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/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
/* vim: set ts=8 sts=2 et sw=2 tw=80: */
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
/* state used in reflow of block frames */
#include "BlockReflowState.h"
#include <algorithm>
#include "LayoutLogging.h"
#include "nsBlockFrame.h"
#include "nsLineLayout.h"
#include "nsPresContext.h"
#include "nsIFrameInlines.h"
#include "mozilla/AutoRestore.h"
#include "mozilla/DebugOnly.h"
#include "mozilla/Preferences.h"
#include "mozilla/StaticPrefs_layout.h"
#include "TextOverflow.h"
#ifdef DEBUG
# include "nsBlockDebugFlags.h"
#endif
using namespace mozilla;
using namespace mozilla::layout;
BlockReflowState::BlockReflowState(
const ReflowInput& aReflowInput, nsPresContext* aPresContext,
nsBlockFrame* aFrame, bool aBStartMarginRoot, bool aBEndMarginRoot,
bool aBlockNeedsFloatManager, const nscoord aConsumedBSize,
const nscoord aEffectiveContentBoxBSize, const nscoord aInset)
: mBlock(aFrame),
mPresContext(aPresContext),
mReflowInput(aReflowInput),
mContentArea(aReflowInput.GetWritingMode()),
mInsetForBalance(aInset),
mContainerSize(aReflowInput.ComputedSizeAsContainerIfConstrained()),
mOverflowTracker(nullptr),
mBorderPadding(
mReflowInput
.ComputedLogicalBorderPadding(mReflowInput.GetWritingMode())
.ApplySkipSides(aFrame->PreReflowBlockLevelLogicalSkipSides())),
mMinLineHeight(aReflowInput.GetLineHeight()),
mLineNumber(0),
mTrailingClearFromPIF(UsedClear::None),
mConsumedBSize(aConsumedBSize),
mAlignContentShift(mBlock->GetAlignContentShift()) {
NS_ASSERTION(mConsumedBSize != NS_UNCONSTRAINEDSIZE,
"The consumed block-size should be constrained!");
WritingMode wm = aReflowInput.GetWritingMode();
if (aBStartMarginRoot || 0 != mBorderPadding.BStart(wm)) {
mFlags.mIsBStartMarginRoot = true;
mFlags.mShouldApplyBStartMargin = true;
}
if (aBEndMarginRoot || 0 != mBorderPadding.BEnd(wm)) {
mFlags.mIsBEndMarginRoot = true;
}
if (aBlockNeedsFloatManager) {
mFlags.mBlockNeedsFloatManager = true;
}
mFlags.mCanHaveOverflowMarkers = css::TextOverflow::CanHaveOverflowMarkers(
mBlock, css::TextOverflow::BeforeReflow::Yes);
MOZ_ASSERT(FloatManager(),
"Float manager should be valid when creating BlockReflowState!");
// Save the coordinate system origin for later.
FloatManager()->GetTranslation(mFloatManagerI, mFloatManagerB);
FloatManager()->PushState(&mFloatManagerStateBefore); // never popped
mNextInFlow = static_cast<nsBlockFrame*>(mBlock->GetNextInFlow());
LAYOUT_WARN_IF_FALSE(NS_UNCONSTRAINEDSIZE != aReflowInput.ComputedISize(),
"have unconstrained width; this should only result "
"from very large sizes, not attempts at intrinsic "
"width calculation");
mContentArea.ISize(wm) = aReflowInput.ComputedISize();
// Compute content area block-size. Unlike the inline-size, if we have a
// specified style block-size, we ignore it since extra content is managed by
// the "overflow" property. When we don't have a specified style block-size,
// then we may end up limiting our block-size if the available block-size is
// constrained (this situation occurs when we are paginated).
const nscoord availableBSize = aReflowInput.AvailableBSize();
if (availableBSize != NS_UNCONSTRAINEDSIZE) {
// We are in a paginated situation. The block-end edge of the available
// space to reflow the children is within our block-end border and padding.
