Google Git
Sign in
webkit / WebKit / 5b4247e12db58796c9d5572133475cd215934176 / . / Source / WebCore / html / HTMLCanvasElement.cpp
blob: 7d7d3911a768837249bf350a8ab598a275849346 [file] [log] [blame]
/*
* Copyright (C) 2004, 2006, 2007 Apple Inc. All rights reserved.
* Copyright (C) 2007 Alp Toker <alp@atoker.com>
* Copyright (C) 2010 Torch Mobile (Beijing) Co. Ltd. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY APPLE INC. ``AS IS'' AND ANY
* EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
* PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL APPLE INC. OR
* CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
* EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
* PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
* PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY
* OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include "config.h"
#include "HTMLCanvasElement.h"
#include "CanvasGradient.h"
#include "CanvasPattern.h"
#include "CanvasRenderingContext2D.h"
#include "Document.h"
#include "ExceptionCode.h"
#include "Frame.h"
#include "FrameLoaderClient.h"
#include "GeometryUtilities.h"
#include "GraphicsContext.h"
#include "HTMLNames.h"
#include "HTMLParserIdioms.h"
#include "ImageData.h"
#include "MIMETypeRegistry.h"
#include "RenderHTMLCanvas.h"
#include "ScriptController.h"
#include "Settings.h"
#include <math.h>
#include <runtime/JSCInlines.h>
#include <runtime/JSLock.h>
#include <wtf/RAMSize.h>
#include <wtf/text/StringBuilder.h>
#if ENABLE(WEBGL)
#include "WebGLContextAttributes.h"
#include "WebGLRenderingContextBase.h"
#endif
namespace WebCore {
using namespace HTMLNames;
// These values come from the WhatWG/W3C HTML spec.
const int defaultWidth = 300;
const int defaultHeight = 150;
// Firefox limits width/height to 32767 pixels, but slows down dramatically before it
// reaches that limit. We limit by area instead, giving us larger maximum dimensions,
// in exchange for a smaller maximum canvas size. The maximum canvas size is in device pixels.
#if PLATFORM(IOS)
const unsigned maxCanvasArea = 4096 * 4096;
#elif PLATFORM(MAC) && __MAC_OS_X_VERSION_MIN_REQUIRED < 101100
const unsigned maxCanvasArea = 8192 * 8192;
#else
const unsigned maxCanvasArea = 16384 * 16384;
#endif
#if USE(CG)
// FIXME: It seems strange that the default quality is not the one that is literally named "default".
// Should fix names to make this easier to understand, or write an excellent comment here explaining why not.
const InterpolationQuality defaultInterpolationQuality = InterpolationLow;
#else
const InterpolationQuality defaultInterpolationQuality = InterpolationDefault;
#endif
static size_t activePixelMemory = 0;
HTMLCanvasElement::HTMLCanvasElement(const QualifiedName& tagName, Document& document)
: HTMLElement(tagName, document)
, m_size(defaultWidth, defaultHeight)
{
ASSERT(hasTagName(canvasTag));
}
Ref<HTMLCanvasElement> HTMLCanvasElement::create(Document& document)
{
return adoptRef(*new HTMLCanvasElement(canvasTag, document));
}
Ref<HTMLCanvasElement> HTMLCanvasElement::create(const QualifiedName& tagName, Document& document)
{
return adoptRef(*new HTMLCanvasElement(tagName, document));
}
static void removeFromActivePixelMemory(size_t pixelsReleased)
{
if (!pixelsReleased)
return;
if (pixelsReleased < activePixelMemory)
activePixelMemory -= pixelsReleased;
else
activePixelMemory = 0;
}
HTMLCanvasElement::~HTMLCanvasElement()
{
for (auto& observer : m_observers)
observer->canvasDestroyed(*this);
m_context = nullptr; // Ensure this goes away before the ImageBuffer.
