tenfourfox/widget/cocoa/nsCocoaUtils.mm
2018-04-26 18:20:39 -07:00

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/* -*- Mode: C++; tab-width: 20; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
#include <cmath>
#include "gfx2DGlue.h"
#include "gfxPlatform.h"
#include "gfxUtils.h"
#include "ImageRegion.h"
#include "nsCocoaUtils.h"
#include "nsChildView.h"
#include "nsMenuBarX.h"
#include "nsCocoaWindow.h"
#include "nsCOMPtr.h"
#include "nsIInterfaceRequestorUtils.h"
#include "nsIAppShellService.h"
#include "nsIXULWindow.h"
#include "nsIBaseWindow.h"
#include "nsIServiceManager.h"
#include "nsMenuUtilsX.h"
#include "nsToolkit.h"
#include "nsCRT.h"
#include "SVGImageContext.h"
#include "mozilla/gfx/2D.h"
#include "mozilla/MiscEvents.h"
#include "mozilla/Preferences.h"
#include "mozilla/TextEvents.h"
using namespace mozilla;
using namespace mozilla::widget;
using mozilla::gfx::BackendType;
using mozilla::gfx::DataSourceSurface;
using mozilla::gfx::DrawTarget;
using mozilla::gfx::Factory;
using mozilla::gfx::Filter;
using mozilla::gfx::IntPoint;
using mozilla::gfx::IntRect;
using mozilla::gfx::IntSize;
using mozilla::gfx::SurfaceFormat;
using mozilla::gfx::SourceSurface;
using mozilla::image::ImageRegion;
using std::ceil;
static float
MenuBarScreenHeight()
{
NS_OBJC_BEGIN_TRY_ABORT_BLOCK_RETURN;
NSArray* allScreens = [NSScreen screens];
if ([allScreens count]) {
return [[allScreens objectAtIndex:0] frame].size.height;
}
return 0.0;
NS_OBJC_END_TRY_ABORT_BLOCK_RETURN(0.0);
}
float
nsCocoaUtils::FlippedScreenY(float y)
{
return MenuBarScreenHeight() - y;
}
NSRect nsCocoaUtils::GeckoRectToCocoaRect(const nsIntRect &geckoRect)
{
// We only need to change the Y coordinate by starting with the primary screen
// height and subtracting the gecko Y coordinate of the bottom of the rect.
return NSMakeRect(geckoRect.x,
MenuBarScreenHeight() - geckoRect.YMost(),
geckoRect.width,
geckoRect.height);
}
NSRect nsCocoaUtils::GeckoRectToCocoaRectDevPix(const nsIntRect &aGeckoRect)
{
return NSMakeRect(aGeckoRect.x,
MenuBarScreenHeight() - aGeckoRect.YMost(),
aGeckoRect.width,
aGeckoRect.height);
}
nsIntRect nsCocoaUtils::CocoaRectToGeckoRect(const NSRect &cocoaRect)
{
// We only need to change the Y coordinate by starting with the primary screen
// height and subtracting both the cocoa y origin and the height of the
// cocoa rect.
nsIntRect rect;
rect.x = NSToIntRound(cocoaRect.origin.x);
rect.y = NSToIntRound(FlippedScreenY(cocoaRect.origin.y + cocoaRect.size.height));
rect.width = NSToIntRound(cocoaRect.origin.x + cocoaRect.size.width) - rect.x;
rect.height = NSToIntRound(FlippedScreenY(cocoaRect.origin.y)) - rect.y;
return rect;
}
LayoutDeviceIntRect nsCocoaUtils::CocoaRectToGeckoRectDevPix(
const NSRect& aCocoaRect)
{
LayoutDeviceIntRect rect;
rect.x = NSToIntRound(aCocoaRect.origin.x);
rect.y = NSToIntRound(FlippedScreenY(aCocoaRect.origin.y + aCocoaRect.size.height));
rect.width = NSToIntRound((aCocoaRect.origin.x + aCocoaRect.size.width)) - rect.x;
rect.height = NSToIntRound(FlippedScreenY(aCocoaRect.origin.y)) - rect.y;
return rect;
}
NSPoint nsCocoaUtils::ScreenLocationForEvent(NSEvent* anEvent)
{
NS_OBJC_BEGIN_TRY_ABORT_BLOCK_RETURN;
// Don't trust mouse locations of mouse move events, see bug 443178.
if (!anEvent || [anEvent type] == NSMouseMoved)
return [NSEvent mouseLocation];
// Pin momentum scroll events to the location of the last user-controlled
// scroll event.
