gecko-dev/layout/painting/RetainedDisplayListBuilder.cpp

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/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
/* vim: set ts=8 sts=2 et sw=2 tw=80: */
/* 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 "RetainedDisplayListBuilder.h"
#include "nsSubDocumentFrame.h"
#include "nsViewManager.h"
/**
* Code for doing display list building for a modified subset of the window,
* and then merging it into the existing display list (for the full window).
*
* The approach primarily hinges on the observation that the true ordering of
* display items is represented by a DAG (only items that intersect in 2d space
* have a defined ordering). Our display list is just one of a many possible linear
* representations of this ordering.
*
* Each time a frame changes (gets a new style context, or has a size/position
* change), we schedule a paint (as we do currently), but also reord the frame that
* changed.
*
* When the next paint occurs we union the overflow areas (in screen space) of the
* changed frames, and compute a rect/region that contains all changed items. We
* then build a display list just for this subset of the screen and merge it into
* the display list from last paint.
*
* Any items that exist in one list and not the other must not have a defined
* ordering in the DAG, since they need to intersect to have an ordering and
* we would have built both in the new list if they intersected. Given that, we
* can align items that appear in both lists, and any items that appear between
* matched items can be inserted into the merged list in any order.
*/
using namespace mozilla;
void MarkFramesWithItemsAndImagesModified(nsDisplayList* aList)
{
for (nsDisplayItem* i = aList->GetBottom(); i != nullptr; i = i->GetAbove()) {
if (!i->HasDeletedFrame() && i->CanBeReused() && !i->Frame()->IsFrameModified()) {
// If we have existing cached geometry for this item, then check that for
// whether we need to invalidate for a sync decode. If we don't, then
// use the item's flags.
DisplayItemData* data = FrameLayerBuilder::GetOldDataFor(i);
bool invalidate = false;
if (data &&
data->GetGeometry()) {
invalidate = data->GetGeometry()->InvalidateForSyncDecodeImages();
} else if (!(i->GetFlags() & TYPE_RENDERS_NO_IMAGES)) {
invalidate = true;
}
if (invalidate) {
i->FrameForInvalidation()->MarkNeedsDisplayItemRebuild();
if (i->GetDependentFrame()) {
i->GetDependentFrame()->MarkNeedsDisplayItemRebuild();
}
}
}
if (i->GetChildren()) {
MarkFramesWithItemsAndImagesModified(i->GetChildren());
}
}
}
bool IsAnyAncestorModified(nsIFrame* aFrame)
{
nsIFrame* f = aFrame;
while (f) {
if (f->IsFrameModified()) {
return true;
}
f = nsLayoutUtils::GetCrossDocParentFrame(f);
}
return false;
}
// Removes any display items that belonged to a frame that was deleted,
// and mark frames that belong to a different AGR so that get their
// items built again.
// TODO: We currently descend into all children even if we don't have an AGR
// to mark, as child stacking contexts might. It would be nice if we could
// jump into those immediately rather than walking the entire thing.
void
RetainedDisplayListBuilder::PreProcessDisplayList(nsDisplayList* aList,
AnimatedGeometryRoot* aAGR)
{
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nsDisplayList saved;
while (nsDisplayItem* i = aList->RemoveBottom()) {
if (i->HasDeletedFrame() || !i->CanBeReused()) {
i->Destroy(&mBuilder);
continue;
}
nsIFrame* f = i->Frame();
if (i->GetChildren()) {
AnimatedGeometryRoot *childAGR = aAGR;
if (f->IsStackingContext()) {
if (f->HasOverrideDirtyRegion()) {
nsDisplayListBuilder::DisplayListBuildingData* data =
f->GetProperty(nsDisplayListBuilder::DisplayListBuildingRect());
if (data) {
childAGR = data->mModifiedAGR;
}
} else {
childAGR = nullptr;
}
}
PreProcessDisplayList(i->GetChildren(), childAGR);
}
// TODO: We should be able to check the clipped bounds relative
// to the common AGR (of both the existing item and the invalidated
// frame) and determine if they can ever intersect.
if (aAGR && i->GetAnimatedGeometryRoot()->GetAsyncAGR() != aAGR) {
mBuilder.MarkFrameForDisplayIfVisible(f, mBuilder.RootReferenceFrame());
}
// TODO: This is here because we sometimes reuse the previous display list
// completely. For optimization, we could only restore the state for reused
// display items.
