grabDeviceRequest writes a GrabDevice request to a byte slice. func grabDeviceRequest(c *xgb.Conn, GrabWindow xproto.Window, Time xproto.Timestamp, NumClasses uint16, ThisDeviceMode byte, OtherDeviceMode byte, OwnerEvents bool, DeviceId byte, Classes []EventClass) []byte { size := xgb.Pad((20 + xgb.Pad((int(NumClasses) * 4)))) b := 0 buf := make([]byte, size) buf[b] = c.Extensions["XINPUTEXTENSION"] b += 1 buf[b] = 13 // request opcode b += 1 xgb.Put16(buf[b:], uint16(size/4)) // write request size in 4-byte units b += 2 xgb.Put32(buf[b:], uint32(GrabWindow)) b += 4 xgb.Put32(buf[b:], uint32(Time)) b += 4 xgb.Put16(buf[b:], NumClasses) b += 2 buf[b] = ThisDeviceMode b += 1 buf[b] = OtherDeviceMode b += 1 if OwnerEvents { buf[b] = 1 } else { buf[b] = 0 } b += 1 buf[b] = DeviceId b += 1 b += 2 // padding for i := 0; i < int(NumClasses); i++ { xgb.Put32(buf[b:], uint32(Classes[i])) b += 4 } b = xgb.Pad(b) return buf } // GrabDeviceButtonCookie is a cookie used only for GrabDeviceButton requests. type GrabDeviceButtonCookie struct { *xgb.Cookie } // GrabDeviceButton sends an unchecked request. // If an error occurs, it can only be retrieved using xgb.WaitForEvent or xgb.PollForEvent. func GrabDeviceButton(c *xgb.Conn, GrabWindow xproto.Window, GrabbedDevice byte, ModifierDevice byte, NumClasses uint16, Modifiers uint16, ThisDeviceMode byte, OtherDeviceMode byte, Button byte, OwnerEvents byte, Classes []EventClass) GrabDeviceButtonCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'GrabDeviceButton' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(false, false) c.NewRequest(grabDeviceButtonRequest(c, GrabWindow, GrabbedDevice, ModifierDevice, NumClasses, Modifiers, ThisDeviceMode, OtherDeviceMode, Button, OwnerEvents, Classes), cookie) return GrabDeviceButtonCookie{cookie} } // GrabDeviceButtonChecked sends a checked request. // If an error occurs, it can be retrieved using GrabDeviceButtonCookie.Check() func GrabDeviceButtonChecked(c *xgb.Conn, GrabWindow xproto.Window, GrabbedDevice byte, ModifierDevice byte, NumClasses uint16, Modifiers uint16, ThisDeviceMode byte, OtherDeviceMode byte, Button byte, OwnerEvents byte, Classes []EventClass) GrabDeviceButtonCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'GrabDeviceButton' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(true, false) c.NewRequest(grabDeviceButtonRequest(c, GrabWindow, GrabbedDevice, ModifierDevice, NumClasses, Modifiers, ThisDeviceMode, OtherDeviceMode, Button, OwnerEvents, Classes), cookie) return GrabDeviceButtonCookie{cookie} } // Check returns an error if one occurred for checked requests that are not expecting a reply. // This cannot be called for requests expecting a reply, nor for unchecked requests. func (cook GrabDeviceButtonCookie) Check() error { return cook.Cookie.Check() } // Write request to wire for GrabDeviceButton // grabDeviceButtonRequest writes a GrabDeviceButton request to a byte slice. func grabDeviceButtonRequest(c *xgb.Conn, GrabWindow xproto.Window, GrabbedDevice byte, ModifierDevice byte, NumClasses uint16, Modifiers uint16, ThisDeviceMode byte, OtherDeviceMode byte, Button byte, OwnerEvents byte, Classes []EventClass) []byte { size := xgb.Pad((20 + xgb.Pad((int(NumClasses) * 4)))) b := 0 buf := make([]byte, size) buf[b] = c.Extensions["XINPUTEXTENSION"] b += 1 buf[b] = 17 // request opcode b += 1 xgb.Put16(buf[b:], uint16(size/4)) // write request size in 4-byte units b += 2 xgb.Put32(buf[b:], uint32(GrabWindow)) b += 4 buf[b] = GrabbedDevice b += 1 buf[b] = ModifierDevice b += 1 xgb.Put16(buf[b:], NumClasses) b += 2 xgb.Put16(buf[b:], Modifiers) b += 2 buf[b] = ThisDeviceMode b += 1 buf[b] = OtherDeviceMode b += 1 buf[b] = Button b += 1 buf[b] = OwnerEvents b += 1 b += 2 // padding for i := 0; i < int(NumClasses); i++ { xgb.Put32(buf[b:], uint32(Classes[i])) b += 4 } b = xgb.Pad(b) return buf } // GrabDeviceKeyCookie is a cookie used only for GrabDeviceKey requests. type GrabDeviceKeyCookie struct { *xgb.Cookie } // GrabDeviceKey sends an unchecked request. // If an error occurs, it can only be retrieved using xgb.WaitForEvent or xgb.PollForEvent. func GrabDeviceKey(c *xgb.Conn, GrabWindow xproto.Window, NumClasses uint16, Modifiers uint16, ModifierDevice byte, GrabbedDevice byte, Key byte, ThisDeviceMode byte, OtherDeviceMode byte, OwnerEvents bool, Classes []EventClass) GrabDeviceKeyCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'GrabDeviceKey' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(false, false) c.NewRequest(grabDeviceKeyRequest(c, GrabWindow, NumClasses, Modifiers, ModifierDevice, GrabbedDevice, Key, ThisDeviceMode, OtherDeviceMode, OwnerEvents, Classes), cookie) return GrabDeviceKeyCookie{cookie} } // GrabDeviceKeyChecked sends a checked request. // If an error occurs, it can be retrieved using GrabDeviceKeyCookie.Check() func