// If we're cloning our border and padding, and we're going to request
// additional continuations because of our excessive content-box block-size,
// then reserve some of our available space for our (cloned) block-end
// border and padding.
const bool reserveSpaceForBlockEndBP =
mReflowInput.mStyleBorder->mBoxDecorationBreak ==
StyleBoxDecorationBreak::Clone &&
(aEffectiveContentBoxBSize == NS_UNCONSTRAINEDSIZE ||
aEffectiveContentBoxBSize + mBorderPadding.BStartEnd(wm) >
availableBSize);
const nscoord bp = reserveSpaceForBlockEndBP ? mBorderPadding.BStartEnd(wm)
: mBorderPadding.BStart(wm);
mContentArea.BSize(wm) = std::max(0, availableBSize - bp);
} else {
// When we are not in a paginated situation, then we always use a
// unconstrained block-size.
mContentArea.BSize(wm) = NS_UNCONSTRAINEDSIZE;
}
mContentArea.IStart(wm) = mBorderPadding.IStart(wm);
mBCoord = mContentArea.BStart(wm) = mBorderPadding.BStart(wm);
// Account for existing cached shift, we'll re-position in AlignContent() if
// needed.
if (mAlignContentShift) {
mBCoord += mAlignContentShift;
mContentArea.BStart(wm) += mAlignContentShift;
if (availableBSize != NS_UNCONSTRAINEDSIZE) {
mContentArea.BSize(wm) += mAlignContentShift;
}
}
mPrevChild = nullptr;
mCurrentLine = aFrame->LinesEnd();
}
void BlockReflowState::UndoAlignContentShift() {
if (!mAlignContentShift) {
return;
}
mBCoord -= mAlignContentShift;
mContentArea.BStart(mReflowInput.GetWritingMode()) -= mAlignContentShift;
if (mReflowInput.AvailableBSize() != NS_UNCONSTRAINEDSIZE) {
mContentArea.BSize(mReflowInput.GetWritingMode()) -= mAlignContentShift;
}
}
void BlockReflowState::ComputeFloatAvoidingOffsets(
nsIFrame* aFloatAvoidingBlock, const LogicalRect& aFloatAvailableSpace,
nscoord& aIStartResult, nscoord& aIEndResult) const {
WritingMode wm = mReflowInput.GetWritingMode();
// The frame is clueless about the float manager and therefore we
// only give it free space. An example is a table frame - the
// tables do not flow around floats.
// However, we can let its margins intersect floats.
NS_ASSERTION(aFloatAvailableSpace.IStart(wm) >= mContentArea.IStart(wm),
"bad avail space rect inline-coord");
NS_ASSERTION(aFloatAvailableSpace.ISize(wm) == 0 ||
aFloatAvailableSpace.IEnd(wm) <= mContentArea.IEnd(wm),
"bad avail space rect inline-size");
nscoord iStartOffset, iEndOffset;
if (aFloatAvailableSpace.ISize(wm) == mContentArea.ISize(wm)) {
// We don't need to compute margins when there are no floats around.
iStartOffset = 0;
iEndOffset = 0;
} else {
const LogicalMargin frameMargin =
SizeComputationInput(aFloatAvoidingBlock,
mReflowInput.mRenderingContext, wm,
mContentArea.ISize(wm))
.ComputedLogicalMargin(wm);
nscoord iStartFloatIOffset =
aFloatAvailableSpace.IStart(wm) - mContentArea.IStart(wm);
iStartOffset = std::max(iStartFloatIOffset, frameMargin.IStart(wm)) -
frameMargin.IStart(wm);
iStartOffset = std::max(iStartOffset, 0); // in case of negative margin
nscoord iEndFloatIOffset =
mContentArea.IEnd(wm) - aFloatAvailableSpace.IEnd(wm);
iEndOffset =
std::max(iEndFloatIOffset, frameMargin.IEnd(wm)) - frameMargin.IEnd(wm);
iEndOffset = std::max(iEndOffset, 0); // in case of negative margin
}
aIStartResult = iStartOffset;
aIEndResult = iEndOffset;
}
LogicalRect BlockReflowState::ComputeBlockAvailSpace(
nsIFrame* aFrame, const nsFlowAreaRect& aFloatAvailableSpace,
bool aBlockAvoidsFloats) {
#ifdef REALLY_NOISY_REFLOW
printf("CBAS frame=%p has floats %d\n", aFrame,
aFloatAvailableSpace.HasFloats());
#endif
WritingMode wm = mReflowInput.GetWritingMode();
LogicalRect result(wm);
result.BStart(wm) = mBCoord;
// Note: ContentBSize() and ContentBEnd() are not our content-box size and its
// block-end edge. They really mean "the available block-size for children",
// and "the block-end edge of the available space for children".
result.BSize(wm) = ContentBSize() == NS_UNCONSTRAINEDSIZE
? NS_UNCONSTRAINEDSIZE
: ContentBEnd() - mBCoord;
// mBCoord might be greater than ContentBEnd() if the block's top margin
// pushes it off the page/column. Negative available block-size can confuse
// other code and is nonsense in principle.