i->RestoreState();
saved.AppendToTop(i);
}
aList->AppendToTop(&saved);
aList->RestoreState();
}
bool IsSameItem(nsDisplayItem* aFirst, nsDisplayItem* aSecond)
{
return aFirst->Frame() == aSecond->Frame() &&
aFirst->GetPerFrameKey() == aSecond->GetPerFrameKey();
}
struct DisplayItemKey
{
bool operator ==(const DisplayItemKey& aOther) const {
return mFrame == aOther.mFrame &&
mPerFrameKey == aOther.mPerFrameKey;
}
nsIFrame* mFrame;
uint32_t mPerFrameKey;
};
class DisplayItemHashEntry : public PLDHashEntryHdr
{
public:
typedef DisplayItemKey KeyType;
typedef const DisplayItemKey* KeyTypePointer;
explicit DisplayItemHashEntry(KeyTypePointer aKey)
: mKey(*aKey) {}
explicit DisplayItemHashEntry(const DisplayItemHashEntry& aCopy)=default;
~DisplayItemHashEntry() = default;
KeyType GetKey() const { return mKey; }
bool KeyEquals(KeyTypePointer aKey) const
{
return mKey == *aKey;
}
static KeyTypePointer KeyToPointer(KeyType& aKey) { return &aKey; }
static PLDHashNumber HashKey(KeyTypePointer aKey)
{
if (!aKey)
return 0;
return mozilla::HashGeneric(aKey->mFrame, aKey->mPerFrameKey);
}
enum { ALLOW_MEMMOVE = true };
DisplayItemKey mKey;
};
template<typename T>
void SwapAndRemove(nsTArray<T>& aArray, uint32_t aIndex)
{
if (aIndex != (aArray.Length() - 1)) {
T last = aArray.LastElement();
aArray.LastElement() = aArray[aIndex];
aArray[aIndex] = last;
}
aArray.RemoveElementAt(aArray.Length() - 1);
}
static void
MergeFrameRects(nsDisplayLayerEventRegions* aOldItem,
nsDisplayLayerEventRegions* aNewItem,
nsDisplayLayerEventRegions::FrameRects nsDisplayLayerEventRegions::*aRectList,
nsTArray<nsIFrame*>& aAddedFrames)
{
// Go through the old item's rect list and remove any rectangles
// belonging to invalidated frames (deleted frames should
// already be gone at this point)
nsDisplayLayerEventRegions::FrameRects& oldRects = aOldItem->*aRectList;
uint32_t i = 0;
while (i < oldRects.mFrames.Length()) {
// TODO: As mentioned in nsDisplayLayerEventRegions, this
// operation might perform really poorly on a vector.
nsIFrame* f = oldRects.mFrames[i];
if (IsAnyAncestorModified(f)) {
MOZ_ASSERT(f != aOldItem->Frame());
f->RemoveDisplayItem(aOldItem);
SwapAndRemove(oldRects.mFrames, i);
SwapAndRemove(oldRects.mBoxes, i);
} else {
i++;
}
}
if (!aNewItem) {
return;
}
// Copy items from the source list to the dest list, but
// only if the dest doesn't already include them.
nsDisplayItem* destItem = aOldItem;
nsDisplayLayerEventRegions::FrameRects* destRects = &(aOldItem->*aRectList);
nsDisplayLayerEventRegions::FrameRects* srcRects = &(aNewItem->*aRectList);
for (uint32_t i = 0; i < srcRects->mFrames.Length(); i++) {
nsIFrame* f = srcRects->mFrames[i];
if (!f->HasDisplayItem(destItem)) {
// If this frame isn't already in the destination item,
// then add it!
destRects->Add(f, srcRects->mBoxes[i]);
// We also need to update RealDisplayItemData for 'f',
// but that'll mess up this check for the following
// FrameRects lists, so defer that until the end.
aAddedFrames.AppendElement(f);
MOZ_ASSERT(f != aOldItem->Frame());
}
}
}
void MergeLayerEventRegions(nsDisplayItem* aOldItem,
nsDisplayItem* aNewItem)
{
nsDisplayLayerEventRegions* oldItem =
static_cast<nsDisplayLayerEventRegions*>(aOldItem);
nsDisplayLayerEventRegions* newItem =
static_cast<nsDisplayLayerEventRegions*>(aNewItem);
nsTArray<nsIFrame*> addedFrames;
MergeFrameRects(oldItem, newItem, &nsDisplayLayerEventRegions::mHitRegion, addedFrames);
MergeFrameRects(oldItem, newItem, &nsDisplayLayerEventRegions::mMaybeHitRegion, addedFrames);
MergeFrameRects(oldItem, newItem, &nsDisplayLayerEventRegions::mDispatchToContentHitRegion, addedFrames);
MergeFrameRects(oldItem, newItem, &nsDisplayLayerEventRegions::mNoActionRegion, addedFrames);
MergeFrameRects(oldItem, newItem, &nsDisplayLayerEventRegions::mHorizontalPanRegion, addedFrames);
MergeFrameRects(oldItem, newItem, &nsDisplayLayerEventRegions::mVerticalPanRegion, addedFrames);
// MergeFrameRects deferred updating the display item data list during
// processing so that earlier calls didn't change the result of later
// ones. Fix that up now.