GrabDeviceKeyChecked(c *xgb.Conn, GrabWindow xproto.Window, NumClasses uint16, Modifiers uint16, ModifierDevice byte, GrabbedDevice byte, Key byte, ThisDeviceMode byte, OtherDeviceMode byte, OwnerEvents bool, Classes []EventClass) GrabDeviceKeyCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'GrabDeviceKey' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(true, false) c.NewRequest(grabDeviceKeyRequest(c, GrabWindow, NumClasses, Modifiers, ModifierDevice, GrabbedDevice, Key, ThisDeviceMode, OtherDeviceMode, OwnerEvents, Classes), cookie) return GrabDeviceKeyCookie{cookie} } // Check returns an error if one occurred for checked requests that are not expecting a reply. // This cannot be called for requests expecting a reply, nor for unchecked requests. func (cook GrabDeviceKeyCookie) Check() error { return cook.Cookie.Check() } // Write request to wire for GrabDeviceKey // grabDeviceKeyRequest writes a GrabDeviceKey request to a byte slice. func grabDeviceKeyRequest(c *xgb.Conn, GrabWindow xproto.Window, NumClasses uint16, Modifiers uint16, ModifierDevice byte, GrabbedDevice byte, Key byte, ThisDeviceMode byte, OtherDeviceMode byte, OwnerEvents bool, Classes []EventClass) []byte { size := xgb.Pad((20 + xgb.Pad((int(NumClasses) * 4)))) b := 0 buf := make([]byte, size) buf[b] = c.Extensions["XINPUTEXTENSION"] b += 1 buf[b] = 15 // request opcode b += 1 xgb.Put16(buf[b:], uint16(size/4)) // write request size in 4-byte units b += 2 xgb.Put32(buf[b:], uint32(GrabWindow)) b += 4 xgb.Put16(buf[b:], NumClasses) b += 2 xgb.Put16(buf[b:], Modifiers) b += 2 buf[b] = ModifierDevice b += 1 buf[b] = GrabbedDevice b += 1 buf[b] = Key b += 1 buf[b] = ThisDeviceMode b += 1 buf[b] = OtherDeviceMode b += 1 if OwnerEvents { buf[b] = 1 } else { buf[b] = 0 } b += 1 b += 2 // padding for i := 0; i < int(NumClasses); i++ { xgb.Put32(buf[b:], uint32(Classes[i])) b += 4 } b = xgb.Pad(b) return buf } // ListInputDevicesCookie is a cookie used only for ListInputDevices requests. type ListInputDevicesCookie struct { *xgb.Cookie } // ListInputDevices sends a checked request. // If an error occurs, it will be returned with the reply by calling ListInputDevicesCookie.Reply() func ListInputDevices(c *xgb.Conn) ListInputDevicesCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'ListInputDevices' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(true, true) c.NewRequest(listInputDevicesRequest(c), cookie) return ListInputDevicesCookie{cookie} } // ListInputDevicesUnchecked sends an unchecked request. // If an error occurs, it can only be retrieved using xgb.WaitForEvent or xgb.PollForEvent. func ListInputDevicesUnchecked(c *xgb.Conn) ListInputDevicesCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'ListInputDevices' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(false, true) c.NewRequest(listInputDevicesRequest(c), cookie) return ListInputDevicesCookie{cookie} } // ListInputDevicesReply represents the data returned from a ListInputDevices request. type ListInputDevicesReply struct { Sequence uint16 // sequence number of the request for this reply Length uint32 // number of bytes in this reply // padding: 1 bytes DevicesLen byte // padding: 23 bytes Devices []DeviceInfo // size: xgb.Pad((int(DevicesLen) * 8)) } // Reply blocks and returns the reply data for a ListInputDevices request. func (cook ListInputDevicesCookie) Reply() (*ListInputDevicesReply, error) { buf, err := cook.Cookie.Reply() if err != nil { return nil, err } if buf == nil { return nil, nil } return listInputDevicesReply(buf), nil } // listInputDevicesReply reads a byte slice into a ListInputDevicesReply value. func listInputDevicesReply(buf []byte) *ListInputDevicesReply { v := new(ListInputDevicesReply) b := 1 // skip reply determinant b += 1 // padding v.Sequence = xgb.Get16(buf[b:]) b += 2 v.Length = xgb.Get32(buf[b:]) // 4-byte units b += 4 v.DevicesLen = buf[b] b += 1 b += 23 // padding v.Devices = make([]DeviceInfo, v.DevicesLen) b += DeviceInfoReadList(buf[b:], v.Devices) return v } // Write request to wire for ListInputDevices // listInputDevicesRequest writes a ListInputDevices request to a byte slice. func listInputDevicesRequest(c *xgb.Conn) []byte { size := 4 b := 0 buf := make([]byte, size) buf[b] = c.Extensions["XINPUTEXTENSION"] b += 1 buf[b] = 2 // request opcode b += 1 xgb.Put16(buf[b:], uint16(size/4)) // write request size in 4-byte units b += 2 return buf } // OpenDeviceCookie is a cookie used only for OpenDevice requests. type OpenDeviceCookie struct { *xgb.Cookie } // OpenDevice sends a checked request. // If an error occurs, it will be returned with the reply by calling OpenDeviceCookie.Reply() func OpenDevice(c *xgb.Conn, DeviceId byte) OpenDeviceCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'OpenDevice' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(true, true) c.NewRequest(openDeviceRequest(c, DeviceId), cookie) return