releaseImageBufferAndContext();
}
void HTMLCanvasElement::parseAttribute(const QualifiedName& name, const AtomicString& value)
{
if (name == widthAttr || name == heightAttr)
reset();
HTMLElement::parseAttribute(name, value);
}
RenderPtr<RenderElement> HTMLCanvasElement::createElementRenderer(RenderStyle&& style, const RenderTreePosition& insertionPosition)
{
Frame* frame = document().frame();
if (frame && frame->script().canExecuteScripts(NotAboutToExecuteScript))
return createRenderer<RenderHTMLCanvas>(*this, WTFMove(style));
return HTMLElement::createElementRenderer(WTFMove(style), insertionPosition);
}
bool HTMLCanvasElement::canContainRangeEndPoint() const
{
return false;
}
bool HTMLCanvasElement::canStartSelection() const
{
return false;
}
void HTMLCanvasElement::addObserver(CanvasObserver& observer)
{
m_observers.add(&observer);
}
void HTMLCanvasElement::removeObserver(CanvasObserver& observer)
{
m_observers.remove(&observer);
}
void HTMLCanvasElement::setHeight(unsigned value)
{
setAttributeWithoutSynchronization(heightAttr, AtomicString::number(limitToOnlyHTMLNonNegative(value, defaultHeight)));
}
void HTMLCanvasElement::setWidth(unsigned value)
{
setAttributeWithoutSynchronization(widthAttr, AtomicString::number(limitToOnlyHTMLNonNegative(value, defaultWidth)));
}
static inline size_t maxActivePixelMemory()
{
static size_t maxPixelMemory;
static std::once_flag onceFlag;
std::call_once(onceFlag, [] {
maxPixelMemory = std::max(ramSize() / 4, 2151 * MB);
});
return maxPixelMemory;
}
CanvasRenderingContext* HTMLCanvasElement::getContext(const String& type)
{
if (HTMLCanvasElement::is2dType(type))
return getContext2d(type);
#if ENABLE(WEBGL)
if (HTMLCanvasElement::is3dType(type))
return getContextWebGL(type);
#endif
return nullptr;
}
bool HTMLCanvasElement::is2dType(const String& type)
{
return type == "2d";
}
CanvasRenderingContext* HTMLCanvasElement::getContext2d(const String& type)
{
ASSERT_UNUSED(HTMLCanvasElement::is2dType(type), type);
if (m_context && !m_context->is2d())
return nullptr;
if (!m_context) {
bool usesDashboardCompatibilityMode = false;
#if ENABLE(DASHBOARD_SUPPORT)
usesDashboardCompatibilityMode = document().settings().usesDashboardBackwardCompatibilityMode();
#endif
// Make sure we don't use more pixel memory than the system can support.
size_t requestedPixelMemory = 4 * width() * height();
if (activePixelMemory + requestedPixelMemory > maxActivePixelMemory()) {
StringBuilder stringBuilder;
stringBuilder.appendLiteral("Total canvas memory use exceeds the maximum limit (");
stringBuilder.appendNumber(maxActivePixelMemory() / 1024 / 1024);
stringBuilder.appendLiteral(" MB).");
document().addConsoleMessage(MessageSource::JS, MessageLevel::Warning, stringBuilder.toString());
return nullptr;
}
m_context = std::make_unique<CanvasRenderingContext2D>(*this, document().inQuirksMode(), usesDashboardCompatibilityMode);
downcast<CanvasRenderingContext2D>(*m_context).setUsesDisplayListDrawing(m_usesDisplayListDrawing);
downcast<CanvasRenderingContext2D>(*m_context).setTracksDisplayListReplay(m_tracksDisplayListReplay);
#if USE(IOSURFACE_CANVAS_BACKING_STORE) || ENABLE(ACCELERATED_2D_CANVAS)
// Need to make sure a RenderLayer and compositing layer get created for the Canvas
invalidateStyleAndLayerComposition();
#endif
}
return m_context.get();
}
#if ENABLE(WEBGL)
static bool requiresAcceleratedCompositingForWebGL()
{
#if PLATFORM(GTK)
return false;
#else
return true;
#endif
}
static bool shouldEnableWebGL(const Settings& settings)
{
if (!settings.webGLEnabled())
return false;
if (!requiresAcceleratedCompositingForWebGL())
return true;
return settings.acceleratedCompositingEnabled();
}
bool HTMLCanvasElement::is3dType(const String& type)
{
// Retain support for the legacy "webkit-3d" name.