for (nsIFrame* f : addedFrames) {
if (!f->HasDisplayItem(aOldItem)) {
f->AddDisplayItem(aOldItem);
}
}
}
void
RetainedDisplayListBuilder::IncrementSubDocPresShellPaintCount(nsDisplayItem* aItem)
{
MOZ_ASSERT(aItem->GetType() == DisplayItemType::TYPE_SUBDOCUMENT);
nsSubDocumentFrame* subDocFrame =
static_cast<nsDisplaySubDocument*>(aItem)->SubDocumentFrame();
MOZ_ASSERT(subDocFrame);
nsIPresShell* presShell = subDocFrame->GetSubdocumentPresShellForPainting(0);
MOZ_ASSERT(presShell);
mBuilder.IncrementPresShellPaintCount(presShell);
}
void UpdateASR(nsDisplayItem* aItem,
Maybe<const ActiveScrolledRoot*>& aContainerASR)
{
if (!aContainerASR) {
return;
}
nsDisplayWrapList* wrapList = aItem->AsDisplayWrapList();
if (!wrapList) {
aItem->SetActiveScrolledRoot(aContainerASR.value());
return;
}
wrapList->SetActiveScrolledRoot(
ActiveScrolledRoot::PickAncestor(wrapList->GetFrameActiveScrolledRoot(),
aContainerASR.value()));
}
/**
* Takes two display lists and merges them into an output list.
*
* The basic algorithm is:
*
* For-each item i in the new list:
* If the item has a matching item in the old list:
* Remove items from the start of the old list up until we reach an item that also exists in the new list (leaving the matched item in place):
* Add valid items to the merged list, destroy invalid items.
* Add i into the merged list.
* If the start of the old list matches i, remove and destroy it, otherwise mark the old version of i as used.
* Add all remaining valid items from the old list into the merged list, skipping over (and destroying) any that are marked as used.
*
* If any item has a child display list, then we recurse into the merge
* algorithm once we match up the new/old versions (if present).
*
* Example 1:
*
* Old List: A,B,C,D
* Modified List: A,D
* Invalidations: C,D
*
* We first match the A items, and add the new one to the merged list.
* We then match the D items, copy B into the merged list, but not C
* (since it's invalid). We then add the new D to the list and we're
* finished.
*
* Merged List: A,B,D
*
* Example 2 (layout/reftests/retained-dl-zindex-1.html):
*
* Old List: A, B
* Modified List: B, A
* Invalidations: A
*
* In this example A has been explicitly moved to the back.
*
* We match the B items, but don't copy A since it's invalid, and then add the
* new B into the merged list. We then add A, and we're done.
*
* Merged List: B, A
*
* Example 3:
*
* Old List: A, B
* Modified List: B, A
* Invalidations: -
*
* This can happen because a prior merge might have changed the ordering
* for non-intersecting items.
*
* We match the B items, but don't copy A since it's also present in the new list
* and then add the new B into the merged list. We then add A, and we're done.
*
* Merged List: B, A
*
* Example 4 (layout/reftests/retained-dl-zindex-2.html):
*
* Element A has two elements covering it (B and C), that don't intersect each
* other. We then move C to the back.
*
* The correct initial ordering has B and C after A, in any order.
*
* Old List: A, B, C
* Modified List: C, A
* Invalidations: C
*
* We match the C items, but don't add anything from the old list because A is present
* in both lists. We add C to the merged list, and mark the old version of C as reused.
*
* We then match A, add the new version the merged list and delete the old version.
*
* We then process the remainder of the old list, B is added (since it is valid,
* and hasn't been mark as reused), C is destroyed since it's marked as reused and
* is already present in the merged list.