OpenDeviceCookie{cookie} } // OpenDeviceUnchecked sends an unchecked request. // If an error occurs, it can only be retrieved using xgb.WaitForEvent or xgb.PollForEvent. func OpenDeviceUnchecked(c *xgb.Conn, DeviceId byte) OpenDeviceCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'OpenDevice' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(false, true) c.NewRequest(openDeviceRequest(c, DeviceId), cookie) return OpenDeviceCookie{cookie} } // OpenDeviceReply represents the data returned from a OpenDevice request. type OpenDeviceReply struct { Sequence uint16 // sequence number of the request for this reply Length uint32 // number of bytes in this reply // padding: 1 bytes NumClasses byte // padding: 23 bytes ClassInfo []InputClassInfo // size: xgb.Pad((int(NumClasses) * 2)) } // Reply blocks and returns the reply data for a OpenDevice request. func (cook OpenDeviceCookie) Reply() (*OpenDeviceReply, error) { buf, err := cook.Cookie.Reply() if err != nil { return nil, err } if buf == nil { return nil, nil } return openDeviceReply(buf), nil } // openDeviceReply reads a byte slice into a OpenDeviceReply value. func openDeviceReply(buf []byte) *OpenDeviceReply { v := new(OpenDeviceReply) b := 1 // skip reply determinant b += 1 // padding v.Sequence = xgb.Get16(buf[b:]) b += 2 v.Length = xgb.Get32(buf[b:]) // 4-byte units b += 4 v.NumClasses = buf[b] b += 1 b += 23 // padding v.ClassInfo = make([]InputClassInfo, v.NumClasses) b += InputClassInfoReadList(buf[b:], v.ClassInfo) return v } // Write request to wire for OpenDevice // openDeviceRequest writes a OpenDevice request to a byte slice. func openDeviceRequest(c *xgb.Conn, DeviceId byte) []byte { size := 8 b := 0 buf := make([]byte, size) buf[b] = c.Extensions["XINPUTEXTENSION"] b += 1 buf[b] = 3 // request opcode b += 1 xgb.Put16(buf[b:], uint16(size/4)) // write request size in 4-byte units b += 2 buf[b] = DeviceId b += 1 b += 3 // padding return buf } // QueryDeviceStateCookie is a cookie used only for QueryDeviceState requests. type QueryDeviceStateCookie struct { *xgb.Cookie } // QueryDeviceState sends a checked request. // If an error occurs, it will be returned with the reply by calling QueryDeviceStateCookie.Reply() func QueryDeviceState(c *xgb.Conn, DeviceId byte) QueryDeviceStateCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'QueryDeviceState' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(true, true) c.NewRequest(queryDeviceStateRequest(c, DeviceId), cookie) return QueryDeviceStateCookie{cookie} } // QueryDeviceStateUnchecked sends an unchecked request. // If an error occurs, it can only be retrieved using xgb.WaitForEvent or xgb.PollForEvent. func QueryDeviceStateUnchecked(c *xgb.Conn, DeviceId byte) QueryDeviceStateCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'QueryDeviceState' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(false, true) c.NewRequest(queryDeviceStateRequest(c, DeviceId), cookie) return QueryDeviceStateCookie{cookie} } // QueryDeviceStateReply represents the data returned from a QueryDeviceState request. type QueryDeviceStateReply struct { Sequence uint16 // sequence number of the request for this reply Length uint32 // number of bytes in this reply // padding: 1 bytes NumClasses byte // padding: 23 bytes } // Reply blocks and returns the reply data for a QueryDeviceState request. func (cook QueryDeviceStateCookie) Reply() (*QueryDeviceStateReply, error) { buf, err := cook.Cookie.Reply() if err != nil { return nil, err } if buf == nil { return nil, nil } return queryDeviceStateReply(buf), nil } // queryDeviceStateReply reads a byte slice into a QueryDeviceStateReply value. func queryDeviceStateReply(buf []byte) *QueryDeviceStateReply { v := new(QueryDeviceStateReply) b := 1 // skip reply determinant b += 1 // padding v.Sequence = xgb.Get16(buf[b:]) b += 2 v.Length = xgb.Get32(buf[b:]) // 4-byte units b += 4 v.NumClasses = buf[b] b += 1 b += 23 // padding return v } // Write request to wire for QueryDeviceState // queryDeviceStateRequest writes a QueryDeviceState request to a byte slice. func queryDeviceStateRequest(c *xgb.Conn, DeviceId byte) []byte { size := 8 b := 0 buf := make([]byte, size) buf[b] = c.Extensions["XINPUTEXTENSION"] b += 1 buf[b] = 30 // request opcode b += 1 xgb.Put16(buf[b:], uint16(size/4)) // write request size in 4-byte units b += 2 buf[b] = DeviceId b += 1 b += 3 // padding return buf } // SelectExtensionEventCookie is a cookie used only for SelectExtensionEvent requests. type SelectExtensionEventCookie struct { *xgb.Cookie } // SelectExtensionEvent sends an unchecked request. // If an error occurs, it can only be retrieved using xgb.WaitForEvent or xgb.PollForEvent. func SelectExtensionEvent(c *xgb.Conn, Window xproto.Window, NumClasses