ebiten/internal/uidriver/glfw/ui.go
2020-01-01 23:59:56 +09:00

1015 lines
24 KiB
Go

// Copyright 2015 Hajime Hoshi
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
// +build darwin freebsd linux windows
// +build !js
// +build !android
// +build !ios
package glfw
import (
"context"
"fmt"
"image"
"os"
"runtime"
"sync"
"time"
"unsafe"
"github.com/hajimehoshi/ebiten/internal/devicescale"
"github.com/hajimehoshi/ebiten/internal/driver"
"github.com/hajimehoshi/ebiten/internal/glfw"
"github.com/hajimehoshi/ebiten/internal/hooks"
"github.com/hajimehoshi/ebiten/internal/thread"
)
type UserInterface struct {
title string
window *glfw.Window
// windowWidth and windowHeight represents a window size.
// The unit is device-dependent pixels.
windowWidth int
windowHeight int
running bool
toChangeSize bool
origPosX int
origPosY int
runnableInBackground bool
vsync bool
lastDeviceScaleFactor float64
initMonitor *glfw.Monitor
initTitle string
initFullscreenWidthInDP int
initFullscreenHeightInDP int
initFullscreen bool
initCursorMode driver.CursorMode
initWindowDecorated bool
initWindowResizable bool
initWindowPositionXInDP int
initWindowPositionYInDP int
initWindowWidthInDP int
initWindowHeightInDP int
initScreenTransparent bool
initIconImages []image.Image
reqWidth int
reqHeight int
graphics driver.Graphics
input Input
iwindow window
t *thread.Thread
m sync.RWMutex
}
const (
maxInt = int(^uint(0) >> 1)
minInt = -maxInt - 1
invalidPos = minInt
)
var (
theUI = &UserInterface{
origPosX: invalidPos,
origPosY: invalidPos,
initCursorMode: driver.CursorModeVisible,
initWindowDecorated: true,
initWindowPositionXInDP: invalidPos,
initWindowPositionYInDP: invalidPos,
initWindowWidthInDP: 640,
initWindowHeightInDP: 480,
vsync: true,
}
)
func init() {
theUI.input.ui = theUI
theUI.iwindow.ui = theUI
}
func Get() *UserInterface {
return theUI
}
func init() {
hideConsoleWindowOnWindows()
if err := initialize(); err != nil {
panic(err)
}
glfw.SetMonitorCallback(func(monitor *glfw.Monitor, event glfw.PeripheralEvent) {
cacheMonitors()
})
cacheMonitors()
}
func initialize() error {
if err := glfw.Init(); err != nil {
return err
}
glfw.WindowHint(glfw.Visible, glfw.False)
// Create a window to set the initial monitor.
w, err := glfw.CreateWindow(16, 16, "", nil, nil)
if err != nil {
return err
}
if w == nil {
// This can happen on Windows Remote Desktop (#903).
panic("glfw: glfw.CreateWindow must not return nil")
}
// Create a window and leave it as it is: this affects the result of currentMonitorFromPosition.
theUI.window = w
theUI.initMonitor = theUI.currentMonitor()
v := theUI.initMonitor.GetVideoMode()
theUI.initFullscreenWidthInDP = int(theUI.toDeviceIndependentPixel(float64(v.Width)))
theUI.initFullscreenHeightInDP = int(theUI.toDeviceIndependentPixel(float64(v.Height)))
return nil
}
type cachedMonitor struct {
m *glfw.Monitor
vm *glfw.VidMode
// Pos of monitor in virtual coords
x int
y int
}
// monitors is the monitor list cache for desktop glfw compile targets.
// populated by 'cacheMonitors' which is called on init and every
// monitor config change event.
//
// monitors must be manipulated on the main thread.
var monitors []*cachedMonitor
func cacheMonitors() {
monitors = nil
ms := glfw.GetMonitors()
for _, m := range ms {
x, y := m.GetPos()
monitors = append(monitors, &cachedMonitor{
m: m,
vm: m.GetVideoMode(),
x: x,
y: y,
})
}
}
// getCachedMonitor returns a monitor for the given window x/y
// returns false if monitor is not found.