return type == "webgl" || type == "experimental-webgl"
#if ENABLE(WEBGL2)
|| type == "webgl2"
#endif
|| type == "webkit-3d";
}
CanvasRenderingContext* HTMLCanvasElement::getContextWebGL(const String& type, WebGLContextAttributes&& attrs)
{
ASSERT(HTMLCanvasElement::is3dType(type));
if (!shouldEnableWebGL(document().settings()))
return nullptr;
if (m_context && !m_context->is3d())
return nullptr;
if (!m_context) {
m_context = WebGLRenderingContextBase::create(*this, attrs, type);
if (m_context) {
// Need to make sure a RenderLayer and compositing layer get created for the Canvas
invalidateStyleAndLayerComposition();
}
}
return m_context.get();
}
#endif
void HTMLCanvasElement::didDraw(const FloatRect& rect)
{
clearCopiedImage();
FloatRect dirtyRect = rect;
if (RenderBox* ro = renderBox()) {
FloatRect destRect = ro->contentBoxRect();
// Inflate dirty rect to cover antialiasing on image buffers.
if (drawingContext() && drawingContext()->shouldAntialias())
dirtyRect.inflate(1);
FloatRect r = mapRect(dirtyRect, FloatRect(0, 0, size().width(), size().height()), destRect);
r.intersect(destRect);
if (r.isEmpty() || m_dirtyRect.contains(r))
return;
m_dirtyRect.unite(r);
ro->repaintRectangle(enclosingIntRect(m_dirtyRect));
}
notifyObserversCanvasChanged(dirtyRect);
}
void HTMLCanvasElement::notifyObserversCanvasChanged(const FloatRect& rect)
{
for (auto& observer : m_observers)
observer->canvasChanged(*this, rect);
}
void HTMLCanvasElement::reset()
{
if (m_ignoreReset)
return;
bool hadImageBuffer = hasCreatedImageBuffer();
int w = limitToOnlyHTMLNonNegative(attributeWithoutSynchronization(widthAttr), defaultWidth);
int h = limitToOnlyHTMLNonNegative(attributeWithoutSynchronization(heightAttr), defaultHeight);
if (m_contextStateSaver) {
// Reset to the initial graphics context state.
m_contextStateSaver->restore();
m_contextStateSaver->save();
}
if (is<CanvasRenderingContext2D>(m_context.get()))
downcast<CanvasRenderingContext2D>(*m_context).reset();
IntSize oldSize = size();
IntSize newSize(w, h);
// If the size of an existing buffer matches, we can just clear it instead of reallocating.
// This optimization is only done for 2D canvases for now.