uint16, Classes []EventClass) SelectExtensionEventCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'SelectExtensionEvent' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(false, false) c.NewRequest(selectExtensionEventRequest(c, Window, NumClasses, Classes), cookie) return SelectExtensionEventCookie{cookie} } // SelectExtensionEventChecked sends a checked request. // If an error occurs, it can be retrieved using SelectExtensionEventCookie.Check() func SelectExtensionEventChecked(c *xgb.Conn, Window xproto.Window, NumClasses uint16, Classes []EventClass) SelectExtensionEventCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'SelectExtensionEvent' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(true, false) c.NewRequest(selectExtensionEventRequest(c, Window, NumClasses, Classes), cookie) return SelectExtensionEventCookie{cookie} } // Check returns an error if one occurred for checked requests that are not expecting a reply. // This cannot be called for requests expecting a reply, nor for unchecked requests. func (cook SelectExtensionEventCookie) Check() error { return cook.Cookie.Check() } // Write request to wire for SelectExtensionEvent // selectExtensionEventRequest writes a SelectExtensionEvent request to a byte slice. func selectExtensionEventRequest(c *xgb.Conn, Window xproto.Window, NumClasses uint16, Classes []EventClass) []byte { size := xgb.Pad((12 + xgb.Pad((int(NumClasses) * 4)))) b := 0 buf := make([]byte, size) buf[b] = c.Extensions["XINPUTEXTENSION"] b += 1 buf[b] = 6 // request opcode b += 1 xgb.Put16(buf[b:], uint16(size/4)) // write request size in 4-byte units b += 2 xgb.Put32(buf[b:], uint32(Window)) b += 4 xgb.Put16(buf[b:], NumClasses) b += 2 b += 2 // padding for i := 0; i < int(NumClasses); i++ { xgb.Put32(buf[b:], uint32(Classes[i])) b += 4 } b = xgb.Pad(b) return buf } // SendExtensionEventCookie is a cookie used only for SendExtensionEvent requests. type SendExtensionEventCookie struct { *xgb.Cookie } // SendExtensionEvent sends an unchecked request. // If an error occurs, it can only be retrieved using xgb.WaitForEvent or xgb.PollForEvent. func SendExtensionEvent(c *xgb.Conn, Destination xproto.Window, DeviceId byte, Propagate bool, NumClasses uint16, NumEvents byte, Events string, Classes []EventClass) SendExtensionEventCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'SendExtensionEvent' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(false, false) c.NewRequest(sendExtensionEventRequest(c, Destination, DeviceId, Propagate, NumClasses, NumEvents, Events, Classes), cookie) return SendExtensionEventCookie{cookie} } // SendExtensionEventChecked sends a checked request. // If an error occurs, it can be retrieved using SendExtensionEventCookie.Check() func SendExtensionEventChecked(c *xgb.Conn, Destination xproto.Window, DeviceId byte, Propagate bool, NumClasses uint16, NumEvents byte, Events string, Classes []EventClass) SendExtensionEventCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'SendExtensionEvent' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(true, false) c.NewRequest(sendExtensionEventRequest(c, Destination, DeviceId, Propagate, NumClasses, NumEvents, Events, Classes), cookie) return SendExtensionEventCookie{cookie} } // Check returns an error if one occurred for checked requests that are not expecting a reply. // This cannot be called for requests expecting a reply, nor for unchecked requests. func (cook SendExtensionEventCookie) Check() error { return cook.Cookie.Check() } // Write request to wire for SendExtensionEvent // sendExtensionEventRequest writes a SendExtensionEvent request to a byte slice. func sendExtensionEventRequest(c *xgb.Conn, Destination xproto.Window, DeviceId byte, Propagate bool, NumClasses uint16, NumEvents byte, Events string, Classes []EventClass) []byte { size := xgb.Pad(((16 + xgb.Pad(((int(NumEvents) * 32) * 1))) + xgb.Pad((int(NumClasses) * 4)))) b := 0 buf := make([]byte, size) buf[b] = c.Extensions["XINPUTEXTENSION"] b += 1 buf[b] = 31 // request opcode b += 1 xgb.Put16(buf[b:], uint16(size/4)) // write request size in 4-byte units b += 2 xgb.Put32(buf[b:], uint32(Destination)) b += 4 buf[b] = DeviceId b += 1 if Propagate { buf[b] = 1 } else { buf[b] = 0 } b += 1 xgb.Put16(buf[b:], NumClasses) b += 2 buf[b] = NumEvents b += 1 b += 3 // padding copy(buf[b:], Events[:(int(NumEvents)*32)]) b += xgb.Pad(int((int(NumEvents) * 32))) for i := 0; i < int(NumClasses); i++ { xgb.Put32(buf[b:], uint32(Classes[i])) b += 4 } b = xgb.Pad(b) return buf } // SetDeviceButtonMappingCookie is a cookie used only for SetDeviceButtonMapping requests. type SetDeviceButtonMappingCookie struct { *xgb.Cookie } // SetDeviceButtonMapping sends a checked request. // If an error occurs, it will be returned with the reply by calling SetDeviceButtonMappingCookie.Reply() func