// XXX Do we really want this condition to be this restrictive (i.e.,
// more restrictive than it used to be)? The |else| here is allowed
// by the CSS spec, but only out of desperation given implementations,
// and the behavior it leads to is quite undesirable (it can cause
// things to become extremely narrow when they'd fit quite well a
// little bit lower). Should the else be a quirk or something that
// applies to a specific set of frame classes and no new ones?
// If we did that, then for those frames where the condition below is
// true but nsBlockFrame::BlockCanIntersectFloats is false,
// nsBlockFrame::ISizeToClearPastFloats would need to use the
// shrink-wrap formula, max(MinISize, min(avail width, PrefISize))
// rather than just using MinISize.
NS_ASSERTION(
nsBlockFrame::BlockCanIntersectFloats(aFrame) == !aBlockAvoidsFloats,
"unexpected replaced width");
if (!aBlockAvoidsFloats) {
if (aFloatAvailableSpace.HasFloats()) {
// Use the float-edge property to determine how the child block
// will interact with the float.
const nsStyleBorder* borderStyle = aFrame->StyleBorder();
switch (borderStyle->mFloatEdge) {
default:
case StyleFloatEdge::ContentBox: // content and only content does
// runaround of floats
// The child block will flow around the float. Therefore
// give it all of the available space.
result.IStart(wm) = mContentArea.IStart(wm);
result.ISize(wm) = mContentArea.ISize(wm);
break;
case StyleFloatEdge::MarginBox: {
// The child block's margins should be placed adjacent to,
// but not overlap the float.
result.IStart(wm) = aFloatAvailableSpace.mRect.IStart(wm);
result.ISize(wm) = aFloatAvailableSpace.mRect.ISize(wm);
} break;
}
} else {
// Since there are no floats present the float-edge property
// doesn't matter therefore give the block element all of the
// available space since it will flow around the float itself.
result.IStart(wm) = mContentArea.IStart(wm);
result.ISize(wm) = mContentArea.ISize(wm);
}
} else {
nscoord iStartOffset, iEndOffset;
ComputeFloatAvoidingOffsets(aFrame, aFloatAvailableSpace.mRect,
iStartOffset, iEndOffset);
result.IStart(wm) = mContentArea.IStart(wm) + iStartOffset;
result.ISize(wm) = mContentArea.ISize(wm) - iStartOffset - iEndOffset;
}
#ifdef REALLY_NOISY_REFLOW
printf(" CBAS: result %d %d %d %d\n", result.IStart(wm), result.BStart(wm),
result.ISize(wm), result.BSize(wm));
#endif
return result;
}
LogicalSize BlockReflowState::ComputeAvailableSizeForFloat() const {
const auto wm = mReflowInput.GetWritingMode();
const nscoord availBSize = ContentBSize() == NS_UNCONSTRAINEDSIZE
? NS_UNCONSTRAINEDSIZE
: std::max(0, ContentBEnd() - mBCoord);
return LogicalSize(wm, ContentISize(), availBSize);
}
bool BlockReflowState::FloatAvoidingBlockFitsInAvailSpace(
nsIFrame* aFloatAvoidingBlock,
const nsFlowAreaRect& aFloatAvailableSpace) const {
if (!aFloatAvailableSpace.HasFloats()) {
// If there aren't any floats here, then we always fit.
// We check this before calling ISizeToClearPastFloats, which is
// somewhat expensive.
return true;
}
// |aFloatAvailableSpace| was computed as having a negative size, which means
// there are floats on both sides pushing inwards past each other, and
// |aFloatAvoidingBlock| would necessarily intersect a float if we put it
// here. So, it doesn't fit.
if (aFloatAvailableSpace.ISizeIsActuallyNegative()) {
return false;
}
WritingMode wm = mReflowInput.GetWritingMode();
nsBlockFrame::FloatAvoidingISizeToClear replacedISize =
nsBlockFrame::ISizeToClearPastFloats(*this, aFloatAvailableSpace.mRect,
aFloatAvoidingBlock);
// The inline-start side of the replaced element should be offset by
// the larger of the float intrusion or the replaced element's own
// start margin. The inline-end side is similar, except for Web
// compatibility we ignore the margin.
