/* -*- Mode: C++; tab-width: 2; 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/. */ /* state and methods used while laying out a single line of a block frame */ // This has to be defined before nsLineLayout.h is included, because // nsLineLayout.h has a #include for plarena.h, which needs this defined: #define PL_ARENA_CONST_ALIGN_MASK (sizeof(void*)-1) #include "nsLineLayout.h" #include "LayoutLogging.h" #include "SVGTextFrame.h" #include "nsBlockFrame.h" #include "nsFontMetrics.h" #include "nsStyleConsts.h" #include "nsContainerFrame.h" #include "nsFloatManager.h" #include "nsStyleContext.h" #include "nsPresContext.h" #include "nsGkAtoms.h" #include "nsIContent.h" #include "nsLayoutUtils.h" #include "nsTextFrame.h" #include "nsStyleStructInlines.h" #include "nsBidiPresUtils.h" #include "nsRubyFrame.h" #include "nsRubyTextFrame.h" #include "RubyUtils.h" #include <algorithm> #ifdef DEBUG #undef NOISY_INLINEDIR_ALIGN #undef NOISY_BLOCKDIR_ALIGN #undef NOISY_REFLOW #undef REALLY_NOISY_REFLOW #undef NOISY_PUSHING #undef REALLY_NOISY_PUSHING #undef NOISY_CAN_PLACE_FRAME #undef NOISY_TRIM #undef REALLY_NOISY_TRIM #endif using namespace mozilla; //---------------------------------------------------------------------- #define FIX_BUG_50257 nsLineLayout::nsLineLayout(nsPresContext* aPresContext, nsFloatManager* aFloatManager, const ReflowInput* aOuterReflowInput, const nsLineList::iterator* aLine, nsLineLayout* aBaseLineLayout) : mPresContext(aPresContext), mFloatManager(aFloatManager), mBlockReflowInput(aOuterReflowInput), mBaseLineLayout(aBaseLineLayout), mLastOptionalBreakFrame(nullptr), mForceBreakFrame(nullptr), mBlockRI(nullptr),/* XXX temporary */ mLastOptionalBreakPriority(gfxBreakPriority::eNoBreak), mLastOptionalBreakFrameOffset(-1), mForceBreakFrameOffset(-1), mMinLineBSize(0), mTextIndent(0), mFirstLetterStyleOK(false), mIsTopOfPage(false), mImpactedByFloats(false), mLastFloatWasLetterFrame(false), mLineIsEmpty(false), mLineEndsInBR(false), mNeedBackup(false), mInFirstLine(false), mGotLineBox(false), mInFirstLetter(false), mHasBullet(false), mDirtyNextLine(false), mLineAtStart(false), mHasRuby(false), mSuppressLineWrap(aOuterReflowInput->mFrame->IsSVGText()) { MOZ_ASSERT(aOuterReflowInput, "aOuterReflowInput must not be null"); NS_ASSERTION(aFloatManager || aOuterReflowInput->mFrame->GetType() == nsGkAtoms::letterFrame, "float manager should be present"); MOZ_ASSERT((!!mBaseLineLayout) == (aOuterReflowInput->mFrame->GetType() == nsGkAtoms::rubyTextContainerFrame), "Only ruby text container frames have " "a different base line layout"); MOZ_COUNT_CTOR(nsLineLayout); // Stash away some style data that we need nsBlockFrame* blockFrame = do_QueryFrame(aOuterReflowInput->mFrame); if (blockFrame) mStyleText = blockFrame->StyleTextForLineLayout(); else mStyleText = aOuterReflowInput->mFrame->StyleText(); mLineNumber = 0; mTotalPlacedFrames = 0; mBStartEdge = 0; mTrimmableISize = 0; mInflationMinFontSize = nsLayoutUtils::InflationMinFontSizeFor(aOuterReflowInput->mFrame); // Instead of always pre-initializing the free-lists for frames and // spans, we do it on demand so that situations that only use a few // frames and spans won't waste a lot of time in unneeded // initialization. PL_INIT_ARENA_POOL(&mArena, "nsLineLayout", 1024); mFrameFreeList = nullptr; mSpanFreeList = nullptr; mCurrentSpan = mRootSpan = nullptr; mSpanDepth = 0; if (aLine) { mGotLineBox = true; mLineBox = *aLine; } } nsLineLayout::~nsLineLayout() { MOZ_COUNT_DTOR(nsLineLayout); NS_ASSERTION(nullptr == mRootSpan, "bad line-layout user"); PL_FinishArenaPool(&mArena); } // Find out if the frame has a non-null prev-in-flow, i.e., whether it // is a continuation. inline bool HasPrevInFlow(nsIFrame *aFrame) { nsIFrame *prevInFlow = aFrame->GetPrevInFlow(); return prevInFlow != nullptr; } void nsLineLayout::BeginLineReflow(nscoord aICoord, nscoord aBCoord, nscoord aISize, nscoord aBSize, bool aImpactedByFloats, bool aIsTopOfPage, WritingMode aWritingMode, const nsSize& aContainerSize) { NS_ASSERTION(nullptr == mRootSpan, "bad linelayout user"); LAYOUT_WARN_IF_FALSE(aISize != NS_UNCONSTRAINEDSIZE, "have unconstrained width; this should only result from " "very large sizes, not attempts at intrinsic width " "calculation"); #ifdef DEBUG if ((aISize != NS_UNCONSTRAINEDSIZE) && CRAZY_SIZE(aISize) && !LineContainerFrame()->GetParent()->IsCrazySizeAssertSuppressed()) { nsFrame::ListTag(stdout, mBlockReflowInput->mFrame); printf(": Init: bad caller: width WAS %d(0x%x)\n", aISize, aISize); } if ((aBSize != NS_UNCONSTRAINEDSIZE) && CRAZY_SIZE(aBSize) && !LineContainerFrame()->GetParent()->IsCrazySizeAssertSuppressed()) { nsFrame::ListTag(stdout, mBlockReflowInput->mFrame); printf(": Init: bad caller: height WAS %d(0x%x)\n", aBSize, aBSize); } #endif #ifdef NOISY_REFLOW nsFrame::ListTag(stdout, mBlockReflowInput->mFrame); printf(": BeginLineReflow: %d,%d,%d,%d impacted=%s %s\n", aICoord, aBCoord, aISize, aBSize, aImpactedByFloats?"true":"false", aIsTopOfPage ? "top-of-page" : ""); #endif #ifdef DEBUG mSpansAllocated = mSpansFreed = mFramesAllocated = mFramesFreed = 0; #endif mFirstLetterStyleOK = false; mIsTopOfPage = aIsTopOfPage; mImpactedByFloats = aImpactedByFloats; mTotalPlacedFrames = 0; if (!mBaseLineLayout) { mLineIsEmpty = true; mLineAtStart = true; } else { mLineIsEmpty = false; mLineAtStart = false; } mLineEndsInBR = false; mSpanDepth = 0; mMaxStartBoxBSize = mMaxEndBoxBSize = 0; if (mGotLineBox) { mLineBox->ClearHasBullet(); } PerSpanData* psd = NewPerSpanData(); mCurrentSpan = mRootSpan = psd; psd->mReflowInput = mBlockReflowInput; psd->mIStart = aICoord; psd->mICoord = aICoord; psd->mIEnd = aICoord + aISize; mContainerSize = aContainerSize; mBStartEdge = aBCoord; psd->mNoWrap = !mStyleText->WhiteSpaceCanWrapStyle() || mSuppressLineWrap; psd->mWritingMode = aWritingMode; // If this is the first line of a block then see if the text-indent // property amounts to anything. if (0 == mLineNumber && !HasPrevInFlow(mBlockReflowInput->mFrame)) { const nsStyleCoord &textIndent = mStyleText->mTextIndent; nscoord pctBasis = 0; if (textIndent.HasPercent()) { pctBasis = mBlockReflowInput->GetContainingBlockContentISize(aWritingMode); } nscoord indent = nsRuleNode::ComputeCoordPercentCalc(textIndent, pctBasis); mTextIndent = indent; psd->mICoord += indent; } PerFrameData* pfd = NewPerFrameData(mBlockReflowInput->mFrame); pfd->mAscent = 0; pfd->mSpan = psd; psd->mFrame = pfd; nsIFrame* frame = mBlockReflowInput->mFrame; if (frame->GetType() == nsGkAtoms::rubyTextContainerFrame) { // Ruby text container won't be reflowed via ReflowFrame, hence the // relative positioning information should be recorded here. MOZ_ASSERT(mBaseLineLayout != this); pfd->mRelativePos = mBlockReflowInput->mStyleDisplay->IsRelativelyPositionedStyle(); if (pfd->mRelativePos) { MOZ_ASSERT( mBlockReflowInput->GetWritingMode() == pfd->mWritingMode, "mBlockReflowInput->frame == frame, " "hence they should have identical writing mode"); pfd->mOffsets = mBlockReflowInput->ComputedLogicalOffsets(); } } } void nsLineLayout::EndLineReflow() { #ifdef NOISY_REFLOW nsFrame::ListTag(stdout, mBlockReflowInput->mFrame); printf(": EndLineReflow: width=%d\n", mRootSpan->mICoord - mRootSpan->mIStart); #endif NS_ASSERTION(!mBaseLineLayout || (!mSpansAllocated && !mSpansFreed && !mSpanFreeList && !mFramesAllocated && !mFramesFreed && !mFrameFreeList), "Allocated frames or spans on non-base line layout?"); UnlinkFrame(mRootSpan->mFrame); mCurrentSpan = mRootSpan = nullptr; NS_ASSERTION(mSpansAllocated == mSpansFreed, "leak"); NS_ASSERTION(mFramesAllocated == mFramesFreed, "leak"); #if 0 static int32_t maxSpansAllocated = NS_LINELAYOUT_NUM_SPANS; static int32_t maxFramesAllocated = NS_LINELAYOUT_NUM_FRAMES; if (mSpansAllocated > maxSpansAllocated) { printf("XXX: saw a line with %d spans\n", mSpansAllocated); maxSpansAllocated = mSpansAllocated; } if (mFramesAllocated > maxFramesAllocated) { printf("XXX: saw a line with %d frames\n", mFramesAllocated); maxFramesAllocated = mFramesAllocated; } #endif } // XXX swtich to a single mAvailLineWidth that we adjust as each frame // on the line is placed. Each span can still have a per-span mICoord that // tracks where a child frame is going in its span; they don't need a // per-span mIStart? void nsLineLayout::UpdateBand(WritingMode aWM, const LogicalRect& aNewAvailSpace, nsIFrame* aFloatFrame) { WritingMode lineWM = mRootSpan->mWritingMode; // need to convert to our writing mode, because we might have a different // mode from the caller due to dir: auto LogicalRect availSpace = aNewAvailSpace.ConvertTo(lineWM, aWM, ContainerSize()); #ifdef REALLY_NOISY_REFLOW printf("nsLL::UpdateBand %d, %d, %d, %d, (converted to %d, %d, %d, %d); frame=%p\n will set mImpacted to true\n", aNewAvailSpace.IStart(aWM), aNewAvailSpace.BStart(aWM), aNewAvailSpace.ISize(aWM), aNewAvailSpace.BSize(aWM), availSpace.IStart(lineWM), availSpace.BStart(lineWM), availSpace.ISize(lineWM), availSpace.BSize(lineWM), aFloatFrame); #endif #ifdef DEBUG if ((availSpace.ISize(lineWM) != NS_UNCONSTRAINEDSIZE) && CRAZY_SIZE(availSpace.ISize(lineWM)) && !LineContainerFrame()->GetParent()->IsCrazySizeAssertSuppressed()) { nsFrame::ListTag(stdout, mBlockReflowInput->mFrame); printf(": UpdateBand: bad caller: ISize WAS %d(0x%x)\n", availSpace.ISize(lineWM), availSpace.ISize(lineWM)); } if ((availSpace.BSize(lineWM) != NS_UNCONSTRAINEDSIZE) && CRAZY_SIZE(availSpace.BSize(lineWM)) && !LineContainerFrame()->GetParent()->IsCrazySizeAssertSuppressed()) { nsFrame::ListTag(stdout, mBlockReflowInput->mFrame); printf(": UpdateBand: bad caller: BSize WAS %d(0x%x)\n", availSpace.BSize(lineWM), availSpace.BSize(lineWM)); } #endif // Compute the difference between last times width and the new width NS_WARNING_ASSERTION( mRootSpan->mIEnd != NS_UNCONSTRAINEDSIZE && availSpace.ISize(lineWM) != NS_UNCONSTRAINEDSIZE, "have unconstrained inline size; this should only result from very large " "sizes, not attempts at intrinsic width calculation"); // The root span's mIStart moves to aICoord nscoord deltaICoord = availSpace.IStart(lineWM) - mRootSpan->mIStart; // The inline size of all spans changes by this much (the root span's // mIEnd moves to aICoord + aISize, its new inline size is aISize) nscoord deltaISize = availSpace.ISize(lineWM) - (mRootSpan->mIEnd - mRootSpan->mIStart); #ifdef NOISY_REFLOW nsFrame::ListTag(stdout, mBlockReflowInput->mFrame); printf(": UpdateBand: %d,%d,%d,%d deltaISize=%d deltaICoord=%d\n", availSpace.IStart(lineWM), availSpace.BStart(lineWM), availSpace.ISize(lineWM), availSpace.BSize(lineWM), deltaISize, deltaICoord); #endif // Update the root span position mRootSpan->mIStart += deltaICoord; mRootSpan->mIEnd += deltaICoord; mRootSpan->mICoord += deltaICoord; // Now update the right edges of the open spans to account for any // change in available space width for (PerSpanData* psd = mCurrentSpan; psd; psd = psd->mParent) { psd->mIEnd += deltaISize; psd->mContainsFloat = true; #ifdef NOISY_REFLOW printf(" span %p: oldIEnd=%d newIEnd=%d\n", psd, psd->mIEnd - deltaISize, psd->mIEnd); #endif } NS_ASSERTION(mRootSpan->mContainsFloat && mRootSpan->mIStart == availSpace.IStart(lineWM) && mRootSpan->mIEnd == availSpace.IEnd(lineWM), "root span was updated incorrectly?"); // Update frame bounds // Note: Only adjust the outermost frames (the ones that are direct // children of the block), not the ones in the child spans. The reason // is simple: the frames in the spans have coordinates local to their // parent therefore they are moved when their parent span is moved. if (deltaICoord != 0) { for (PerFrameData* pfd = mRootSpan->mFirstFrame; pfd; pfd = pfd->mNext) { pfd->mBounds.IStart(lineWM) += deltaICoord; } } mBStartEdge = availSpace.BStart(lineWM); mImpactedByFloats = true; mLastFloatWasLetterFrame = nsGkAtoms::letterFrame == aFloatFrame->GetType(); } nsLineLayout::PerSpanData* nsLineLayout::NewPerSpanData() { nsLineLayout* outerLineLayout = GetOutermostLineLayout(); PerSpanData* psd = outerLineLayout->mSpanFreeList; if (!psd) { void *mem; size_t sz = sizeof(PerSpanData); PL_ARENA_ALLOCATE(mem, &outerLineLayout->mArena, sz); if (!mem) { NS_ABORT_OOM(sz); } psd = reinterpret_cast<PerSpanData*>(mem); } else { outerLineLayout->mSpanFreeList = psd->mNextFreeSpan; } psd->mParent = nullptr; psd->mFrame = nullptr; psd->mFirstFrame = nullptr; psd->mLastFrame = nullptr; psd->mContainsFloat = false; psd->mHasNonemptyContent = false; #ifdef DEBUG outerLineLayout->mSpansAllocated++; #endif return psd; } void nsLineLayout::BeginSpan(nsIFrame* aFrame, const ReflowInput* aSpanReflowInput, nscoord aIStart, nscoord aIEnd, nscoord* aBaseline) { NS_ASSERTION(aIEnd != NS_UNCONSTRAINEDSIZE, "should no longer be using unconstrained sizes"); #ifdef NOISY_REFLOW nsFrame::IndentBy(stdout, mSpanDepth+1); nsFrame::ListTag(stdout, aFrame); printf(": BeginSpan leftEdge=%d rightEdge=%d\n", aIStart, aIEnd); #endif PerSpanData* psd = NewPerSpanData(); // Link up span frame's pfd to point to its child span data PerFrameData* pfd = mCurrentSpan->mLastFrame; NS_ASSERTION(pfd->mFrame == aFrame, "huh?"); pfd->mSpan = psd; // Init new span psd->mFrame = pfd; psd->mParent = mCurrentSpan; psd->mReflowInput = aSpanReflowInput; psd->mIStart = aIStart; psd->mICoord = aIStart; psd->mIEnd = aIEnd; psd->mBaseline = aBaseline; nsIFrame* frame = aSpanReflowInput->mFrame; psd->mNoWrap = !frame->StyleText()->WhiteSpaceCanWrap(frame) || mSuppressLineWrap || frame->StyleContext()->ShouldSuppressLineBreak(); psd->mWritingMode = aSpanReflowInput->GetWritingMode(); // Switch to new span mCurrentSpan = psd; mSpanDepth++; } nscoord nsLineLayout::EndSpan(nsIFrame* aFrame) { NS_ASSERTION(mSpanDepth > 0, "end-span without begin-span"); #ifdef NOISY_REFLOW nsFrame::IndentBy(stdout, mSpanDepth); nsFrame::ListTag(stdout, aFrame); printf(": EndSpan width=%d\n", mCurrentSpan->mICoord - mCurrentSpan->mIStart); #endif