SetDeviceButtonMapping(c *xgb.Conn, DeviceId byte, MapSize byte, Map []byte) SetDeviceButtonMappingCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'SetDeviceButtonMapping' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(true, true) c.NewRequest(setDeviceButtonMappingRequest(c, DeviceId, MapSize, Map), cookie) return SetDeviceButtonMappingCookie{cookie} } // SetDeviceButtonMappingUnchecked sends an unchecked request. // If an error occurs, it can only be retrieved using xgb.WaitForEvent or xgb.PollForEvent. func SetDeviceButtonMappingUnchecked(c *xgb.Conn, DeviceId byte, MapSize byte, Map []byte) SetDeviceButtonMappingCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'SetDeviceButtonMapping' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(false, true) c.NewRequest(setDeviceButtonMappingRequest(c, DeviceId, MapSize, Map), cookie) return SetDeviceButtonMappingCookie{cookie} } // SetDeviceButtonMappingReply represents the data returned from a SetDeviceButtonMapping request. type SetDeviceButtonMappingReply struct { Sequence uint16 // sequence number of the request for this reply Length uint32 // number of bytes in this reply // padding: 1 bytes Status byte // padding: 23 bytes } // Reply blocks and returns the reply data for a SetDeviceButtonMapping request. func (cook SetDeviceButtonMappingCookie) Reply() (*SetDeviceButtonMappingReply, error) { buf, err := cook.Cookie.Reply() if err != nil { return nil, err } if buf == nil { return nil, nil } return setDeviceButtonMappingReply(buf), nil } // setDeviceButtonMappingReply reads a byte slice into a SetDeviceButtonMappingReply value. func setDeviceButtonMappingReply(buf []byte) *SetDeviceButtonMappingReply { v := new(SetDeviceButtonMappingReply) b := 1 // skip reply determinant b += 1 // padding v.Sequence = xgb.Get16(buf[b:]) b += 2 v.Length = xgb.Get32(buf[b:]) // 4-byte units b += 4 v.Status = buf[b] b += 1 b += 23 // padding return v } // Write request to wire for SetDeviceButtonMapping // setDeviceButtonMappingRequest writes a SetDeviceButtonMapping request to a byte slice. func setDeviceButtonMappingRequest(c *xgb.Conn, DeviceId byte, MapSize byte, Map []byte) []byte { size := xgb.Pad((8 + xgb.Pad((int(MapSize) * 1)))) b := 0 buf := make([]byte, size) buf[b] = c.Extensions["XINPUTEXTENSION"] b += 1 buf[b] = 29 // request opcode b += 1 xgb.Put16(buf[b:], uint16(size/4)) // write request size in 4-byte units b += 2 buf[b] = DeviceId b += 1 buf[b] = MapSize b += 1 b += 2 // padding copy(buf[b:], Map[:MapSize]) b += xgb.Pad(int(MapSize)) return buf } // SetDeviceFocusCookie is a cookie used only for SetDeviceFocus requests. type SetDeviceFocusCookie struct { *xgb.Cookie } // SetDeviceFocus sends an unchecked request. // If an error occurs, it can only be retrieved using xgb.WaitForEvent or xgb.PollForEvent. func SetDeviceFocus(c *xgb.Conn, Focus xproto.Window, Time xproto.Timestamp, RevertTo byte, DeviceId byte) SetDeviceFocusCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'SetDeviceFocus' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(false, false) c.NewRequest(setDeviceFocusRequest(c, Focus, Time, RevertTo, DeviceId), cookie) return SetDeviceFocusCookie{cookie} } // SetDeviceFocusChecked sends a checked request. // If an error occurs, it can be retrieved using SetDeviceFocusCookie.Check() func SetDeviceFocusChecked(c *xgb.Conn, Focus xproto.Window, Time xproto.Timestamp, RevertTo byte, DeviceId byte) SetDeviceFocusCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'SetDeviceFocus' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(true, false) c.NewRequest(setDeviceFocusRequest(c, Focus, Time, RevertTo, DeviceId), cookie) return SetDeviceFocusCookie{cookie} } // Check returns an error if one occurred for checked requests that are not expecting a reply. // This cannot be called for requests expecting a reply, nor for unchecked requests. func (cook SetDeviceFocusCookie) Check() error { return cook.Cookie.Check() } // Write request to wire for SetDeviceFocus // setDeviceFocusRequest writes a SetDeviceFocus request to a byte slice. func setDeviceFocusRequest(c *xgb.Conn, Focus xproto.Window, Time xproto.Timestamp, RevertTo byte, DeviceId byte) []byte { size := 16 b := 0 buf := make([]byte, size) buf[b] = c.Extensions["XINPUTEXTENSION"] b += 1 buf[b] = 21 // request opcode b += 1 xgb.Put16(buf[b:], uint16(size/4)) // write request size in 4-byte units b += 2 xgb.Put32(buf[b:], uint32(Focus)) b += 4 xgb.Put32(buf[b:], uint32(Time)) b += 4 buf[b] = RevertTo b += 1 buf[b] = DeviceId b += 1 return buf } // SetDeviceModeCookie is a cookie used only for SetDeviceMode requests. type SetDeviceModeCookie struct { *xgb.Cookie } // SetDeviceMode sends a checked request. // If an error occurs, it will be returned with the reply by calling SetDeviceModeCookie.Reply() func