shiny/driver/x11driver/window.go - exp - Git at Google

 // Copyright 2015 The Go Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 package x11driver

 // TODO: implement a back buffer.

 import (
 	"image"
 	"image/color"
 	"image/draw"
 	"sync"

 	"github.com/BurntSushi/xgb"
 	"github.com/BurntSushi/xgb/render"
 	"github.com/BurntSushi/xgb/xproto"

 	"golang.org/x/exp/shiny/driver/internal/drawer"
 	"golang.org/x/exp/shiny/driver/internal/event"
 	"golang.org/x/exp/shiny/driver/internal/lifecycler"
 	"golang.org/x/exp/shiny/driver/internal/x11key"
 	"golang.org/x/exp/shiny/screen"
 	"golang.org/x/image/math/f64"
 	"golang.org/x/mobile/event/key"
 	"golang.org/x/mobile/event/mouse"
 	"golang.org/x/mobile/event/paint"
 	"golang.org/x/mobile/event/size"
 	"golang.org/x/mobile/geom"
 )

 type windowImpl struct {
 	s *screenImpl

 	xw xproto.Window
 	xg xproto.Gcontext
 	xp render.Picture

 	event.Deque
 	xevents chan xgb.Event

 	// This next group of variables are mutable, but are only modified in the
 	// screenImpl.run goroutine.
 	width, height int

 	lifecycler lifecycler.State

 	mu       sync.Mutex
 	released bool
 }

 func (w *windowImpl) Release() {
 	w.mu.Lock()
 	released := w.released
 	w.released = true
 	w.mu.Unlock()

 	// TODO: call w.lifecycler.SetDead and w.lifecycler.SendEvent, a la
 	// handling atomWMDeleteWindow?

 	if released {
 		return
 	}
 	render.FreePicture(w.s.xc, w.xp)
 	xproto.FreeGC(w.s.xc, w.xg)
 	xproto.DestroyWindow(w.s.xc, w.xw)
 }

 func (w *windowImpl) Upload(dp image.Point, src screen.Buffer, sr image.Rectangle) {
 	src.(*bufferImpl).upload(xproto.Drawable(w.xw), w.xg, w.s.xsi.RootDepth, dp, sr)
 }

 func (w *windowImpl) Fill(dr image.Rectangle, src color.Color, op draw.Op) {
 	fill(w.s.xc, w.xp, dr, src, op)
 }

 func (w *windowImpl) DrawUniform(src2dst f64.Aff3, src color.Color, sr image.Rectangle, op draw.Op, opts *screen.DrawOptions) {
 	w.s.drawUniform(w.xp, &src2dst, src, sr, op, opts)
 }

 func (w *windowImpl) Draw(src2dst f64.Aff3, src screen.Texture, sr image.Rectangle, op draw.Op, opts *screen.DrawOptions) {
 	src.(*textureImpl).draw(w.xp, &src2dst, sr, op, opts)
 }

 func (w *windowImpl) Copy(dp image.Point, src screen.Texture, sr image.Rectangle, op draw.Op, opts *screen.DrawOptions) {
 	drawer.Copy(w, dp, src, sr, op, opts)
 }

 func (w *windowImpl) Scale(dr image.Rectangle, src screen.Texture, sr image.Rectangle, op draw.Op, opts *screen.DrawOptions) {
 	drawer.Scale(w, dr, src, sr, op, opts)
 }

 func (w *windowImpl) Publish() screen.PublishResult {
 	// TODO: implement a back buffer, and copy or flip that here to the front
 	// buffer.