PerSpanData* psd = mCurrentSpan; nscoord iSizeResult = psd->mLastFrame ? (psd->mICoord - psd->mIStart) : 0; mSpanDepth--; mCurrentSpan->mReflowInput = nullptr; // no longer valid so null it out! mCurrentSpan = mCurrentSpan->mParent; return iSizeResult; } void nsLineLayout::AttachFrameToBaseLineLayout(PerFrameData* aFrame) { NS_PRECONDITION(mBaseLineLayout, "This method must not be called in a base line layout."); PerFrameData* baseFrame = mBaseLineLayout->LastFrame(); MOZ_ASSERT(aFrame && baseFrame); MOZ_ASSERT(!aFrame->mIsLinkedToBase, "The frame must not have been linked with the base"); #ifdef DEBUG nsIAtom* baseType = baseFrame->mFrame->GetType(); nsIAtom* annotationType = aFrame->mFrame->GetType(); MOZ_ASSERT((baseType == nsGkAtoms::rubyBaseContainerFrame && annotationType == nsGkAtoms::rubyTextContainerFrame) || (baseType == nsGkAtoms::rubyBaseFrame && annotationType == nsGkAtoms::rubyTextFrame)); #endif aFrame->mNextAnnotation = baseFrame->mNextAnnotation; baseFrame->mNextAnnotation = aFrame; aFrame->mIsLinkedToBase = true; } int32_t nsLineLayout::GetCurrentSpanCount() const { NS_ASSERTION(mCurrentSpan == mRootSpan, "bad linelayout user"); int32_t count = 0; PerFrameData* pfd = mRootSpan->mFirstFrame; while (nullptr != pfd) { count++; pfd = pfd->mNext; } return count; } void nsLineLayout::SplitLineTo(int32_t aNewCount) { NS_ASSERTION(mCurrentSpan == mRootSpan, "bad linelayout user"); #ifdef REALLY_NOISY_PUSHING printf("SplitLineTo %d (current count=%d); before:\n", aNewCount, GetCurrentSpanCount()); DumpPerSpanData(mRootSpan, 1); #endif PerSpanData* psd = mRootSpan; PerFrameData* pfd = psd->mFirstFrame; while (nullptr != pfd) { if (--aNewCount == 0) { // Truncate list at pfd (we keep pfd, but anything following is freed) PerFrameData* next = pfd->mNext; pfd->mNext = nullptr; psd->mLastFrame = pfd; // Now unlink all of the frames following pfd UnlinkFrame(next); break; } pfd = pfd->mNext; } #ifdef NOISY_PUSHING printf("SplitLineTo %d (current count=%d); after:\n", aNewCount, GetCurrentSpanCount()); DumpPerSpanData(mRootSpan, 1); #endif } void nsLineLayout::PushFrame(nsIFrame* aFrame) { PerSpanData* psd = mCurrentSpan; NS_ASSERTION(psd->mLastFrame->mFrame == aFrame, "pushing non-last frame"); #ifdef REALLY_NOISY_PUSHING nsFrame::IndentBy(stdout, mSpanDepth); printf("PushFrame %p, before:\n", psd); DumpPerSpanData(psd, 1); #endif // Take the last frame off of the span's frame list PerFrameData* pfd = psd->mLastFrame; if (pfd == psd->mFirstFrame) { // We are pushing away the only frame...empty the list psd->mFirstFrame = nullptr; psd->mLastFrame = nullptr; } else { PerFrameData* prevFrame = pfd->mPrev; prevFrame->mNext = nullptr; psd->mLastFrame = prevFrame; } // Now unlink the frame MOZ_ASSERT(!pfd->mNext); UnlinkFrame(pfd); #ifdef NOISY_PUSHING nsFrame::IndentBy(stdout, mSpanDepth); printf("PushFrame: %p after:\n", psd); DumpPerSpanData(psd, 1); #endif } void nsLineLayout::UnlinkFrame(PerFrameData* pfd) { while (nullptr != pfd) { PerFrameData* next = pfd->mNext; if (pfd->mIsLinkedToBase) { // This frame is linked to a ruby base, and should not be freed // now. Just unlink it from the span. It will be freed when its // base frame gets unlinked. pfd->mNext = pfd->mPrev = nullptr; pfd = next; continue; } // It is a ruby base frame. If there are any annotations // linked to this frame, free them first. PerFrameData* annotationPFD = pfd->mNextAnnotation; while (annotationPFD) { PerFrameData* nextAnnotation = annotationPFD->mNextAnnotation; MOZ_ASSERT(annotationPFD->mNext == nullptr && annotationPFD->mPrev == nullptr, "PFD in annotations should have been unlinked."); FreeFrame(annotationPFD); annotationPFD = nextAnnotation; } FreeFrame(pfd); pfd = next; } } void nsLineLayout::FreeFrame(PerFrameData* pfd) { if (nullptr != pfd->mSpan) { FreeSpan(pfd->mSpan); } nsLineLayout* outerLineLayout = GetOutermostLineLayout(); pfd->mNext = outerLineLayout->mFrameFreeList; outerLineLayout->mFrameFreeList = pfd; #ifdef DEBUG outerLineLayout->mFramesFreed++; #endif } void nsLineLayout::FreeSpan(PerSpanData* psd) { // Unlink its frames UnlinkFrame(psd->mFirstFrame); nsLineLayout* outerLineLayout = GetOutermostLineLayout(); // Now put the span on the free list since it's free too psd->mNextFreeSpan = outerLineLayout->mSpanFreeList; outerLineLayout->mSpanFreeList = psd; #ifdef DEBUG outerLineLayout->mSpansFreed++; #endif } bool nsLineLayout::IsZeroBSize() { PerSpanData* psd = mCurrentSpan; PerFrameData* pfd = psd->mFirstFrame; while (nullptr != pfd) { if (0 != pfd->mBounds.BSize(psd->mWritingMode)) { return false; } pfd = pfd->mNext; } return true; } nsLineLayout::PerFrameData* nsLineLayout::NewPerFrameData(nsIFrame* aFrame) { nsLineLayout* outerLineLayout = GetOutermostLineLayout(); PerFrameData* pfd = outerLineLayout->mFrameFreeList; if (!pfd) { void *mem; size_t sz = sizeof(PerFrameData); PL_ARENA_ALLOCATE(mem, &outerLineLayout->mArena, sz); if (!mem) { NS_ABORT_OOM(sz); } pfd = reinterpret_cast<PerFrameData*>(mem); } else { outerLineLayout->mFrameFreeList = pfd->mNext; } pfd->mSpan = nullptr; pfd->mNext = nullptr; pfd->mPrev = nullptr; pfd->mNextAnnotation = nullptr; pfd->mFrame = aFrame; // all flags default to false pfd->mRelativePos = false; pfd->mIsTextFrame = false; pfd->mIsNonEmptyTextFrame = false; pfd->mIsNonWhitespaceTextFrame = false; pfd->mIsLetterFrame = false; pfd->mRecomputeOverflow = false; pfd->mIsBullet = false; pfd->mSkipWhenTrimmingWhitespace = false; pfd->mIsEmpty = false; pfd->mIsLinkedToBase = false; pfd->mWritingMode = aFrame->GetWritingMode(); WritingMode lineWM = mRootSpan->mWritingMode; pfd->mBounds = LogicalRect(lineWM); pfd->mOverflowAreas.Clear(); pfd->mMargin = LogicalMargin(lineWM); pfd->mBorderPadding = LogicalMargin(lineWM); pfd->mOffsets = LogicalMargin(pfd->mWritingMode); pfd->mJustificationInfo = JustificationInfo(); pfd->mJustificationAssignment = JustificationAssignment(); #ifdef DEBUG pfd->mBlockDirAlign = 0xFF; outerLineLayout->mFramesAllocated++; #endif return pfd; } bool nsLineLayout::LineIsBreakable() const { // XXX mTotalPlacedFrames should go away and we should just use // mLineIsEmpty here instead if ((0 != mTotalPlacedFrames) || mImpactedByFloats) { return true; } return false; } // Checks all four sides for percentage units. This means it should // only be used for things (margin, padding) where percentages on top // and bottom depend on the *width* just like percentages on left and // right. static bool HasPercentageUnitSide(const nsStyleSides& aSides) { NS_FOR_CSS_SIDES(side) { if (aSides.Get(side).HasPercent()) return true; } return false; } static bool IsPercentageAware(const nsIFrame* aFrame) { NS_ASSERTION(aFrame, "null frame is not allowed"); nsIAtom *fType = aFrame->GetType(); if (fType == nsGkAtoms::textFrame) { // None of these things can ever be true for text frames. return false; } // Some of these things don't apply to non-replaced inline frames // (that is, fType == nsGkAtoms::inlineFrame), but we won't bother making // things unnecessarily complicated, since they'll probably be set // quite rarely. const nsStyleMargin* margin = aFrame->StyleMargin(); if (HasPercentageUnitSide(margin->mMargin)) { return true; } const nsStylePadding* padding = aFrame->StylePadding(); if (HasPercentageUnitSide(padding->mPadding)) { return true; } // Note that borders can't be aware of percentages const nsStylePosition* pos = aFrame->StylePosition(); if ((pos->WidthDependsOnContainer() && pos->mWidth.GetUnit() != eStyleUnit_Auto) || pos->MaxWidthDependsOnContainer() || pos->MinWidthDependsOnContainer() || pos->OffsetHasPercent(NS_SIDE_RIGHT) || pos->OffsetHasPercent(NS_SIDE_LEFT)) { return true; } if (eStyleUnit_Auto == pos->mWidth.GetUnit()) { // We need to check for frames that shrink-wrap when they're auto // width. const nsStyleDisplay* disp = aFrame->StyleDisplay(); if (disp->mDisplay == StyleDisplay::InlineBlock || disp->mDisplay == StyleDisplay::InlineTable || fType == nsGkAtoms::HTMLButtonControlFrame || fType == nsGkAtoms::gfxButtonControlFrame || fType == nsGkAtoms::fieldSetFrame || fType == nsGkAtoms::comboboxDisplayFrame) { return true; } // Per CSS 2.1, section 10.3.2: // If 'height' and 'width' both have computed values of 'auto' and // the element has an intrinsic ratio but no intrinsic height or // width and the containing block's width does not itself depend // on the replaced element's width, then the used value of 'width' // is calculated from the constraint equation used for // block-level, non-replaced elements in normal flow. nsIFrame *f = const_cast<nsIFrame*>(aFrame); if (f->GetIntrinsicRatio() != nsSize(0, 0) && // Some percents are treated like 'auto', so check != coord pos->mHeight.GetUnit() != eStyleUnit_Coord) { const IntrinsicSize &intrinsicSize = f->GetIntrinsicSize(); if (intrinsicSize.width.GetUnit() == eStyleUnit_None && intrinsicSize.height.GetUnit() == eStyleUnit_None) { return true; } } } return false; } void nsLineLayout::ReflowFrame(nsIFrame* aFrame, nsReflowStatus& aReflowStatus, ReflowOutput* aMetrics, bool& aPushedFrame) { // Initialize OUT parameter aPushedFrame = false; PerFrameData* pfd = NewPerFrameData(aFrame); PerSpanData* psd = mCurrentSpan; psd->AppendFrame(pfd); #ifdef REALLY_NOISY_REFLOW nsFrame::IndentBy(stdout, mSpanDepth); printf("%p: Begin ReflowFrame pfd=%p ", psd, pfd); nsFrame::ListTag(stdout, aFrame); printf("\n"); #endif if (mCurrentSpan == mRootSpan) { pfd->mFrame->Properties().Remove(nsIFrame::LineBaselineOffset()); } else { #ifdef DEBUG bool hasLineOffset; pfd->mFrame->Properties().Get(nsIFrame::LineBaselineOffset(), &hasLineOffset); NS_ASSERTION(!hasLineOffset, "LineBaselineOffset was set but was not expected"); #endif } mJustificationInfo = JustificationInfo(); // Stash copies of some of the computed state away for later // (block-direction alignment, for example) WritingMode frameWM = pfd->mWritingMode; WritingMode lineWM = mRootSpan->mWritingMode; // NOTE: While the inline direction coordinate remains relative to the // parent span, the block direction coordinate is fixed at the top // edge for the line. During VerticalAlignFrames we will repair this // so that the block direction coordinate is properly set and relative // to the appropriate span. pfd->mBounds.IStart(lineWM) = psd->mICoord; pfd->mBounds.BStart(lineWM) = mBStartEdge; // We want to guarantee that we always make progress when // formatting. Therefore, if the object being placed on the line is // too big for the line, but it is the only thing on the line and is not // impacted by a float, then we go ahead and place it anyway. (If the line // is impacted by one or more floats, then it is safe to break because // we can move the line down below float(s).) // // Capture this state *before* we reflow the frame in case it clears // the state out. We need to know how to treat the current frame // when breaking. bool notSafeToBreak = LineIsEmpty() && !mImpactedByFloats; // Figure out whether we're talking about a textframe here nsIAtom* frameType = aFrame->GetType(); bool isText = frameType == nsGkAtoms::textFrame; // Inline-ish and text-ish things don't compute their width; // everything else does. We need to give them an available width that // reflects the space left on the line. LAYOUT_WARN_IF_FALSE(psd->mIEnd != NS_UNCONSTRAINEDSIZE, "have unconstrained width; this should only result from " "very large sizes, not attempts at intrinsic width " "calculation"); nscoord availableSpaceOnLine = psd->mIEnd - psd->mICoord; // Setup reflow state for reflowing the frame Maybe<ReflowInput> reflowInputHolder; if (!isText) { // Compute the available size for the frame. This available width // includes room for the side margins. // For now, set the available block-size to unconstrained always. LogicalSize availSize = mBlockReflowInput->ComputedSize(frameWM); availSize.BSize(frameWM) = NS_UNCONSTRAINEDSIZE; reflowInputHolder.emplace(mPresContext, *psd->mReflowInput, aFrame, availSize); ReflowInput& reflowInput = *reflowInputHolder; reflowInput.mLineLayout = this; reflowInput.mFlags.mIsTopOfPage = mIsTopOfPage; if (reflowInput.ComputedISize() == NS_UNCONSTRAINEDSIZE) { reflowInput.AvailableISize() = availableSpaceOnLine; } WritingMode stateWM = reflowInput.GetWritingMode(); pfd->mMargin = reflowInput.ComputedLogicalMargin().ConvertTo(lineWM, stateWM); pfd->mBorderPadding = reflowInput.ComputedLogicalBorderPadding().ConvertTo(lineWM, stateWM); pfd->mRelativePos = reflowInput.mStyleDisplay->IsRelativelyPositionedStyle(); if (pfd->mRelativePos) { pfd->mOffsets = reflowInput.ComputedLogicalOffsets().ConvertTo(frameWM, stateWM); } // Calculate whether the the frame should have a start margin and // subtract the margin from the available width if necessary. // The margin will be applied to the starting inline coordinates of // the frame in CanPlaceFrame() after reflowing the frame. AllowForStartMargin(pfd, reflowInput); } // if isText(), no need to propagate NS_FRAME_IS_DIRTY from the parent, // because reflow doesn't look at the dirty bits on the frame being reflowed. // See if this frame depends on the width of its containing block. If // so, disable resize reflow optimizations for the line. (Note that, // to be conservative, we do this if we *try* to fit a frame on a // line, even if we don't succeed.) (Note also that we can only make // this IsPercentageAware check *after* we've constructed our // ReflowInput, because that construction may be what forces aFrame // to lazily initialize its (possibly-percent-valued) intrinsic size.) if (mGotLineBox && IsPercentageAware(aFrame)) { mLineBox->DisableResizeReflowOptimization(); } // Note that we don't bother positioning the frame yet, because we're probably // going to end up moving it when we do the block-direction alignment. // Adjust spacemanager coordinate system for the frame. ReflowOutput reflowOutput(lineWM); #ifdef DEBUG