//
// getCachedMonitor must be called on the main thread.
func getCachedMonitor(wx, wy int) (*cachedMonitor, bool) {
for _, m := range monitors {
if m.x <= wx && wx < m.x+m.vm.Width && m.y <= wy && wy < m.y+m.vm.Height {
return m, true
}
}
return nil, false
}
func (u *UserInterface) isRunning() bool {
u.m.RLock()
v := u.running
u.m.RUnlock()
return v
}
func (u *UserInterface) setRunning(running bool) {
u.m.Lock()
u.running = running
u.m.Unlock()
}
func (u *UserInterface) getInitTitle() string {
u.m.RLock()
v := u.initTitle
u.m.RUnlock()
return v
}
func (u *UserInterface) setInitTitle(title string) {
u.m.RLock()
u.initTitle = title
u.m.RUnlock()
}
func (u *UserInterface) isInitFullscreen() bool {
u.m.RLock()
v := u.initFullscreen
u.m.RUnlock()
return v
}
func (u *UserInterface) setInitFullscreen(initFullscreen bool) {
u.m.Lock()
u.initFullscreen = initFullscreen
u.m.Unlock()
}
func (u *UserInterface) getInitCursorMode() driver.CursorMode {
u.m.RLock()
v := u.initCursorMode
u.m.RUnlock()
return v
}
func (u *UserInterface) setInitCursorMode(mode driver.CursorMode) {
u.m.Lock()
u.initCursorMode = mode
u.m.Unlock()
}
func (u *UserInterface) isInitWindowDecorated() bool {
u.m.RLock()
v := u.initWindowDecorated
u.m.RUnlock()
return v
}
func (u *UserInterface) setInitWindowDecorated(decorated bool) {
u.m.Lock()
u.initWindowDecorated = decorated
u.m.Unlock()
}
func (u *UserInterface) isRunnableInBackground() bool {
u.m.RLock()
v := u.runnableInBackground
u.m.RUnlock()
return v
}
func (u *UserInterface) setRunnableInBackground(runnableInBackground bool) {
u.m.Lock()
u.runnableInBackground = runnableInBackground
u.m.Unlock()
}
func (u *UserInterface) isInitWindowResizable() bool {
u.m.RLock()
v := u.initWindowResizable
u.m.RUnlock()
return v
}
func (u *UserInterface) setInitWindowResizable(resizable bool) {
u.m.Lock()
u.initWindowResizable = resizable
u.m.Unlock()
}
func (u *UserInterface) isInitScreenTransparent() bool {
u.m.RLock()
v := u.initScreenTransparent
u.m.RUnlock()
return v
}
func (u *UserInterface) setInitScreenTransparent(transparent bool) {
u.m.RLock()
u.initScreenTransparent = transparent
u.m.RUnlock()
}
func (u *UserInterface) getInitIconImages() []image.Image {
u.m.RLock()
i := u.initIconImages
u.m.RUnlock()
return i
}
func (u *UserInterface) setInitIconImages(iconImages []image.Image) {
u.m.Lock()
u.initIconImages = iconImages
u.m.Unlock()
}
func (u *UserInterface) getInitWindowPosition() (int, int) {
u.m.RLock()
defer u.m.RUnlock()
if u.initWindowPositionXInDP != invalidPos && u.initWindowPositionYInDP != invalidPos {
return u.initWindowPositionXInDP, u.initWindowPositionYInDP
}
return invalidPos, invalidPos
}
func (u *UserInterface) setInitWindowPosition(x, y int) {
u.m.Lock()
defer u.m.Unlock()
u.initWindowPositionXInDP = x
u.initWindowPositionYInDP = y
}
func (u *UserInterface) getInitWindowSize() (int, int) {
u.m.Lock()
w, h := u.initWindowWidthInDP, u.initWindowHeightInDP
u.m.Unlock()
return w, h
}
func (u *UserInterface) setInitWindowSize(width, height int) {
u.m.Lock()
u.initWindowWidthInDP, u.initWindowHeightInDP = width, height
u.m.Unlock()
}
// toDeviceIndependentPixel must be called from the main thread.
func (u *UserInterface) toDeviceIndependentPixel(x float64) float64 {
return x / u.glfwScale()
}
// toDeviceDependentPixel must be called from the main thread.
func (u *UserInterface) toDeviceDependentPixel(x float64) float64 {
return x * u.glfwScale()
}
func (u *UserInterface) ScreenSizeInFullscreen() (int, int) {
if !u.isRunning() {
return u.initFullscreenWidthInDP, u.initFullscreenHeightInDP
}
var w, h int
_ = u.t.Call(func() error {
v := u.currentMonitor().GetVideoMode()
w = int(u.toDeviceIndependentPixel(float64(v.Width)))
h = int(u.toDeviceIndependentPixel(float64(v.Height)))
return nil
})
return w, h
}
// isFullscreen must be called from the main thread.