 	// This sync isn't needed to flush the outgoing X11 requests. Instead, it
 	// acts as a form of flow control. Outgoing requests can be quite small on
 	// the wire, e.g. draw this texture ID (an integer) to this rectangle (four
 	// more integers), but much more expensive on the server (blending a
 	// million source and destination pixels). Without this sync, the Go X11
 	// client could easily end up sending work at a faster rate than the X11
 	// server can serve.
 	w.s.xc.Sync()

 	return screen.PublishResult{}
 }

 func (w *windowImpl) handleConfigureNotify(ev xproto.ConfigureNotifyEvent) {
 	// TODO: does the order of these lifecycle and size events matter? Should
 	// they really be a single, atomic event?
 	w.lifecycler.SetVisible((int(ev.X)+int(ev.Width)) > 0 && (int(ev.Y)+int(ev.Height)) > 0)
 	w.lifecycler.SendEvent(w, nil)

 	newWidth, newHeight := int(ev.Width), int(ev.Height)
 	if w.width == newWidth && w.height == newHeight {
 		return
 	}
 	w.width, w.height = newWidth, newHeight
 	w.Send(size.Event{
 		WidthPx:     newWidth,
 		HeightPx:    newHeight,
 		WidthPt:     geom.Pt(newWidth),
 		HeightPt:    geom.Pt(newHeight),
 		PixelsPerPt: w.s.pixelsPerPt,
 	})
 }

 func (w *windowImpl) handleExpose() {
 	w.Send(paint.Event{})
 }

 func (w *windowImpl) handleKey(detail xproto.Keycode, state uint16, dir key.Direction) {
 	r, c := w.s.keysyms.Lookup(uint8(detail), state)
 	w.Send(key.Event{
 		Rune:      r,
 		Code:      c,
 		Modifiers: x11key.KeyModifiers(state),
 		Direction: dir,
 	})
 }

 func (w *windowImpl) handleMouse(x, y int16, b xproto.Button, state uint16, dir mouse.Direction) {
 	// TODO: should a mouse.Event have a separate MouseModifiers field, for
 	// which buttons are pressed during a mouse move?
 	btn := mouse.Button(b)
 	switch btn {
 	case 4:
 		btn = mouse.ButtonWheelUp
 	case 5:
 		btn = mouse.ButtonWheelDown
 	case 6:
 		btn = mouse.ButtonWheelLeft
 	case 7:
 		btn = mouse.ButtonWheelRight
 	}
 	if btn.IsWheel() {
 		if dir != mouse.DirPress {
 			return
 		}
 		dir = mouse.DirStep
 	}
 	w.Send(mouse.Event{
 		X:         float32(x),
 		Y:         float32(y),
 		Button:    btn,
 		Modifiers: x11key.KeyModifiers(state),
 		Direction: dir,
 	})
 }
	// Copyright 2015 The Go Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	package x11driver

	// TODO: implement a back buffer.

	import (
	"image"
	"image/color"
	"image/draw"
	"sync"

	"github.com/BurntSushi/xgb"
	"github.com/BurntSushi/xgb/render"
	"github.com/BurntSushi/xgb/xproto"

	"golang.org/x/exp/shiny/driver/internal/drawer"
	"golang.org/x/exp/shiny/driver/internal/event"
	"golang.org/x/exp/shiny/driver/internal/lifecycler"
	"golang.org/x/exp/shiny/driver/internal/x11key"
	"golang.org/x/exp/shiny/screen"
	"golang.org/x/image/math/f64"
	"golang.org/x/mobile/event/key"
	"golang.org/x/mobile/event/mouse"
	"golang.org/x/mobile/event/paint"
	"golang.org/x/mobile/event/size"
	"golang.org/x/mobile/geom"
	)

	type windowImpl struct {
	s *screenImpl

	xw xproto.Window
	xg xproto.Gcontext
	xp render.Picture

	event.Deque
	xevents chan xgb.Event

	// This next group of variables are mutable, but are only modified in the
	// screenImpl.run goroutine.
	width, height int

	lifecycler lifecycler.State

	mu sync.Mutex
	released bool
	}

	func (w *windowImpl) Release() {
	w.mu.Lock()
	released := w.released
	w.released = true
	w.mu.Unlock()

	// TODO: call w.lifecycler.SetDead and w.lifecycler.SendEvent, a la
	// handling atomWMDeleteWindow?