reflowOutput.ISize(lineWM) = nscoord(0xdeadbeef); reflowOutput.BSize(lineWM) = nscoord(0xdeadbeef); #endif nscoord tI = pfd->mBounds.LineLeft(lineWM, ContainerSize()); nscoord tB = pfd->mBounds.BStart(lineWM); mFloatManager->Translate(tI, tB); int32_t savedOptionalBreakOffset; gfxBreakPriority savedOptionalBreakPriority; nsIFrame* savedOptionalBreakFrame = GetLastOptionalBreakPosition(&savedOptionalBreakOffset, &savedOptionalBreakPriority); if (!isText) { aFrame->Reflow(mPresContext, reflowOutput, *reflowInputHolder, aReflowStatus); } else { static_cast<nsTextFrame*>(aFrame)-> ReflowText(*this, availableSpaceOnLine, psd->mReflowInput->mRenderingContext->GetDrawTarget(), reflowOutput, aReflowStatus); } pfd->mJustificationInfo = mJustificationInfo; mJustificationInfo = JustificationInfo(); // See if the frame is a placeholderFrame and if it is process // the float. At the same time, check if the frame has any non-collapsed-away // content. bool placedFloat = false; bool isEmpty; if (!frameType) { isEmpty = pfd->mFrame->IsEmpty(); } else { if (nsGkAtoms::placeholderFrame == frameType) { isEmpty = true; pfd->mSkipWhenTrimmingWhitespace = true; nsIFrame* outOfFlowFrame = nsLayoutUtils::GetFloatFromPlaceholder(aFrame); if (outOfFlowFrame) { // Add mTrimmableISize to the available width since if the line ends // here, the width of the inline content will be reduced by // mTrimmableISize. nscoord availableISize = psd->mIEnd - (psd->mICoord - mTrimmableISize); if (psd->mNoWrap) { // If we place floats after inline content where there's // no break opportunity, we don't know how much additional // width is required for the non-breaking content after the float, // so we can't know whether the float plus that content will fit // on the line. So for now, don't place floats after inline // content where there's no break opportunity. This is incorrect // but hopefully rare. Fixing it will require significant // restructuring of line layout. // We might as well allow zero-width floats to be placed, though. availableISize = 0; } placedFloat = GetOutermostLineLayout()-> AddFloat(outOfFlowFrame, availableISize); NS_ASSERTION(!(outOfFlowFrame->GetType() == nsGkAtoms::letterFrame && GetFirstLetterStyleOK()), "FirstLetterStyle set on line with floating first letter"); } } else if (isText) { // Note non-empty text-frames for inline frame compatibility hackery pfd->mIsTextFrame = true; nsTextFrame* textFrame = static_cast<nsTextFrame*>(pfd->mFrame); isEmpty = !textFrame->HasNoncollapsedCharacters(); if (!isEmpty) { pfd->mIsNonEmptyTextFrame = true; nsIContent* content = textFrame->GetContent(); const nsTextFragment* frag = content->GetText(); if (frag) { pfd->mIsNonWhitespaceTextFrame = !content->TextIsOnlyWhitespace(); } } } else if (nsGkAtoms::brFrame == frameType) { pfd->mSkipWhenTrimmingWhitespace = true; isEmpty = false; } else { if (nsGkAtoms::letterFrame==frameType) { pfd->mIsLetterFrame = true; } if (pfd->mSpan) { isEmpty = !pfd->mSpan->mHasNonemptyContent && pfd->mFrame->IsSelfEmpty(); } else { isEmpty = pfd->mFrame->IsEmpty(); } } } pfd->mIsEmpty = isEmpty; mFloatManager->Translate(-tI, -tB); NS_ASSERTION(reflowOutput.ISize(lineWM) >= 0, "bad inline size"); NS_ASSERTION(reflowOutput.BSize(lineWM) >= 0,"bad block size"); if (reflowOutput.ISize(lineWM) < 0) { reflowOutput.ISize(lineWM) = 0; } if (reflowOutput.BSize(lineWM) < 0) { reflowOutput.BSize(lineWM) = 0; } #ifdef DEBUG // Note: break-before means ignore the reflow metrics since the // frame will be reflowed another time. if (!NS_INLINE_IS_BREAK_BEFORE(aReflowStatus)) { if ((CRAZY_SIZE(reflowOutput.ISize(lineWM)) || CRAZY_SIZE(reflowOutput.BSize(lineWM))) && !LineContainerFrame()->GetParent()->IsCrazySizeAssertSuppressed()) { printf("nsLineLayout: "); nsFrame::ListTag(stdout, aFrame); printf(" metrics=%d,%d!\n", reflowOutput.Width(), reflowOutput.Height()); } if ((reflowOutput.Width() == nscoord(0xdeadbeef)) || (reflowOutput.Height() == nscoord(0xdeadbeef))) { printf("nsLineLayout: "); nsFrame::ListTag(stdout, aFrame); printf(" didn't set w/h %d,%d!\n", reflowOutput.Width(), reflowOutput.Height()); } } #endif // Unlike with non-inline reflow, the overflow area here does *not* // include the accumulation of the frame's bounds and its inline // descendants' bounds. Nor does it include the outline area; it's // just the union of the bounds of any absolute children. That is // added in later by nsLineLayout::ReflowInlineFrames. pfd->mOverflowAreas = reflowOutput.mOverflowAreas; pfd->mBounds.ISize(lineWM) = reflowOutput.ISize(lineWM); pfd->mBounds.BSize(lineWM) = reflowOutput.BSize(lineWM); // Size the frame, but |RelativePositionFrames| will size the view. aFrame->SetRect(lineWM, pfd->mBounds, ContainerSizeForSpan(psd)); // Tell the frame that we're done reflowing it aFrame->DidReflow(mPresContext, isText ? nullptr : reflowInputHolder.ptr(), nsDidReflowStatus::FINISHED); if (aMetrics) { *aMetrics = reflowOutput; } if (!NS_INLINE_IS_BREAK_BEFORE(aReflowStatus)) { // If frame is complete and has a next-in-flow, we need to delete // them now. Do not do this when a break-before is signaled because // the frame is going to get reflowed again (and may end up wanting // a next-in-flow where it ends up). if (NS_FRAME_IS_COMPLETE(aReflowStatus)) { nsIFrame* kidNextInFlow = aFrame->GetNextInFlow(); if (nullptr != kidNextInFlow) { // Remove all of the childs next-in-flows. Make sure that we ask // the right parent to do the removal (it's possible that the // parent is not this because we are executing pullup code) kidNextInFlow->GetParent()-> DeleteNextInFlowChild(kidNextInFlow, true); } } // Check whether this frame breaks up text runs. All frames break up text // runs (hence return false here) except for text frames and inline containers. bool continuingTextRun = aFrame->CanContinueTextRun(); // Clear any residual mTrimmableISize if this isn't a text frame if (!continuingTextRun && !pfd->mSkipWhenTrimmingWhitespace) { mTrimmableISize = 0; } // See if we can place the frame. If we can't fit it, then we // return now. bool optionalBreakAfterFits; NS_ASSERTION(isText || !reflowInputHolder->IsFloating(), "How'd we get a floated inline frame? " "The frame ctor should've dealt with this."); if (CanPlaceFrame(pfd, notSafeToBreak, continuingTextRun, savedOptionalBreakFrame != nullptr, reflowOutput, aReflowStatus, &optionalBreakAfterFits)) { if (!isEmpty) { psd->mHasNonemptyContent = true; mLineIsEmpty = false; if (!pfd->mSpan) { // nonempty leaf content has been placed mLineAtStart = false; } if (nsGkAtoms::rubyFrame == frameType) { mHasRuby = true; SyncAnnotationBounds(pfd); } } // Place the frame, updating aBounds with the final size and // location. Then apply the bottom+right margins (as // appropriate) to the frame. PlaceFrame(pfd, reflowOutput); PerSpanData* span = pfd->mSpan; if (span) { // The frame we just finished reflowing is an inline // container. It needs its child frames aligned in the block direction, // so do most of it now. VerticalAlignFrames(span); } if (!continuingTextRun) { if (!psd->mNoWrap && (!LineIsEmpty() || placedFloat)) { // record soft break opportunity after this content that can't be // part of a text run. This is not a text frame so we know // that offset INT32_MAX means "after the content". if (NotifyOptionalBreakPosition(aFrame, INT32_MAX, optionalBreakAfterFits, gfxBreakPriority::eNormalBreak)) { // If this returns true then we are being told to actually break here. aReflowStatus = NS_INLINE_LINE_BREAK_AFTER(aReflowStatus); } } } } else { PushFrame(aFrame); aPushedFrame = true; // Undo any saved break positions that the frame might have told us about, // since we didn't end up placing it RestoreSavedBreakPosition(savedOptionalBreakFrame, savedOptionalBreakOffset, savedOptionalBreakPriority); } } else { PushFrame(aFrame); aPushedFrame = true; } #ifdef REALLY_NOISY_REFLOW nsFrame::IndentBy(stdout, mSpanDepth); printf("End ReflowFrame "); nsFrame::ListTag(stdout, aFrame); printf(" status=%x\n", aReflowStatus); #endif } void nsLineLayout::AllowForStartMargin(PerFrameData* pfd, ReflowInput& aReflowInput) { NS_ASSERTION(!aReflowInput.IsFloating(), "How'd we get a floated inline frame? " "The frame ctor should've dealt with this."); WritingMode lineWM = mRootSpan->mWritingMode; // Only apply start-margin on the first-in flow for inline frames, // and make sure to not apply it to any inline other than the first // in an ib split. Note that the ib sibling (block-in-inline // sibling) annotations only live on the first continuation, but we // don't want to apply the start margin for later continuations // anyway. For box-decoration-break:clone we apply the start-margin // on all continuations. if ((pfd->mFrame->GetPrevContinuation() || pfd->mFrame->FrameIsNonFirstInIBSplit()) && aReflowInput.mStyleBorder->mBoxDecorationBreak == StyleBoxDecorationBreak::Slice) { // Zero this out so that when we compute the max-element-width of // the frame we will properly avoid adding in the starting margin. pfd->mMargin.IStart(lineWM) = 0; } else if (NS_UNCONSTRAINEDSIZE == aReflowInput.ComputedISize()) { NS_WARNING_ASSERTION( NS_UNCONSTRAINEDSIZE != aReflowInput.AvailableISize(), "have unconstrained inline-size; this should only result from very " "large sizes, not attempts at intrinsic inline-size calculation"); // For inline-ish and text-ish things (which don't compute widths // in the reflow state), adjust available inline-size to account // for the start margin. The end margin will be accounted for when // we finish flowing the frame. WritingMode wm = aReflowInput.GetWritingMode(); aReflowInput.AvailableISize() -= pfd->mMargin.ConvertTo(wm, lineWM).IStart(wm); } } nscoord nsLineLayout::GetCurrentFrameInlineDistanceFromBlock() { PerSpanData* psd; nscoord x = 0; for (psd = mCurrentSpan; psd; psd = psd->mParent) { x += psd->mICoord; } return x; } /** * This method syncs bounds of ruby annotations and ruby annotation * containers from their rect. It is necessary because: * Containers are not part of the line in their levels, which means * their bounds are not set properly before. * Ruby annotations' position may have been changed when reflowing * their containers. */ void nsLineLayout::SyncAnnotationBounds(PerFrameData* aRubyFrame) { MOZ_ASSERT(aRubyFrame->mFrame->GetType() == nsGkAtoms::rubyFrame); MOZ_ASSERT(aRubyFrame->mSpan); PerSpanData* span = aRubyFrame->mSpan; WritingMode lineWM = mRootSpan->mWritingMode; for (PerFrameData* pfd = span->mFirstFrame; pfd; pfd = pfd->mNext) { for (PerFrameData* rtc = pfd->mNextAnnotation; rtc; rtc = rtc->mNextAnnotation) { // When the annotation container is reflowed, the width of the // ruby container is unknown so we use a dummy container size; // in the case of RTL block direction, the final position will be // fixed up later. const nsSize dummyContainerSize; LogicalRect rtcBounds(lineWM, rtc->mFrame->GetRect(), dummyContainerSize); rtc->mBounds = rtcBounds; nsSize rtcSize = rtcBounds.Size(lineWM).GetPhysicalSize(lineWM); for (PerFrameData* rt = rtc->mSpan->mFirstFrame; rt; rt = rt->mNext) { LogicalRect rtBounds = rt->mFrame->GetLogicalRect(lineWM, rtcSize); MOZ_ASSERT(rt->mBounds.Size(lineWM) == rtBounds.Size(lineWM), "Size of the annotation should not have been changed"); rt->mBounds.SetOrigin(lineWM, rtBounds.Origin(lineWM)); } } } } /** * See if the frame can be placed now that we know it's desired size. * We can always place the frame if the line is empty. Note that we * know that the reflow-status is not a break-before because if it was * ReflowFrame above would have returned false, preventing this method * from being called. The logic in this method assumes that. * * Note that there is no check against the Y coordinate because we * assume that the caller will take care of that. */ bool nsLineLayout::CanPlaceFrame(PerFrameData* pfd, bool aNotSafeToBreak, bool aFrameCanContinueTextRun, bool aCanRollBackBeforeFrame, ReflowOutput& aMetrics, nsReflowStatus& aStatus, bool* aOptionalBreakAfterFits) { NS_PRECONDITION(pfd && pfd->mFrame, "bad args, null pointers for frame data"); *aOptionalBreakAfterFits = true; WritingMode lineWM = mRootSpan->mWritingMode; /* * We want to only apply the end margin if we're the last continuation and * either not in an {ib} split or the last inline in it. In all other * cases we want to zero it out. That means zeroing it out if any of these * conditions hold: * 1) The frame is not complete (in this case it will get a next-in-flow) * 2) The frame is complete but has a non-fluid continuation on its * continuation chain. Note that if it has a fluid continuation, that * continuation will get destroyed later, so we don't want to drop the * end-margin in that case. * 3) The frame is in an {ib} split and is not the last part. * * However, none of that applies if this is a letter frame (XXXbz why?) * * For box-decoration-break:clone we apply the end margin on all * continuations (that are not letter frames). */ if ((NS_FRAME_IS_NOT_COMPLETE(aStatus) || pfd->mFrame->LastInFlow()->GetNextContinuation() || pfd->mFrame->FrameIsNonLastInIBSplit()) && !pfd->mIsLetterFrame && pfd->mFrame->StyleBorder()->mBoxDecorationBreak == StyleBoxDecorationBreak::Slice) { pfd->mMargin.IEnd(lineWM) = 0; } // Apply the start margin to the frame bounds. nscoord startMargin = pfd->mMargin.IStart(lineWM); nscoord endMargin = pfd->mMargin.IEnd(lineWM); pfd->mBounds.IStart(lineWM) += startMargin; PerSpanData* psd = mCurrentSpan; if (psd->mNoWrap) { // When wrapping is off, everything fits. return true; } #ifdef NOISY_CAN_PLACE_FRAME if (nullptr != psd->mFrame) { nsFrame::ListTag(stdout, psd->mFrame->mFrame); } printf(": aNotSafeToBreak=%s frame=", aNotSafeToBreak ? "true" : "false"); nsFrame::ListTag(stdout, pfd->mFrame); printf(" frameWidth=%d, margins=%d,%d\n", pfd->mBounds.IEnd(lineWM) + endMargin - psd->mICoord, startMargin, endMargin); #endif // Set outside to true if the result of the