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LeafOS / LeafOS-Project / android_frameworks_base / 6e66b39e4a5903f4ff17a1418d8af2779ded70b7 / . / libs / hwui / RecordingCanvas.cpp
blob: 2e33609665b0da51ad76ab43864c8db7a0e90883 [file] [log] [blame]
/*
* Copyright (C) 2015 The Android Open Source Project
*
* 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.
*/
#include "RecordingCanvas.h"
#include "DeferredLayerUpdater.h"
#include "RecordedOp.h"
#include "RenderNode.h"
#include "VectorDrawable.h"
#include "hwui/MinikinUtils.h"
namespace android {
namespace uirenderer {
RecordingCanvas::RecordingCanvas(size_t width, size_t height)
: mState(*this)
, mResourceCache(ResourceCache::getInstance()) {
resetRecording(width, height);
}
RecordingCanvas::~RecordingCanvas() {
LOG_ALWAYS_FATAL_IF(mDisplayList,
"Destroyed a RecordingCanvas during a record!");
}
void RecordingCanvas::resetRecording(int width, int height, RenderNode* node) {
LOG_ALWAYS_FATAL_IF(mDisplayList,
"prepareDirty called a second time during a recording!");
mDisplayList = new DisplayList();
mState.initializeRecordingSaveStack(width, height);
mDeferredBarrierType = DeferredBarrierType::InOrder;
}
DisplayList* RecordingCanvas::finishRecording() {
restoreToCount(1);
mPaintMap.clear();
mRegionMap.clear();
mPathMap.clear();
DisplayList* displayList = mDisplayList;
mDisplayList = nullptr;
mSkiaCanvasProxy.reset(nullptr);
return displayList;
}
void RecordingCanvas::insertReorderBarrier(bool enableReorder) {
if (enableReorder) {
mDeferredBarrierType = DeferredBarrierType::OutOfOrder;
mDeferredBarrierClip = getRecordedClip();
} else {
mDeferredBarrierType = DeferredBarrierType::InOrder;
mDeferredBarrierClip = nullptr;
}
}
SkCanvas* RecordingCanvas::asSkCanvas() {
LOG_ALWAYS_FATAL_IF(!mDisplayList,
"attempting to get an SkCanvas when we are not recording!");
if (!mSkiaCanvasProxy) {
mSkiaCanvasProxy.reset(new SkiaCanvasProxy(this));
}
// SkCanvas instances default to identity transform, but should inherit
// the state of this Canvas; if this code was in the SkiaCanvasProxy
// constructor, we couldn't cache mSkiaCanvasProxy.
SkMatrix parentTransform;
getMatrix(&parentTransform);
mSkiaCanvasProxy.get()->setMatrix(parentTransform);
return mSkiaCanvasProxy.get();
}
// ----------------------------------------------------------------------------
// CanvasStateClient implementation
// ----------------------------------------------------------------------------
void RecordingCanvas::onViewportInitialized() {
}
void RecordingCanvas::onSnapshotRestored(const Snapshot& removed, const Snapshot& restored) {
if (removed.flags & Snapshot::kFlagIsFboLayer) {
addOp(alloc().create_trivial<EndLayerOp>());
} else if (removed.flags & Snapshot::kFlagIsLayer) {
addOp(alloc().create_trivial<EndUnclippedLayerOp>());
}
}
// ----------------------------------------------------------------------------
// android/graphics/Canvas state operations
// ----------------------------------------------------------------------------
// Save (layer)
int RecordingCanvas::save(SaveFlags::Flags flags) {
return mState.save((int) flags);
}
void RecordingCanvas::RecordingCanvas::restore() {
mState.restore();
}
void RecordingCanvas::restoreToCount(int saveCount) {
mState.restoreToCount(saveCount);
}
int RecordingCanvas::saveLayer(float left, float top, float right, float bottom,
const SkPaint* paint, SaveFlags::Flags flags) {
// force matrix/clip isolation for layer
flags |= SaveFlags::MatrixClip;
bool clippedLayer = flags & SaveFlags::ClipToLayer;
const Snapshot& previous = *mState.currentSnapshot();
// initialize the snapshot as though it almost represents an FBO layer so deferred draw
// operations will be able to store and restore the current clip and transform info, and
// quick rejection will be correct (for display lists)
Rect unmappedBounds(left, top, right, bottom);
unmappedBounds.roundOut();
// determine clipped bounds relative to previous viewport.