	if released {
	return
	}
	render.FreePicture(w.s.xc, w.xp)
	xproto.FreeGC(w.s.xc, w.xg)
	xproto.DestroyWindow(w.s.xc, w.xw)
	}

	func (w *windowImpl) Upload(dp image.Point, src screen.Buffer, sr image.Rectangle) {
	src.(*bufferImpl).upload(xproto.Drawable(w.xw), w.xg, w.s.xsi.RootDepth, dp, sr)
	}

	func (w *windowImpl) Fill(dr image.Rectangle, src color.Color, op draw.Op) {
	fill(w.s.xc, w.xp, dr, src, op)
	}

	func (w windowImpl) DrawUniform(src2dst f64.Aff3, src color.Color, sr image.Rectangle, op draw.Op, opts screen.DrawOptions) {
	w.s.drawUniform(w.xp, &src2dst, src, sr, op, opts)
	}

	func (w windowImpl) Draw(src2dst f64.Aff3, src screen.Texture, sr image.Rectangle, op draw.Op, opts screen.DrawOptions) {
	src.(*textureImpl).draw(w.xp, &src2dst, sr, op, opts)
	}

	func (w windowImpl) Copy(dp image.Point, src screen.Texture, sr image.Rectangle, op draw.Op, opts screen.DrawOptions) {
	drawer.Copy(w, dp, src, sr, op, opts)
	}

	func (w windowImpl) Scale(dr image.Rectangle, src screen.Texture, sr image.Rectangle, op draw.Op, opts screen.DrawOptions) {
	drawer.Scale(w, dr, src, sr, op, opts)
	}

	func (w *windowImpl) Publish() screen.PublishResult {
	// TODO: implement a back buffer, and copy or flip that here to the front
	// buffer.

	// This sync isn't needed to flush the outgoing X11 requests. Instead, it
	// acts as a form of flow control. Outgoing requests can be quite small on
	// the wire, e.g. draw this texture ID (an integer) to this rectangle (four
	// more integers), but much more expensive on the server (blending a
	// million source and destination pixels). Without this sync, the Go X11
	// client could easily end up sending work at a faster rate than the X11
	// server can serve.
	w.s.xc.Sync()

	return screen.PublishResult{}
	}

	func (w *windowImpl) handleConfigureNotify(ev xproto.ConfigureNotifyEvent) {
	// TODO: does the order of these lifecycle and size events matter? Should
	// they really be a single, atomic event?
	w.lifecycler.SetVisible((int(ev.X)+int(ev.Width)) > 0 && (int(ev.Y)+int(ev.Height)) > 0)
	w.lifecycler.SendEvent(w, nil)

	newWidth, newHeight := int(ev.Width), int(ev.Height)
	if w.width == newWidth && w.height == newHeight {
	return
	}
	w.width, w.height = newWidth, newHeight
	w.Send(size.Event{
	WidthPx: newWidth,
	HeightPx: newHeight,
	WidthPt: geom.Pt(newWidth),
	HeightPt: geom.Pt(newHeight),
	PixelsPerPt: w.s.pixelsPerPt,
	})
	}

	func (w *windowImpl) handleExpose() {
	w.Send(paint.Event{})
	}

	func (w *windowImpl) handleKey(detail xproto.Keycode, state uint16, dir key.Direction) {
	r, c := w.s.keysyms.Lookup(uint8(detail), state)
	w.Send(key.Event{
	Rune: r,
	Code: c,
	Modifiers: x11key.KeyModifiers(state),
	Direction: dir,
	})
	}

	func (w *windowImpl) handleMouse(x, y int16, b xproto.Button, state uint16, dir mouse.Direction) {
	// TODO: should a mouse.Event have a separate MouseModifiers field, for
	// which buttons are pressed during a mouse move?
	btn := mouse.Button(b)
	switch btn {
	case 4:
	btn = mouse.ButtonWheelUp
	case 5:
	btn = mouse.ButtonWheelDown
	case 6:
	btn = mouse.ButtonWheelLeft
	case 7:
	btn = mouse.ButtonWheelRight
	}
	if btn.IsWheel() {
	if dir != mouse.DirPress {
	return
	}
	dir = mouse.DirStep
	}
	w.Send(mouse.Event{
	X: float32(x),
	Y: float32(y),
	Button: btn,
	Modifiers: x11key.KeyModifiers(state),
	Direction: dir,
	})
	}