return std::max(
aFloatAvailableSpace.mRect.IStart(wm) - mContentArea.IStart(wm),
replacedISize.marginIStart) +
replacedISize.borderBoxISize +
(mContentArea.IEnd(wm) - aFloatAvailableSpace.mRect.IEnd(wm)) <=
mContentArea.ISize(wm);
}
nsFlowAreaRect BlockReflowState::GetFloatAvailableSpaceWithState(
WritingMode aCBWM, nscoord aBCoord, ShapeType aShapeType,
nsFloatManager::SavedState* aState) const {
WritingMode wm = mReflowInput.GetWritingMode();
#ifdef DEBUG
// Verify that the caller setup the coordinate system properly
nscoord wI, wB;
FloatManager()->GetTranslation(wI, wB);
NS_ASSERTION((wI == mFloatManagerI) && (wB == mFloatManagerB),
"bad coord system");
#endif
nscoord blockSize = (mContentArea.BSize(wm) == nscoord_MAX)
? nscoord_MAX
: std::max(mContentArea.BEnd(wm) - aBCoord, 0);
nsFlowAreaRect result = FloatManager()->GetFlowArea(
aCBWM, wm, aBCoord, blockSize, BandInfoType::BandFromPoint, aShapeType,
mContentArea, aState, ContainerSize());
// Keep the inline size >= 0 for compatibility with nsSpaceManager.
if (result.mRect.ISize(wm) < 0) {
result.mRect.ISize(wm) = 0;
}
#ifdef DEBUG
if (nsBlockFrame::gNoisyReflow) {
nsIFrame::IndentBy(stdout, nsBlockFrame::gNoiseIndent);
printf("%s: band=%d,%d,%d,%d hasfloats=%d\n", __func__,
result.mRect.IStart(wm), result.mRect.BStart(wm),
result.mRect.ISize(wm), result.mRect.BSize(wm), result.HasFloats());
}
#endif
return result;
}
nsFlowAreaRect BlockReflowState::GetFloatAvailableSpaceForBSize(
WritingMode aCBWM, nscoord aBCoord, nscoord aBSize,
nsFloatManager::SavedState* aState) const {
WritingMode wm = mReflowInput.GetWritingMode();
#ifdef DEBUG
// Verify that the caller setup the coordinate system properly
nscoord wI, wB;
FloatManager()->GetTranslation(wI, wB);
NS_ASSERTION((wI == mFloatManagerI) && (wB == mFloatManagerB),
"bad coord system");
#endif
nsFlowAreaRect result = FloatManager()->GetFlowArea(
aCBWM, wm, aBCoord, aBSize, BandInfoType::WidthWithinHeight,
ShapeType::ShapeOutside, mContentArea, aState, ContainerSize());
// Keep the width >= 0 for compatibility with nsSpaceManager.
if (result.mRect.ISize(wm) < 0) {
result.mRect.ISize(wm) = 0;
}
#ifdef DEBUG
if (nsBlockFrame::gNoisyReflow) {
nsIFrame::IndentBy(stdout, nsBlockFrame::gNoiseIndent);
printf("%s: space=%d,%d,%d,%d hasfloats=%d\n", __func__,
result.mRect.IStart(wm), result.mRect.BStart(wm),
result.mRect.ISize(wm), result.mRect.BSize(wm), result.HasFloats());
}
#endif
return result;
}
/*
* Reconstruct the vertical margin before the line |aLine| in order to
* do an incremental reflow that begins with |aLine| without reflowing
* the line before it. |aLine| may point to the fencepost at the end of
* the line list, and it is used this way since we (for now, anyway)
* always need to recover margins at the end of a block.
*
* The reconstruction involves walking backward through the line list to
* find any collapsed margins preceding the line that would have been in
* the reflow input's |mPrevBEndMargin| when we reflowed that line in
* a full reflow (under the rule in CSS2 that all adjacent vertical
* margins of blocks collapse).
*/
void BlockReflowState::ReconstructMarginBefore(nsLineList::iterator aLine) {
mPrevBEndMargin.Zero();
nsBlockFrame* block = mBlock;
nsLineList::iterator firstLine = block->LinesBegin();
for (;;) {
--aLine;
if (aLine->IsBlock()) {
mPrevBEndMargin = aLine->GetCarriedOutBEndMargin();
break;
}
if (!aLine->IsEmpty()) {
break;
}
if (aLine == firstLine) {
// If the top margin was carried out (and thus already applied),
// set it to zero. Either way, we're done.
if (!mFlags.mIsBStartMarginRoot) {
mPrevBEndMargin.Zero();
}
break;
}
}
}
void BlockReflowState::AppendPushedFloatChain(nsIFrame* aFloatCont) {
nsFrameList* pushedFloats = mBlock->EnsurePushedFloats();
while (true) {
aFloatCont->AddStateBits(NS_FRAME_IS_PUSHED_FLOAT);
pushedFloats->AppendFrame(mBlock, aFloatCont);
aFloatCont = aFloatCont->GetNextInFlow();
if (!aFloatCont || aFloatCont->GetParent() != mBlock) {
break;
}
mBlock->StealFrame(aFloatCont);
}
}
/**
* Restore information about floats into the float manager for an
* incremental reflow, and simultaneously push the floats by
* |aDeltaBCoord|, which is the amount |aLine| was pushed relative to its
* parent. The recovery of state is one of the things that makes
* incremental reflow O(N^2) and this state should really be kept
* around, attached to the frame tree.