reflow leads to the // frame sticking outside of our available area. bool outside = pfd->mBounds.IEnd(lineWM) - mTrimmableISize + endMargin > psd->mIEnd; if (!outside) { // If it fits, it fits #ifdef NOISY_CAN_PLACE_FRAME printf(" ==> inside\n"); #endif return true; } *aOptionalBreakAfterFits = false; // When it doesn't fit, check for a few special conditions where we // allow it to fit anyway. if (0 == startMargin + pfd->mBounds.ISize(lineWM) + endMargin) { // Empty frames always fit right where they are #ifdef NOISY_CAN_PLACE_FRAME printf(" ==> empty frame fits\n"); #endif return true; } #ifdef FIX_BUG_50257 // another special case: always place a BR if (nsGkAtoms::brFrame == pfd->mFrame->GetType()) { #ifdef NOISY_CAN_PLACE_FRAME printf(" ==> BR frame fits\n"); #endif return true; } #endif if (aNotSafeToBreak) { // There are no frames on the line that take up width and the line is // not impacted by floats, so we must allow the current frame to be // placed on the line #ifdef NOISY_CAN_PLACE_FRAME printf(" ==> not-safe and not-impacted fits: "); while (nullptr != psd) { printf("<psd=%p x=%d left=%d> ", psd, psd->mICoord, psd->mIStart); psd = psd->mParent; } printf("\n"); #endif return true; } // Special check for span frames if (pfd->mSpan && pfd->mSpan->mContainsFloat) { // If the span either directly or indirectly contains a float then // it fits. Why? It's kind of complicated, but here goes: // // 1. CanPlaceFrame is used for all frame placements on a line, // and in a span. This includes recursively placement of frames // inside of spans, and the span itself. Because the logic always // checks for room before proceeding (the code above here), the // only things on a line will be those things that "fit". // // 2. Before a float is placed on a line, the line has to be empty // (otherwise it's a "below current line" float and will be placed // after the line). // // Therefore, if the span directly or indirectly has a float // then it means that at the time of the placement of the float // the line was empty. Because of #1, only the frames that fit can // be added after that point, therefore we can assume that the // current span being placed has fit. // // So how do we get here and have a span that should already fit // and yet doesn't: Simple: span's that have the no-wrap attribute // set on them and contain a float and are placed where they // don't naturally fit. return true; } if (aFrameCanContinueTextRun) { // Let it fit, but we reserve the right to roll back. // Note that we usually won't get here because a text frame will break // itself to avoid exceeding the available width. // We'll only get here for text frames that couldn't break early enough. #ifdef NOISY_CAN_PLACE_FRAME printf(" ==> placing overflowing textrun, requesting backup\n"); #endif // We will want to try backup. mNeedBackup = true; return true; } #ifdef NOISY_CAN_PLACE_FRAME printf(" ==> didn't fit\n"); #endif aStatus = NS_INLINE_LINE_BREAK_BEFORE(); return false; } /** * Place the frame. Update running counters. */ void nsLineLayout::PlaceFrame(PerFrameData* pfd, ReflowOutput& aMetrics) { WritingMode lineWM = mRootSpan->mWritingMode; // If the frame's block direction does not match the line's, we can't use // its ascent; instead, treat it as a block with baseline at the block-end // edge (or block-begin in the case of an "inverted" line). if (pfd->mWritingMode.GetBlockDir() != lineWM.GetBlockDir()) { pfd->mAscent = lineWM.IsLineInverted() ? 0 : aMetrics.BSize(lineWM); } else { if (aMetrics.BlockStartAscent() == ReflowOutput::ASK_FOR_BASELINE) { pfd->mAscent = pfd->mFrame->GetLogicalBaseline(lineWM); } else { pfd->mAscent = aMetrics.BlockStartAscent(); } } // Advance to next inline coordinate mCurrentSpan->mICoord = pfd->mBounds.IEnd(lineWM) + pfd->mMargin.IEnd(lineWM); // Count the number of non-placeholder frames on the line... if (pfd->mFrame->GetType() == nsGkAtoms::placeholderFrame) { NS_ASSERTION(pfd->mBounds.ISize(lineWM) == 0 && pfd->mBounds.BSize(lineWM) == 0, "placeholders should have 0 width/height (checking " "placeholders were never counted by the old code in " "this function)"); } else { mTotalPlacedFrames++; } } void nsLineLayout::AddBulletFrame(nsIFrame* aFrame, const ReflowOutput& aMetrics) { NS_ASSERTION(mCurrentSpan == mRootSpan, "bad linelayout user"); NS_ASSERTION(mGotLineBox, "must have line box"); nsIFrame *blockFrame = mBlockReflowInput->mFrame; NS_ASSERTION(blockFrame->IsFrameOfType(nsIFrame::eBlockFrame), "must be for block"); if (!static_cast<nsBlockFrame*>(blockFrame)->BulletIsEmpty()) { mHasBullet = true; mLineBox->SetHasBullet(); } WritingMode lineWM = mRootSpan->mWritingMode; PerFrameData* pfd = NewPerFrameData(aFrame); mRootSpan->AppendFrame(pfd); pfd->mIsBullet = true; if (aMetrics.BlockStartAscent() == ReflowOutput::ASK_FOR_BASELINE) { pfd->mAscent = aFrame->GetLogicalBaseline(lineWM); } else { pfd->mAscent = aMetrics.BlockStartAscent(); } // Note: block-coord value will be updated during block-direction alignment pfd->mBounds = LogicalRect(lineWM, aFrame->GetRect(), ContainerSize()); pfd->mOverflowAreas = aMetrics.mOverflowAreas; } #ifdef DEBUG void nsLineLayout::DumpPerSpanData(PerSpanData* psd, int32_t aIndent) { nsFrame::IndentBy(stdout, aIndent); printf("%p: left=%d x=%d right=%d\n", static_cast<void*>(psd), psd->mIStart, psd->mICoord, psd->mIEnd); PerFrameData* pfd = psd->mFirstFrame; while (nullptr != pfd) { nsFrame::IndentBy(stdout, aIndent+1); nsFrame::ListTag(stdout, pfd->mFrame); nsRect rect = pfd->mBounds.GetPhysicalRect(psd->mWritingMode, ContainerSize()); printf(" %d,%d,%d,%d\n", rect.x, rect.y, rect.width, rect.height); if (pfd->mSpan) { DumpPerSpanData(pfd->mSpan, aIndent + 1); } pfd = pfd->mNext; } } #endif #define VALIGN_OTHER 0 #define VALIGN_TOP 1 #define VALIGN_BOTTOM 2 void nsLineLayout::VerticalAlignLine() { // Partially place the children of the block frame. The baseline for // this operation is set to zero so that the y coordinates for all // of the placed children will be relative to there. PerSpanData* psd = mRootSpan; VerticalAlignFrames(psd); // *** Note that comments here still use the anachronistic term // "line-height" when we really mean "size of the line in the block // direction", "vertical-align" when we really mean "alignment in // the block direction", and "top" and "bottom" when we really mean // "block start" and "block end". This is partly for brevity and // partly to retain the association with the CSS line-height and // vertical-align properties. // // Compute the line-height. The line-height will be the larger of: // // [1] maxBCoord - minBCoord (the distance between the first child's // block-start edge and the last child's block-end edge) // // [2] the maximum logical box block size (since not every frame may have // participated in #1; for example: "top" and "botttom" aligned frames) // // [3] the minimum line height ("line-height" property set on the // block frame) nscoord lineBSize = psd->mMaxBCoord - psd->mMinBCoord; // Now that the line-height is computed, we need to know where the // baseline is in the line. Position baseline so that mMinBCoord is just // inside the start of the line box. nscoord baselineBCoord; if (psd->mMinBCoord < 0) { baselineBCoord = mBStartEdge - psd->mMinBCoord; } else { baselineBCoord = mBStartEdge; } // It's also possible that the line block-size isn't tall enough because // of "top" and "bottom" aligned elements that were not accounted for in // min/max BCoord. // // The CSS2 spec doesn't really say what happens when to the // baseline in this situations. What we do is if the largest start // aligned box block size is greater than the line block-size then we leave // the baseline alone. If the largest end aligned box is greater // than the line block-size then we slide the baseline forward by the extra // amount. // // Navigator 4 gives precedence to the first top/bottom aligned // object. We just let block end aligned objects win. if (lineBSize < mMaxEndBoxBSize) { // When the line is shorter than the maximum block start aligned box nscoord extra = mMaxEndBoxBSize - lineBSize; baselineBCoord += extra; lineBSize = mMaxEndBoxBSize; } if (lineBSize < mMaxStartBoxBSize) { lineBSize = mMaxStartBoxBSize; } #ifdef NOISY_BLOCKDIR_ALIGN printf(" [line]==> lineBSize=%d baselineBCoord=%d\n", lineBSize, baselineBCoord); #endif // Now position all of the frames in the root span. We will also // recurse over the child spans and place any frames we find with // vertical-align: top or bottom. // XXX PERFORMANCE: set a bit per-span to avoid the extra work // (propagate it upward too) WritingMode lineWM = psd->mWritingMode; for (PerFrameData* pfd = psd->mFirstFrame; pfd; pfd = pfd->mNext) { if (pfd->mBlockDirAlign == VALIGN_OTHER) { pfd->mBounds.BStart(lineWM) += baselineBCoord; pfd->mFrame->SetRect(lineWM, pfd->mBounds, ContainerSize()); } } PlaceTopBottomFrames(psd, -mBStartEdge, lineBSize); mFinalLineBSize = lineBSize; if (mGotLineBox) { // Fill in returned line-box and max-element-width data mLineBox->SetBounds(lineWM, psd->mIStart, mBStartEdge, psd->mICoord - psd->mIStart, lineBSize, ContainerSize()); mLineBox->SetLogicalAscent(baselineBCoord - mBStartEdge); #ifdef NOISY_BLOCKDIR_ALIGN printf( " [line]==> bounds{x,y,w,h}={%d,%d,%d,%d} lh=%d a=%d\n", mLineBox->GetBounds().IStart(lineWM), mLineBox->GetBounds().BStart(lineWM), mLineBox->GetBounds().ISize(lineWM), mLineBox->GetBounds().BSize(lineWM), mFinalLineBSize, mLineBox->GetLogicalAscent()); #endif } } // Place frames with CSS property vertical-align: top or bottom. void nsLineLayout::PlaceTopBottomFrames(PerSpanData* psd, nscoord aDistanceFromStart, nscoord aLineBSize) { for (PerFrameData* pfd = psd->mFirstFrame; pfd; pfd = pfd->mNext) { PerSpanData* span = pfd->mSpan; #ifdef DEBUG NS_ASSERTION(0xFF != pfd->mBlockDirAlign, "umr"); #endif WritingMode lineWM = mRootSpan->mWritingMode; nsSize containerSize = ContainerSizeForSpan(psd); switch (pfd->mBlockDirAlign) { case VALIGN_TOP: if (span) { pfd->mBounds.BStart(lineWM) = -aDistanceFromStart - span->mMinBCoord; } else { pfd->mBounds.BStart(lineWM) = -aDistanceFromStart + pfd->mMargin.BStart(lineWM); } pfd->mFrame->SetRect(lineWM, pfd->mBounds, containerSize); #ifdef NOISY_BLOCKDIR_ALIGN printf(" "); nsFrame::ListTag(stdout, pfd->mFrame); printf(": y=%d dTop=%d [bp.top=%d topLeading=%d]\n", pfd->mBounds.BStart(lineWM), aDistanceFromStart, span ? pfd->mBorderPadding.BStart(lineWM) : 0, span ? span->mBStartLeading : 0); #endif break; case VALIGN_BOTTOM: if (span) { // Compute bottom leading pfd->mBounds.BStart(lineWM) = -aDistanceFromStart + aLineBSize - span->mMaxBCoord; } else { pfd->mBounds.BStart(lineWM) = -aDistanceFromStart + aLineBSize - pfd->mMargin.BEnd(lineWM) - pfd->mBounds.BSize(lineWM); } pfd->mFrame->SetRect(lineWM, pfd->mBounds, containerSize); #ifdef NOISY_BLOCKDIR_ALIGN printf(" "); nsFrame::ListTag(stdout, pfd->mFrame); printf(": y=%d\n", pfd->mBounds.BStart(lineWM)); #endif break; } if (span) { nscoord fromStart = aDistanceFromStart + pfd->mBounds.BStart(lineWM); PlaceTopBottomFrames(span, fromStart, aLineBSize); } } } static nscoord GetBSizeOfEmphasisMarks(nsIFrame* aSpanFrame, float aInflation) { RefPtr<nsFontMetrics> fm = nsLayoutUtils:: GetFontMetricsOfEmphasisMarks(aSpanFrame->StyleContext(), aInflation); return fm->MaxHeight(); } void nsLineLayout::AdjustLeadings(nsIFrame* spanFrame, PerSpanData* psd, const nsStyleText* aStyleText, float aInflation, bool* aZeroEffectiveSpanBox) { MOZ_ASSERT(spanFrame == psd->mFrame->mFrame); nscoord requiredStartLeading = 0; nscoord requiredEndLeading = 0; if (spanFrame->GetType() == nsGkAtoms::rubyFrame) { // We may need to extend leadings here for ruby annotations as // required by section Line Spacing in the CSS Ruby spec. // See http://dev.w3.org/csswg/css-ruby/#line-height auto rubyFrame = static_cast<nsRubyFrame*>(spanFrame); RubyBlockLeadings leadings = rubyFrame->GetBlockLeadings(); requiredStartLeading += leadings.mStart; requiredEndLeading += leadings.mEnd; } if (aStyleText->HasTextEmphasis()) { nscoord bsize = GetBSizeOfEmphasisMarks(spanFrame, aInflation); LogicalSide side = aStyleText->TextEmphasisSide(mRootSpan->mWritingMode); if (side == eLogicalSideBStart) { requiredStartLeading += bsize; } else { MOZ_ASSERT(side == eLogicalSideBEnd, "emphasis marks must be in block axis"); requiredEndLeading += bsize; } } nscoord requiredLeading = requiredStartLeading + requiredEndLeading; // If we do not require any additional leadings, don't touch anything // here even if it is greater than the original leading, because the // latter could be negative. if (requiredLeading != 0) { nscoord leading = psd->mBStartLeading + psd->mBEndLeading; nscoord deltaLeading = requiredLeading - leading; if (deltaLeading > 0) { // If the total leading is not wide enough for ruby annotations // and/or emphasis marks, extend the side which is not enough. If // both sides are not wide enough, replace the leadings with the // requested values. if (requiredStartLeading < psd->mBStartLeading) { psd->mBEndLeading += deltaLeading; } else if (requiredEndLeading < psd->mBEndLeading) { psd->mBStartLeading += deltaLeading; } else { psd->mBStartLeading = requiredStartLeading; psd->mBEndLeading = requiredEndLeading; } psd->mLogicalBSize += deltaLeading; // We have adjusted the leadings, it is no longer a zero // effective span box. *aZeroEffectiveSpanBox = false; } } } static float GetInflationForBlockDirAlignment(nsIFrame* aFrame, nscoord aInflationMinFontSize) { if (aFrame->IsSVGText()) { const nsIFrame* container = nsLayoutUtils::GetClosestFrameOfType(aFrame, nsGkAtoms::svgTextFrame); NS_ASSERTION(container, "expected to find an ancestor SVGTextFrame"); return static_cast<const SVGTextFrame*>(container)->GetFontSizeScaleFactor(); } return nsLayoutUtils::FontSizeInflationInner(aFrame, aInflationMinFontSize); } #define BLOCKDIR_ALIGN_FRAMES_NO_MINIMUM