func (u *UserInterface) isFullscreen() bool {
if !u.isRunning() {
panic("glfw: isFullscreen can't be called before the main loop starts")
}
return u.window.GetMonitor() != nil
}
func (u *UserInterface) IsFullscreen() bool {
if !u.isRunning() {
return u.isInitFullscreen()
}
b := false
_ = u.t.Call(func() error {
b = u.isFullscreen()
return nil
})
return b
}
func (u *UserInterface) SetFullscreen(fullscreen bool) {
if !u.isRunning() {
u.setInitFullscreen(fullscreen)
return
}
var update bool
_ = u.t.Call(func() error {
update = u.isFullscreen() != fullscreen
return nil
})
if !update {
return
}
var w, h int
_ = u.t.Call(func() error {
w, h = u.windowWidth, u.windowHeight
return nil
})
u.setWindowSize(w, h, fullscreen, u.vsync)
}
func (u *UserInterface) SetRunnableInBackground(runnableInBackground bool) {
u.setRunnableInBackground(runnableInBackground)
}
func (u *UserInterface) IsRunnableInBackground() bool {
return u.isRunnableInBackground()
}
func (u *UserInterface) SetVsyncEnabled(enabled bool) {
if !u.isRunning() {
// In general, m is used for locking init* values.
// m is not used for updating vsync in setWindowSize so far, but
// it should be OK since any goroutines can't reach here when
// the game already starts and setWindowSize can be called.
u.m.Lock()
u.vsync = enabled
u.m.Unlock()
return
}
var w, h int
_ = u.t.Call(func() error {
w, h = u.windowWidth, u.windowHeight
return nil
})
u.setWindowSize(w, h, u.isFullscreen(), enabled)
}
func (u *UserInterface) IsVsyncEnabled() bool {
u.m.RLock()
r := u.vsync
u.m.RUnlock()
return r
}
func (u *UserInterface) CursorMode() driver.CursorMode {
if !u.isRunning() {
return u.getInitCursorMode()
}
var v driver.CursorMode
_ = u.t.Call(func() error {
mode := u.window.GetInputMode(glfw.CursorMode)
switch mode {
case glfw.CursorNormal:
v = driver.CursorModeVisible
case glfw.CursorHidden:
v = driver.CursorModeHidden
case glfw.CursorDisabled:
v = driver.CursorModeCaptured
default:
panic(fmt.Sprintf("invalid cursor mode: %d", mode))
}
return nil
})
return v
}
func (u *UserInterface) SetCursorMode(mode driver.CursorMode) {
if !u.isRunning() {
u.setInitCursorMode(mode)
return
}
_ = u.t.Call(func() error {
var c int
switch mode {
case driver.CursorModeVisible:
c = glfw.CursorNormal
case driver.CursorModeHidden:
c = glfw.CursorHidden
case driver.CursorModeCaptured:
c = glfw.CursorDisabled
default:
panic(fmt.Sprintf("invalid cursor mode: %d", mode))
}
u.window.SetInputMode(glfw.CursorMode, c)
return nil
})
}
func (u *UserInterface) DeviceScaleFactor() float64 {
if !u.isRunning() {
return devicescale.GetAt(u.initMonitor.GetPos())
}
f := 0.0
_ = u.t.Call(func() error {
f = u.deviceScaleFactor()
return nil
})
return f
}
// deviceScaleFactor must be called from the main thread.
func (u *UserInterface) deviceScaleFactor() float64 {
// Avoid calling monitor.GetPos if we have the monitor position cached already.
if cm, ok := getCachedMonitor(u.window.GetPos()); ok {
return devicescale.GetAt(cm.x, cm.y)
}
// TODO: When is this reached?
return devicescale.GetAt(u.currentMonitor().GetPos())
}
func init() {
// Lock the main thread.
runtime.LockOSThread()
}
func (u *UserInterface) Run(uicontext driver.UIContext, graphics driver.Graphics) error {
// Initialize the main thread first so the thread is available at u.run (#809).
u.t = thread.New()
u.graphics = graphics
u.graphics.SetThread(u.t)
ctx, cancel := context.WithCancel(context.Background())
ch := make(chan error, 1)
go func() {
defer cancel()
defer close(ch)
if err := u.run(uicontext); err != nil {
ch <- err
}
}()
u.setRunning(true)
u.t.Loop(ctx)
u.setRunning(false)
return <-ch
}
func (u *UserInterface) RunWithoutMainLoop(width, height int, scale float64, title string, context driver.UIContext, graphics driver.Graphics) <-chan error {
panic("glfw: RunWithoutMainLoop is not implemented")
}
// createWindow creates a GLFW window.