if (IsMomentumScrollEvent(anEvent))
return ChildViewMouseTracker::sLastScrollEventScreenLocation;
return [[anEvent window] convertBaseToScreen:[anEvent locationInWindow]];
NS_OBJC_END_TRY_ABORT_BLOCK_RETURN(NSMakePoint(0.0, 0.0));
}
BOOL nsCocoaUtils::IsEventOverWindow(NSEvent* anEvent, NSWindow* aWindow)
{
NS_OBJC_BEGIN_TRY_ABORT_BLOCK_RETURN;
return NSPointInRect(ScreenLocationForEvent(anEvent), [aWindow frame]);
NS_OBJC_END_TRY_ABORT_BLOCK_RETURN(NO);
}
NSPoint nsCocoaUtils::EventLocationForWindow(NSEvent* anEvent, NSWindow* aWindow)
{
NS_OBJC_BEGIN_TRY_ABORT_BLOCK_RETURN;
return [aWindow convertScreenToBase:ScreenLocationForEvent(anEvent)];
NS_OBJC_END_TRY_ABORT_BLOCK_RETURN(NSMakePoint(0.0, 0.0));
}
@interface NSEvent (ScrollPhase)
// 10.5 and 10.6
- (long long)_scrollPhase;
// 10.7 and above
- (NSEventPhase)phase;
- (NSEventPhase)momentumPhase;
@end
NSEventPhase nsCocoaUtils::EventPhase(NSEvent* aEvent)
{
if ([aEvent respondsToSelector:@selector(phase)]) {
return [aEvent phase];
}
return NSEventPhaseNone;
}
NSEventPhase nsCocoaUtils::EventMomentumPhase(NSEvent* aEvent)
{
if ([aEvent respondsToSelector:@selector(momentumPhase)]) {
return [aEvent momentumPhase];
}
if ([aEvent respondsToSelector:@selector(_scrollPhase)]) {
switch ([aEvent _scrollPhase]) {
case 1: return NSEventPhaseBegan;
case 2: return NSEventPhaseChanged;
case 3: return NSEventPhaseEnded;
default: return NSEventPhaseNone;
}
}
return NSEventPhaseNone;
}
BOOL nsCocoaUtils::IsMomentumScrollEvent(NSEvent* aEvent)
{
return [aEvent type] == NSScrollWheel &&
EventMomentumPhase(aEvent) != NSEventPhaseNone;
}
@interface NSEvent (HasPreciseScrollingDeltas)
// 10.7 and above
- (BOOL)hasPreciseScrollingDeltas;
// For 10.6 and below, see the comment in nsChildView.h about _eventRef
- (EventRef)_eventRef;
@end
BOOL nsCocoaUtils::HasPreciseScrollingDeltas(NSEvent* aEvent)
{
if ([aEvent respondsToSelector:@selector(hasPreciseScrollingDeltas)]) {
return [aEvent hasPreciseScrollingDeltas];
}
// For events that don't contain pixel scrolling information, the event
// kind of their underlaying carbon event is kEventMouseWheelMoved instead
// of kEventMouseScroll.
EventRef carbonEvent = [aEvent _eventRef];
return carbonEvent && ::GetEventKind(carbonEvent) == 11; //10.4/5 kEventMouseScroll;
}
@interface NSEvent (ScrollingDeltas)
// 10.6 and below
- (CGFloat)deviceDeltaX;
- (CGFloat)deviceDeltaY;
// 10.7 and above
- (CGFloat)scrollingDeltaX;
- (CGFloat)scrollingDeltaY;
@end
void nsCocoaUtils::GetScrollingDeltas(NSEvent* aEvent, CGFloat* aOutDeltaX, CGFloat* aOutDeltaY)
{
if ([aEvent respondsToSelector:@selector(scrollingDeltaX)]) {
*aOutDeltaX = [aEvent scrollingDeltaX];
*aOutDeltaY = [aEvent scrollingDeltaY];
return;
}
if ([aEvent respondsToSelector:@selector(deviceDeltaX)] &&
HasPreciseScrollingDeltas(aEvent)) {
// Calling deviceDeltaX/Y on those events that do not contain pixel
// scrolling information triggers a Cocoa assertion and an
// Objective-C NSInternalInconsistencyException.
*aOutDeltaX = [aEvent deviceDeltaX];
*aOutDeltaY = [aEvent deviceDeltaY];
return;
}
// This is only hit pre-10.7 when we are called on a scroll event that does
// not contain pixel scrolling information.
CGFloat lineDeltaPixels = 12;
*aOutDeltaX = [aEvent deltaX] * lineDeltaPixels;
*aOutDeltaY = [aEvent deltaY] * lineDeltaPixels;
}
BOOL nsCocoaUtils::EventHasPhaseInformation(NSEvent* aEvent)
{
if (![aEvent respondsToSelector:@selector(phase)]) {
return NO;
}
return EventPhase(aEvent) != NSEventPhaseNone ||
EventMomentumPhase(aEvent) != NSEventPhaseNone;
}
void nsCocoaUtils::HideOSChromeOnScreen(bool aShouldHide, NSScreen* aScreen)
{
NS_OBJC_BEGIN_TRY_ABORT_BLOCK;
// Keep track of how many hiding requests have been made, so that they can
// be nested.
static int sHiddenCount = 0;
sHiddenCount += aShouldHide ? 1 : -1;
NS_ASSERTION(sHiddenCount >= 0, "Unbalanced HideMenuAndDockForWindow calls");
// Not on 10.4.
// Restore the 38 code, since we don't have NSApplicationPresentationOptions
// (and the NSScreen* pointer so that we know which screen the window's on).
#if(0)
NSApplicationPresentationOptions options =
sHiddenCount <= 0 ? NSApplicationPresentationDefault :
NSApplicationPresentationHideDock | NSApplicationPresentationHideMenuBar;
[NSApp setPresentationOptions:options];
#else
static int sMenuBarHiddenCount = 0;
// Although we always hide the Dock, since it may or may not be on the
// primary screen, we should only hide the menu bar if it's on the
// same screen as the window. (XXX: Perhaps this is wrong? See issue 97.)
// The menu bar is always on the first screen in the screen list.
if (aScreen == [[NSScreen screens] objectAtIndex:0]) {
sMenuBarHiddenCount += aShouldHide ? 1 : -1;
}
if (sMenuBarHiddenCount > 0) {
::SetSystemUIMode(kUIModeAllHidden, 0);
} else if (sHiddenCount > 0) {
::SetSystemUIMode(kUIModeContentHidden, 0);
} else {
::SetSystemUIMode(kUIModeNormal, 0);
}
#endif
NS_OBJC_END_TRY_ABORT_BLOCK;
}
#define NS_APPSHELLSERVICE_CONTRACTID "@mozilla.org/appshell/appShellService;1"
nsIWidget* nsCocoaUtils::GetHiddenWindowWidget()
{
nsCOMPtr<nsIAppShellService> appShell(do_GetService(NS_APPSHELLSERVICE_CONTRACTID));
if (!appShell) {
NS_WARNING("Couldn't get AppShellService in order to get hidden window ref");
return nullptr;
}
nsCOMPtr<nsIXULWindow> hiddenWindow;
appShell->GetHiddenWindow(getter_AddRefs(hiddenWindow));
if (!hiddenWindow) {
// Don't warn, this happens during shutdown, bug 358607.