SetDeviceMode(c *xgb.Conn, DeviceId byte, Mode byte) SetDeviceModeCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'SetDeviceMode' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(true, true) c.NewRequest(setDeviceModeRequest(c, DeviceId, Mode), cookie) return SetDeviceModeCookie{cookie} } // SetDeviceModeUnchecked sends an unchecked request. // If an error occurs, it can only be retrieved using xgb.WaitForEvent or xgb.PollForEvent. func SetDeviceModeUnchecked(c *xgb.Conn, DeviceId byte, Mode byte) SetDeviceModeCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'SetDeviceMode' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(false, true) c.NewRequest(setDeviceModeRequest(c, DeviceId, Mode), cookie) return SetDeviceModeCookie{cookie} } // SetDeviceModeReply represents the data returned from a SetDeviceMode request. type SetDeviceModeReply struct { Sequence uint16 // sequence number of the request for this reply Length uint32 // number of bytes in this reply // padding: 1 bytes Status byte // padding: 23 bytes } // Reply blocks and returns the reply data for a SetDeviceMode request. func (cook SetDeviceModeCookie) Reply() (*SetDeviceModeReply, error) { buf, err := cook.Cookie.Reply() if err != nil { return nil, err } if buf == nil { return nil, nil } return setDeviceModeReply(buf), nil } // setDeviceModeReply reads a byte slice into a SetDeviceModeReply value. func setDeviceModeReply(buf []byte) *SetDeviceModeReply { v := new(SetDeviceModeReply) b := 1 // skip reply determinant b += 1 // padding v.Sequence = xgb.Get16(buf[b:]) b += 2 v.Length = xgb.Get32(buf[b:]) // 4-byte units b += 4 v.Status = buf[b] b += 1 b += 23 // padding return v } // Write request to wire for SetDeviceMode // setDeviceModeRequest writes a SetDeviceMode request to a byte slice. func setDeviceModeRequest(c *xgb.Conn, DeviceId byte, Mode byte) []byte { size := 8 b := 0 buf := make([]byte, size) buf[b] = c.Extensions["XINPUTEXTENSION"] b += 1 buf[b] = 5 // request opcode b += 1 xgb.Put16(buf[b:], uint16(size/4)) // write request size in 4-byte units b += 2 buf[b] = DeviceId b += 1 buf[b] = Mode b += 1 b += 2 // padding return buf } // SetDeviceModifierMappingCookie is a cookie used only for SetDeviceModifierMapping requests. type SetDeviceModifierMappingCookie struct { *xgb.Cookie } // SetDeviceModifierMapping sends a checked request. // If an error occurs, it will be returned with the reply by calling SetDeviceModifierMappingCookie.Reply() func SetDeviceModifierMapping(c *xgb.Conn, DeviceId byte, KeycodesPerModifier byte, Keymaps []byte) SetDeviceModifierMappingCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'SetDeviceModifierMapping' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(true, true) c.NewRequest(setDeviceModifierMappingRequest(c, DeviceId, KeycodesPerModifier, Keymaps), cookie) return SetDeviceModifierMappingCookie{cookie} } // SetDeviceModifierMappingUnchecked sends an unchecked request. // If an error occurs, it can only be retrieved using xgb.WaitForEvent or xgb.PollForEvent. func SetDeviceModifierMappingUnchecked(c *xgb.Conn, DeviceId byte, KeycodesPerModifier byte, Keymaps []byte) SetDeviceModifierMappingCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'SetDeviceModifierMapping' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(false, true) c.NewRequest(setDeviceModifierMappingRequest(c, DeviceId, KeycodesPerModifier, Keymaps), cookie) return SetDeviceModifierMappingCookie{cookie} } // SetDeviceModifierMappingReply represents the data returned from a SetDeviceModifierMapping request. type SetDeviceModifierMappingReply struct { Sequence uint16 // sequence number of the request for this reply Length uint32 // number of bytes in this reply // padding: 1 bytes Status byte // padding: 23 bytes } // Reply blocks and returns the reply data for a SetDeviceModifierMapping request. func (cook SetDeviceModifierMappingCookie) Reply() (*SetDeviceModifierMappingReply, error) { buf, err := cook.Cookie.Reply() if err != nil { return nil, err } if buf == nil { return nil, nil } return setDeviceModifierMappingReply(buf), nil } // setDeviceModifierMappingReply reads a byte slice into a SetDeviceModifierMappingReply value. func setDeviceModifierMappingReply(buf []byte) *SetDeviceModifierMappingReply { v := new(SetDeviceModifierMappingReply) b := 1 // skip reply determinant b += 1 // padding v.Sequence = xgb.Get16(buf[b:]) b += 2 v.Length = xgb.Get32(buf[b:]) // 4-byte units b += 4 v.Status = buf[b] b += 1 b += 23 // padding return v } // Write request to wire for SetDeviceModifierMapping // setDeviceModifierMappingRequest writes a SetDeviceModifierMapping request to a byte slice. func setDeviceModifierMappingRequest(c *xgb.Conn, DeviceId byte, KeycodesPerModifier byte, Keymaps []byte) []byte { size := xgb.Pad((7 + xgb.Pad(((int(KeycodesPerModifier) * 