//
// createWindow must be called from the main thread.
//
// createWindow does not set the position or size so far.
func (u *UserInterface) createWindow() error {
if u.window != nil {
panic("glfw: u.window must not exist at createWindow")
}
// As a start, create a window with temporary size to create OpenGL context thread.
window, err := glfw.CreateWindow(16, 16, "", nil, nil)
if err != nil {
return err
}
u.window = window
if u.graphics.IsGL() {
u.window.MakeContextCurrent()
}
u.window.SetInputMode(glfw.StickyMouseButtonsMode, glfw.True)
u.window.SetInputMode(glfw.StickyKeysMode, glfw.True)
mode := glfw.CursorNormal
switch u.getInitCursorMode() {
case driver.CursorModeHidden:
mode = glfw.CursorHidden
case driver.CursorModeCaptured:
mode = glfw.CursorDisabled
}
u.window.SetInputMode(glfw.CursorMode, mode)
u.window.SetTitle(u.title)
// TODO: Set icons
u.window.SetSizeCallback(func(_ *glfw.Window, width, height int) {
if u.window.GetAttrib(glfw.Resizable) == glfw.False {
return
}
if u.isFullscreen() {
return
}
u.reqWidth = width
u.reqHeight = height
})
return nil
}
func (u *UserInterface) run(context driver.UIContext) error {
if err := u.t.Call(func() error {
// The window is created at initialize().
u.window.Destroy()
u.window = nil
if u.graphics.IsGL() {
glfw.WindowHint(glfw.ContextVersionMajor, 2)
glfw.WindowHint(glfw.ContextVersionMinor, 1)
} else {
glfw.WindowHint(glfw.ClientAPI, glfw.NoAPI)
}
decorated := glfw.False
if u.isInitWindowDecorated() {
decorated = glfw.True
}
glfw.WindowHint(glfw.Decorated, decorated)
transparent := glfw.False
if u.isInitScreenTransparent() {
transparent = glfw.True
}
glfw.WindowHint(glfw.TransparentFramebuffer, transparent)
u.graphics.SetTransparent(u.isInitScreenTransparent())
resizable := glfw.False
if u.isInitWindowResizable() {
resizable = glfw.True
}
glfw.WindowHint(glfw.Resizable, resizable)
// Set the window visible explicitly or the application freezes on Wayland (#974).
if os.Getenv("WAYLAND_DISPLAY") != "" {
glfw.WindowHint(glfw.Visible, glfw.True)
}
if err := u.createWindow(); err != nil {
return err
}
if i := u.getInitIconImages(); i != nil {
u.window.SetIcon(i)
}
return nil
}); err != nil {
return err
}
u.iwindow.SetPosition(u.getInitWindowPosition())
ww, wh := u.getInitWindowSize()
ww = int(u.toDeviceDependentPixel(float64(ww)))
wh = int(u.toDeviceDependentPixel(float64(wh)))
u.setWindowSize(ww, wh, u.isFullscreen(), u.vsync)
_ = u.t.Call(func() error {
u.title = u.getInitTitle()
u.window.SetTitle(u.title)
u.window.Show()
return nil
})
var w unsafe.Pointer
_ = u.t.Call(func() error {
w = u.nativeWindow()
return nil
})
u.graphics.SetWindow(w)
return u.loop(context)
}
func (u *UserInterface) updateSize(context driver.UIContext) {
var w, h int
_ = u.t.Call(func() error {
w, h = u.windowWidth, u.windowHeight
return nil
})
u.setWindowSize(w, h, u.isFullscreen(), u.vsync)
sizeChanged := false
_ = u.t.Call(func() error {
if !u.toChangeSize {
return nil
}
u.toChangeSize = false
sizeChanged = true
return nil
})
if sizeChanged {
var w, h float64
_ = u.t.Call(func() error {
var ww, wh int
if u.isFullscreen() {
v := u.currentMonitor().GetVideoMode()
ww = v.Width
wh = v.Height
} else {
ww, wh = u.windowWidth, u.windowHeight
}
w = u.toDeviceIndependentPixel(float64(ww))
h = u.toDeviceIndependentPixel(float64(wh))
return nil
})
context.Layout(w, h)
}
}
func (u *UserInterface) update(context driver.UIContext) error {
shouldClose := false
_ = u.t.Call(func() error {
shouldClose = u.window.ShouldClose()
return nil
})
if shouldClose {
return driver.RegularTermination
}
if u.isInitFullscreen() {
var w, h int
_ = u.t.Call(func() error {
w, h = u.window.GetSize()
return nil
})
u.setWindowSize(w, h, true, u.vsync)
u.setInitFullscreen(false)
}
// This call is needed for initialization.