return nullptr;
}
nsCOMPtr<nsIBaseWindow> baseHiddenWindow;
baseHiddenWindow = do_GetInterface(hiddenWindow);
if (!baseHiddenWindow) {
NS_WARNING("Couldn't get nsIBaseWindow from hidden window (nsIXULWindow)");
return nullptr;
}
nsCOMPtr<nsIWidget> hiddenWindowWidget;
if (NS_FAILED(baseHiddenWindow->GetMainWidget(getter_AddRefs(hiddenWindowWidget)))) {
NS_WARNING("Couldn't get nsIWidget from hidden window (nsIBaseWindow)");
return nullptr;
}
return hiddenWindowWidget;
}
void nsCocoaUtils::PrepareForNativeAppModalDialog()
{
NS_OBJC_BEGIN_TRY_ABORT_BLOCK;
// Don't do anything if this is embedding. We'll assume that if there is no hidden
// window we shouldn't do anything, and that should cover the embedding case.
nsMenuBarX* hiddenWindowMenuBar = nsMenuUtilsX::GetHiddenWindowMenuBar();
if (!hiddenWindowMenuBar)
return;
// First put up the hidden window menu bar so that app menu event handling is correct.
hiddenWindowMenuBar->Paint();
NSMenu* mainMenu = [NSApp mainMenu];
NS_ASSERTION([mainMenu numberOfItems] > 0, "Main menu does not have any items, something is terribly wrong!");
// Create new menu bar for use with modal dialog
NSMenu* newMenuBar = [[NSMenu alloc] initWithTitle:@""];
// Swap in our app menu. Note that the event target is whatever window is up when
// the app modal dialog goes up.
NSMenuItem* firstMenuItem = [[mainMenu itemAtIndex:0] retain];
[mainMenu removeItemAtIndex:0];
[newMenuBar insertItem:firstMenuItem atIndex:0];
[firstMenuItem release];
// Add standard edit menu
[newMenuBar addItem:nsMenuUtilsX::GetStandardEditMenuItem()];
// Show the new menu bar
[NSApp setMainMenu:newMenuBar];
[newMenuBar release];
NS_OBJC_END_TRY_ABORT_BLOCK;
}
void nsCocoaUtils::CleanUpAfterNativeAppModalDialog()
{
NS_OBJC_BEGIN_TRY_ABORT_BLOCK;
// Don't do anything if this is embedding. We'll assume that if there is no hidden
// window we shouldn't do anything, and that should cover the embedding case.
nsMenuBarX* hiddenWindowMenuBar = nsMenuUtilsX::GetHiddenWindowMenuBar();
if (!hiddenWindowMenuBar)
return;
NSWindow* mainWindow = [NSApp mainWindow];
if (!mainWindow)
hiddenWindowMenuBar->Paint();
else
[WindowDelegate paintMenubarForWindow:mainWindow];
NS_OBJC_END_TRY_ABORT_BLOCK;
}
unsigned short nsCocoaUtils::GetCocoaEventKeyCode(NSEvent *theEvent)
{
#if(0)
unsigned short keyCode = [theEvent keyCode];
if (nsCocoaFeatures::OnLeopardOrLater())
return keyCode;
NSEventType type = [theEvent type];
// GetCocoaEventKeyCode() can get called with theEvent set to a FlagsChanged
// event, which triggers an NSInternalInconsistencyException when
// charactersIgnoringModifiers is called on it. For some reason there's no
// problem calling keyCode on it (as we do above).
if ((type != NSKeyDown) && (type != NSKeyUp))
return keyCode;
NSString *unmodchars = [theEvent charactersIgnoringModifiers];
if (!keyCode && ([unmodchars length] == 1)) {
// An OS-X-10.4.X-specific Apple bug causes the 'theEvent' parameter of
// all calls to performKeyEquivalent: (whether on NSMenu, NSWindow or
// NSView objects) to have most of its fields zeroed on a ctrl-ESC event.
// These include its keyCode and modifierFlags fields, but fortunately
// not its characters and charactersIgnoringModifiers fields. So if
// charactersIgnoringModifiers has length == 1 and corresponds to the ESC
// character (0x1b), we correct keyCode to 0x35 (kEscapeKeyCode).
if ([unmodchars characterAtIndex:0] == 0x1b)
keyCode = 0x35;
}
#else
// Clean this up a bit for faster calls.
unsigned short keyCode = [theEvent keyCode];
// If there is a keyCode (likely), or this is Leopard, return keyCode.
if (MOZ_LIKELY(keyCode) || nsCocoaFeatures::OnLeopardOrLater())
return keyCode;
// Tiger kludge from above.
// If the type is not NSKeyDown or KeyUp (unlikely), return keyCode.
NSEventType type = [theEvent type];
if (MOZ_UNLIKELY((type != NSKeyDown) && (type != NSKeyUp)))
return keyCode;
NSString *unmodchars = [theEvent charactersIgnoringModifiers];
if ([unmodchars length] == 1) {
if ([unmodchars characterAtIndex:0] == 0x1b)
keyCode = 0x35;
}
#endif
return keyCode;
}
NSUInteger nsCocoaUtils::GetCocoaEventModifierFlags(NSEvent *theEvent)
{
NSUInteger modifierFlags = [theEvent modifierFlags];
if (nsCocoaFeatures::OnLeopardOrLater())
return modifierFlags;
NSEventType type = [theEvent type];
if ((type != NSKeyDown) && (type != NSKeyUp))
return modifierFlags;
NSString *unmodchars = [theEvent charactersIgnoringModifiers];
if (!modifierFlags && ([unmodchars length] == 1)) {
// An OS-X-10.4.X-specific Apple bug causes the 'theEvent' parameter of
// all calls to performKeyEquivalent: (whether on NSMenu, NSWindow or
// NSView objects) to have most of its fields zeroed on a ctrl-ESC event.