Rect visibleBounds = unmappedBounds;
previous.transform->mapRect(visibleBounds);
if (CC_UNLIKELY(!clippedLayer
&& previous.transform->rectToRect()
&& visibleBounds.contains(previous.getRenderTargetClip()))) {
// unlikely case where an unclipped savelayer is recorded with a clip it can use,
// as none of its unaffected/unclipped area is visible
clippedLayer = true;
flags |= SaveFlags::ClipToLayer;
}
visibleBounds.doIntersect(previous.getRenderTargetClip());
visibleBounds.snapToPixelBoundaries();
visibleBounds.doIntersect(Rect(previous.getViewportWidth(), previous.getViewportHeight()));
// Map visible bounds back to layer space, and intersect with parameter bounds
Rect layerBounds = visibleBounds;
if (CC_LIKELY(!layerBounds.isEmpty())) {
// if non-empty, can safely map by the inverse transform
Matrix4 inverse;
inverse.loadInverse(*previous.transform);
inverse.mapRect(layerBounds);
layerBounds.doIntersect(unmappedBounds);
}
int saveValue = mState.save((int) flags);
Snapshot& snapshot = *mState.writableSnapshot();
// layerBounds is in original bounds space, but clipped by current recording clip
if (!layerBounds.isEmpty() && !unmappedBounds.isEmpty()) {
if (CC_LIKELY(clippedLayer)) {
auto previousClip = getRecordedClip(); // capture before new snapshot clip has changed
if (addOp(alloc().create_trivial<BeginLayerOp>(
unmappedBounds,
*previous.transform, // transform to *draw* with
previousClip, // clip to *draw* with
refPaint(paint))) >= 0) {
snapshot.flags |= Snapshot::kFlagIsLayer | Snapshot::kFlagIsFboLayer;
snapshot.initializeViewport(unmappedBounds.getWidth(), unmappedBounds.getHeight());
snapshot.transform->loadTranslate(-unmappedBounds.left, -unmappedBounds.top, 0.0f);
Rect clip = layerBounds;
clip.translate(-unmappedBounds.left, -unmappedBounds.top);
snapshot.resetClip(clip.left, clip.top, clip.right, clip.bottom);
snapshot.roundRectClipState = nullptr;
return saveValue;
}
} else {
if (addOp(alloc().create_trivial<BeginUnclippedLayerOp>(
unmappedBounds,
*mState.currentSnapshot()->transform,
getRecordedClip(),
refPaint(paint))) >= 0) {
snapshot.flags |= Snapshot::kFlagIsLayer;
return saveValue;
}
}
}
// Layer not needed, so skip recording it...
if (CC_LIKELY(clippedLayer)) {
// ... and set empty clip to reject inner content, if possible
snapshot.resetClip(0, 0, 0, 0);
}
return saveValue;
}
// Matrix
void RecordingCanvas::rotate(float degrees) {
if (degrees == 0) return;
mState.rotate(degrees);
}
void RecordingCanvas::scale(float sx, float sy) {
if (sx == 1 && sy == 1) return;
mState.scale(sx, sy);
}
void RecordingCanvas::skew(float sx, float sy) {
mState.skew(sx, sy);
}
void RecordingCanvas::translate(float dx, float dy) {
if (dx == 0 && dy == 0) return;
mState.translate(dx, dy, 0);
}
// Clip
bool RecordingCanvas::getClipBounds(SkRect* outRect) const {
*outRect = mState.getLocalClipBounds().toSkRect();
return !(outRect->isEmpty());
}
bool RecordingCanvas::quickRejectRect(float left, float top, float right, float bottom) const {
return mState.quickRejectConservative(left, top, right, bottom);
}
bool RecordingCanvas::quickRejectPath(const SkPath& path) const {
SkRect bounds = path.getBounds();
return mState.quickRejectConservative(bounds.fLeft, bounds.fTop, bounds.fRight, bounds.fBottom);
}
bool RecordingCanvas::clipRect(float left, float top, float right, float bottom, SkClipOp op) {
return mState.clipRect(left, top, right, bottom, op);
}
bool RecordingCanvas::clipPath(const SkPath* path, SkClipOp op) {
return mState.clipPath(path, op);
}
// ----------------------------------------------------------------------------