u.updateSize(context)
_ = u.t.Call(func() error {
glfw.PollEvents()
return nil
})
u.input.update(u.window, context)
_ = u.t.Call(func() error {
defer hooks.ResumeAudio()
for !u.isRunnableInBackground() && u.window.GetAttrib(glfw.Focused) == 0 {
hooks.SuspendAudio()
// Wait for an arbitrary period to avoid busy loop.
time.Sleep(time.Second / 60)
glfw.PollEvents()
if u.window.ShouldClose() {
return nil
}
}
return nil
})
if err := context.Update(func() {
// The offscreens must be updated every frame (#490).
u.updateSize(context)
}); err != nil {
return err
}
// Update the screen size when the window is resizable.
var w, h int
_ = u.t.Call(func() error {
w, h = u.reqWidth, u.reqHeight
return nil
})
if w != 0 || h != 0 {
u.setWindowSize(w, h, u.isFullscreen(), u.vsync)
}
_ = u.t.Call(func() error {
u.reqWidth = 0
u.reqHeight = 0
return nil
})
return nil
}
func (u *UserInterface) loop(context driver.UIContext) error {
defer func() {
_ = u.t.Call(func() error {
glfw.Terminate()
return nil
})
}()
for {
var unfocused bool
// On Windows, the focusing state might be always false (#987).
// On Windows, even if a window is in another workspace, vsync seems to work.
// Then let's assume the window is always 'focused' as a workaround.
if runtime.GOOS != "windows" {
unfocused = u.window.GetAttrib(glfw.Focused) == glfw.False
}
var t1, t2 time.Time
if unfocused {
t1 = time.Now()
}
if err := u.update(context); err != nil {
return err
}
_ = u.t.Call(func() error {
u.swapBuffers()
return nil
})
if unfocused {
t2 = time.Now()
}
// When a window is not focused, SwapBuffers might return immediately and CPU might be busy.
// Mitigate this by sleeping (#982).
if unfocused {
d := t2.Sub(t1)
const wait = time.Second / 60
if d < wait {
time.Sleep(wait - d)
}
}
}
}
// swapBuffers must be called from the main thread.
func (u *UserInterface) swapBuffers() {
if u.graphics.IsGL() {
u.window.SwapBuffers()
}
}
func (u *UserInterface) setWindowSize(width, height int, fullscreen bool, vsync bool) {
windowRecreated := false
_ = u.t.Call(func() error {
if u.windowWidth == width && u.windowHeight == height && u.isFullscreen() == fullscreen && u.vsync == vsync && u.lastDeviceScaleFactor == u.deviceScaleFactor() {
return nil
}
if width < 1 {
width = 1
}
if height < 1 {
height = 1
}
u.vsync = vsync
u.lastDeviceScaleFactor = u.deviceScaleFactor()
// To make sure the current existing framebuffers are rendered,
// swap buffers here before SetSize is called.
u.swapBuffers()
if fullscreen {
if u.origPosX == invalidPos || u.origPosY == invalidPos {
u.origPosX, u.origPosY = u.window.GetPos()
}
m := u.currentMonitor()
v := m.GetVideoMode()
u.window.SetMonitor(m, 0, 0, v.Width, v.Height, v.RefreshRate)
// Swapping buffer is necesary to prevent the image lag (#1004).
// TODO: This might not work when vsync is disabled.
if u.graphics.IsGL() {
glfw.PollEvents()
u.swapBuffers()
}
} else {
if u.window.GetMonitor() != nil {
if u.graphics.IsGL() {
// When OpenGL is used, swapping buffer is enough to solve the image-lag
// issue (#1004). Rather, recreating window destroys GPU resources.