// These include its keyCode and modifierFlags fields, but fortunately
// not its characters and charactersIgnoringModifiers fields. So if
// charactersIgnoringModifiers has length == 1 and corresponds to the ESC
// character (0x1b), we correct modifierFlags to NSControlKeyMask. (ESC
// key events don't get messed up (anywhere they're sent) on opt-ESC,
// shift-ESC or cmd-ESC.)
if ([unmodchars characterAtIndex:0] == 0x1b)
modifierFlags = NSControlKeyMask;
}
return modifierFlags;
}
void data_ss_release_callback(void *aDataSourceSurface,
const void *data,
size_t size)
{
if (aDataSourceSurface) {
static_cast<DataSourceSurface*>(aDataSourceSurface)->Unmap();
static_cast<DataSourceSurface*>(aDataSourceSurface)->Release();
}
}
nsresult nsCocoaUtils::CreateCGImageFromSurface(SourceSurface* aSurface,
CGImageRef* aResult)
{
RefPtr<DataSourceSurface> dataSurface;
if (aSurface->GetFormat() == SurfaceFormat::B8G8R8A8) {
dataSurface = aSurface->GetDataSurface();
} else {
// CGImageCreate only supports 16- and 32-bit bit-depth
// Convert format to SurfaceFormat::B8G8R8A8
dataSurface = gfxUtils::
CopySurfaceToDataSourceSurfaceWithFormat(aSurface,
SurfaceFormat::B8G8R8A8);
}
NS_ENSURE_TRUE(dataSurface, NS_ERROR_FAILURE);
int32_t width = dataSurface->GetSize().width;
int32_t height = dataSurface->GetSize().height;
if (height < 1 || width < 1) {
return NS_ERROR_FAILURE;
}
DataSourceSurface::MappedSurface map;
if (!dataSurface->Map(DataSourceSurface::MapType::READ, &map)) {
return NS_ERROR_FAILURE;
}
// The Unmap() call happens in data_ss_release_callback
// Create a CGImageRef with the bits from the image, taking into account
// the alpha ordering and endianness of the machine so we don't have to
// touch the bits ourselves.
CGDataProviderRef dataProvider = ::CGDataProviderCreateWithData(dataSurface.forget().take(),
map.mData,
map.mStride * height,
data_ss_release_callback);
CGColorSpaceRef colorSpace = ::CGColorSpaceCreateWithName(kCGColorSpaceGenericRGB);
*aResult = ::CGImageCreate(width,
height,
8,
32,
map.mStride,
colorSpace,
kCGBitmapByteOrder32Host | kCGImageAlphaPremultipliedFirst,
dataProvider,
NULL,
0,
kCGRenderingIntentDefault);
::CGColorSpaceRelease(colorSpace);
::CGDataProviderRelease(dataProvider);
return *aResult ? NS_OK : NS_ERROR_FAILURE;
}
nsresult nsCocoaUtils::CreateNSImageFromCGImage(CGImageRef aInputImage, NSImage **aResult)
{
NS_OBJC_BEGIN_TRY_ABORT_BLOCK_NSRESULT;
#if(0)
// Be very careful when creating the NSImage that the backing NSImageRep is
// exactly 1:1 with the input image. On a retina display, both [NSImage
// lockFocus] and [NSImage initWithCGImage:size:] will create an image with a
// 2x backing NSImageRep. This prevents NSCursor from recognizing a retina
// cursor, which only occurs if pixelsWide and pixelsHigh are exactly 2x the
// size of the NSImage.
//
// For example, if a 32x32 SVG cursor is rendered on a retina display, then
// aInputImage will be 64x64. The resulting NSImage will be scaled back down
// to 32x32 so it stays the correct size on the screen by changing its size
// (resizing a NSImage only scales the image and doesn't resample the data).
// If aInputImage is converted using [NSImage initWithCGImage:size:] then the
// bitmap will be 128x128 and NSCursor won't recognize a retina cursor, since
// it will expect a 64x64 bitmap.
int32_t width = ::CGImageGetWidth(aInputImage);
int32_t height = ::CGImageGetHeight(aInputImage);
NSRect imageRect = ::NSMakeRect(0.0, 0.0, width, height);
NSBitmapImageRep *offscreenRep = [[NSBitmapImageRep alloc]
initWithBitmapDataPlanes:NULL
pixelsWide:width
pixelsHigh:height
bitsPerSample:8
samplesPerPixel:4
hasAlpha:YES
isPlanar:NO
colorSpaceName:NSDeviceRGBColorSpace
bitmapFormat:NSAlphaFirstBitmapFormat
bytesPerRow:0
bitsPerPixel:0];
NSGraphicsContext *context = [NSGraphicsContext graphicsContextWithBitmapImageRep:offscreenRep];
[NSGraphicsContext saveGraphicsState];
[NSGraphicsContext setCurrentContext:context];
// Get the Quartz context and draw.
CGContextRef imageContext = (CGContextRef)[[NSGraphicsContext currentContext] graphicsPort];
::CGContextDrawImage(imageContext, *(CGRect*)&imageRect, aInputImage);
[NSGraphicsContext restoreGraphicsState];
*aResult = [[NSImage alloc] initWithSize:NSMakeSize(width, height)];
[*aResult addRepresentation:offscreenRep];
[offscreenRep release];
return NS_OK;
#else
// The code above generates mangled icons on 10.4 and 10.5, so restore the
// Firefox 26 code (backout bug 888689).
int32_t width = ::CGImageGetWidth(aInputImage);
int32_t height = ::CGImageGetHeight(aInputImage);
NSRect imageRect = ::NSMakeRect(0.0, 0.0, width, height);
// Create a new image to receive the Quartz image data.