if (m_hasCreatedImageBuffer && oldSize == newSize && m_context && m_context->is2d()) {
if (!m_didClearImageBuffer)
clearImageBuffer();
return;
}
setSurfaceSize(newSize);
#if ENABLE(WEBGL)
if (is3D() && oldSize != size())
static_cast<WebGLRenderingContextBase*>(m_context.get())->reshape(width(), height());
#endif
auto renderer = this->renderer();
if (is<RenderHTMLCanvas>(renderer)) {
auto& canvasRenderer = downcast<RenderHTMLCanvas>(*renderer);
if (oldSize != size()) {
canvasRenderer.canvasSizeChanged();
if (canvasRenderer.hasAcceleratedCompositing())
canvasRenderer.contentChanged(CanvasChanged);
}
if (hadImageBuffer)
canvasRenderer.repaint();
}
for (auto& observer : m_observers)
observer->canvasResized(*this);
}
bool HTMLCanvasElement::paintsIntoCanvasBuffer() const
{
ASSERT(m_context);
#if USE(IOSURFACE_CANVAS_BACKING_STORE)
if (m_context->is2d())
return true;
#endif
if (!m_context->isAccelerated())
return true;
if (renderBox() && renderBox()->hasAcceleratedCompositing())
return false;
return true;
}
void HTMLCanvasElement::paint(GraphicsContext& context, const LayoutRect& r)
{
// Clear the dirty rect
m_dirtyRect = FloatRect();
if (context.paintingDisabled())
return;
if (m_context) {
if (!paintsIntoCanvasBuffer() && !document().printing())
return;
m_context->paintRenderingResultsToCanvas();
}
if (hasCreatedImageBuffer()) {
ImageBuffer* imageBuffer = buffer();
if (imageBuffer) {
if (m_presentedImage) {
ImageOrientationDescription orientationDescription;
#if ENABLE(CSS_IMAGE_ORIENTATION)
orientationDescription.setImageOrientationEnum(renderer()->style().imageOrientation());
#endif
context.drawImage(*m_presentedImage, snappedIntRect(r), ImagePaintingOptions(orientationDescription));
} else
context.drawImageBuffer(*imageBuffer, snappedIntRect(r));
}
}
#if ENABLE(WEBGL)
if (is3D())
static_cast<WebGLRenderingContextBase*>(m_context.get())->markLayerComposited();
#endif
}
#if ENABLE(WEBGL)
bool HTMLCanvasElement::is3D() const
{
return m_context && m_context->is3d();
}
#endif
void HTMLCanvasElement::makeRenderingResultsAvailable()
{
if (m_context)
m_context->paintRenderingResultsToCanvas();
}
void HTMLCanvasElement::makePresentationCopy()
{
if (!m_presentedImage) {
// The buffer contains the last presented data, so save a copy of it.
m_presentedImage = buffer()->copyImage(CopyBackingStore, Unscaled);
}
}
void HTMLCanvasElement::clearPresentationCopy()
{
m_presentedImage = nullptr;
}
void HTMLCanvasElement::releaseImageBufferAndContext()
{
m_contextStateSaver = nullptr;
setImageBuffer(nullptr);
}
void HTMLCanvasElement::setSurfaceSize(const IntSize& size)
{
m_size = size;
m_hasCreatedImageBuffer = false;
releaseImageBufferAndContext();
clearCopiedImage();
}
String HTMLCanvasElement::toEncodingMimeType(const String& mimeType)
{
if (!MIMETypeRegistry::isSupportedImageMIMETypeForEncoding(mimeType))
return ASCIILiteral("image/png");
return mimeType.convertToASCIILowercase();
}
ExceptionOr<String> HTMLCanvasElement::toDataURL(const String& mimeType, std::optional<double> quality)
{
if (!m_originClean)
return Exception { SECURITY_ERR };
if (m_size.isEmpty() || !buffer())
return String { ASCIILiteral { "data:," } };
String encodingMIMEType = toEncodingMimeType(mimeType);
#if USE(CG)
// Try to get ImageData first, as that may avoid lossy conversions.