// android/graphics/Canvas draw operations
// ----------------------------------------------------------------------------
void RecordingCanvas::drawColor(int color, SkBlendMode mode) {
addOp(alloc().create_trivial<ColorOp>(
getRecordedClip(),
color,
mode));
}
void RecordingCanvas::drawPaint(const SkPaint& paint) {
SkRect bounds;
if (getClipBounds(&bounds)) {
drawRect(bounds.fLeft, bounds.fTop, bounds.fRight, bounds.fBottom, paint);
}
}
static Rect calcBoundsOfPoints(const float* points, int floatCount) {
Rect unmappedBounds(points[0], points[1], points[0], points[1]);
for (int i = 2; i < floatCount; i += 2) {
unmappedBounds.expandToCover(points[i], points[i + 1]);
}
return unmappedBounds;
}
// Geometry
void RecordingCanvas::drawPoints(const float* points, int floatCount, const SkPaint& paint) {
if (CC_UNLIKELY(floatCount < 2 || PaintUtils::paintWillNotDraw(paint))) return;
floatCount &= ~0x1; // round down to nearest two
addOp(alloc().create_trivial<PointsOp>(
calcBoundsOfPoints(points, floatCount),
*mState.currentSnapshot()->transform,
getRecordedClip(),
refPaint(&paint), refBuffer<float>(points, floatCount), floatCount));
}
void RecordingCanvas::drawLines(const float* points, int floatCount, const SkPaint& paint) {
if (CC_UNLIKELY(floatCount < 4 || PaintUtils::paintWillNotDraw(paint))) return;
floatCount &= ~0x3; // round down to nearest four
addOp(alloc().create_trivial<LinesOp>(
calcBoundsOfPoints(points, floatCount),
*mState.currentSnapshot()->transform,
getRecordedClip(),
refPaint(&paint), refBuffer<float>(points, floatCount), floatCount));
}
void RecordingCanvas::drawRect(float left, float top, float right, float bottom, const SkPaint& paint) {
if (CC_UNLIKELY(PaintUtils::paintWillNotDraw(paint))) return;
addOp(alloc().create_trivial<RectOp>(
Rect(left, top, right, bottom),
*(mState.currentSnapshot()->transform),
getRecordedClip(),
refPaint(&paint)));
}
void RecordingCanvas::drawSimpleRects(const float* rects, int vertexCount, const SkPaint* paint) {
if (rects == nullptr) return;
Vertex* rectData = (Vertex*) mDisplayList->allocator.create_trivial_array<Vertex>(vertexCount);
Vertex* vertex = rectData;
float left = FLT_MAX;
float top = FLT_MAX;
float right = FLT_MIN;
float bottom = FLT_MIN;
for (int index = 0; index < vertexCount; index += 4) {
float l = rects[index + 0];
float t = rects[index + 1];
float r = rects[index + 2];
float b = rects[index + 3];
Vertex::set(vertex++, l, t);
Vertex::set(vertex++, r, t);
Vertex::set(vertex++, l, b);
Vertex::set(vertex++, r, b);
left = std::min(left, l);
top = std::min(top, t);
right = std::max(right, r);
bottom = std::max(bottom, b);
}
addOp(alloc().create_trivial<SimpleRectsOp>(
Rect(left, top, right, bottom),
*(mState.currentSnapshot()->transform),
getRecordedClip(),
refPaint(paint), rectData, vertexCount));
}
void RecordingCanvas::drawRegion(const SkRegion& region, const SkPaint& paint) {
if (CC_UNLIKELY(PaintUtils::paintWillNotDraw(paint))) return;
if (paint.getStyle() == SkPaint::kFill_Style
&& (!paint.isAntiAlias() || mState.currentTransform()->isSimple())) {
int count = 0;
Vector<float> rects;
SkRegion::Iterator it(region);
while (!it.done()) {
const SkIRect& r = it.rect();
rects.push(r.fLeft);
rects.push(r.fTop);
rects.push(r.fRight);
rects.push(r.fBottom);
count += 4;
it.next();
}
drawSimpleRects(rects.array(), count, &paint);
} else {
SkRegion::Iterator it(region);
while (!it.done()) {
const SkIRect& r = it.rect();
drawRect(r.fLeft, r.fTop, r.fRight, r.fBottom, paint);
it.next();
}
}
}
void RecordingCanvas::drawRoundRect(float left, float top, float right, float bottom,