*
* Merged List: C, A, B
*/
void
RetainedDisplayListBuilder::MergeDisplayLists(nsDisplayList* aNewList,
nsDisplayList* aOldList,
nsDisplayList* aOutList,
Maybe<const ActiveScrolledRoot*>& aOutContainerASR)
{
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nsDisplayList merged;
const auto UseItem = [&](nsDisplayItem* aItem) {
const ActiveScrolledRoot* itemClipASR =
aItem->GetClipChain() ? aItem->GetClipChain()->mASR : nullptr;
const ActiveScrolledRoot* finiteBoundsASR = ActiveScrolledRoot::PickDescendant(
itemClipASR, aItem->GetActiveScrolledRoot());
if (!aOutContainerASR) {
aOutContainerASR = Some(finiteBoundsASR);
} else {
aOutContainerASR =
Some(ActiveScrolledRoot::PickAncestor(aOutContainerASR.value(), finiteBoundsASR));
}
merged.AppendToTop(aItem);
};
const auto ReuseItem = [&](nsDisplayItem* aItem) {
UseItem(aItem);
aItem->SetReused(true);
if (aItem->GetType() == DisplayItemType::TYPE_SUBDOCUMENT) {
IncrementSubDocPresShellPaintCount(aItem);
}
};
// Build a hashtable of items in the old list so we can look for them quickly.
// We have similar data in the nsIFrame DisplayItems() property, but it doesn't
// know which display list items are in, and we only want to match items in
// this list.
nsDataHashtable<DisplayItemHashEntry, nsDisplayItem*> oldListLookup(aOldList->Count());
for (nsDisplayItem* i = aOldList->GetBottom(); i != nullptr; i = i->GetAbove()) {
i->SetReused(false);
if (!aNewList->IsEmpty()) {
oldListLookup.Put({ i->Frame(), i->GetPerFrameKey() }, i);
}
}
nsDataHashtable<DisplayItemHashEntry, nsDisplayItem*> newListLookup(aNewList->Count());
for (nsDisplayItem* i = aNewList->GetBottom(); i != nullptr; i = i->GetAbove()) {
#ifdef DEBUG
if (newListLookup.Get({ i->Frame(), i->GetPerFrameKey() }, nullptr)) {
MOZ_CRASH_UNSAFE_PRINTF("Duplicate display items detected!: %s(0x%p) type=%d key=%d",
i->Name(), i->Frame(),
static_cast<int>(i->GetType()), i->GetPerFrameKey());
}
#endif
newListLookup.Put({ i->Frame(), i->GetPerFrameKey() }, i);
}
while (nsDisplayItem* newItem = aNewList->RemoveBottom()) {
if (nsDisplayItem* oldItem = oldListLookup.Get({ newItem->Frame(), newItem->GetPerFrameKey() })) {
// The new item has a matching counterpart in the old list that we haven't yet reached,
// so copy all valid items from the old list into the merged list until we get to the
// matched item.
nsDisplayItem* old = nullptr;
while ((old = aOldList->GetBottom()) && old != oldItem) {
if (IsAnyAncestorModified(old->FrameForInvalidation())) {
// The old item is invalid, discard it.
oldListLookup.Remove({ old->Frame(), old->GetPerFrameKey() });
aOldList->RemoveBottom();
old->Destroy(&mBuilder);
} else if (newListLookup.Get({ old->Frame(), old->GetPerFrameKey() })) {
// This old item is also in the new list, but we haven't got to it yet.
// Stop now, and we'll deal with it when we get to the new entry.
break;
} else {
// Recurse into the child list (without a matching new list) to
// ensure that we find and remove any invalidated items.
if (old->GetChildren()) {
nsDisplayList empty;
Maybe<const ActiveScrolledRoot*> containerASRForChildren;
MergeDisplayLists(&empty, old->GetChildren(),
old->GetChildren(), containerASRForChildren);
UpdateASR(old, containerASRForChildren);
old->UpdateBounds(&mBuilder);
}
aOldList->RemoveBottom();
ReuseItem(old);
}
}
bool destroy = false;
if (old == oldItem) {
// If we advanced the old list until the matching item then we can pop
// the matching item off the old list and make sure we clean it up.
aOldList->RemoveBottom();
destroy = true;
} else {
// If we didn't get to the matching item, then mark the old item
// as being reused (since we're adding the new version to the new
// list now) so that we don't add it twice at the end.
oldItem->SetReused(true);
}
// Recursively merge any child lists, destroy the old item and add
// the new one to the list.
if (!destroy &&
oldItem->GetType() == DisplayItemType::TYPE_LAYER_EVENT_REGIONS &&
!IsAnyAncestorModified(oldItem->FrameForInvalidation())) {
// Event regions items don't have anything interesting other than
// the lists of regions and frames, so we have no need to use the
// newer item. Always use the old item instead since we assume it's
// likely to have the bigger lists and merging will be quicker.