*aResult = [[NSImage alloc] initWithSize:imageRect.size];
[*aResult lockFocus];
// Get the Quartz context and draw.
CGContextRef imageContext = (CGContextRef)[[NSGraphicsContext currentContext] graphicsPort];
::CGContextDrawImage(imageContext, *(CGRect*)&imageRect, aInputImage);
[*aResult unlockFocus];
return NS_OK;
#endif
NS_OBJC_END_TRY_ABORT_BLOCK_NSRESULT;
}
nsresult nsCocoaUtils::CreateNSImageFromImageContainer(imgIContainer *aImage, uint32_t aWhichFrame, NSImage **aResult)
{
RefPtr<SourceSurface> surface;
int32_t width = 0, height = 0;
aImage->GetWidth(&width);
aImage->GetHeight(&height);
#if(0)
// Render a vector image at the correct resolution on a retina display
if (aImage->GetType() == imgIContainer::TYPE_VECTOR && scaleFactor != 1.0f) {
IntSize scaledSize(ceil(width * scaleFactor), ceil(height * scaleFactor));
RefPtr<DrawTarget> drawTarget = gfxPlatform::GetPlatform()->
CreateOffscreenContentDrawTarget(scaledSize, SurfaceFormat::B8G8R8A8);
if (!drawTarget) {
NS_ERROR("Failed to create DrawTarget");
return NS_ERROR_FAILURE;
}
RefPtr<gfxContext> context = new gfxContext(drawTarget);
if (!context) {
NS_ERROR("Failed to create gfxContext");
return NS_ERROR_FAILURE;
}
aImage->Draw(context, scaledSize, ImageRegion::Create(scaledSize),
aWhichFrame, Filter::POINT, Nothing(),
imgIContainer::FLAG_SYNC_DECODE);
surface = drawTarget->Snapshot();
} else {
surface = aImage->GetFrame(aWhichFrame, imgIContainer::FLAG_SYNC_DECODE);
}
#else
surface = aImage->GetFrame(aWhichFrame, imgIContainer::FLAG_SYNC_DECODE);
#endif
NS_ENSURE_TRUE(surface, NS_ERROR_FAILURE);
CGImageRef imageRef = NULL;
nsresult rv = nsCocoaUtils::CreateCGImageFromSurface(surface, &imageRef);
if (NS_FAILED(rv) || !imageRef) {
return NS_ERROR_FAILURE;
}
rv = nsCocoaUtils::CreateNSImageFromCGImage(imageRef, aResult);
if (NS_FAILED(rv) || !aResult) {
return NS_ERROR_FAILURE;
}
::CGImageRelease(imageRef);
// Ensure the image will be rendered the correct size on a retina display
NSSize size = NSMakeSize(width, height);
[*aResult setSize:size];
[[[*aResult representations] objectAtIndex:0] setSize:size];
return NS_OK;
}
// static
void
nsCocoaUtils::GetStringForNSString(const NSString *aSrc, nsAString& aDist)
{
NS_OBJC_BEGIN_TRY_ABORT_BLOCK;
if (!aSrc) {
aDist.Truncate();
return;
}
aDist.SetLength([aSrc length]);
[aSrc getCharacters: reinterpret_cast<unichar*>(aDist.BeginWriting())];
NS_OBJC_END_TRY_ABORT_BLOCK;
}
// static
NSString*
nsCocoaUtils::ToNSString(const nsAString& aString)
{
if (aString.IsEmpty()) {
return [NSString string];
}
return [NSString stringWithCharacters:reinterpret_cast<const unichar*>(aString.BeginReading())
length:aString.Length()];
}
// static
void
nsCocoaUtils::GeckoRectToNSRect(const nsIntRect& aGeckoRect,
NSRect& aOutCocoaRect)
{
aOutCocoaRect.origin.x = aGeckoRect.x;
aOutCocoaRect.origin.y = aGeckoRect.y;
aOutCocoaRect.size.width = aGeckoRect.width;
aOutCocoaRect.size.height = aGeckoRect.height;
}
// static
void
nsCocoaUtils::NSRectToGeckoRect(const NSRect& aCocoaRect,
nsIntRect& aOutGeckoRect)
{
aOutGeckoRect.x = NSToIntRound(aCocoaRect.origin.x);
aOutGeckoRect.y = NSToIntRound(aCocoaRect.origin.y);
aOutGeckoRect.width = NSToIntRound(aCocoaRect.origin.x + aCocoaRect.size.width) - aOutGeckoRect.x;
aOutGeckoRect.height = NSToIntRound(aCocoaRect.origin.y + aCocoaRect.size.height) - aOutGeckoRect.y;
}
// static
NSEvent*
nsCocoaUtils::MakeNewCocoaEventWithType(NSEventType aEventType, NSEvent *aEvent)
{
NS_OBJC_BEGIN_TRY_ABORT_BLOCK_NIL;
NSEvent* newEvent =
[NSEvent keyEventWithType:aEventType
location:[aEvent locationInWindow]
#ifdef NS_LEOPARD_AND_LATER
modifierFlags:[aEvent modifierFlags]
#else
modifierFlags: nsCocoaUtils::GetCocoaEventModifierFlags(aEvent)
#endif
timestamp:[aEvent timestamp]
windowNumber:[aEvent windowNumber]
context:[aEvent context]
characters:[aEvent characters]
charactersIgnoringModifiers:[aEvent charactersIgnoringModifiers]
isARepeat:[aEvent isARepeat]
keyCode:[aEvent keyCode]];
return newEvent;
NS_OBJC_END_TRY_ABORT_BLOCK_NIL;
}
// static
void
nsCocoaUtils::InitNPCocoaEvent(NPCocoaEvent* aNPCocoaEvent)
{
memset(aNPCocoaEvent, 0, sizeof(NPCocoaEvent));
}
// static
void
nsCocoaUtils::InitInputEvent(WidgetInputEvent& aInputEvent,
NSEvent* aNativeEvent)
{
NS_OBJC_BEGIN_TRY_ABORT_BLOCK;
aInputEvent.modifiers = ModifiersForEvent(aNativeEvent);
aInputEvent.time = PR_IntervalNow();
NS_OBJC_END_TRY_ABORT_BLOCK;
}
// static
Modifiers
nsCocoaUtils::ModifiersForEvent(NSEvent* aNativeEvent)
{
NSUInteger modifiers =
#if(0)
aNativeEvent ? [aNativeEvent modifierFlags] : [NSEvent modifierFlags];
#else
aNativeEvent ? nsCocoaUtils::GetCocoaEventModifierFlags(aNativeEvent) :
nsCocoaFeatures::OnSnowLeopardOrLater() ? [NSEvent modifierFlags] :
0;
#endif
Modifiers result = 0;
// Account for Carbon events here too. (See bug 801601.)