float rx, float ry, const SkPaint& paint) {
if (CC_UNLIKELY(PaintUtils::paintWillNotDraw(paint))) return;
if (CC_LIKELY(MathUtils::isPositive(rx) || MathUtils::isPositive(ry))) {
addOp(alloc().create_trivial<RoundRectOp>(
Rect(left, top, right, bottom),
*(mState.currentSnapshot()->transform),
getRecordedClip(),
refPaint(&paint), rx, ry));
} else {
drawRect(left, top, right, bottom, paint);
}
}
void RecordingCanvas::drawRoundRect(
CanvasPropertyPrimitive* left, CanvasPropertyPrimitive* top,
CanvasPropertyPrimitive* right, CanvasPropertyPrimitive* bottom,
CanvasPropertyPrimitive* rx, CanvasPropertyPrimitive* ry,
CanvasPropertyPaint* paint) {
mDisplayList->ref(left);
mDisplayList->ref(top);
mDisplayList->ref(right);
mDisplayList->ref(bottom);
mDisplayList->ref(rx);
mDisplayList->ref(ry);
mDisplayList->ref(paint);
refBitmapsInShader(paint->value.getShader());
addOp(alloc().create_trivial<RoundRectPropsOp>(
*(mState.currentSnapshot()->transform),
getRecordedClip(),
&paint->value,
&left->value, &top->value, &right->value, &bottom->value,
&rx->value, &ry->value));
}
void RecordingCanvas::drawCircle(float x, float y, float radius, const SkPaint& paint) {
// TODO: move to Canvas.h
if (CC_UNLIKELY(radius <= 0 || PaintUtils::paintWillNotDraw(paint))) return;
drawOval(x - radius, y - radius, x + radius, y + radius, paint);
}
void RecordingCanvas::drawCircle(
CanvasPropertyPrimitive* x, CanvasPropertyPrimitive* y,
CanvasPropertyPrimitive* radius, CanvasPropertyPaint* paint) {
mDisplayList->ref(x);
mDisplayList->ref(y);
mDisplayList->ref(radius);
mDisplayList->ref(paint);
refBitmapsInShader(paint->value.getShader());
addOp(alloc().create_trivial<CirclePropsOp>(
*(mState.currentSnapshot()->transform),
getRecordedClip(),
&paint->value,
&x->value, &y->value, &radius->value));
}
void RecordingCanvas::drawOval(float left, float top, float right, float bottom, const SkPaint& paint) {
if (CC_UNLIKELY(PaintUtils::paintWillNotDraw(paint))) return;
addOp(alloc().create_trivial<OvalOp>(
Rect(left, top, right, bottom),
*(mState.currentSnapshot()->transform),
getRecordedClip(),
refPaint(&paint)));
}
void RecordingCanvas::drawArc(float left, float top, float right, float bottom,
float startAngle, float sweepAngle, bool useCenter, const SkPaint& paint) {
if (CC_UNLIKELY(PaintUtils::paintWillNotDraw(paint))) return;
if (fabs(sweepAngle) >= 360.0f) {
drawOval(left, top, right, bottom, paint);
} else {
addOp(alloc().create_trivial<ArcOp>(
Rect(left, top, right, bottom),
*(mState.currentSnapshot()->transform),
getRecordedClip(),
refPaint(&paint),
startAngle, sweepAngle, useCenter));
}
}
void RecordingCanvas::drawPath(const SkPath& path, const SkPaint& paint) {
if (CC_UNLIKELY(PaintUtils::paintWillNotDraw(paint))) return;
addOp(alloc().create_trivial<PathOp>(
Rect(path.getBounds()),
*(mState.currentSnapshot()->transform),
getRecordedClip(),
refPaint(&paint), refPath(&path)));
}
void RecordingCanvas::drawVectorDrawable(VectorDrawableRoot* tree) {
mDisplayList->ref(tree);
mDisplayList->vectorDrawables.push_back(tree);
addOp(alloc().create_trivial<VectorDrawableOp>(
tree,
Rect(tree->stagingProperties()->getBounds()),
*(mState.currentSnapshot()->transform),
getRecordedClip()));
}
// Bitmap-based
void RecordingCanvas::drawBitmap(Bitmap& bitmap, float left, float top, const SkPaint* paint) {
save(SaveFlags::Matrix);
translate(left, top);
drawBitmap(bitmap, paint);
restore();
}
void RecordingCanvas::drawBitmap(Bitmap& bitmap, const SkMatrix& matrix,
const SkPaint* paint) {
if (matrix.isIdentity()) {
drawBitmap(bitmap, paint);