*/
void BlockReflowState::RecoverFloats(nsLineList::iterator aLine,
nscoord aDeltaBCoord) {
WritingMode wm = mReflowInput.GetWritingMode();
if (aLine->HasFloats()) {
// Place the floats into the float manager again. Also slide
// them, just like the regular frames on the line.
for (nsIFrame* floatFrame : aLine->Floats()) {
if (aDeltaBCoord != 0) {
floatFrame->MovePositionBy(nsPoint(0, aDeltaBCoord));
nsContainerFrame::PositionFrameView(floatFrame);
nsContainerFrame::PositionChildViews(floatFrame);
}
#ifdef DEBUG
if (nsBlockFrame::gNoisyReflow || nsBlockFrame::gNoisyFloatManager) {
nscoord tI, tB;
FloatManager()->GetTranslation(tI, tB);
nsIFrame::IndentBy(stdout, nsBlockFrame::gNoiseIndent);
printf("RecoverFloats: tIB=%d,%d (%d,%d) ", tI, tB, mFloatManagerI,
mFloatManagerB);
floatFrame->ListTag(stdout);
LogicalRect region =
nsFloatManager::GetRegionFor(wm, floatFrame, ContainerSize());
printf(" aDeltaBCoord=%d region={%d,%d,%d,%d}\n", aDeltaBCoord,
region.IStart(wm), region.BStart(wm), region.ISize(wm),
region.BSize(wm));
}
#endif
FloatManager()->AddFloat(
floatFrame,
nsFloatManager::GetRegionFor(wm, floatFrame, ContainerSize()), wm,
ContainerSize());
}
} else if (aLine->IsBlock()) {
nsBlockFrame::RecoverFloatsFor(aLine->mFirstChild, *FloatManager(), wm,
ContainerSize());
}
}
/**
* Everything done in this function is done O(N) times for each pass of
* reflow so it is O(N*M) where M is the number of incremental reflow
* passes. That's bad. Don't do stuff here.
*
* When this function is called, |aLine| has just been slid by |aDeltaBCoord|
* and the purpose of RecoverStateFrom is to ensure that the
* BlockReflowState is in the same state that it would have been in
* had the line just been reflowed.
*
* Most of the state recovery that we have to do involves floats.
*/
void BlockReflowState::RecoverStateFrom(nsLineList::iterator aLine,
nscoord aDeltaBCoord) {
// Make the line being recovered the current line
mCurrentLine = aLine;
// Place floats for this line into the float manager
if (aLine->HasFloats() || aLine->IsBlock()) {
RecoverFloats(aLine, aDeltaBCoord);
#ifdef DEBUG
if (nsBlockFrame::gNoisyReflow || nsBlockFrame::gNoisyFloatManager) {
FloatManager()->List(stdout);
}
#endif
}
}
// This is called by the line layout's AddFloat method when a
// place-holder frame is reflowed in a line. If the float is a
// left-most child (it's x coordinate is at the line's left margin)
// then the float is place immediately, otherwise the float
// placement is deferred until the line has been reflowed.
// XXXldb This behavior doesn't quite fit with CSS1 and CSS2 --
// technically we're supposed let the current line flow around the
// float as well unless it won't fit next to what we already have.
// But nobody else implements it that way...
bool BlockReflowState::AddFloat(nsLineLayout* aLineLayout, nsIFrame* aFloat,
nscoord aAvailableISize) {
MOZ_ASSERT(aLineLayout, "must have line layout");
MOZ_ASSERT(mBlock->LinesEnd() != mCurrentLine, "null ptr");
MOZ_ASSERT(aFloat->HasAnyStateBits(NS_FRAME_OUT_OF_FLOW),
"aFloat must be an out-of-flow frame");
MOZ_ASSERT(aFloat->GetParent(), "float must have parent");
MOZ_ASSERT(aFloat->GetParent()->IsBlockFrameOrSubclass(),
"float's parent must be block");
if (aFloat->HasAnyStateBits(NS_FRAME_IS_PUSHED_FLOAT) ||
aFloat->GetParent() != mBlock) {
MOZ_ASSERT(aFloat->HasAnyStateBits(NS_FRAME_IS_PUSHED_FLOAT |
NS_FRAME_FIRST_REFLOW),
"float should be in this block unless it was marked as "
"pushed float, or just inserted");
MOZ_ASSERT(aFloat->GetParent()->FirstContinuation() ==
mBlock->FirstContinuation());
// If, in a previous reflow, the float was pushed entirely to
// another column/page, we need to steal it back. (We might just
// push it again, though.) Likewise, if that previous reflow
// reflowed this block but not its next continuation, we might need
// to steal it from our own float-continuations list.