MergeLayerEventRegions(oldItem, newItem);
ReuseItem(oldItem);
newItem->Destroy(&mBuilder);
} else {
if (!IsAnyAncestorModified(oldItem->FrameForInvalidation()) &&
oldItem->GetChildren()) {
MOZ_ASSERT(newItem->GetChildren());
Maybe<const ActiveScrolledRoot*> containerASRForChildren;
MergeDisplayLists(newItem->GetChildren(), oldItem->GetChildren(),
newItem->GetChildren(), containerASRForChildren);
UpdateASR(newItem, containerASRForChildren);
newItem->UpdateBounds(&mBuilder);
}
if (destroy) {
oldItem->Destroy(&mBuilder);
}
UseItem(newItem);
}
} else {
// If there was no matching item in the old list, then we only need to
// add the new item to the merged list.
UseItem(newItem);
}
}
// Reuse the remaining valid items from the old display list.
while (nsDisplayItem* old = aOldList->RemoveBottom()) {
if (!IsAnyAncestorModified(old->FrameForInvalidation()) &&
!old->IsReused()) {
if (old->GetChildren()) {
// We are calling MergeDisplayLists() to ensure that the display items
// with modified or deleted children will be correctly handled.
// Passing an empty new display list as an argument skips the merging
// loop above and jumps back here.
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nsDisplayList empty;
Maybe<const ActiveScrolledRoot*> containerASRForChildren;
MergeDisplayLists(&empty, old->GetChildren(),
old->GetChildren(), containerASRForChildren);
UpdateASR(old, containerASRForChildren);
old->UpdateBounds(&mBuilder);
}
if (old->GetType() == DisplayItemType::TYPE_LAYER_EVENT_REGIONS) {
MergeLayerEventRegions(old, nullptr);
}
ReuseItem(old);
} else {
old->Destroy(&mBuilder);
}
}
aOutList->AppendToTop(&merged);
}
static void
TakeAndAddModifiedFramesFromRootFrame(nsTArray<nsIFrame*>& aFrames,
nsIFrame* aRootFrame)
{
MOZ_ASSERT(aRootFrame);
nsTArray<nsIFrame*>* frames =
aRootFrame->GetProperty(nsIFrame::ModifiedFrameList());
if (!frames) {
return;
}
for (nsIFrame* f : *frames) {
if (f) {
aFrames.AppendElement(f);
}
}
frames->Clear();
}
struct CbData {
nsDisplayListBuilder* builder;
nsTArray<nsIFrame*> modifiedFrames;
};
static bool
SubDocEnumCb(nsIDocument* aDocument, void* aData)
{
MOZ_ASSERT(aDocument);
MOZ_ASSERT(aData);
CbData* data = static_cast<CbData*>(aData);
// Although this is the actual subdocument, it might not be
// what painting uses. Walk up to the nsSubDocumentFrame owning
// us, and then ask that which subdoc it's going to paint.
nsIPresShell* presShell = aDocument->GetShell();
if (presShell) {
nsView* rootView = presShell->GetViewManager()->GetRootView();
MOZ_ASSERT(rootView);
// There should be an anonymous inner view between the root view
// of the subdoc, and the view for the nsSubDocumentFrame.
nsView* innerView = rootView->GetParent();
MOZ_ASSERT(innerView);
nsView* subDocView = innerView->GetParent();
MOZ_ASSERT(subDocView);
nsIFrame* subDocFrame = subDocView->GetFrame();
if (subDocFrame) {
nsSubDocumentFrame* subdocumentFrame = do_QueryFrame(subDocFrame);
MOZ_ASSERT(subdocumentFrame);
presShell = subdocumentFrame->GetSubdocumentPresShellForPainting(
data->builder->IsIgnoringPaintSuppression() ? nsSubDocumentFrame::IGNORE_PAINT_SUPPRESSION : 0);
nsIFrame* rootFrame = presShell ? presShell->GetRootFrame() : nullptr;
if (rootFrame) {
TakeAndAddModifiedFramesFromRootFrame(data->modifiedFrames, rootFrame);
}
}
}
aDocument->EnumerateSubDocuments(SubDocEnumCb, aData);
return true;
}
static nsTArray<nsIFrame*>
GetModifiedFrames(nsDisplayListBuilder* aBuilder)
{
MOZ_ASSERT(aBuilder->RootReferenceFrame());
CbData data;
data.builder = aBuilder;
TakeAndAddModifiedFramesFromRootFrame(data.modifiedFrames, aBuilder->RootReferenceFrame());
nsIDocument* rootdoc = aBuilder->RootReferenceFrame()->PresContext()->Document();
if (rootdoc) {
rootdoc->EnumerateSubDocuments(SubDocEnumCb, &data);
}
return Move(data.modifiedFrames);
}
// ComputeRebuildRegion debugging
// #define CRR_DEBUG 1
#if CRR_DEBUG
# define CRR_LOG(...) printf_stderr(__VA_ARGS__)
#else
# define CRR_LOG(...)
#endif
/**
* Given a list of frames that has been modified, computes the region that we need to
* do display list building for in order to build all modified display items.