} else if (!(matrix.getType() & ~(SkMatrix::kScale_Mask | SkMatrix::kTranslate_Mask))
&& MathUtils::isPositive(matrix.getScaleX())
&& MathUtils::isPositive(matrix.getScaleY())) {
// SkMatrix::isScaleTranslate() not available in L
SkRect src;
SkRect dst;
bitmap.getBounds(&src);
matrix.mapRect(&dst, src);
drawBitmap(bitmap, src.fLeft, src.fTop, src.fRight, src.fBottom,
dst.fLeft, dst.fTop, dst.fRight, dst.fBottom, paint);
} else {
save(SaveFlags::Matrix);
concat(matrix);
drawBitmap(bitmap, paint);
restore();
}
}
void RecordingCanvas::drawBitmap(Bitmap& bitmap, float srcLeft, float srcTop,
float srcRight, float srcBottom, float dstLeft, float dstTop,
float dstRight, float dstBottom, const SkPaint* paint) {
if (srcLeft == 0 && srcTop == 0
&& srcRight == bitmap.width()
&& srcBottom == bitmap.height()
&& (srcBottom - srcTop == dstBottom - dstTop)
&& (srcRight - srcLeft == dstRight - dstLeft)) {
// transform simple rect to rect drawing case into position bitmap ops, since they merge
save(SaveFlags::Matrix);
translate(dstLeft, dstTop);
drawBitmap(bitmap, paint);
restore();
} else {
addOp(alloc().create_trivial<BitmapRectOp>(
Rect(dstLeft, dstTop, dstRight, dstBottom),
*(mState.currentSnapshot()->transform),
getRecordedClip(),
refPaint(paint), refBitmap(bitmap),
Rect(srcLeft, srcTop, srcRight, srcBottom)));
}
}
void RecordingCanvas::drawBitmapMesh(Bitmap& bitmap, int meshWidth, int meshHeight,
const float* vertices, const int* colors, const SkPaint* paint) {
int vertexCount = (meshWidth + 1) * (meshHeight + 1);
addOp(alloc().create_trivial<BitmapMeshOp>(
calcBoundsOfPoints(vertices, vertexCount * 2),
*(mState.currentSnapshot()->transform),
getRecordedClip(),
refPaint(paint), refBitmap(bitmap), meshWidth, meshHeight,
refBuffer<float>(vertices, vertexCount * 2), // 2 floats per vertex
refBuffer<int>(colors, vertexCount))); // 1 color per vertex
}
void RecordingCanvas::drawNinePatch(Bitmap& bitmap, const android::Res_png_9patch& patch,
float dstLeft, float dstTop, float dstRight, float dstBottom,
const SkPaint* paint) {
addOp(alloc().create_trivial<PatchOp>(
Rect(dstLeft, dstTop, dstRight, dstBottom),
*(mState.currentSnapshot()->transform),
getRecordedClip(),
refPaint(paint), refBitmap(bitmap), refPatch(&patch)));
}
// Text
void RecordingCanvas::drawGlyphs(const uint16_t* glyphs, const float* positions, int glyphCount,
const SkPaint& paint, float x, float y, float boundsLeft, float boundsTop,
float boundsRight, float boundsBottom, float totalAdvance) {
if (!glyphs || !positions || glyphCount <= 0 || PaintUtils::paintWillNotDrawText(paint)) return;
glyphs = refBuffer<glyph_t>(glyphs, glyphCount);
positions = refBuffer<float>(positions, glyphCount * 2);
// TODO: either must account for text shadow in bounds, or record separate ops for text shadows
addOp(alloc().create_trivial<TextOp>(
Rect(boundsLeft, boundsTop, boundsRight, boundsBottom),
*(mState.currentSnapshot()->transform),
getRecordedClip(),
refPaint(&paint), glyphs, positions, glyphCount, x, y));
drawTextDecorations(x, y, totalAdvance, paint);
}
void RecordingCanvas::drawLayoutOnPath(const minikin::Layout& layout, float hOffset, float vOffset,
const SkPaint& paint, const SkPath& path, size_t start, size_t end) {
uint16_t glyphs[1];
for (size_t i = start; i < end; i++) {
glyphs[0] = layout.getGlyphId(i);
float x = hOffset + layout.getX(i);
float y = vOffset + layout.getY(i);
if (PaintUtils::paintWillNotDrawText(paint)) return;
const uint16_t* tempGlyphs = refBuffer<glyph_t>(glyphs, 1);
addOp(alloc().create_trivial<TextOnPathOp>(
*(mState.currentSnapshot()->transform),