8) * 1)))) b := 0 buf := make([]byte, size) buf[b] = c.Extensions["XINPUTEXTENSION"] b += 1 buf[b] = 27 // request opcode b += 1 xgb.Put16(buf[b:], uint16(size/4)) // write request size in 4-byte units b += 2 buf[b] = DeviceId b += 1 buf[b] = KeycodesPerModifier b += 1 b += 1 // padding copy(buf[b:], Keymaps[:(int(KeycodesPerModifier)*8)]) b += xgb.Pad(int((int(KeycodesPerModifier) * 8))) return buf } // SetDeviceValuatorsCookie is a cookie used only for SetDeviceValuators requests. type SetDeviceValuatorsCookie struct { *xgb.Cookie } // SetDeviceValuators sends a checked request. // If an error occurs, it will be returned with the reply by calling SetDeviceValuatorsCookie.Reply() func SetDeviceValuators(c *xgb.Conn, DeviceId byte, FirstValuator byte, NumValuators byte, Valuators []int32) SetDeviceValuatorsCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'SetDeviceValuators' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(true, true) c.NewRequest(setDeviceValuatorsRequest(c, DeviceId, FirstValuator, NumValuators, Valuators), cookie) return SetDeviceValuatorsCookie{cookie} } // SetDeviceValuatorsUnchecked sends an unchecked request. // If an error occurs, it can only be retrieved using xgb.WaitForEvent or xgb.PollForEvent. func SetDeviceValuatorsUnchecked(c *xgb.Conn, DeviceId byte, FirstValuator byte, NumValuators byte, Valuators []int32) SetDeviceValuatorsCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'SetDeviceValuators' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(false, true) c.NewRequest(setDeviceValuatorsRequest(c, DeviceId, FirstValuator, NumValuators, Valuators), cookie) return SetDeviceValuatorsCookie{cookie} } // SetDeviceValuatorsReply represents the data returned from a SetDeviceValuators request. type SetDeviceValuatorsReply struct { Sequence uint16 // sequence number of the request for this reply Length uint32 // number of bytes in this reply // padding: 1 bytes Status byte // padding: 23 bytes } // Reply blocks and returns the reply data for a SetDeviceValuators request. func (cook SetDeviceValuatorsCookie) Reply() (*SetDeviceValuatorsReply, error) { buf, err := cook.Cookie.Reply() if err != nil { return nil, err } if buf == nil { return nil, nil } return setDeviceValuatorsReply(buf), nil } // setDeviceValuatorsReply reads a byte slice into a SetDeviceValuatorsReply value. func setDeviceValuatorsReply(buf []byte) *SetDeviceValuatorsReply { v := new(SetDeviceValuatorsReply) b := 1 // skip reply determinant b += 1 // padding v.Sequence = xgb.Get16(buf[b:]) b += 2 v.Length = xgb.Get32(buf[b:]) // 4-byte units b += 4 v.Status = buf[b] b += 1 b += 23 // padding return v } // Write request to wire for SetDeviceValuators // setDeviceValuatorsRequest writes a SetDeviceValuators request to a byte slice. func setDeviceValuatorsRequest(c *xgb.Conn, DeviceId byte, FirstValuator byte, NumValuators byte, Valuators []int32) []byte { size := xgb.Pad((8 + xgb.Pad((int(NumValuators) * 4)))) b := 0 buf := make([]byte, size) buf[b] = c.Extensions["XINPUTEXTENSION"] b += 1 buf[b] = 33 // request opcode b += 1 xgb.Put16(buf[b:], uint16(size/4)) // write request size in 4-byte units b += 2 buf[b] = DeviceId b += 1 buf[b] = FirstValuator b += 1 buf[b] = NumValuators b += 1 b += 1 // padding for i := 0; i < int(NumValuators); i++ { xgb.Put32(buf[b:], uint32(Valuators[i])) b += 4 } b = xgb.Pad(b) return buf } // UngrabDeviceCookie is a cookie used only for UngrabDevice requests. type UngrabDeviceCookie struct { *xgb.Cookie } // UngrabDevice sends an unchecked request. // If an error occurs, it can only be retrieved using xgb.WaitForEvent or xgb.PollForEvent. func UngrabDevice(c *xgb.Conn, Time xproto.Timestamp, DeviceId byte) UngrabDeviceCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'UngrabDevice' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(false, false) c.NewRequest(ungrabDeviceRequest(c, Time, DeviceId), cookie) return UngrabDeviceCookie{cookie} } // UngrabDeviceChecked sends a checked request. // If an error occurs, it can be retrieved using UngrabDeviceCookie.Check() func UngrabDeviceChecked(c *xgb.Conn, Time xproto.Timestamp, DeviceId byte) UngrabDeviceCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'UngrabDevice' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(true, false) c.NewRequest(ungrabDeviceRequest(c, Time, DeviceId), cookie) return UngrabDeviceCookie{cookie} } // Check returns an error if one occurred for checked requests that are not expecting a reply. // This cannot be called for requests expecting a reply, nor for unchecked requests. func (cook UngrabDeviceCookie) Check() error { return cook.Cookie.Check() } // Write request to wire for UngrabDevice // ungrabDeviceRequest writes a UngrabDevice request to a byte slice. func ungrabDeviceRequest(c *xgb.Conn, Time xproto.Timestamp, DeviceId