if (auto imageData = getImageData())
return dataURL(*imageData, encodingMIMEType, quality);
#endif
makeRenderingResultsAvailable();
return buffer()->toDataURL(encodingMIMEType, quality);
}
RefPtr<ImageData> HTMLCanvasElement::getImageData()
{
#if ENABLE(WEBGL)
if (!is3D())
return nullptr;
WebGLRenderingContextBase* ctx = static_cast<WebGLRenderingContextBase*>(m_context.get());
return ctx->paintRenderingResultsToImageData();
#else
return nullptr;
#endif
}
FloatRect HTMLCanvasElement::convertLogicalToDevice(const FloatRect& logicalRect) const
{
FloatRect deviceRect(logicalRect);
float x = floorf(deviceRect.x());
float y = floorf(deviceRect.y());
float w = ceilf(deviceRect.maxX() - x);
float h = ceilf(deviceRect.maxY() - y);
deviceRect.setX(x);
deviceRect.setY(y);
deviceRect.setWidth(w);
deviceRect.setHeight(h);
return deviceRect;
}
FloatSize HTMLCanvasElement::convertLogicalToDevice(const FloatSize& logicalSize) const
{
float width = ceilf(logicalSize.width());
float height = ceilf(logicalSize.height());
return FloatSize(width, height);
}
FloatSize HTMLCanvasElement::convertDeviceToLogical(const FloatSize& deviceSize) const
{
float width = ceilf(deviceSize.width());
float height = ceilf(deviceSize.height());
return FloatSize(width, height);
}
SecurityOrigin* HTMLCanvasElement::securityOrigin() const
{
return &document().securityOrigin();
}
bool HTMLCanvasElement::shouldAccelerate(const IntSize& size) const
{
auto& settings = document().settings();
auto area = size.area<RecordOverflow>();
if (area.hasOverflowed())
return false;
if (area > settings.maximumAccelerated2dCanvasSize())
return false;
#if USE(IOSURFACE_CANVAS_BACKING_STORE)
return settings.canvasUsesAcceleratedDrawing();
#elif ENABLE(ACCELERATED_2D_CANVAS)
if (m_context && !m_context->is2d())
return false;
if (!settings.accelerated2dCanvasEnabled())
return false;
if (area < settings.minimumAccelerated2dCanvasSize())
return false;
return true;
#else
UNUSED_PARAM(size);
return false;
#endif
}
size_t HTMLCanvasElement::memoryCost() const
{
if (!m_imageBuffer)
return 0;
return m_imageBuffer->memoryCost();
}
size_t HTMLCanvasElement::externalMemoryCost() const
{
if (!m_imageBuffer)
return 0;
return m_imageBuffer->externalMemoryCost();
}
void HTMLCanvasElement::setUsesDisplayListDrawing(bool usesDisplayListDrawing)
{
if (usesDisplayListDrawing == m_usesDisplayListDrawing)
return;
m_usesDisplayListDrawing = usesDisplayListDrawing;
if (is<CanvasRenderingContext2D>(m_context.get()))
downcast<CanvasRenderingContext2D>(*m_context).setUsesDisplayListDrawing(m_usesDisplayListDrawing);
}
void HTMLCanvasElement::setTracksDisplayListReplay(bool tracksDisplayListReplay)
{
if (tracksDisplayListReplay == m_tracksDisplayListReplay)
return;
m_tracksDisplayListReplay = tracksDisplayListReplay;
if (is<CanvasRenderingContext2D>(m_context.get()))
downcast<CanvasRenderingContext2D>(*m_context).setTracksDisplayListReplay(m_tracksDisplayListReplay);
}
String HTMLCanvasElement::displayListAsText(DisplayList::AsTextFlags flags) const
{
if (is<CanvasRenderingContext2D>(m_context.get()))
return downcast<CanvasRenderingContext2D>(*m_context).displayListAsText(flags);
return String();
}
String HTMLCanvasElement::replayDisplayListAsText(DisplayList::AsTextFlags flags) const
{
if (is<CanvasRenderingContext2D>(m_context.get()))
return downcast<CanvasRenderingContext2D>(*m_context).replayDisplayListAsText(flags);
return String();
}
void HTMLCanvasElement::createImageBuffer() const
{
ASSERT(!m_imageBuffer);
m_hasCreatedImageBuffer = true;
m_didClearImageBuffer = true;
FloatSize logicalSize = size();
FloatSize deviceSize = convertLogicalToDevice(logicalSize);
if (!deviceSize.isExpressibleAsIntSize())
return;
if (deviceSize.width() * deviceSize.height() > maxCanvasArea) {
StringBuilder stringBuilder;
stringBuilder.appendLiteral("Canvas area exceeds the maximum limit (width * height > ");
stringBuilder.appendNumber(maxCanvasArea);
stringBuilder.appendLiteral(").");
document().addConsoleMessage(MessageSource::JS, MessageLevel::Warning, stringBuilder.toString());
return;
}
// Make sure we don't use more pixel memory than the system can support.