nscoord_MAX #define BLOCKDIR_ALIGN_FRAMES_NO_MAXIMUM nscoord_MIN // Place frames in the block direction within a given span (CSS property // vertical-align) Note: this doesn't place frames with vertical-align: // top or bottom as those have to wait until the entire line box block // size is known. This is called after the span frame has finished being // reflowed so that we know its block size. void nsLineLayout::VerticalAlignFrames(PerSpanData* psd) { // Get parent frame info PerFrameData* spanFramePFD = psd->mFrame; nsIFrame* spanFrame = spanFramePFD->mFrame; // Get the parent frame's font for all of the frames in this span float inflation = GetInflationForBlockDirAlignment(spanFrame, mInflationMinFontSize); RefPtr<nsFontMetrics> fm = nsLayoutUtils::GetFontMetricsForFrame(spanFrame, inflation); bool preMode = mStyleText->WhiteSpaceIsSignificant(); // See if the span is an empty continuation. It's an empty continuation iff: // - it has a prev-in-flow // - it has no next in flow // - it's zero sized WritingMode lineWM = mRootSpan->mWritingMode; bool emptyContinuation = psd != mRootSpan && spanFrame->GetPrevInFlow() && !spanFrame->GetNextInFlow() && spanFramePFD->mBounds.IsZeroSize(); #ifdef NOISY_BLOCKDIR_ALIGN printf("[%sSpan]", (psd == mRootSpan)?"Root":""); nsFrame::ListTag(stdout, spanFrame); printf(": preMode=%s strictMode=%s w/h=%d,%d emptyContinuation=%s", preMode ? "yes" : "no", mPresContext->CompatibilityMode() != eCompatibility_NavQuirks ? "yes" : "no", spanFramePFD->mBounds.ISize(lineWM), spanFramePFD->mBounds.BSize(lineWM), emptyContinuation ? "yes" : "no"); if (psd != mRootSpan) { printf(" bp=%d,%d,%d,%d margin=%d,%d,%d,%d", spanFramePFD->mBorderPadding.Top(lineWM), spanFramePFD->mBorderPadding.Right(lineWM), spanFramePFD->mBorderPadding.Bottom(lineWM), spanFramePFD->mBorderPadding.Left(lineWM), spanFramePFD->mMargin.Top(lineWM), spanFramePFD->mMargin.Right(lineWM), spanFramePFD->mMargin.Bottom(lineWM), spanFramePFD->mMargin.Left(lineWM)); } printf("\n"); #endif // Compute the span's zeroEffectiveSpanBox flag. What we are trying // to determine is how we should treat the span: should it act // "normally" according to css2 or should it effectively // "disappear". // // In general, if the document being processed is in full standards // mode then it should act normally (with one exception). The // exception case is when a span is continued and yet the span is // empty (e.g. compressed whitespace). For this kind of span we treat // it as if it were not there so that it doesn't impact the // line block-size. // // In almost standards mode or quirks mode, we should sometimes make // it disappear. The cases that matter are those where the span // contains no real text elements that would provide an ascent and // descent and height. However, if css style elements have been // applied to the span (border/padding/margin) so that it's clear the // document author is intending css2 behavior then we act as if strict // mode is set. // // This code works correctly for preMode, because a blank line // in PRE mode is encoded as a text node with a LF in it, since // text nodes with only whitespace are considered in preMode. // // Much of this logic is shared with the various implementations of // nsIFrame::IsEmpty since they need to duplicate the way it makes // some lines empty. However, nsIFrame::IsEmpty can't be reused here // since this code sets zeroEffectiveSpanBox even when there are // non-empty children. bool zeroEffectiveSpanBox = false; // XXXldb If we really have empty continuations, then all these other // checks don't make sense for them. // XXXldb This should probably just use nsIFrame::IsSelfEmpty, assuming that // it agrees with this code. (If it doesn't agree, it probably should.) if ((emptyContinuation || mPresContext->CompatibilityMode() != eCompatibility_FullStandards) && ((psd == mRootSpan) || (spanFramePFD->mBorderPadding.IsAllZero() && spanFramePFD->mMargin.IsAllZero()))) { // This code handles an issue with compatibility with non-css // conformant browsers. In particular, there are some cases // where the font-size and line-height for a span must be // ignored and instead the span must *act* as if it were zero // sized. In general, if the span contains any non-compressed // text then we don't use this logic. // However, this is not propagated outwards, since (in compatibility // mode) we don't want big line heights for things like // <p><font size="-1">Text</font></p> // We shouldn't include any whitespace that collapses, unless we're // preformatted (in which case it shouldn't, but the width=0 test is // perhaps incorrect). This includes whitespace at the beginning of // a line and whitespace preceded (?) by other whitespace. // See bug 134580 and bug 155333. zeroEffectiveSpanBox = true; for (PerFrameData* pfd = psd->mFirstFrame; pfd; pfd = pfd->mNext) { if (pfd->mIsTextFrame && (pfd->mIsNonWhitespaceTextFrame || preMode || pfd->mBounds.ISize(mRootSpan->mWritingMode) != 0)) { zeroEffectiveSpanBox = false; break; } } } // Setup baselineBCoord, minBCoord, and maxBCoord nscoord baselineBCoord, minBCoord, maxBCoord; if (psd == mRootSpan) { // Use a zero baselineBCoord since we don't yet know where the baseline // will be (until we know how tall the line is; then we will // know). In addition, use extreme values for the minBCoord and maxBCoord // values so that only the child frames will impact their values // (since these are children of the block, there is no span box to // provide initial values). baselineBCoord = 0; minBCoord = BLOCKDIR_ALIGN_FRAMES_NO_MINIMUM; maxBCoord = BLOCKDIR_ALIGN_FRAMES_NO_MAXIMUM; #ifdef NOISY_BLOCKDIR_ALIGN printf("[RootSpan]"); nsFrame::ListTag(stdout, spanFrame); printf(": pass1 valign frames: topEdge=%d minLineBSize=%d zeroEffectiveSpanBox=%s\n", mBStartEdge, mMinLineBSize, zeroEffectiveSpanBox ? "yes" : "no"); #endif } else { // Compute the logical block size for this span. The logical block size // is based on the "line-height" value, not the font-size. Also // compute the top leading. float inflation = GetInflationForBlockDirAlignment(spanFrame, mInflationMinFontSize); nscoord logicalBSize = ReflowInput:: CalcLineHeight(spanFrame->GetContent(), spanFrame->StyleContext(), mBlockReflowInput->ComputedHeight(), inflation); nscoord contentBSize = spanFramePFD->mBounds.BSize(lineWM) - spanFramePFD->mBorderPadding.BStartEnd(lineWM); // Special-case for a ::first-letter frame, set the line height to // the frame block size if the user has left line-height == normal const nsStyleText* styleText = spanFrame->StyleText(); if (spanFramePFD->mIsLetterFrame && !spanFrame->GetPrevInFlow() && styleText->mLineHeight.GetUnit() == eStyleUnit_Normal) { logicalBSize = spanFramePFD->mBounds.BSize(lineWM); } nscoord leading = logicalBSize - contentBSize; psd->mBStartLeading = leading / 2; psd->mBEndLeading = leading - psd->mBStartLeading; psd->mLogicalBSize = logicalBSize; AdjustLeadings(spanFrame, psd, styleText, inflation, &zeroEffectiveSpanBox); if (zeroEffectiveSpanBox) { // When the span-box is to be ignored, zero out the initial // values so that the span doesn't impact the final line // height. The contents of the span can impact the final line // height. // Note that things are readjusted for this span after its children // are reflowed minBCoord = BLOCKDIR_ALIGN_FRAMES_NO_MINIMUM; maxBCoord = BLOCKDIR_ALIGN_FRAMES_NO_MAXIMUM; } else { // The initial values for the min and max block coord values are in the // span's coordinate space, and cover the logical block size of the span. // If there are child frames in this span that stick out of this area // then the minBCoord and maxBCoord are updated by the amount of logical // blockSize that is outside this range. minBCoord = spanFramePFD->mBorderPadding.BStart(lineWM) - psd->mBStartLeading; maxBCoord = minBCoord + psd->mLogicalBSize; } // This is the distance from the top edge of the parents visual // box to the baseline. The span already computed this for us, // so just use it. *psd->mBaseline = baselineBCoord = spanFramePFD->mAscent; #ifdef NOISY_BLOCKDIR_ALIGN printf("[%sSpan]", (psd == mRootSpan)?"Root":""); nsFrame::ListTag(stdout, spanFrame); printf(": baseLine=%d logicalBSize=%d topLeading=%d h=%d bp=%d,%d zeroEffectiveSpanBox=%s\n", baselineBCoord, psd->mLogicalBSize, psd->mBStartLeading, spanFramePFD->mBounds.BSize(lineWM), spanFramePFD->mBorderPadding.Top(lineWM), spanFramePFD->mBorderPadding.Bottom(lineWM), zeroEffectiveSpanBox ? "yes" : "no"); #endif } nscoord maxStartBoxBSize = 0; nscoord maxEndBoxBSize = 0; PerFrameData* pfd = psd->mFirstFrame; while (nullptr != pfd) { nsIFrame* frame = pfd->mFrame; // sanity check (see bug 105168, non-reproducible crashes from null frame) NS_ASSERTION(frame, "null frame in PerFrameData - something is very very bad"); if (!frame) { return; } // Compute the logical block size of the frame nscoord logicalBSize; PerSpanData* frameSpan = pfd->mSpan; if (frameSpan) { // For span frames the logical-block-size and start-leading were // pre-computed when the span was reflowed. logicalBSize = frameSpan->mLogicalBSize; } else { // For other elements the logical block size is the same as the // frame's block size plus its margins. logicalBSize = pfd->mBounds.BSize(lineWM) + pfd->mMargin.BStartEnd(lineWM); if (logicalBSize < 0 && mPresContext->CompatibilityMode() == eCompatibility_NavQuirks) { pfd->mAscent -= logicalBSize; logicalBSize = 0; } } // Get vertical-align property ("vertical-align" is the CSS name for // block-direction align) const nsStyleCoord& verticalAlign = frame->StyleDisplay()->mVerticalAlign; uint8_t verticalAlignEnum = frame->VerticalAlignEnum(); #ifdef NOISY_BLOCKDIR_ALIGN printf(" [frame]"); nsFrame::ListTag(stdout, frame); printf(": verticalAlignUnit=%d (enum == %d", verticalAlign.GetUnit(), ((eStyleUnit_Enumerated == verticalAlign.GetUnit()) ? verticalAlign.GetIntValue() : -1)); if (verticalAlignEnum != nsIFrame::eInvalidVerticalAlign) { printf(", after SVG dominant-baseline conversion == %d", verticalAlignEnum); } printf(")\n"); #endif if (verticalAlignEnum != nsIFrame::eInvalidVerticalAlign) { if (lineWM.IsVertical()) { if (verticalAlignEnum == NS_STYLE_VERTICAL_ALIGN_MIDDLE) { // For vertical writing mode where the dominant baseline is centered // (i.e. text-orientation is not sideways-*), we remap 'middle' to // 'middle-with-baseline' so that images align sensibly with the // center-baseline-aligned text. if (!lineWM.IsSideways()) { verticalAlignEnum = NS_STYLE_VERTICAL_ALIGN_MIDDLE_WITH_BASELINE; } } else if (lineWM.IsLineInverted()) { // Swap the meanings of top and bottom when line is inverted // relative to block direction. switch (verticalAlignEnum) { case NS_STYLE_VERTICAL_ALIGN_TOP: verticalAlignEnum = NS_STYLE_VERTICAL_ALIGN_BOTTOM; break; case NS_STYLE_VERTICAL_ALIGN_BOTTOM: verticalAlignEnum = NS_STYLE_VERTICAL_ALIGN_TOP; break; case NS_STYLE_VERTICAL_ALIGN_TEXT_TOP: verticalAlignEnum = NS_STYLE_VERTICAL_ALIGN_TEXT_BOTTOM; break; case NS_STYLE_VERTICAL_ALIGN_TEXT_BOTTOM: verticalAlignEnum = NS_STYLE_VERTICAL_ALIGN_TEXT_TOP; break; } } } // baseline coord that may be adjusted for script offset nscoord revisedBaselineBCoord = baselineBCoord; // For superscript and subscript, raise or lower the baseline of the box // to the proper offset of the parent's box, then proceed as for BASELINE if (verticalAlignEnum == NS_STYLE_VERTICAL_ALIGN_SUB || verticalAlignEnum == NS_STYLE_VERTICAL_ALIGN_SUPER) { revisedBaselineBCoord += lineWM.FlowRelativeToLineRelativeFactor() * (verticalAlignEnum == NS_STYLE_VERTICAL_ALIGN_SUB ? fm->SubscriptOffset() : -fm->SuperscriptOffset()); verticalAlignEnum = NS_STYLE_VERTICAL_ALIGN_BASELINE; } switch (verticalAlignEnum) { default: case NS_STYLE_VERTICAL_ALIGN_BASELINE: if (lineWM.IsVertical() && !lineWM.IsSideways()) { if (frameSpan) { pfd->mBounds.BStart(lineWM) = revisedBaselineBCoord - pfd->mBounds.BSize(lineWM)/2; } else { pfd->mBounds.BStart(lineWM) = revisedBaselineBCoord - logicalBSize/2 + pfd->mMargin.BStart(lineWM); } } else { pfd->mBounds.BStart(lineWM) = revisedBaselineBCoord - pfd->mAscent; } pfd->mBlockDirAlign = VALIGN_OTHER; break; case NS_STYLE_VERTICAL_ALIGN_TOP: { pfd->mBlockDirAlign = VALIGN_TOP; nscoord subtreeBSize = logicalBSize; if (frameSpan) { subtreeBSize = frameSpan->mMaxBCoord - frameSpan->mMinBCoord; NS_ASSERTION(subtreeBSize >= logicalBSize, "unexpected subtree block size"); } if (subtreeBSize > maxStartBoxBSize) { maxStartBoxBSize = subtreeBSize; } break; } case NS_STYLE_VERTICAL_ALIGN_BOTTOM: { pfd->mBlockDirAlign = VALIGN_BOTTOM; nscoord subtreeBSize = logicalBSize; if (frameSpan) { subtreeBSize = frameSpan->mMaxBCoord - frameSpan->mMinBCoord; NS_ASSERTION(subtreeBSize >= logicalBSize, "unexpected subtree block size"); } if (subtreeBSize > maxEndBoxBSize) { maxEndBoxBSize = subtreeBSize; } break; } case NS_STYLE_VERTICAL_ALIGN_MIDDLE: { // Align the midpoint of the frame with 1/2 the parents // x-height above the baseline. nscoord parentXHeight = lineWM.FlowRelativeToLineRelativeFactor() * fm->XHeight(); if (frameSpan) { pfd->mBounds.BStart(lineWM) = baselineBCoord - (parentXHeight + pfd->mBounds.BSize(lineWM))/2; } else { pfd->mBounds.BStart(lineWM) = baselineBCoord - (parentXHeight + logicalBSize)/2 + pfd->mMargin.BStart(lineWM); } pfd->mBlockDirAlign = VALIGN_OTHER; break; } case NS_STYLE_VERTICAL_ALIGN_TEXT_TOP: { // The top of the logical box is aligned with the top of // the parent element's text. // XXX For vertical text we will need a new API to get the logical // max-ascent here nscoord parentAscent = lineWM.IsLineInverted() ? fm->MaxDescent() : fm->MaxAscent(); if (frameSpan) { pfd->mBounds.BStart(lineWM) = baselineBCoord - parentAscent - pfd->mBorderPadding.BStart(lineWM) + frameSpan->mBStartLeading; } else { pfd->mBounds.BStart(lineWM) = baselineBCoord - parentAscent + pfd->mMargin.BStart(lineWM); } pfd->mBlockDirAlign = VALIGN_OTHER; break; } case NS_STYLE_VERTICAL_ALIGN_TEXT_BOTTOM: { // The bottom of the logical box is aligned with the // bottom of the parent elements text. nscoord parentDescent = lineWM.IsLineInverted() ? fm->MaxAscent() : fm->MaxDescent(); if (frameSpan) { pfd->mBounds.BStart(lineWM) = baselineBCoord + parentDescent - pfd->mBounds.BSize(lineWM) + pfd->mBorderPadding.BEnd(lineWM) - frameSpan->mBEndLeading; } else { pfd->mBounds.BStart(lineWM) = baselineBCoord + parentDescent - pfd->mBounds.BSize(lineWM) - pfd->mMargin.BEnd(lineWM); } pfd->mBlockDirAlign = VALIGN_OTHER; break; } case NS_STYLE_VERTICAL_ALIGN_MIDDLE_WITH_BASELINE: { // Align the midpoint of the frame with the baseline of the parent. if (frameSpan) { pfd->mBounds.BStart(lineWM) = baselineBCoord - pfd->mBounds.BSize(lineWM)/2; } else { pfd->mBounds.BStart(lineWM) = baselineBCoord - logicalBSize/2 + pfd->mMargin.BStart(lineWM); } pfd->mBlockDirAlign = VALIGN_OTHER; break; } } } else { // We have either a coord, a percent, or a calc(). nscoord pctBasis = 0; if (verticalAlign.HasPercent()) { // Percentages are like lengths, except treated as a percentage // of the elements line block size value. float inflation = GetInflationForBlockDirAlignment(frame, mInflationMinFontSize); pctBasis = ReflowInput::CalcLineHeight(frame->GetContent(), frame->StyleContext(), mBlockReflowInput->ComputedBSize(), inflation); } nscoord offset = nsRuleNode::ComputeCoordPercentCalc(verticalAlign, pctBasis); // According to the CSS2 spec (10.8.1), a positive value // "raises" the box by the given distance while a negative value // "lowers" the box by the given distance (with zero being the // baseline). Since Y coordinates increase towards the bottom of // the screen we reverse the sign, unless the line orientation is // inverted relative to block direction. nscoord revisedBaselineBCoord = baselineBCoord - offset * lineWM.FlowRelativeToLineRelativeFactor(); if (lineWM.IsVertical() && !lineWM.IsSideways()) { // If we're using a dominant center baseline, we align with the center // of the frame being placed (bug 1133945). pfd->mBounds.BStart(lineWM) = revisedBaselineBCoord - pfd->mBounds.BSize(lineWM)/2; } else { pfd->mBounds.BStart(lineWM) = revisedBaselineBCoord - pfd->mAscent; } pfd->mBlockDirAlign = VALIGN_OTHER; } // Update minBCoord/maxBCoord for frames that we just placed. Do not factor // text into the equation. if (pfd->mBlockDirAlign == VALIGN_OTHER) { // Text frames do not contribute to the min/max Y values for the // line (instead their parent frame's font-size contributes). // XXXrbs -- relax this restriction because it causes text frames // to jam together when 'font-size-adjust' is enabled // and layout is using dynamic font heights (bug 20394) // -- Note #1: With this code enabled and with the fact that we are not // using Em[Ascent|Descent] as nsDimensions for text metrics in // GFX mean that the discussion in bug 13072 cannot hold. // -- Note #2: We still don't want empty-text frames to interfere. // For example in quirks mode, avoiding empty text frames prevents // "tall" lines around elements like <hr> since the rules of <hr> // in quirks.css have pseudo text contents with LF in them. #if 0 if (!pfd->mIsTextFrame) { #else // Only consider non empty text frames when line-height=normal bool canUpdate = !pfd->mIsTextFrame; if (!canUpdate && pfd->mIsNonWhitespaceTextFrame) { canUpdate = frame->StyleText()->mLineHeight.GetUnit() == eStyleUnit_Normal; } if (canUpdate) { #endif nscoord blockStart, blockEnd; if (frameSpan) { // For spans that were are now placing, use their position // plus their already computed min-Y and max-Y values for // computing blockStart and blockEnd. blockStart = pfd->mBounds.BStart(lineWM) + frameSpan->mMinBCoord; blockEnd = pfd->mBounds.BStart(lineWM) + frameSpan->mMaxBCoord; } else { blockStart = pfd->mBounds.BStart(lineWM) - pfd->mMargin.BStart(lineWM); blockEnd = blockStart + logicalBSize; } if (!preMode && mPresContext->CompatibilityMode() != eCompatibility_FullStandards && !logicalBSize) { // Check if it's a BR frame that is not alone on its line (it // is given a block size of zero to indicate this), and if so reset // blockStart and blockEnd so that BR frames don't influence the line. if (nsGkAtoms::brFrame == frame->GetType()) { blockStart = BLOCKDIR_ALIGN_FRAMES_NO_MINIMUM; blockEnd = BLOCKDIR_ALIGN_FRAMES_NO_MAXIMUM; } } if (blockStart < minBCoord) minBCoord = blockStart; if (blockEnd > maxBCoord) maxBCoord = blockEnd; #ifdef NOISY_BLOCKDIR_ALIGN printf(" [frame]raw: a=%d h=%d bp=%d,%d logical: h=%d leading=%d y=%d minBCoord=%d maxBCoord=%d\n", pfd->mAscent, pfd->mBounds.BSize(lineWM), pfd->mBorderPadding.Top(lineWM), pfd->mBorderPadding.Bottom(lineWM), logicalBSize, frameSpan ? frameSpan->mBStartLeading : 0, pfd->mBounds.BStart(lineWM), minBCoord, maxBCoord); #endif } if (psd != mRootSpan) { frame->SetRect(lineWM, pfd->mBounds, ContainerSizeForSpan(psd)); } } pfd = pfd->mNext; } // Factor in the minimum line block-size when handling the root-span for // the block. if (psd == mRootSpan) { // We should factor in the block element's minimum line-height (as // defined in section 10.8.1 of the css2 spec) assuming that // zeroEffectiveSpanBox is not set on the root span. This only happens // in some cases in quirks mode: // (1) if the root span contains non-whitespace text directly (this // is handled by zeroEffectiveSpanBox // (2) if this line has a bullet // (3) if this is the last line of an LI, DT, or DD element // (The last line before a block also counts, but not before a // BR) (NN4/IE5 quirk) // (1) and (2) above bool applyMinLH = !zeroEffectiveSpanBox || mHasBullet; bool isLastLine = !mGotLineBox || (!mLineBox->IsLineWrapped() && !mLineEndsInBR); if (!applyMinLH && isLastLine) { nsIContent* blockContent = mRootSpan->mFrame->mFrame->GetContent(); if (blockContent) { // (3) above, if the last line of LI, DT, or DD if (blockContent->IsAnyOfHTMLElements(nsGkAtoms::li, nsGkAtoms::dt, nsGkAtoms::dd)) { applyMinLH = true; } } } if (applyMinLH) { if (psd->mHasNonemptyContent || preMode || mHasBullet) { #ifdef NOISY_BLOCKDIR_ALIGN printf(" [span]==> adjusting min/maxBCoord: currentValues: %d,%d", minBCoord, maxBCoord); #endif nscoord minimumLineBSize = mMinLineBSize; nscoord blockStart = -nsLayoutUtils::GetCenteredFontBaseline(fm, minimumLineBSize, lineWM.IsLineInverted()); nscoord blockEnd = blockStart + minimumLineBSize; if (mStyleText->HasTextEmphasis()) { nscoord fontMaxHeight = fm->MaxHeight(); nscoord emphasisHeight = GetBSizeOfEmphasisMarks(spanFrame, inflation); nscoord delta = fontMaxHeight + emphasisHeight - minimumLineBSize; if (delta > 0) { if (minimumLineBSize < fontMaxHeight) { // If the leadings are negative, fill them first. nscoord ascent = fm->MaxAscent(); nscoord descent = fm->MaxDescent(); if (lineWM.IsLineInverted()) { Swap(ascent, descent); } blockStart = -ascent; blockEnd = descent; delta = emphasisHeight; } LogicalSide side = mStyleText->TextEmphasisSide(lineWM); if (side == eLogicalSideBStart) { blockStart -= delta; } else { blockEnd += delta; } } } if (blockStart < minBCoord) minBCoord = blockStart; if (blockEnd > maxBCoord) maxBCoord = blockEnd; #ifdef NOISY_BLOCKDIR_ALIGN printf(" new values: %d,%d\n", minBCoord, maxBCoord); #endif #ifdef NOISY_BLOCKDIR_ALIGN printf(" Used mMinLineBSize: %d, blockStart: %d, blockEnd: %d\n", mMinLineBSize, blockStart, blockEnd); #endif } else { // XXX issues: // [1] BR's on empty lines stop working // [2] May not honor css2's notion of handling empty elements // [3] blank lines in a pre-section ("\n") (handled with preMode) // XXX Are there other problems with this? #ifdef NOISY_BLOCKDIR_ALIGN printf(" [span]==> zapping min/maxBCoord: currentValues: %d,%d newValues: 0,0\n", minBCoord, maxBCoord); #endif minBCoord = maxBCoord = 0; } } } if ((minBCoord == BLOCKDIR_ALIGN_FRAMES_NO_MINIMUM) || (maxBCoord == BLOCKDIR_ALIGN_FRAMES_NO_MAXIMUM)) { minBCoord = maxBCoord = baselineBCoord; } if (psd != mRootSpan && zeroEffectiveSpanBox) { #ifdef NOISY_BLOCKDIR_ALIGN printf(" [span]adjusting for zeroEffectiveSpanBox\n"); printf(" Original: minBCoord=%d, maxBCoord=%d, bSize=%d, ascent=%d, logicalBSize=%d, topLeading=%d, bottomLeading=%d\n", minBCoord, maxBCoord, spanFramePFD->mBounds.BSize(lineWM), spanFramePFD->mAscent, psd->mLogicalBSize, psd->mBStartLeading, psd->mBEndLeading); #endif nscoord goodMinBCoord = spanFramePFD->mBorderPadding.BStart(lineWM) - psd->mBStartLeading; nscoord goodMaxBCoord = goodMinBCoord + psd->mLogicalBSize; // For cases like the one in bug 714519 (text-decoration placement // or making nsLineLayout::IsZeroBSize() handle // vertical-align:top/bottom on a descendant of the line that's not // a child of it), we want to treat elements that are // vertical-align: top or bottom somewhat like children for the // purposes of this quirk. To some extent, this is guessing, since // they might end up being aligned anywhere. However, we'll guess // that they'll be placed aligned with the top or bottom of this // frame (as though this frame is the only thing in the line). // (Guessing isn't crazy, since all we're doing is reducing the // scope of a quirk and making the behavior more standards-like.) if (maxStartBoxBSize > maxBCoord - minBCoord) { // Distribute maxStartBoxBSize to ascent (baselineBCoord - minBCoord), and // then to descent (maxBCoord - baselineBCoord) by adjusting minBCoord or // maxBCoord, but not to exceed goodMinBCoord and goodMaxBCoord. nscoord distribute = maxStartBoxBSize - (maxBCoord - minBCoord); nscoord ascentSpace = std::max(minBCoord - goodMinBCoord, 0); if (distribute > ascentSpace) { distribute -= ascentSpace; minBCoord -= ascentSpace; nscoord descentSpace = std::max(goodMaxBCoord - maxBCoord, 0); if (distribute > descentSpace) { maxBCoord += descentSpace; } else { maxBCoord += distribute; } } else { minBCoord -= distribute; } } if (maxEndBoxBSize > maxBCoord - minBCoord) { // Likewise, but preferring descent to ascent. nscoord distribute = maxEndBoxBSize - (maxBCoord - minBCoord); nscoord descentSpace = std::max(goodMaxBCoord - maxBCoord, 0); if (distribute > descentSpace) { distribute -= descentSpace; maxBCoord += descentSpace; nscoord ascentSpace = std::max(minBCoord - goodMinBCoord, 0); if (distribute > ascentSpace) { minBCoord -= ascentSpace; } else { minBCoord -= distribute; } } else { maxBCoord += distribute; } } if (minBCoord > goodMinBCoord) { nscoord adjust = minBCoord - goodMinBCoord; // positive // shrink the logical extents psd->mLogicalBSize -= adjust; psd->mBStartLeading -= adjust; } if (maxBCoord < goodMaxBCoord) { nscoord adjust = goodMaxBCoord - maxBCoord; psd->mLogicalBSize -= adjust; psd->mBEndLeading -= adjust; } if (minBCoord > 0) { // shrink the content by moving its block start down. This is tricky, // since the block start is the 0 for many coordinates, so what we do is // move everything else up. spanFramePFD->mAscent -= minBCoord; // move the baseline up spanFramePFD->mBounds.BSize(lineWM) -= minBCoord; // move the block end up psd->mBStartLeading += minBCoord; *psd->mBaseline -= minBCoord; pfd = psd->mFirstFrame; while (nullptr != pfd) { pfd->mBounds.BStart(lineWM) -= minBCoord; // move all the children // back up pfd->mFrame->SetRect(lineWM, pfd->mBounds, ContainerSizeForSpan(psd)); pfd = pfd->mNext; } maxBCoord -= minBCoord; // since minBCoord is in the frame's own // coordinate system minBCoord = 0; } if (maxBCoord < spanFramePFD->mBounds.BSize(lineWM)) { nscoord adjust = spanFramePFD->mBounds.BSize(lineWM) - maxBCoord; spanFramePFD->mBounds.BSize(lineWM) -= adjust; // move the bottom up psd->mBEndLeading += adjust; } #ifdef NOISY_BLOCKDIR_ALIGN printf(" New: minBCoord=%d, maxBCoord=%d, bSize=%d, ascent=%d, logicalBSize=%d, topLeading=%d, bottomLeading=%d\n", minBCoord, maxBCoord, spanFramePFD->mBounds.BSize(lineWM), spanFramePFD->mAscent, psd->mLogicalBSize, psd->mBStartLeading, psd->mBEndLeading); #endif } psd->mMinBCoord = minBCoord; psd->mMaxBCoord = maxBCoord; #ifdef NOISY_BLOCKDIR_ALIGN printf(" [span]==> minBCoord=%d maxBCoord=%d delta=%d maxStartBoxBSize=%d maxEndBoxBSize=%d\n", minBCoord, maxBCoord, maxBCoord - minBCoord, maxStartBoxBSize, maxEndBoxBSize); #endif if (maxStartBoxBSize > mMaxStartBoxBSize) { mMaxStartBoxBSize = maxStartBoxBSize; } if (maxEndBoxBSize > mMaxEndBoxBSize) { mMaxEndBoxBSize = maxEndBoxBSize; } } static void SlideSpanFrameRect(nsIFrame* aFrame, nscoord aDeltaWidth) { // This should not use nsIFrame::MovePositionBy because it happens // prior to relative positioning. In particular, because // nsBlockFrame::PlaceLine calls aLineLayout.TrimTrailingWhiteSpace() // prior to calling aLineLayout.RelativePositionFrames(). nsPoint p = aFrame->GetPosition(); p.x -= aDeltaWidth; aFrame->SetPosition(p); } bool nsLineLayout::TrimTrailingWhiteSpaceIn(PerSpanData* psd, nscoord* aDeltaISize) { PerFrameData* pfd = psd->mFirstFrame; if (!pfd) { *aDeltaISize = 0; return false; } pfd = pfd->Last(); while (nullptr != pfd) { #ifdef REALLY_NOISY_TRIM nsFrame::ListTag(stdout, psd->mFrame->mFrame); printf(": attempting trim of "); nsFrame::ListTag(stdout, pfd->mFrame); printf("\n"); #endif PerSpanData* childSpan = pfd->mSpan; WritingMode lineWM = mRootSpan->mWritingMode; if (childSpan) { // Maybe the child span has the trailing white-space in it? if (TrimTrailingWhiteSpaceIn(childSpan, aDeltaISize)) { nscoord deltaISize = *aDeltaISize; if (deltaISize) { // Adjust the child spans frame size pfd->mBounds.ISize(lineWM) -= deltaISize; if (psd != mRootSpan) { // When the child span is not a direct child of the block // we need to update the child spans frame rectangle // because it most likely will not be done again. Spans // that are direct children of the block will be updated // later, however, because the VerticalAlignFrames method // will be run after this method. nsSize containerSize = ContainerSizeForSpan(childSpan); nsIFrame* f = pfd->mFrame; LogicalRect r(lineWM, f->GetRect(), containerSize); r.ISize(lineWM) -= deltaISize; f->SetRect(lineWM, r, containerSize); } // Adjust the inline end edge of the span that contains the child span psd->mICoord -= deltaISize; // Slide any frames that follow the child span over by the // correct amount. The only thing that can follow the child // span is empty stuff, so we are just making things // sensible (keeping the combined area honest). while (pfd->mNext) { pfd = pfd->mNext; pfd->mBounds.IStart(lineWM) -= deltaISize; if (psd != mRootSpan) { // When the child span is not a direct child of the block // we need to update the child span's frame rectangle // because it most likely will not be done again. Spans // that are direct children of the block will be updated // later, however, because the VerticalAlignFrames method // will be run after this method. SlideSpanFrameRect(pfd->mFrame, deltaISize); } } } return true; } } else if (!pfd->mIsTextFrame && !pfd->mSkipWhenTrimmingWhitespace) { // If we hit a frame on the end that's not text and not a placeholder, // then there is no trailing whitespace to trim. Stop the search. *aDeltaISize = 0; return true; } else if (pfd->mIsTextFrame) { // Call TrimTrailingWhiteSpace even on empty textframes because they // might have a soft hyphen which should now appear, changing the frame's // width nsTextFrame::TrimOutput trimOutput = static_cast<nsTextFrame*>(pfd->mFrame)-> TrimTrailingWhiteSpace(mBlockReflowInput->mRenderingContext->GetDrawTarget()); #ifdef NOISY_TRIM nsFrame::ListTag(stdout, psd->mFrame->mFrame); printf(": trim of "); nsFrame::ListTag(stdout, pfd->mFrame); printf(" returned %d\n", trimOutput.mDeltaWidth); #endif if (trimOutput.mChanged) { pfd->mRecomputeOverflow = true; } // Delta width not being zero means that // there is trimmed space in the frame. if (trimOutput.mDeltaWidth) { pfd->mBounds.ISize(lineWM) -= trimOutput.mDeltaWidth; // If any trailing space is trimmed, the justification opportunity // generated by the space should be removed as well. pfd->mJustificationInfo.CancelOpportunityForTrimmedSpace(); // See if the text frame has already been placed in its parent if (psd != mRootSpan) { // The frame was already placed during psd's // reflow. Update the frames rectangle now. pfd->mFrame->SetRect(lineWM, pfd->mBounds, ContainerSizeForSpan(psd)); } // Adjust containing span's right edge psd->mICoord -= trimOutput.mDeltaWidth; // Slide any frames that follow the text frame over by the // right amount. The only thing that can follow the text // frame is empty stuff, so we are just making things // sensible (keeping the combined area honest). while (pfd->mNext) { pfd = pfd->mNext; pfd->mBounds.IStart(lineWM) -= trimOutput.mDeltaWidth; if (psd != mRootSpan) { // When the child span is not a direct child of the block // we need to update the child spans frame rectangle // because it most likely will not be done again. Spans // that are direct children of the block will be updated // later, however, because the VerticalAlignFrames method // will be run after this method. SlideSpanFrameRect(pfd->mFrame, trimOutput.mDeltaWidth); } } } if (pfd->mIsNonEmptyTextFrame || trimOutput.mChanged) { // Pass up to caller so they can shrink their span *aDeltaISize = trimOutput.mDeltaWidth; return true; } } pfd = pfd->mPrev; } *aDeltaISize = 0; return false; } bool nsLineLayout::TrimTrailingWhiteSpace() { PerSpanData* psd = mRootSpan; nscoord deltaISize; TrimTrailingWhiteSpaceIn(psd, &deltaISize); return 0 != deltaISize; } bool nsLineLayout::PerFrameData::ParticipatesInJustification() const { if (mIsBullet || mIsEmpty || mSkipWhenTrimmingWhitespace) { // Skip bullets, empty frames, and placeholders return false; } if (mIsTextFrame && !mIsNonWhitespaceTextFrame && static_cast<nsTextFrame*>(mFrame)->IsAtEndOfLine()) { // Skip trimmed whitespaces return false; } return true; } struct nsLineLayout::JustificationComputationState { PerFrameData* mFirstParticipant; PerFrameData* mLastParticipant; // When we are going across a boundary of ruby base, i.e. entering // one, leaving one, or both, the following fields will be set to // the corresponding ruby base frame for handling ruby-align. PerFrameData* mLastExitedRubyBase; PerFrameData* mLastEnteredRubyBase; JustificationComputationState() : mFirstParticipant(nullptr) , mLastParticipant(nullptr) , mLastExitedRubyBase(nullptr) , mLastEnteredRubyBase(nullptr) { } }; static bool IsRubyAlignSpaceAround(nsIFrame* aRubyBase) { return aRubyBase->StyleText()->mRubyAlign == NS_STYLE_RUBY_ALIGN_SPACE_AROUND; } /** * Assign justification gaps for justification * opportunities across two frames. */ /* static */ int nsLineLayout::AssignInterframeJustificationGaps( PerFrameData* aFrame, JustificationComputationState& aState) { PerFrameData* prev = aState.mLastParticipant; MOZ_ASSERT(prev); auto& assign = aFrame->mJustificationAssignment; auto& prevAssign = prev->mJustificationAssignment; if (aState.mLastExitedRubyBase || aState.mLastEnteredRubyBase) { PerFrameData* exitedRubyBase = aState.mLastExitedRubyBase; if (!exitedRubyBase || IsRubyAlignSpaceAround(exitedRubyBase->mFrame)) { prevAssign.mGapsAtEnd = 1; } else { exitedRubyBase->mJustificationAssignment.mGapsAtEnd = 1; } PerFrameData* enteredRubyBase = aState.mLastEnteredRubyBase; if (!enteredRubyBase || IsRubyAlignSpaceAround(enteredRubyBase->mFrame)) { assign.mGapsAtStart = 1; } else { enteredRubyBase->mJustificationAssignment.mGapsAtStart = 1; } // We are no longer going across a ruby base boundary. aState.mLastExitedRubyBase = nullptr; aState.mLastEnteredRubyBase = nullptr; return 1; } const auto& info = aFrame->mJustificationInfo; const auto& prevInfo = prev->mJustificationInfo; if (!info.mIsStartJustifiable && !prevInfo.mIsEndJustifiable) { return 0; } if (!info.mIsStartJustifiable) { prevAssign.mGapsAtEnd = 2; assign.mGapsAtStart = 0; } else if (!prevInfo.mIsEndJustifiable) { prevAssign.mGapsAtEnd = 0; assign.mGapsAtStart = 2; } else { prevAssign.mGapsAtEnd = 1; assign.mGapsAtStart = 1; } return 1; } /** * Compute the justification info of the given span, and store the * number of inner opportunities into the frame's justification info. * It returns the number of non-inner opportunities it detects. */ int32_t nsLineLayout::ComputeFrameJustification(PerSpanData* aPSD, JustificationComputationState& aState) { NS_ASSERTION(aPSD, "null arg"); NS_ASSERTION(!aState.mLastParticipant || !aState.mLastParticipant->mSpan, "Last participant shall always be a leaf frame"); bool firstChild = true; int32_t& innerOpportunities = aPSD->mFrame->mJustificationInfo.mInnerOpportunities; MOZ_ASSERT(innerOpportunities == 0, "Justification info should not have been set yet."); int32_t outerOpportunities = 0; for (PerFrameData* pfd = aPSD->mFirstFrame; pfd; pfd = pfd->mNext) { if (!pfd->ParticipatesInJustification()) { continue; } bool isRubyBase = pfd->mFrame->GetType() == nsGkAtoms::rubyBaseFrame; PerFrameData* outerRubyBase = aState.mLastEnteredRubyBase; if (isRubyBase) { aState.mLastEnteredRubyBase = pfd; } int extraOpportunities = 0; if (pfd->mSpan) { PerSpanData* span = pfd->mSpan; extraOpportunities = ComputeFrameJustification(span, aState); innerOpportunities += pfd->mJustificationInfo.mInnerOpportunities; } else { if (pfd->mIsTextFrame) { innerOpportunities += pfd->mJustificationInfo.mInnerOpportunities; } if (!aState.mLastParticipant) { aState.mFirstParticipant = pfd; // It is not an empty ruby base, but we are not assigning gaps // to the content for now. Clear the last entered ruby base so // that we can correctly set the last exited ruby base. aState.mLastEnteredRubyBase = nullptr; } else { extraOpportunities = AssignInterframeJustificationGaps(pfd, aState); } aState.mLastParticipant = pfd; } if (isRubyBase) { if (aState.mLastEnteredRubyBase == pfd) { // There is no justification participant inside this ruby base. // Ignore this ruby base completely and restore the outer ruby // base here. aState.mLastEnteredRubyBase = outerRubyBase; } else { aState.mLastExitedRubyBase = pfd; } } if (firstChild) { outerOpportunities = extraOpportunities; firstChild = false; } else { innerOpportunities += extraOpportunities; } } return outerOpportunities; } void nsLineLayout::AdvanceAnnotationInlineBounds(PerFrameData* aPFD, const nsSize& aContainerSize, nscoord aDeltaICoord, nscoord aDeltaISize) { nsIFrame* frame = aPFD->mFrame; nsIAtom* frameType = frame->GetType(); MOZ_ASSERT(frameType == nsGkAtoms::rubyTextFrame || frameType == nsGkAtoms::rubyTextContainerFrame); MOZ_ASSERT(aPFD->mSpan, "rt and rtc should have span."); PerSpanData* psd = aPFD->mSpan; WritingMode lineWM = mRootSpan->mWritingMode; aPFD->mBounds.IStart(lineWM) += aDeltaICoord; // Check whether this expansion should be counted into the reserved // isize or not. When it is a ruby text container, and it has some // children linked to the base, it must not have reserved isize, // or its children won't align with their bases. Otherwise, this // expansion should be reserved. There are two cases a ruby text // container does not have children linked to the base: // 1. it is a container for span; 2. its children are collapsed. // See bug 1055674 for the second case. if (frameType == nsGkAtoms::rubyTextFrame || // This ruby text container is a span. (psd->mFirstFrame == psd->mLastFrame && psd->mFirstFrame && !psd->mFirstFrame->mIsLinkedToBase)) { // For ruby text frames, only increase frames // which are not auto-hidden. if (frameType != nsGkAtoms::rubyTextFrame || !static_cast<nsRubyTextFrame*>(frame)->IsAutoHidden()) { nscoord reservedISize = RubyUtils::GetReservedISize(frame); RubyUtils::SetReservedISize(frame, reservedISize + aDeltaISize); } } else { // It is a normal ruby text container. Its children will expand // themselves properly. We only need to expand its own size here. aPFD->mBounds.ISize(lineWM) += aDeltaISize; } aPFD->mFrame->SetRect(lineWM, aPFD->mBounds, aContainerSize); } /** * This function applies the changes of icoord and isize caused by * justification to annotations of the given frame. */ void nsLineLayout::ApplyLineJustificationToAnnotations(PerFrameData* aPFD, nscoord aDeltaICoord, nscoord aDeltaISize) { PerFrameData* pfd = aPFD->mNextAnnotation; while (pfd) { nsSize containerSize = pfd->mFrame->GetParent()->GetSize(); AdvanceAnnotationInlineBounds(pfd, containerSize, aDeltaICoord, aDeltaISize); // There are two cases where an annotation frame has siblings which // do not attached to a ruby base-level frame: // 1. there's an intra-annotation whitespace which has no intra-base // white-space to pair with; // 2. there are not enough ruby bases to be paired with annotations. // In these cases, their size should not be affected, but we still // need to move them so that they won't overlap other frames. PerFrameData* sibling = pfd->mNext; while (sibling && !sibling->mIsLinkedToBase) { AdvanceAnnotationInlineBounds(sibling, containerSize, aDeltaICoord + aDeltaISize, 0); sibling = sibling->mNext; } pfd = pfd->mNextAnnotation; } } nscoord nsLineLayout::ApplyFrameJustification(PerSpanData* aPSD, JustificationApplicationState& aState) { NS_ASSERTION(aPSD, "null arg"); nscoord deltaICoord = 0; for (PerFrameData* pfd = aPSD->mFirstFrame; pfd != nullptr; pfd = pfd->mNext) { // Don't reposition bullets (and other frames that occur out of X-order?) if (!pfd->mIsBullet) { nscoord dw = 0; WritingMode lineWM = mRootSpan->mWritingMode; const auto& assign = pfd->mJustificationAssignment; bool isInlineText = pfd->mIsTextFrame && !pfd->mWritingMode.IsOrthogonalTo(lineWM); if (isInlineText) { if (aState.IsJustifiable()) { // Set corresponding justification gaps here, so that the // text frame knows how it should add gaps at its sides. const auto& info = pfd->mJustificationInfo; auto textFrame = static_cast<nsTextFrame*>(pfd->mFrame); textFrame->AssignJustificationGaps(assign); dw = aState.Consume(JustificationUtils::CountGaps(info, assign)); } if (dw) { pfd->mRecomputeOverflow = true; } } else { if (nullptr != pfd->mSpan) { dw = ApplyFrameJustification(pfd->mSpan, aState); } } pfd->mBounds.ISize(lineWM) += dw; nscoord gapsAtEnd = 0; if (!isInlineText && assign.TotalGaps()) { // It is possible that we assign gaps to non-text frame or an // orthogonal text frame. Apply the gaps as margin for them. deltaICoord += aState.Consume(assign.mGapsAtStart); gapsAtEnd = aState.Consume(assign.mGapsAtEnd); dw += gapsAtEnd; } pfd->mBounds.IStart(lineWM) += deltaICoord; // The gaps added to the end of the frame should also be // excluded from the isize added to the annotation. ApplyLineJustificationToAnnotations(pfd, deltaICoord, dw - gapsAtEnd); deltaICoord += dw; pfd->mFrame->SetRect(lineWM, pfd->mBounds, ContainerSizeForSpan(aPSD)); } } return deltaICoord; } static nsIFrame* FindNearestRubyBaseAncestor(nsIFrame* aFrame) { MOZ_ASSERT(aFrame->StyleContext()->ShouldSuppressLineBreak()); while (aFrame && aFrame->GetType() != nsGkAtoms::rubyBaseFrame) { aFrame = aFrame->GetParent(); } // XXX It is possible that no ruby base ancestor is found because of // some edge cases like form control or canvas inside ruby text. // See bug 1138092 comment 4. NS_WARNING_ASSERTION(aFrame, "no ruby base ancestor?"); return aFrame; } /** * This method expands the given frame by the given reserved isize. */ void nsLineLayout::ExpandRubyBox(PerFrameData* aFrame, nscoord aReservedISize, const nsSize& aContainerSize) { WritingMode lineWM = mRootSpan->mWritingMode; auto rubyAlign = aFrame->mFrame->StyleText()->mRubyAlign; switch (rubyAlign) { case NS_STYLE_RUBY_ALIGN_START: // do nothing for start break; case NS_STYLE_RUBY_ALIGN_SPACE_BETWEEN: case NS_STYLE_RUBY_ALIGN_SPACE_AROUND: { int32_t opportunities = aFrame->mJustificationInfo.mInnerOpportunities; int32_t gaps = opportunities * 2; if (rubyAlign == NS_STYLE_RUBY_ALIGN_SPACE_AROUND) { // Each expandable ruby box with ruby-align space-around