*
* When a modified frame is within a stacking context (with an existing display item),
* then we only contribute to the build area within the stacking context, as well as forcing
* display list building to descend to the stacking context. We don't need to add build
* area outside of the stacking context (and force items above/below the stacking context
* container item to be built), since just matching the position of the stacking context
* container item is sufficient to ensure correct ordering during merging.
*
* We need to rebuild all items that might intersect with the modified frame, both now
* and during async changes on the compositor. We do this by rebuilding the area covered
* by the changed frame, as well as rebuilding all items that have a different (async)
* AGR to the changed frame. If we have changes to multiple AGRs (within a stacking
* context), then we rebuild that stacking context entirely.
*
* @param aModifiedFrames The list of modified frames.
* @param aOutDirty The result region to use for display list building.
* @param aOutModifiedAGR The modified AGR for the root stacking context.
* @param aOutFramesWithProps The list of frames to which we attached partial build
* data so that it can be cleaned up.
*
* @return true if we succesfully computed a partial rebuild region, false if a full
* build is required.
*/
bool
RetainedDisplayListBuilder::ComputeRebuildRegion(nsTArray<nsIFrame*>& aModifiedFrames,
nsRect* aOutDirty,
AnimatedGeometryRoot** aOutModifiedAGR,
nsTArray<nsIFrame*>* aOutFramesWithProps)
{
CRR_LOG("Computing rebuild regions for %d frames:\n", aModifiedFrames.size());
for (nsIFrame* f : aModifiedFrames) {
MOZ_ASSERT(f);
if (f->HasOverrideDirtyRegion()) {
aOutFramesWithProps->AppendElement(f);
}
if (f->HasAnyStateBits(NS_FRAME_IN_POPUP)) {
continue;
}
// TODO: There is almost certainly a faster way of doing this, probably can be combined with the ancestor
// walk for TransformFrameRectToAncestor.
AnimatedGeometryRoot* agr = mBuilder.FindAnimatedGeometryRootFor(f)->GetAsyncAGR();
CRR_LOG("Processing frame %p with agr %p\n", f, agr->mFrame);
// Convert the frame's overflow rect into the coordinate space
// of the nearest stacking context that has an existing display item.
// We store that as a dirty rect on that stacking context so that we build
// all items that intersect the changed frame within the stacking context,
// and then we use MarkFrameForDisplayIfVisible to make sure the stacking
// context itself gets built. We don't need to build items that intersect outside
// of the stacking context, since we know the stacking context item exists in
// the old list, so we can trivially merge without needing other items.
nsRect overflow = f->GetVisualOverflowRectRelativeToSelf();
nsIFrame* currentFrame = f;
while (currentFrame != mBuilder.RootReferenceFrame()) {
// Preserve-3d frames don't have valid overflow areas, and they might
// have singular transforms (despite still being visible when combined
// with their ancestors). If we're at one, jump up to the root of the
// preserve-3d context and use the whole overflow area.
nsIFrame* last = currentFrame;
while (currentFrame->Extend3DContext() ||
currentFrame->Combines3DTransformWithAncestors()) {
last = currentFrame;
currentFrame = currentFrame->GetParent();
}
if (last != currentFrame) {
overflow = last->GetVisualOverflowRectRelativeToParent();
}
// Convert 'overflow' into the coordinate space of the nearest stacking context
// or display port ancestor and update 'currentFrame' to point to that frame.