// XXX: Do we need to always do this, or only if this is a non-native event?
UInt32 carbonModifiers = ::GetCurrentKeyModifiers();
if (carbonModifiers & alphaLock)
result |= MODIFIER_CAPSLOCK;
if (carbonModifiers & (controlKey | rightControlKey))
result |= MODIFIER_CONTROL;
if (carbonModifiers & (optionKey | rightOptionKey))
result |= MODIFIER_ALT | MODIFIER_ALTGRAPH;
if (carbonModifiers & (shiftKey | rightShiftKey))
result |= MODIFIER_SHIFT;
if (carbonModifiers & cmdKey)
result |= MODIFIER_META;
// XXX MODIFIER_NUMLOCK
if (modifiers & NSShiftKeyMask) {
result |= MODIFIER_SHIFT;
}
if (modifiers & NSControlKeyMask) {
result |= MODIFIER_CONTROL;
}
if (modifiers & NSAlternateKeyMask) {
result |= MODIFIER_ALT;
// Mac's option key is similar to other platforms' AltGr key.
// Let's set AltGr flag when option key is pressed for consistency with
// other platforms.
result |= MODIFIER_ALTGRAPH;
}
if (modifiers & NSCommandKeyMask) {
result |= MODIFIER_META;
}
if (modifiers & NSAlphaShiftKeyMask) {
result |= MODIFIER_CAPSLOCK;
}
// Mac doesn't have NumLock key. We can assume that NumLock is always locked
// if user is using a keyboard which has numpad. Otherwise, if user is using
// a keyboard which doesn't have numpad, e.g., MacBook's keyboard, we can
// assume that NumLock is always unlocked.
// Unfortunately, we cannot know whether current keyboard has numpad or not.
// We should notify locked state only when keys in numpad are pressed.
// By this, web applications may not be confused by unexpected numpad key's
// key event with unlocked state.
if (modifiers & NSNumericPadKeyMask) {
result |= MODIFIER_NUMLOCK;
}
// Be aware, NSFunctionKeyMask is included when arrow keys, home key or some
// other keys are pressed. We cannot check whether 'fn' key is pressed or
// not by the flag.
return result;
}
// static
UInt32
nsCocoaUtils::ConvertToCarbonModifier(NSUInteger aCocoaModifier)
{
UInt32 carbonModifier = 0;
if (aCocoaModifier & NSAlphaShiftKeyMask) {
carbonModifier |= alphaLock;
}
if (aCocoaModifier & NSControlKeyMask) {
carbonModifier |= controlKey;
}
if (aCocoaModifier & NSAlternateKeyMask) {
carbonModifier |= optionKey;
}
if (aCocoaModifier & NSShiftKeyMask) {
carbonModifier |= shiftKey;
}
if (aCocoaModifier & NSCommandKeyMask) {
carbonModifier |= cmdKey;
}
if (aCocoaModifier & NSNumericPadKeyMask) {
carbonModifier |= kEventKeyModifierNumLockMask;
}
if (aCocoaModifier & NSFunctionKeyMask) {
carbonModifier |= kEventKeyModifierFnMask;
}
return carbonModifier;
}
// While HiDPI support is not 100% complete and tested, we'll have a pref
// to allow it to be turned off in case of problems (or for testing purposes).
// gfx.hidpi.enabled is an integer with the meaning:
// <= 0 : HiDPI support is disabled
// 1 : HiDPI enabled provided all screens have the same backing resolution
// > 1 : HiDPI enabled even if there are a mixture of screen modes
// All the following code is to be removed once HiDPI work is more complete.
static bool sHiDPIEnabled = false;
static bool sHiDPIPrefInitialized = false;
// static
bool
nsCocoaUtils::HiDPIEnabled()
{
#if(0)
if (!sHiDPIPrefInitialized) {
sHiDPIPrefInitialized = true;
int prefSetting = Preferences::GetInt("gfx.hidpi.enabled", 1);
if (prefSetting <= 0) {
return false;
}
// prefSetting is at least 1, need to check attached screens...
int scaleFactors = 0; // used as a bitset to track the screen types found
NSEnumerator *screenEnum = [[NSScreen screens] objectEnumerator];
while (NSScreen *screen = [screenEnum nextObject]) {
NSDictionary *desc = [screen deviceDescription];
if ([desc objectForKey:NSDeviceIsScreen] == nil) {
continue;
}
CGFloat scale =
[screen respondsToSelector:@selector(backingScaleFactor)] ?
[screen backingScaleFactor] : 1.0;
// Currently, we only care about differentiating "1.0" and "2.0",
// so we set one of the two low bits to record which.
if (scale > 1.0) {
scaleFactors |= 2;
} else {
scaleFactors |= 1;
}
}
// Now scaleFactors will be:
// 0 if no screens (supporting backingScaleFactor) found
// 1 if only lo-DPI screens
// 2 if only hi-DPI screens
// 3 if both lo- and hi-DPI screens
// We'll enable HiDPI support if there's only a single screen type,
// OR if the pref setting is explicitly greater than 1.
sHiDPIEnabled = (scaleFactors <= 2) || (prefSetting > 1);
}
return sHiDPIEnabled;
#else
return false; // Eliminate this since it leaks NSObjects.