//
// For more about pushed floats, see the comment above
// nsBlockFrame::DrainPushedFloats.
auto* floatParent = static_cast<nsBlockFrame*>(aFloat->GetParent());
floatParent->StealFrame(aFloat);
aFloat->RemoveStateBits(NS_FRAME_IS_PUSHED_FLOAT);
// Appending is fine, since if a float was pushed to the next
// page/column, all later floats were also pushed.
mBlock->EnsureFloats()->AppendFrame(mBlock, aFloat);
}
// Because we are in the middle of reflowing a placeholder frame
// within a line (and possibly nested in an inline frame or two
// that's a child of our block) we need to restore the space
// manager's translation to the space that the block resides in
// before placing the float.
nscoord oI, oB;
FloatManager()->GetTranslation(oI, oB);
nscoord dI = oI - mFloatManagerI;
nscoord dB = oB - mFloatManagerB;
FloatManager()->Translate(-dI, -dB);
bool placed = false;
// Now place the float immediately if possible. Otherwise stash it
// away in mBelowCurrentLineFloats and place it later.
// If one or more floats has already been pushed to the next line,
// don't let this one go on the current line, since that would violate
// float ordering.
bool shouldPlaceFloatBelowCurrentLine = false;
if (mBelowCurrentLineFloats.IsEmpty()) {
// If the current line is empty, we don't impose any inline-size constraint
// from the line layout.
Maybe<nscoord> availableISizeInCurrentLine =
aLineLayout->LineIsEmpty() ? Nothing() : Some(aAvailableISize);
PlaceFloatResult result =
FlowAndPlaceFloat(aFloat, availableISizeInCurrentLine);
if (result == PlaceFloatResult::Placed) {
placed = true;
// Pass on updated available space to the current inline reflow engine
WritingMode wm = mReflowInput.GetWritingMode();
// If we have mLineBSize, we are reflowing the line again due to
// LineReflowStatus::RedoMoreFloats. We should use mLineBSize to query the
// correct available space.
nsFlowAreaRect floatAvailSpace =
mLineBSize.isNothing()
? GetFloatAvailableSpace(wm, mBCoord)
: GetFloatAvailableSpaceForBSize(wm, mBCoord, mLineBSize.value(),
nullptr);
LogicalRect availSpace(wm, floatAvailSpace.mRect.IStart(wm), mBCoord,
floatAvailSpace.mRect.ISize(wm),
floatAvailSpace.mRect.BSize(wm));
aLineLayout->UpdateBand(wm, availSpace, aFloat);
// Record this float in the current-line list
mCurrentLineFloats.AppendElement(aFloat);
} else if (result == PlaceFloatResult::ShouldPlaceInNextContinuation) {
(*aLineLayout->GetLine())->SetHadFloatPushed();
} else {
MOZ_ASSERT(result == PlaceFloatResult::ShouldPlaceBelowCurrentLine);
shouldPlaceFloatBelowCurrentLine = true;
}
} else {
shouldPlaceFloatBelowCurrentLine = true;
}
if (shouldPlaceFloatBelowCurrentLine) {
// Always claim to be placed; we don't know whether we fit yet, so we
// deal with this in PlaceBelowCurrentLineFloats
placed = true;
// This float will be placed after the line is done (it is a
// below-current-line float).
mBelowCurrentLineFloats.AppendElement(aFloat);
}
// Restore coordinate system
FloatManager()->Translate(dI, dB);
return placed;
}
bool BlockReflowState::CanPlaceFloat(
nscoord aFloatISize, const nsFlowAreaRect& aFloatAvailableSpace) {
// A float fits at a given block-dir position if there are no floats
// at its inline-dir position (no matter what its inline size) or if
// its inline size fits in the space remaining after prior floats have
// been placed.
return !aFloatAvailableSpace.HasFloats() ||
aFloatAvailableSpace.mRect.ISize(mReflowInput.GetWritingMode()) >=
aFloatISize;
}
// Return the inline-size that the float (including margins) will take up
// in the writing mode of the containing block. If this returns
// NS_UNCONSTRAINEDSIZE, we're dealing with an orthogonal block that
// has block-size:auto, and we'll need to actually reflow it to find out
// how much inline-size it will occupy in the containing block's mode.
static nscoord FloatMarginISize(WritingMode aCBWM,
const ReflowInput& aFloatRI) {
if (aFloatRI.ComputedSize(aCBWM).ISize(aCBWM) == NS_UNCONSTRAINEDSIZE) {
return NS_UNCONSTRAINEDSIZE; // reflow is needed to get the true size
}
return aFloatRI.ComputedSizeWithMarginBorderPadding(aCBWM).ISize(aCBWM);
}
// A frame property that stores the last shape source / margin / etc. if there's
// any shape, in order to invalidate the float area properly when it changes.