has a // gap at each of its sides. For rb/rbc, see comment in // AssignInterframeJustificationGaps; for rt/rtc, see comment // in ExpandRubyBoxWithAnnotations. gaps += 2; } if (gaps > 0) { JustificationApplicationState state(gaps, aReservedISize); ApplyFrameJustification(aFrame->mSpan, state); break; } // If there are no justification opportunities for space-between, // fall-through to center per spec. MOZ_FALLTHROUGH; } case NS_STYLE_RUBY_ALIGN_CENTER: // Indent all children by half of the reserved inline size. for (PerFrameData* child = aFrame->mSpan->mFirstFrame; child; child = child->mNext) { child->mBounds.IStart(lineWM) += aReservedISize / 2; child->mFrame->SetRect(lineWM, child->mBounds, aContainerSize); } break; default: MOZ_ASSERT_UNREACHABLE("Unknown ruby-align value"); } aFrame->mBounds.ISize(lineWM) += aReservedISize; aFrame->mFrame->SetRect(lineWM, aFrame->mBounds, aContainerSize); } /** * This method expands the given frame by the reserved inline size. * It also expands its annotations if they are expandable and have * reserved isize larger than zero. */ void nsLineLayout::ExpandRubyBoxWithAnnotations(PerFrameData* aFrame, const nsSize& aContainerSize) { nscoord reservedISize = RubyUtils::GetReservedISize(aFrame->mFrame); if (reservedISize) { ExpandRubyBox(aFrame, reservedISize, aContainerSize); } WritingMode lineWM = mRootSpan->mWritingMode; bool isLevelContainer = aFrame->mFrame->GetType() == nsGkAtoms::rubyBaseContainerFrame; for (PerFrameData* annotation = aFrame->mNextAnnotation; annotation; annotation = annotation->mNextAnnotation) { if (isLevelContainer) { nsIFrame* rtcFrame = annotation->mFrame; MOZ_ASSERT(rtcFrame->GetType() == nsGkAtoms::rubyTextContainerFrame); // It is necessary to set the rect again because the container // width was unknown, and zero was used instead when we reflow // them. The corresponding base containers were repositioned in // VerticalAlignFrames and PlaceTopBottomFrames. MOZ_ASSERT( rtcFrame->GetLogicalSize(lineWM) == annotation->mBounds.Size(lineWM)); rtcFrame->SetPosition(lineWM, annotation->mBounds.Origin(lineWM), aContainerSize); } nscoord reservedISize = RubyUtils::GetReservedISize(annotation->mFrame); if (!reservedISize) { continue; } MOZ_ASSERT(annotation->mSpan); JustificationComputationState computeState; ComputeFrameJustification(annotation->mSpan, computeState); if (!computeState.mFirstParticipant) { continue; } if (IsRubyAlignSpaceAround(annotation->mFrame)) { // Add one gap at each side of this annotation. computeState.mFirstParticipant->mJustificationAssignment.mGapsAtStart = 1; computeState.mLastParticipant->mJustificationAssignment.mGapsAtEnd = 1; } nsIFrame* parentFrame = annotation->mFrame->GetParent(); nsSize containerSize = parentFrame->GetSize(); MOZ_ASSERT(containerSize == aContainerSize || parentFrame->GetType() == nsGkAtoms::rubyTextContainerFrame, "Container width should only be different when the current " "annotation is a ruby text frame, whose parent is not same " "as its base frame."); ExpandRubyBox(annotation, reservedISize, containerSize); ExpandInlineRubyBoxes(annotation->mSpan); } } /** * This method looks for all expandable ruby box in the given span, and * calls ExpandRubyBox to expand them in depth-first preorder. */ void nsLineLayout::ExpandInlineRubyBoxes(PerSpanData* aSpan) { nsSize containerSize = ContainerSizeForSpan(aSpan); for (PerFrameData* pfd = aSpan->mFirstFrame; pfd; pfd = pfd->mNext) { if (RubyUtils::IsExpandableRubyBox(pfd->mFrame)) { ExpandRubyBoxWithAnnotations(pfd, containerSize); } if (pfd->mSpan) { ExpandInlineRubyBoxes(pfd->mSpan); } } } // Align inline frames within the line according to the CSS text-align // property. void nsLineLayout::TextAlignLine(nsLineBox* aLine, bool aIsLastLine) { /** * NOTE: aIsLastLine ain't necessarily so: it is correctly set by caller * only in cases where the last line needs special handling. */ PerSpanData* psd = mRootSpan; WritingMode lineWM = psd->mWritingMode; LAYOUT_WARN_IF_FALSE(psd->mIEnd != NS_UNCONSTRAINEDSIZE, "have unconstrained width; this should only result from " "very large sizes, not attempts at intrinsic width " "calculation"); nscoord availISize = psd->mIEnd - psd->mIStart; nscoord remainingISize = availISize - aLine->ISize(); #ifdef NOISY_INLINEDIR_ALIGN nsFrame::ListTag(stdout, mBlockReflowInput->mFrame); printf(": availISize=%d lineBounds.IStart=%d lineISize=%d delta=%d\n", availISize, aLine->IStart(), aLine->ISize(), remainingISize); #endif // 'text-align-last: auto' is equivalent to the value of the 'text-align' // property except when 'text-align' is set to 'justify', in which case it // is 'justify' when 'text-justify' is 'distribute' and 'start' otherwise. // // XXX: the code below will have to change when we implement text-justify // nscoord dx = 0; uint8_t textAlign = mStyleText->mTextAlign; bool textAlignTrue = mStyleText->mTextAlignTrue; if (aIsLastLine) { textAlignTrue = mStyleText->mTextAlignLastTrue; if (mStyleText->mTextAlignLast == NS_STYLE_TEXT_ALIGN_AUTO) { if (textAlign == NS_STYLE_TEXT_ALIGN_JUSTIFY) { textAlign = NS_STYLE_TEXT_ALIGN_START; } } else { textAlign = mStyleText->mTextAlignLast; } } bool isSVG = mBlockReflowInput->mFrame->IsSVGText(); bool doTextAlign = remainingISize > 0 || textAlignTrue; int32_t additionalGaps = 0; if (!isSVG && (mHasRuby || (doTextAlign && textAlign == NS_STYLE_TEXT_ALIGN_JUSTIFY))) { JustificationComputationState computeState; ComputeFrameJustification(psd, computeState); if (mHasRuby && computeState.mFirstParticipant) { PerFrameData* firstFrame = computeState.mFirstParticipant; if (firstFrame->mFrame->StyleContext()->ShouldSuppressLineBreak()) { MOZ_ASSERT(!firstFrame->mJustificationAssignment.mGapsAtStart); nsIFrame* rubyBase = FindNearestRubyBaseAncestor(firstFrame->mFrame); if (rubyBase && IsRubyAlignSpaceAround(rubyBase)) { firstFrame->mJustificationAssignment.mGapsAtStart = 1; additionalGaps++; } } PerFrameData* lastFrame = computeState.mLastParticipant; if (lastFrame->mFrame->StyleContext()->ShouldSuppressLineBreak()) { MOZ_ASSERT(!lastFrame->mJustificationAssignment.mGapsAtEnd); nsIFrame* rubyBase = FindNearestRubyBaseAncestor(lastFrame->mFrame); if (rubyBase && IsRubyAlignSpaceAround(rubyBase)) { lastFrame->mJustificationAssignment.mGapsAtEnd = 1; additionalGaps++; } } } } if (!isSVG && doTextAlign) { switch (textAlign) { case NS_STYLE_TEXT_ALIGN_JUSTIFY: { int32_t opportunities = psd->mFrame->mJustificationInfo.mInnerOpportunities; if (opportunities > 0) { int32_t gaps = opportunities * 2 + additionalGaps; JustificationApplicationState applyState(gaps, remainingISize); // Apply the justification, and make sure to update our linebox // width to account for it. aLine->ExpandBy(ApplyFrameJustification(psd, applyState), ContainerSizeForSpan(psd)); MOZ_ASSERT(applyState.mGaps.mHandled == applyState.mGaps.mCount, "Unprocessed justification gaps"); MOZ_ASSERT(applyState.mWidth.mConsumed == applyState.mWidth.mAvailable, "Unprocessed justification width"); break; } // Fall through to the default case if we could not justify to fill // the space. MOZ_FALLTHROUGH; } case NS_STYLE_TEXT_ALIGN_START: // default alignment is to start edge so do nothing break; case NS_STYLE_TEXT_ALIGN_LEFT: case NS_STYLE_TEXT_ALIGN_MOZ_LEFT: if (!lineWM.IsBidiLTR()) { dx = remainingISize; } break; case NS_STYLE_TEXT_ALIGN_RIGHT: case NS_STYLE_TEXT_ALIGN_MOZ_RIGHT: if (lineWM.IsBidiLTR()) { dx = remainingISize; } break; case NS_STYLE_TEXT_ALIGN_END: dx = remainingISize; break; case NS_STYLE_TEXT_ALIGN_CENTER: case NS_STYLE_TEXT_ALIGN_MOZ_CENTER: dx = remainingISize / 2; break; } } if (mHasRuby) { ExpandInlineRubyBoxes(mRootSpan); } if (mPresContext->BidiEnabled() && (!mPresContext->IsVisualMode() || !lineWM.IsBidiLTR())) { nsBidiPresUtils::ReorderFrames(psd->mFirstFrame->mFrame, aLine->GetChildCount(), lineWM, mContainerSize, psd->mIStart + mTextIndent + dx); if (dx) { aLine->IndentBy(dx, ContainerSize()); } } else if (dx) { for (PerFrameData* pfd = psd->mFirstFrame; pfd; pfd = pfd->mNext) { pfd->mBounds.IStart(lineWM) += dx; pfd->mFrame->SetRect(lineWM, pfd->mBounds, ContainerSizeForSpan(psd)); } aLine->IndentBy(dx, ContainerSize()); } } // This method applies any relative positioning to the given frame. void nsLineLayout::ApplyRelativePositioning(PerFrameData* aPFD) { if (!aPFD->mRelativePos) { return; } nsIFrame* frame = aPFD->mFrame; WritingMode frameWM = aPFD->mWritingMode; LogicalPoint origin = frame->GetLogicalPosition(ContainerSize()); // right and bottom are handled by // ReflowInput::ComputeRelativeOffsets ReflowInput::ApplyRelativePositioning(frame, frameWM, aPFD->mOffsets, &origin, ContainerSize()); frame->SetPosition(frameWM, origin, ContainerSize()); } // This method do relative positioning for ruby annotations. void nsLineLayout::RelativePositionAnnotations(PerSpanData* aRubyPSD, nsOverflowAreas& aOverflowAreas) { MOZ_ASSERT(aRubyPSD->mFrame->mFrame->GetType() == nsGkAtoms::rubyFrame); for (PerFrameData* pfd = aRubyPSD->mFirstFrame; pfd; pfd = pfd->mNext) { MOZ_ASSERT(pfd->mFrame->GetType() == nsGkAtoms::rubyBaseContainerFrame); for (PerFrameData* rtc = pfd->mNextAnnotation; rtc; rtc = rtc->mNextAnnotation) { nsIFrame* rtcFrame = rtc->mFrame; MOZ_ASSERT(rtcFrame->GetType() == nsGkAtoms::rubyTextContainerFrame); ApplyRelativePositioning(rtc); nsOverflowAreas rtcOverflowAreas; RelativePositionFrames(rtc->mSpan, rtcOverflowAreas); aOverflowAreas.UnionWith(rtcOverflowAreas + rtcFrame->GetPosition()); } } } void nsLineLayout::RelativePositionFrames(PerSpanData* psd, nsOverflowAreas& aOverflowAreas) { nsOverflowAreas overflowAreas; WritingMode wm = psd->mWritingMode; if (psd != mRootSpan) { // The span's overflow areas come in three parts: // -- this frame's width and height // -- pfd->mOverflowAreas, which is the area of a bullet or the union // of a relatively positioned frame's absolute children // -- the bounds of all inline descendants // The former two parts are computed right here, we gather the descendants // below. // At this point psd->mFrame->mBounds might be out of date since // bidi reordering can move and resize the frames. So use the frame's // rect instead of mBounds. nsRect adjustedBounds(nsPoint(0, 0), psd->mFrame->mFrame->GetSize()); overflowAreas.ScrollableOverflow().UnionRect( psd->mFrame->mOverflowAreas.ScrollableOverflow(), adjustedBounds); overflowAreas.VisualOverflow().UnionRect( psd->mFrame->mOverflowAreas.VisualOverflow(), adjustedBounds); } else { LogicalRect rect(wm, psd->mIStart, mBStartEdge, psd->mICoord - psd->mIStart, mFinalLineBSize); // The minimum combined area for the frames that are direct // children of the block starts at the upper left corner of the // line and is sized to match the size of the line's bounding box // (the same size as the values returned from VerticalAlignFrames) overflowAreas.VisualOverflow() = rect.GetPhysicalRect(wm, ContainerSize()); overflowAreas.ScrollableOverflow() = overflowAreas.VisualOverflow(); } for (PerFrameData* pfd = psd->mFirstFrame; pfd; pfd = pfd->mNext) { nsIFrame* frame = pfd->mFrame; // Adjust the origin of the frame ApplyRelativePositioning(pfd); // We must position the view correctly before positioning its // descendants so that widgets are positioned properly (since only // some views have widgets). if (frame->HasView()) nsContainerFrame::SyncFrameViewAfterReflow(mPresContext, frame, frame->GetView(), pfd->mOverflowAreas.VisualOverflow(), NS_FRAME_NO_SIZE_VIEW); // Note: the combined area of a child is in its coordinate // system. We adjust the childs combined area into our coordinate // system before computing the aggregated value by adding in // <b>x</b> and <b>y</b> which were computed above. nsOverflowAreas r; if (pfd->mSpan) { // Compute a new combined area for the child span before // aggregating it into our combined area. RelativePositionFrames(pfd->mSpan, r); } else { r = pfd->mOverflowAreas; if (pfd->mIsTextFrame) { // We need to recompute overflow areas in four cases: // (1) When PFD_RECOMPUTEOVERFLOW is set due to trimming // (2) When there are text decorations, since we can't recompute the // overflow area until Reflow and VerticalAlignLine have finished // (3) When there are text emphasis marks, since the marks may be // put further away if the text is inside ruby. // (4) When there are text strokes if (pfd->mRecomputeOverflow || frame->StyleContext()->HasTextDecorationLines() || frame->StyleText()->HasTextEmphasis() || frame->StyleText()->HasWebkitTextStroke()) { nsTextFrame* f = static_cast<nsTextFrame*>(frame); r = f->RecomputeOverflow(mBlockReflowInput->mFrame); } frame->FinishAndStoreOverflow(r, frame->GetSize()); } // If we have something that's not an inline but with a complex frame // hierarchy inside that contains views, they need to be // positioned. // All descendant views must be repositioned even if this frame // does have a view in case this frame's view does not have a // widget and some of the descendant views do have widgets -- // otherwise the widgets won't be repositioned. nsContainerFrame::PositionChildViews(frame); } // Do this here (rather than along with setting the overflow rect // below) so we get leaf frames as well. No need to worry // about the root span, since it doesn't have a frame. if (frame->HasView()) nsContainerFrame::SyncFrameViewAfterReflow(mPresContext, frame, frame->GetView(), r.VisualOverflow(), NS_FRAME_NO_MOVE_VIEW); overflowAreas.UnionWith(r + frame->GetPosition()); } // Also compute relative position in the annotations. if (psd->mFrame->mFrame->GetType() == nsGkAtoms::rubyFrame) { RelativePositionAnnotations(psd, overflowAreas); } // If we just computed a spans combined area, we need to update its // overflow rect... if (psd != mRootSpan) { PerFrameData* spanPFD = psd->mFrame; nsIFrame* frame = spanPFD->mFrame; frame->FinishAndStoreOverflow(overflowAreas, frame->GetSize()); } aOverflowAreas = overflowAreas; }