byte) []byte { size := 12 b := 0 buf := make([]byte, size) buf[b] = c.Extensions["XINPUTEXTENSION"] b += 1 buf[b] = 14 // request opcode b += 1 xgb.Put16(buf[b:], uint16(size/4)) // write request size in 4-byte units b += 2 xgb.Put32(buf[b:], uint32(Time)) b += 4 buf[b] = DeviceId b += 1 return buf } // UngrabDeviceButtonCookie is a cookie used only for UngrabDeviceButton requests. type UngrabDeviceButtonCookie struct { *xgb.Cookie } // UngrabDeviceButton sends an unchecked request. // If an error occurs, it can only be retrieved using xgb.WaitForEvent or xgb.PollForEvent. func UngrabDeviceButton(c *xgb.Conn, GrabWindow xproto.Window, Modifiers uint16, ModifierDevice byte, Button byte, GrabbedDevice byte) UngrabDeviceButtonCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'UngrabDeviceButton' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(false, false) c.NewRequest(ungrabDeviceButtonRequest(c, GrabWindow, Modifiers, ModifierDevice, Button, GrabbedDevice), cookie) return UngrabDeviceButtonCookie{cookie} } // UngrabDeviceButtonChecked sends a checked request. // If an error occurs, it can be retrieved using UngrabDeviceButtonCookie.Check() func UngrabDeviceButtonChecked(c *xgb.Conn, GrabWindow xproto.Window, Modifiers uint16, ModifierDevice byte, Button byte, GrabbedDevice byte) UngrabDeviceButtonCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'UngrabDeviceButton' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(true, false) c.NewRequest(ungrabDeviceButtonRequest(c, GrabWindow, Modifiers, ModifierDevice, Button, GrabbedDevice), cookie) return UngrabDeviceButtonCookie{cookie} } // Check returns an error if one occurred for checked requests that are not expecting a reply. // This cannot be called for requests expecting a reply, nor for unchecked requests. func (cook UngrabDeviceButtonCookie) Check() error { return cook.Cookie.Check() } // Write request to wire for UngrabDeviceButton // ungrabDeviceButtonRequest writes a UngrabDeviceButton request to a byte slice. func ungrabDeviceButtonRequest(c *xgb.Conn, GrabWindow xproto.Window, Modifiers uint16, ModifierDevice byte, Button byte, GrabbedDevice byte) []byte { size := 16 b := 0 buf := make([]byte, size) buf[b] = c.Extensions["XINPUTEXTENSION"] b += 1 buf[b] = 18 // request opcode b += 1 xgb.Put16(buf[b:], uint16(size/4)) // write request size in 4-byte units b += 2 xgb.Put32(buf[b:], uint32(GrabWindow)) b += 4 xgb.Put16(buf[b:], Modifiers) b += 2 buf[b] = ModifierDevice b += 1 buf[b] = Button b += 1 buf[b] = GrabbedDevice b += 1 return buf } // UngrabDeviceKeyCookie is a cookie used only for UngrabDeviceKey requests. type UngrabDeviceKeyCookie struct { *xgb.Cookie } // UngrabDeviceKey sends an unchecked request. // If an error occurs, it can only be retrieved using xgb.WaitForEvent or xgb.PollForEvent. func UngrabDeviceKey(c *xgb.Conn, GrabWindow xproto.Window, Modifiers uint16, ModifierDevice byte, Key byte, GrabbedDevice byte) UngrabDeviceKeyCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'UngrabDeviceKey' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(false, false) c.NewRequest(ungrabDeviceKeyRequest(c, GrabWindow, Modifiers, ModifierDevice, Key, GrabbedDevice), cookie) return UngrabDeviceKeyCookie{cookie} } // UngrabDeviceKeyChecked sends a checked request. // If an error occurs, it can be retrieved using UngrabDeviceKeyCookie.Check() func UngrabDeviceKeyChecked(c *xgb.Conn, GrabWindow xproto.Window, Modifiers uint16, ModifierDevice byte, Key byte, GrabbedDevice byte) UngrabDeviceKeyCookie { if _, ok := c.Extensions["XINPUTEXTENSION"]; !ok { panic("Cannot issue request 'UngrabDeviceKey' using the uninitialized extension 'XInputExtension'. xinput.Init(connObj) must be called first.") } cookie := c.NewCookie(true, false) c.NewRequest(ungrabDeviceKeyRequest(c, GrabWindow, Modifiers, ModifierDevice, Key, GrabbedDevice), cookie) return UngrabDeviceKeyCookie{cookie} } // Check returns an error if one occurred for checked requests that are not expecting a reply. // This cannot be called for requests expecting a reply, nor for unchecked requests. func (cook UngrabDeviceKeyCookie) Check() error { return cook.Cookie.Check() } // Write request to wire for UngrabDeviceKey // ungrabDeviceKeyRequest writes a UngrabDeviceKey request to a byte slice. func ungrabDeviceKeyRequest(c *xgb.Conn, GrabWindow xproto.Window, Modifiers uint16, ModifierDevice byte, Key byte, GrabbedDevice byte) []byte { size := 16 b := 0 buf := make([]byte, size) buf[b] = c.Extensions["XINPUTEXTENSION"] b += 1 buf[b] = 16 // request opcode b += 1 xgb.Put16(buf[b:], uint16(size/4)) // write request size in 4-byte units b += 2 xgb.Put32(buf[b:], uint32(GrabWindow)) b += 4 xgb.Put16(buf[b:], Modifiers) b += 2 buf[b] = ModifierDevice b += 1 buf[b] = Key b += 1 buf[b] = GrabbedDevice b += 1 return buf }