overflow = nsLayoutUtils::TransformFrameRectToAncestor(currentFrame, overflow, mBuilder.RootReferenceFrame(),
nullptr, nullptr,
/* aStopAtStackingContextAndDisplayPort = */ true,
&currentFrame);
MOZ_ASSERT(currentFrame);
if (nsLayoutUtils::FrameHasDisplayPort(currentFrame)) {
CRR_LOG("Frame belongs to displayport frame %p\n", currentFrame);
nsIScrollableFrame* sf = do_QueryFrame(currentFrame);
MOZ_ASSERT(sf);
nsRect displayPort;
DebugOnly<bool> hasDisplayPort =
nsLayoutUtils::GetDisplayPort(currentFrame->GetContent(), &displayPort, RelativeTo::ScrollPort);
MOZ_ASSERT(hasDisplayPort);
// get it relative to the scrollport (from the scrollframe)
nsRect r = overflow - sf->GetScrollPortRect().TopLeft();
r.IntersectRect(r, displayPort);
if (!r.IsEmpty()) {
nsRect* rect =
currentFrame->GetProperty(nsDisplayListBuilder::DisplayListBuildingDisplayPortRect());
if (!rect) {
rect = new nsRect();
currentFrame->SetProperty(nsDisplayListBuilder::DisplayListBuildingDisplayPortRect(), rect);
currentFrame->SetHasOverrideDirtyRegion(true);
}
rect->UnionRect(*rect, r);
aOutFramesWithProps->AppendElement(currentFrame);
CRR_LOG("Adding area to displayport draw area: %d %d %d %d\n", r.x, r.y, r.width, r.height);
// TODO: Can we just use MarkFrameForDisplayIfVisible, plus MarkFramesForDifferentAGR to
// ensure that this displayport, plus any items that move relative to it get rebuilt,
// and then not contribute to the root dirty area?
overflow = sf->GetScrollPortRect();
} else {
// Don't contribute to the root dirty area at all.
overflow.SetEmpty();
break;
}
}
if (currentFrame->IsStackingContext()) {
CRR_LOG("Frame belongs to stacking context frame %p\n", currentFrame);
// If we found an intermediate stacking context with an existing display item
// then we can store the dirty rect there and stop. If we couldn't find one then
// we need to keep bubbling up to the next stacking context.
if (currentFrame != mBuilder.RootReferenceFrame() &&
currentFrame->HasDisplayItems()) {
mBuilder.MarkFrameForDisplayIfVisible(currentFrame, mBuilder.RootReferenceFrame());
// Store the stacking context relative dirty area such
// that display list building will pick it up when it
// gets to it.
nsDisplayListBuilder::DisplayListBuildingData* data =
currentFrame->GetProperty(nsDisplayListBuilder::DisplayListBuildingRect());
if (!data) {
data = new nsDisplayListBuilder::DisplayListBuildingData;
currentFrame->SetProperty(nsDisplayListBuilder::DisplayListBuildingRect(), data);
currentFrame->SetHasOverrideDirtyRegion(true);
aOutFramesWithProps->AppendElement(currentFrame);
}
data->mDirtyRect.UnionRect(data->mDirtyRect, overflow);
CRR_LOG("Adding area to stacking context draw area: %d %d %d %d\n",
overflow.x, overflow.y, overflow.width, overflow.height);
if (!data->mModifiedAGR) {
data->mModifiedAGR = agr;
} else if (data->mModifiedAGR != agr) {
data->mDirtyRect = currentFrame->GetVisualOverflowRectRelativeToSelf();
CRR_LOG("Found multiple modified AGRs within this stacking context, giving up\n");
}
// Don't contribute to the root dirty area at all.
agr = nullptr;
overflow.SetEmpty();
break;
}
}
}
aOutDirty->UnionRect(*aOutDirty, overflow);
CRR_LOG("Adding area to root draw area: %d %d %d %d\n", overflow.x, overflow.y, overflow.width, overflow.height);
// If we get changed frames from multiple AGRS, then just give up as it gets really complex to
// track which items would need to be marked in MarkFramesForDifferentAGR.
if (!*aOutModifiedAGR) {
*aOutModifiedAGR = agr;
} else if (agr && *aOutModifiedAGR != agr) {
CRR_LOG("Found multiple AGRs in root stacking context, giving up\n");
return false;
}
}
return true;
}
/*
* A simple early exit heuristic to avoid slow partial display list rebuilds.
*/
static bool
ShouldBuildPartial(nsTArray<nsIFrame*>& aModifiedFrames)
{
if (aModifiedFrames.Length() > gfxPrefs::LayoutRebuildFrameLimit()) {
return false;
}
for (nsIFrame* f : aModifiedFrames) {
MOZ_ASSERT(f);
const LayoutFrameType type = f->Type();
// If we have any modified frames of the following types, it is likely that
// doing a partial rebuild of the display list will be slower than doing a
// full rebuild.