//
// TODO(emilio): This could really belong to GetRegionFor / StoreRegionFor, but
// when I tried it was a bit awkward because of the logical -> physical
// conversion that happens there.
//
// Maybe all this code could be refactored to make this cleaner, but keeping the
// two properties separated was slightly nicer.
struct ShapeInvalidationData {
StyleShapeOutside mShapeOutside{StyleShapeOutside::None()};
float mShapeImageThreshold = 0.0;
LengthPercentage mShapeMargin;
ShapeInvalidationData() = default;
explicit ShapeInvalidationData(const nsStyleDisplay& aDisplay) {
Update(aDisplay);
}
static bool IsNeeded(const nsStyleDisplay& aDisplay) {
return !aDisplay.mShapeOutside.IsNone();
}
void Update(const nsStyleDisplay& aDisplay) {
MOZ_ASSERT(IsNeeded(aDisplay));
mShapeOutside = aDisplay.mShapeOutside;
mShapeImageThreshold = aDisplay.mShapeImageThreshold;
mShapeMargin = aDisplay.mShapeMargin;
}
bool Matches(const nsStyleDisplay& aDisplay) const {
return mShapeOutside == aDisplay.mShapeOutside &&
mShapeImageThreshold == aDisplay.mShapeImageThreshold &&
mShapeMargin == aDisplay.mShapeMargin;
}
};
NS_DECLARE_FRAME_PROPERTY_DELETABLE(ShapeInvalidationDataProperty,
ShapeInvalidationData)
BlockReflowState::PlaceFloatResult BlockReflowState::FlowAndPlaceFloat(
nsIFrame* aFloat, Maybe<nscoord> aAvailableISizeInCurrentLine) {
MOZ_ASSERT(aFloat->GetParent() == mBlock, "Float frame has wrong parent");
WritingMode wm = mReflowInput.GetWritingMode();
// Save away the block-dir coordinate before placing the float. We will
// restore mBCoord at the end after placing the float. This is
// necessary because any adjustments to mBCoord during the float
// placement are for the float only, not for any non-floating
// content.
AutoRestore<nscoord> restoreBCoord(mBCoord);
// Whether the block-direction position available to place a float has been
// pushed down due to the presence of other floats.
auto HasFloatPushedDown = [this, &restoreBCoord]() {
return mBCoord != restoreBCoord.SavedValue();
};
// Grab the float's display information
const nsStyleDisplay* floatDisplay = aFloat->StyleDisplay();
// The float's old region, so we can propagate damage.
LogicalRect oldRegion =
nsFloatManager::GetRegionFor(wm, aFloat, ContainerSize());
ShapeInvalidationData* invalidationData =
aFloat->GetProperty(ShapeInvalidationDataProperty());
// Enforce CSS2 9.5.1 rule [2], i.e., make sure that a float isn't
// ``above'' another float that preceded it in the flow.
mBCoord = std::max(FloatManager()->LowestFloatBStart(), mBCoord);
// See if the float should clear any preceding floats...
// XXX We need to mark this float somehow so that it gets reflowed
// when floats are inserted before it.
if (StyleClear::None != floatDisplay->mClear) {
// XXXldb Does this handle vertical margins correctly?
auto [bCoord, result] = ClearFloats(mBCoord, floatDisplay->UsedClear(wm));
if (result == ClearFloatsResult::FloatsPushedOrSplit) {
PushFloatPastBreak(aFloat);
return PlaceFloatResult::ShouldPlaceInNextContinuation;
}
mBCoord = bCoord;
}
LogicalSize availSize = ComputeAvailableSizeForFloat();
const WritingMode floatWM = aFloat->GetWritingMode();
Maybe<ReflowInput> floatRI(std::in_place, mPresContext, mReflowInput, aFloat,
availSize.ConvertTo(floatWM, wm));
nscoord floatMarginISize = FloatMarginISize(wm, *floatRI);
LogicalMargin floatMargin = floatRI->ComputedLogicalMargin(wm);
nsReflowStatus reflowStatus;
// If it's a floating first-letter, we need to reflow it before we
// know how wide it is (since we don't compute which letters are part
// of the first letter until reflow!).