#endif
}
void
nsCocoaUtils::GetCommandsFromKeyEvent(NSEvent* aEvent,
nsTArray<KeyBindingsCommand>& aCommands)
{
NS_OBJC_BEGIN_TRY_ABORT_BLOCK;
MOZ_ASSERT(aEvent);
static NativeKeyBindingsRecorder* sNativeKeyBindingsRecorder;
if (!sNativeKeyBindingsRecorder) {
sNativeKeyBindingsRecorder = [NativeKeyBindingsRecorder new];
}
[sNativeKeyBindingsRecorder startRecording:aCommands];
// This will trigger 0 - N calls to doCommandBySelector: and insertText:
[sNativeKeyBindingsRecorder
interpretKeyEvents:[NSArray arrayWithObject:aEvent]];
NS_OBJC_END_TRY_ABORT_BLOCK;
}
@implementation NativeKeyBindingsRecorder
- (void)startRecording:(nsTArray<KeyBindingsCommand>&)aCommands
{
mCommands = &aCommands;
mCommands->Clear();
}
- (void)doCommandBySelector:(SEL)aSelector
{
KeyBindingsCommand command = {
aSelector,
nil
};
mCommands->AppendElement(command);
}
- (void)insertText:(id)aString
{
KeyBindingsCommand command = {
@selector(insertText:),
aString
};
mCommands->AppendElement(command);
}
@end // NativeKeyBindingsRecorder
struct KeyConversionData
{
const char* str;
size_t strLength;
uint32_t geckoKeyCode;
uint32_t charCode;
};
static const KeyConversionData gKeyConversions[] = {
#define KEYCODE_ENTRY(aStr, aCode) \
{#aStr, sizeof(#aStr) - 1, NS_##aStr, aCode}
// Some keycodes may have different name in nsIDOMKeyEvent from its key name.
#define KEYCODE_ENTRY2(aStr, aNSName, aCode) \
{#aStr, sizeof(#aStr) - 1, NS_##aNSName, aCode}
KEYCODE_ENTRY(VK_CANCEL, 0x001B),
KEYCODE_ENTRY(VK_DELETE, NSDeleteFunctionKey),
KEYCODE_ENTRY(VK_BACK, NSBackspaceCharacter),
KEYCODE_ENTRY2(VK_BACK_SPACE, VK_BACK, NSBackspaceCharacter),
KEYCODE_ENTRY(VK_TAB, NSTabCharacter),
KEYCODE_ENTRY(VK_CLEAR, NSClearLineFunctionKey),
KEYCODE_ENTRY(VK_RETURN, NSEnterCharacter),
KEYCODE_ENTRY(VK_SHIFT, 0),
KEYCODE_ENTRY(VK_CONTROL, 0),
KEYCODE_ENTRY(VK_ALT, 0),
KEYCODE_ENTRY(VK_PAUSE, NSPauseFunctionKey),
KEYCODE_ENTRY(VK_CAPS_LOCK, 0),
KEYCODE_ENTRY(VK_ESCAPE, 0),
KEYCODE_ENTRY(VK_SPACE, ' '),
KEYCODE_ENTRY(VK_PAGE_UP, NSPageUpFunctionKey),
KEYCODE_ENTRY(VK_PAGE_DOWN, NSPageDownFunctionKey),
KEYCODE_ENTRY(VK_END, NSEndFunctionKey),
KEYCODE_ENTRY(VK_HOME, NSHomeFunctionKey),
KEYCODE_ENTRY(VK_LEFT, NSLeftArrowFunctionKey),
KEYCODE_ENTRY(VK_UP, NSUpArrowFunctionKey),
KEYCODE_ENTRY(VK_RIGHT, NSRightArrowFunctionKey),
KEYCODE_ENTRY(VK_DOWN, NSDownArrowFunctionKey),
KEYCODE_ENTRY(VK_PRINTSCREEN, NSPrintScreenFunctionKey),
KEYCODE_ENTRY(VK_INSERT, NSInsertFunctionKey),
KEYCODE_ENTRY(VK_HELP, NSHelpFunctionKey),
KEYCODE_ENTRY(VK_0, '0'),
KEYCODE_ENTRY(VK_1, '1'),
KEYCODE_ENTRY(VK_2, '2'),
KEYCODE_ENTRY(VK_3, '3'),
KEYCODE_ENTRY(VK_4, '4'),
KEYCODE_ENTRY(VK_5, '5'),
KEYCODE_ENTRY(VK_6, '6'),
KEYCODE_ENTRY(VK_7, '7'),
KEYCODE_ENTRY(VK_8, '8'),
KEYCODE_ENTRY(VK_9, '9'),
KEYCODE_ENTRY(VK_SEMICOLON, ':'),
KEYCODE_ENTRY(VK_EQUALS, '='),
KEYCODE_ENTRY(VK_A, 'A'),
KEYCODE_ENTRY(VK_B, 'B'),
KEYCODE_ENTRY(VK_C, 'C'),
KEYCODE_ENTRY(VK_D, 'D'),
KEYCODE_ENTRY(VK_E, 'E'),
KEYCODE_ENTRY(VK_F, 'F'),
KEYCODE_ENTRY(VK_G, 'G'),
KEYCODE_ENTRY(VK_H, 'H'),
KEYCODE_ENTRY(VK_I, 'I'),
KEYCODE_ENTRY(VK_J, 'J'),
KEYCODE_ENTRY(VK_K, 'K'),
KEYCODE_ENTRY(VK_L, 'L'),
KEYCODE_ENTRY(VK_M, 'M'),