// This is because these frames either intersect or may intersect with most
// of the page content. This is either due to display port size or different
// async AGR.
if (type == LayoutFrameType::Viewport ||
type == LayoutFrameType::PageContent ||
type == LayoutFrameType::Canvas ||
type == LayoutFrameType::Scrollbar) {
return false;
}
}
return true;
}
static void
ClearFrameProps(nsTArray<nsIFrame*>& aFrames)
{
for (nsIFrame* f : aFrames) {
if (f->HasOverrideDirtyRegion()) {
f->SetHasOverrideDirtyRegion(false);
f->DeleteProperty(nsDisplayListBuilder::DisplayListBuildingRect());
f->DeleteProperty(nsDisplayListBuilder::DisplayListBuildingDisplayPortRect());
}
f->SetFrameIsModified(false);
}
}
void
RetainedDisplayListBuilder::ClearModifiedFrameProps()
{
nsTArray<nsIFrame*> modifiedFrames =
GetModifiedFrames(&mBuilder);
ClearFrameProps(modifiedFrames);
}
bool
RetainedDisplayListBuilder::AttemptPartialUpdate(nscolor aBackstop)
{
mBuilder.RemoveModifiedWindowDraggingRegion();
if (mBuilder.ShouldSyncDecodeImages()) {
MarkFramesWithItemsAndImagesModified(&mList);
}
mBuilder.EnterPresShell(mBuilder.RootReferenceFrame());
nsTArray<nsIFrame*> modifiedFrames =
GetModifiedFrames(&mBuilder);
// Do not allow partial builds if the retained display list is empty, or if
// ShouldBuildPartial heuristic fails.
const bool shouldBuildPartial = !mList.IsEmpty() && ShouldBuildPartial(modifiedFrames);
if (mPreviousCaret != mBuilder.GetCaretFrame()) {
if (mPreviousCaret) {
if (mBuilder.MarkFrameModifiedDuringBuilding(mPreviousCaret)) {
modifiedFrames.AppendElement(mPreviousCaret);
}
}
if (mBuilder.GetCaretFrame()) {
if (mBuilder.MarkFrameModifiedDuringBuilding(mBuilder.GetCaretFrame())) {
modifiedFrames.AppendElement(mBuilder.GetCaretFrame());
}
}
mPreviousCaret = mBuilder.GetCaretFrame();
}
nsRect modifiedDirty;
AnimatedGeometryRoot* modifiedAGR = nullptr;
nsTArray<nsIFrame*> framesWithProps;
bool merged = false;
if (shouldBuildPartial &&
ComputeRebuildRegion(modifiedFrames, &modifiedDirty,
&modifiedAGR, &framesWithProps)) {
modifiedDirty.IntersectRect(modifiedDirty, mBuilder.RootReferenceFrame()->GetVisualOverflowRectRelativeToSelf());
PreProcessDisplayList(&mList, modifiedAGR);
2017-11-16 06:09:28 +03:00
nsDisplayList modifiedDL;
if (!modifiedDirty.IsEmpty() || !framesWithProps.IsEmpty()) {
mBuilder.SetDirtyRect(modifiedDirty);
mBuilder.SetPartialUpdate(true);
mBuilder.RootReferenceFrame()->BuildDisplayListForStackingContext(&mBuilder, &modifiedDL);
nsLayoutUtils::AddExtraBackgroundItems(mBuilder, modifiedDL, mBuilder.RootReferenceFrame(),
nsRect(nsPoint(0, 0), mBuilder.RootReferenceFrame()->GetSize()),
mBuilder.RootReferenceFrame()->GetVisualOverflowRectRelativeToSelf(),
aBackstop);
mBuilder.SetPartialUpdate(false);
//printf_stderr("Painting --- Modified list (dirty %d,%d,%d,%d):\n",
// modifiedDirty.x, modifiedDirty.y, modifiedDirty.width, modifiedDirty.height);
//nsFrame::PrintDisplayList(&mBuilder, modifiedDL);
} else {
// TODO: We can also skip layer building and painting if
// PreProcessDisplayList didn't end up changing anything
// Invariant: display items should have their original state here.
// printf_stderr("Skipping display list building since nothing needed to be done\n");
}
// |modifiedDL| can sometimes be empty here. We still perform the
// display list merging to prune unused items (for example, items that
// are not visible anymore) from the old list.
// TODO: Optimization opportunity. In this case, MergeDisplayLists()
// unnecessarily creates a hashtable of the old items.
Maybe<const ActiveScrolledRoot*> dummy;
MergeDisplayLists(&modifiedDL, &mList, &mList, dummy);
//printf_stderr("Painting --- Merged list:\n");
//nsFrame::PrintDisplayList(&mBuilder, mList);
merged = true;
}
mBuilder.LeavePresShell(mBuilder.RootReferenceFrame(), &mList);
// We set the override dirty regions during ComputeRebuildRegion or in
// nsLayoutUtils::InvalidateForDisplayPortChange. The display port change also
// marks the frame modified, so those regions are cleared here as well.
ClearFrameProps(modifiedFrames);
ClearFrameProps(framesWithProps);
return merged;
}