size_t requestedPixelMemory = 4 * width() * height();
if (activePixelMemory + requestedPixelMemory > maxActivePixelMemory()) {
StringBuilder stringBuilder;
stringBuilder.appendLiteral("Total canvas memory use exceeds the maximum limit (");
stringBuilder.appendNumber(maxActivePixelMemory() / 1024 / 1024);
stringBuilder.appendLiteral(" MB).");
document().addConsoleMessage(MessageSource::JS, MessageLevel::Warning, stringBuilder.toString());
return;
}
IntSize bufferSize(deviceSize.width(), deviceSize.height());
if (!bufferSize.width() || !bufferSize.height())
return;
RenderingMode renderingMode = shouldAccelerate(bufferSize) ? Accelerated : Unaccelerated;
setImageBuffer(ImageBuffer::create(size(), renderingMode));
if (!m_imageBuffer)
return;
m_imageBuffer->context().setShadowsIgnoreTransforms(true);
m_imageBuffer->context().setImageInterpolationQuality(defaultInterpolationQuality);
m_imageBuffer->context().setStrokeThickness(1);
m_contextStateSaver = std::make_unique<GraphicsContextStateSaver>(m_imageBuffer->context());
JSC::JSLockHolder lock(scriptExecutionContext()->vm());
scriptExecutionContext()->vm().heap.reportExtraMemoryAllocated(memoryCost());
#if USE(IOSURFACE_CANVAS_BACKING_STORE) || ENABLE(ACCELERATED_2D_CANVAS)
if (m_context && m_context->is2d())
// Recalculate compositing requirements if acceleration state changed.
const_cast<HTMLCanvasElement*>(this)->invalidateStyleAndLayerComposition();
#endif
}
void HTMLCanvasElement::setImageBuffer(std::unique_ptr<ImageBuffer> buffer) const
{
removeFromActivePixelMemory(memoryCost());
m_imageBuffer = WTFMove(buffer);
activePixelMemory += memoryCost();
}
GraphicsContext* HTMLCanvasElement::drawingContext() const
{
return buffer() ? &m_imageBuffer->context() : nullptr;
}
GraphicsContext* HTMLCanvasElement::existingDrawingContext() const
{
if (!m_hasCreatedImageBuffer)
return nullptr;
return drawingContext();
}
ImageBuffer* HTMLCanvasElement::buffer() const
{
if (!m_hasCreatedImageBuffer)
createImageBuffer();
return m_imageBuffer.get();
}
Image* HTMLCanvasElement::copiedImage() const
{
if (!m_copiedImage && buffer()) {
if (m_context)
m_context->paintRenderingResultsToCanvas();
m_copiedImage = buffer()->copyImage(CopyBackingStore, Unscaled);
}
return m_copiedImage.get();
}
void HTMLCanvasElement::clearImageBuffer() const
{
ASSERT(m_hasCreatedImageBuffer);
ASSERT(!m_didClearImageBuffer);
ASSERT(m_context);
m_didClearImageBuffer = true;
if (is<CanvasRenderingContext2D>(*m_context)) {
// No need to undo transforms/clip/etc. because we are called right after the context is reset.
downcast<CanvasRenderingContext2D>(*m_context).clearRect(0, 0, width(), height());
}
}
void HTMLCanvasElement::clearCopiedImage()
{
m_copiedImage = nullptr;
m_didClearImageBuffer = false;
}
AffineTransform HTMLCanvasElement::baseTransform() const
{
ASSERT(m_hasCreatedImageBuffer);
FloatSize unscaledSize = size();
FloatSize deviceSize = convertLogicalToDevice(unscaledSize);
IntSize size(deviceSize.width(), deviceSize.height());
AffineTransform transform;
if (size.width() && size.height())
transform.scaleNonUniform(size.width() / unscaledSize.width(), size.height() / unscaledSize.height());
return m_imageBuffer->baseTransform() * transform;
}
}