KEYCODE_ENTRY(VK_N, 'N'),
KEYCODE_ENTRY(VK_O, 'O'),
KEYCODE_ENTRY(VK_P, 'P'),
KEYCODE_ENTRY(VK_Q, 'Q'),
KEYCODE_ENTRY(VK_R, 'R'),
KEYCODE_ENTRY(VK_S, 'S'),
KEYCODE_ENTRY(VK_T, 'T'),
KEYCODE_ENTRY(VK_U, 'U'),
KEYCODE_ENTRY(VK_V, 'V'),
KEYCODE_ENTRY(VK_W, 'W'),
KEYCODE_ENTRY(VK_X, 'X'),
KEYCODE_ENTRY(VK_Y, 'Y'),
KEYCODE_ENTRY(VK_Z, 'Z'),
KEYCODE_ENTRY(VK_CONTEXT_MENU, NSMenuFunctionKey),
KEYCODE_ENTRY(VK_NUMPAD0, '0'),
KEYCODE_ENTRY(VK_NUMPAD1, '1'),
KEYCODE_ENTRY(VK_NUMPAD2, '2'),
KEYCODE_ENTRY(VK_NUMPAD3, '3'),
KEYCODE_ENTRY(VK_NUMPAD4, '4'),
KEYCODE_ENTRY(VK_NUMPAD5, '5'),
KEYCODE_ENTRY(VK_NUMPAD6, '6'),
KEYCODE_ENTRY(VK_NUMPAD7, '7'),
KEYCODE_ENTRY(VK_NUMPAD8, '8'),
KEYCODE_ENTRY(VK_NUMPAD9, '9'),
KEYCODE_ENTRY(VK_MULTIPLY, '*'),
KEYCODE_ENTRY(VK_ADD, '+'),
KEYCODE_ENTRY(VK_SEPARATOR, 0),
KEYCODE_ENTRY(VK_SUBTRACT, '-'),
KEYCODE_ENTRY(VK_DECIMAL, '.'),
KEYCODE_ENTRY(VK_DIVIDE, '/'),
KEYCODE_ENTRY(VK_F1, NSF1FunctionKey),
KEYCODE_ENTRY(VK_F2, NSF2FunctionKey),
KEYCODE_ENTRY(VK_F3, NSF3FunctionKey),
KEYCODE_ENTRY(VK_F4, NSF4FunctionKey),
KEYCODE_ENTRY(VK_F5, NSF5FunctionKey),
KEYCODE_ENTRY(VK_F6, NSF6FunctionKey),
KEYCODE_ENTRY(VK_F7, NSF7FunctionKey),
KEYCODE_ENTRY(VK_F8, NSF8FunctionKey),
KEYCODE_ENTRY(VK_F9, NSF9FunctionKey),
KEYCODE_ENTRY(VK_F10, NSF10FunctionKey),
KEYCODE_ENTRY(VK_F11, NSF11FunctionKey),
KEYCODE_ENTRY(VK_F12, NSF12FunctionKey),
KEYCODE_ENTRY(VK_F13, NSF13FunctionKey),
KEYCODE_ENTRY(VK_F14, NSF14FunctionKey),
KEYCODE_ENTRY(VK_F15, NSF15FunctionKey),
KEYCODE_ENTRY(VK_F16, NSF16FunctionKey),
KEYCODE_ENTRY(VK_F17, NSF17FunctionKey),
KEYCODE_ENTRY(VK_F18, NSF18FunctionKey),
KEYCODE_ENTRY(VK_F19, NSF19FunctionKey),
KEYCODE_ENTRY(VK_F20, NSF20FunctionKey),
KEYCODE_ENTRY(VK_F21, NSF21FunctionKey),
KEYCODE_ENTRY(VK_F22, NSF22FunctionKey),
KEYCODE_ENTRY(VK_F23, NSF23FunctionKey),
KEYCODE_ENTRY(VK_F24, NSF24FunctionKey),
KEYCODE_ENTRY(VK_NUM_LOCK, NSClearLineFunctionKey),
KEYCODE_ENTRY(VK_SCROLL_LOCK, NSScrollLockFunctionKey),
KEYCODE_ENTRY(VK_COMMA, ','),
KEYCODE_ENTRY(VK_PERIOD, '.'),
KEYCODE_ENTRY(VK_SLASH, '/'),
KEYCODE_ENTRY(VK_BACK_QUOTE, '`'),
KEYCODE_ENTRY(VK_OPEN_BRACKET, '['),
KEYCODE_ENTRY(VK_BACK_SLASH, '\\'),
KEYCODE_ENTRY(VK_CLOSE_BRACKET, ']'),
KEYCODE_ENTRY(VK_QUOTE, '\'')
#undef KEYCODE_ENTRY
};
uint32_t
nsCocoaUtils::ConvertGeckoNameToMacCharCode(const nsAString& aKeyCodeName)
{
if (aKeyCodeName.IsEmpty()) {
return 0;
}
nsAutoCString keyCodeName;
keyCodeName.AssignWithConversion(aKeyCodeName);
// We want case-insensitive comparison with data stored as uppercase.
ToUpperCase(keyCodeName);
uint32_t keyCodeNameLength = keyCodeName.Length();
const char* keyCodeNameStr = keyCodeName.get();
for (uint16_t i = 0; i < ArrayLength(gKeyConversions); ++i) {
if (keyCodeNameLength == gKeyConversions[i].strLength &&
nsCRT::strcmp(gKeyConversions[i].str, keyCodeNameStr) == 0) {
return gKeyConversions[i].charCode;
}
}
return 0;
}
uint32_t
nsCocoaUtils::ConvertGeckoKeyCodeToMacCharCode(uint32_t aKeyCode)
{
if (!aKeyCode) {
return 0;
}
for (uint16_t i = 0; i < ArrayLength(gKeyConversions); ++i) {
if (gKeyConversions[i].geckoKeyCode == aKeyCode) {
return gKeyConversions[i].charCode;
}
}
return 0;
}