getRecordedClip(),
refPaint(&paint), tempGlyphs, 1, refPath(&path), x, y));
}
}
void RecordingCanvas::drawBitmap(Bitmap& bitmap, const SkPaint* paint) {
addOp(alloc().create_trivial<BitmapOp>(
Rect(bitmap.width(), bitmap.height()),
*(mState.currentSnapshot()->transform),
getRecordedClip(),
refPaint(paint), refBitmap(bitmap)));
}
void RecordingCanvas::drawRenderNode(RenderNode* renderNode) {
auto&& stagingProps = renderNode->stagingProperties();
RenderNodeOp* op = alloc().create_trivial<RenderNodeOp>(
Rect(stagingProps.getWidth(), stagingProps.getHeight()),
*(mState.currentSnapshot()->transform),
getRecordedClip(),
renderNode);
int opIndex = addOp(op);
if (CC_LIKELY(opIndex >= 0)) {
int childIndex = mDisplayList->addChild(op);
// update the chunk's child indices
DisplayList::Chunk& chunk = mDisplayList->chunks.back();
chunk.endChildIndex = childIndex + 1;
if (renderNode->stagingProperties().isProjectionReceiver()) {
// use staging property, since recording on UI thread
mDisplayList->projectionReceiveIndex = opIndex;
}
}
}
void RecordingCanvas::drawLayer(DeferredLayerUpdater* layerHandle) {
// We ref the DeferredLayerUpdater due to its thread-safe ref-counting semantics.
mDisplayList->ref(layerHandle);
LOG_ALWAYS_FATAL_IF(layerHandle->getBackingLayerApi() != Layer::Api::OpenGL);
// Note that the backing layer has *not* yet been updated, so don't trust
// its width, height, transform, etc...!
addOp(alloc().create_trivial<TextureLayerOp>(
Rect(layerHandle->getWidth(), layerHandle->getHeight()),
*(mState.currentSnapshot()->transform),
getRecordedClip(), layerHandle));
}
void RecordingCanvas::callDrawGLFunction(Functor* functor,
GlFunctorLifecycleListener* listener) {
mDisplayList->functors.push_back({functor, listener});
mDisplayList->ref(listener);
addOp(alloc().create_trivial<FunctorOp>(
*(mState.currentSnapshot()->transform),
getRecordedClip(),
functor));
}
int RecordingCanvas::addOp(RecordedOp* op) {
// skip op with empty clip
if (op->localClip && op->localClip->rect.isEmpty()) {
// NOTE: this rejection happens after op construction/content ref-ing, so content ref'd
// and held by renderthread isn't affected by clip rejection.
// Could rewind alloc here if desired, but callers would have to not touch op afterwards.
return -1;
}
int insertIndex = mDisplayList->ops.size();
mDisplayList->ops.push_back(op);
if (mDeferredBarrierType != DeferredBarrierType::None) {
// op is first in new chunk
mDisplayList->chunks.emplace_back();
DisplayList::Chunk& newChunk = mDisplayList->chunks.back();
newChunk.beginOpIndex = insertIndex;
newChunk.endOpIndex = insertIndex + 1;
newChunk.reorderChildren = (mDeferredBarrierType == DeferredBarrierType::OutOfOrder);
newChunk.reorderClip = mDeferredBarrierClip;
int nextChildIndex = mDisplayList->children.size();
newChunk.beginChildIndex = newChunk.endChildIndex = nextChildIndex;
mDeferredBarrierType = DeferredBarrierType::None;
} else {
// standard case - append to existing chunk
mDisplayList->chunks.back().endOpIndex = insertIndex + 1;
}
return insertIndex;
}
void RecordingCanvas::refBitmapsInShader(const SkShader* shader) {
if (!shader) return;
// If this paint has an SkShader that has an SkBitmap add
// it to the bitmap pile
SkBitmap bitmap;
SkShader::TileMode xy[2];
if (shader->isABitmap(&bitmap, nullptr, xy)) {
Bitmap* hwuiBitmap = static_cast<Bitmap*>(bitmap.pixelRef());
refBitmap(*hwuiBitmap);
return;
}
SkShader::ComposeRec rec;
if (shader->asACompose(&rec)) {
refBitmapsInShader(rec.fShaderA);
refBitmapsInShader(rec.fShaderB);
return;
}
}
}; // namespace uirenderer
}; // namespace android