// TODO: This might not work when vsync is disabled.
u.window.SetMonitor(nil, 0, 0, 16, 16, 0)
glfw.PollEvents()
u.swapBuffers()
} else {
// Recreate the window since an image lag remains after coming back from
// fullscreen (#1004).
if u.window != nil {
u.window.Destroy()
u.window = nil
}
if err := u.createWindow(); err != nil {
// TODO: This should return an error.
panic(fmt.Sprintf("glfw: failed to recreate window: %v", err))
}
u.window.Show()
windowRecreated = true
}
}
// On Windows, giving a too small width doesn't call a callback (#165).
// To prevent hanging up, return asap if the width is too small.
// 126 is an arbitrary number and I guess this is small enough.
minWindowWidth := int(u.toDeviceDependentPixel(126))
if u.window.GetAttrib(glfw.Decorated) == glfw.False {
minWindowWidth = 1
}
if width < minWindowWidth {
width = minWindowWidth
}
if u.origPosX != invalidPos && u.origPosY != invalidPos {
x := u.origPosX
y := u.origPosY
u.window.SetPos(x, y)
// Dirty hack for macOS (#703). Rendering doesn't work correctly with one SetPos, but
// work with two or more SetPos.
if runtime.GOOS == "darwin" {
u.window.SetPos(x+1, y)
u.window.SetPos(x, y)
}
u.origPosX = invalidPos
u.origPosY = invalidPos
}
// Set the window size after the position. The order matters.
// In the opposite order, the window size might not be correct when going back from fullscreen with multi monitors.
oldW, oldH := u.window.GetSize()
newW := width
newH := height
if oldW != newW || oldH != newH {
ch := make(chan struct{})
u.window.SetFramebufferSizeCallback(func(_ *glfw.Window, _, _ int) {
u.window.SetFramebufferSizeCallback(nil)
close(ch)
})
u.window.SetSize(newW, newH)
event:
for {
glfw.PollEvents()
select {
case <-ch:
break event
default:
}
}
}
// Window title might be lost on macOS after coming back from fullscreen.
u.window.SetTitle(u.title)
}
// As width might be updated, update windowWidth/Height here.
u.windowWidth = width
u.windowHeight = height
if u.graphics.IsGL() {
// SwapInterval is affected by the current monitor of the window.
// This needs to be called at least after SetMonitor.
// Without SwapInterval after SetMonitor, vsynch doesn't work (#375).
//
// TODO: (#405) If triple buffering is needed, SwapInterval(0) should be called,
// but is this correct? If glfw.SwapInterval(0) and the driver doesn't support triple
// buffering, what will happen?
if u.vsync {
glfw.SwapInterval(1)
} else {
glfw.SwapInterval(0)
}
}
u.graphics.SetVsyncEnabled(vsync)
u.toChangeSize = true
return nil
})
if windowRecreated {
u.graphics.SetWindow(u.nativeWindow())
}
}
// currentMonitor returns the monitor most suitable with the current window.
//
// currentMonitor must be called on the main thread.
func (u *UserInterface) currentMonitor() *glfw.Monitor {
if w := u.window; w != nil {
// TODO: When is the monitor nil?
if m := w.GetMonitor(); m != nil {
return m
}
}
// Get the monitor which the current window belongs to. This requires OS API.
return u.currentMonitorFromPosition()
}
func (u *UserInterface) SetScreenTransparent(transparent bool) {
if !u.isRunning() {
u.setInitScreenTransparent(transparent)
return
}
panic("glfw: SetScreenTransparent can't be called after the main loop starts")
}
func (u *UserInterface) IsScreenTransparent() bool {
if !u.isRunning() {
return u.isInitScreenTransparent()
}
val := false
_ = u.t.Call(func() error {
val = u.window.GetAttrib(glfw.TransparentFramebuffer) == glfw.True
return nil
})
return val
}
func (u *UserInterface) MonitorPosition() (int, int) {
if !u.isRunning() {
return u.monitorPosition()
}
var mx, my int
_ = u.t.Call(func() error {
mx, my = u.monitorPosition()
return nil
})
return mx, my
}
func (u *UserInterface) monitorPosition() (int, int) {
// TODO: toDeviceIndependentPixel might be required.
return u.currentMonitor().GetPos()
}
func (u *UserInterface) Input() driver.Input {
return &u.input
}
func (u *UserInterface) Window() driver.Window {
return &u.iwindow
}