// We also need to do this early reflow if FloatMarginISize returned
// an unconstrained inline-size, which can occur if the float had an
// orthogonal writing mode and 'auto' block-size (in its mode).
bool earlyFloatReflow =
aFloat->IsLetterFrame() || floatMarginISize == NS_UNCONSTRAINEDSIZE;
if (earlyFloatReflow) {
mBlock->ReflowFloat(*this, *floatRI, aFloat, reflowStatus);
floatMarginISize = aFloat->ISize(wm) + floatMargin.IStartEnd(wm);
NS_ASSERTION(reflowStatus.IsComplete(),
"letter frames and orthogonal floats with auto block-size "
"shouldn't break, and if they do now, then they're breaking "
"at the wrong point");
}
// Now we've computed the float's margin inline-size.
if (aAvailableISizeInCurrentLine &&
floatMarginISize > *aAvailableISizeInCurrentLine) {
// The float cannot fit in the available inline-size of the current line.
// Let's notify our caller to place it later.
return PlaceFloatResult::ShouldPlaceBelowCurrentLine;
}
// Find a place to place the float. The CSS2 spec doesn't want
// floats overlapping each other or sticking out of the containing
// block if possible (CSS2 spec section 9.5.1, see the rule list).
UsedFloat floatStyle = floatDisplay->UsedFloat(wm);
MOZ_ASSERT(UsedFloat::Left == floatStyle || UsedFloat::Right == floatStyle,
"Invalid float type!");
// Are we required to place at least part of the float because we're
// at the top of the page (to avoid an infinite loop of pushing and
// breaking).
bool mustPlaceFloat =
mReflowInput.mFlags.mIsTopOfPage && IsAdjacentWithBStart();
// Get the band of available space with respect to margin box.
nsFlowAreaRect floatAvailableSpace =
GetFloatAvailableSpaceForPlacingFloat(wm, mBCoord);
for (;;) {
if (mReflowInput.AvailableBSize() != NS_UNCONSTRAINEDSIZE &&
floatAvailableSpace.mRect.BSize(wm) <= 0 && !mustPlaceFloat) {
// No space, nowhere to put anything.
PushFloatPastBreak(aFloat);
return PlaceFloatResult::ShouldPlaceInNextContinuation;
}
if (CanPlaceFloat(floatMarginISize, floatAvailableSpace)) {
// We found an appropriate place.
break;
}
// Nope. try to advance to the next band.
mBCoord += floatAvailableSpace.mRect.BSize(wm);
floatAvailableSpace = GetFloatAvailableSpaceForPlacingFloat(wm, mBCoord);
mustPlaceFloat = false;
}
// If the float is continued, it will get the same absolute x value as its
// prev-in-flow
// We don't worry about the geometry of the prev in flow, let the continuation
// place and size itself as required.
// Assign inline and block dir coordinates to the float. We don't use
// LineLeft() and LineRight() here, because we would only have to
// convert the result back into this block's writing mode.
LogicalPoint floatPos(wm);
bool leftFloat = floatStyle == UsedFloat::Left;
if (leftFloat == wm.IsBidiLTR()) {
floatPos.I(wm) = floatAvailableSpace.mRect.IStart(wm);
} else {
floatPos.I(wm) = floatAvailableSpace.mRect.IEnd(wm) - floatMarginISize;
}
// CSS2 spec, 9.5.1 rule [4]: "A floating box's outer top may not
// be higher than the top of its containing block." (Since the
// containing block is the content edge of the block box, this
// means the margin edge of the float can't be higher than the
// content edge of the block that contains it.)
floatPos.B(wm) = std::max(mBCoord, ContentBStart());
// Reflow the float after computing its vertical position so it knows
// where to break.
if (!earlyFloatReflow) {
const LogicalSize oldAvailSize = availSize;
availSize = ComputeAvailableSizeForFloat();
if (oldAvailSize != availSize) {
floatRI.reset();
floatRI.emplace(mPresContext, mReflowInput, aFloat,
availSize.ConvertTo(floatWM, wm));
}
// Normally the mIsTopOfPage state is copied from the parent reflow input.
// However, when reflowing a float, if we've placed other floats that force
// this float being pushed down, we should unset the mIsTopOfPage bit.
if (floatRI->mFlags.mIsTopOfPage && HasFloatPushedDown()) {
// HasFloatPushedDown() implies that we increased mBCoord, and we
// should've turned off mustPlaceFloat when we did that.
NS_ASSERTION(!mustPlaceFloat,
"mustPlaceFloat shouldn't be set if we're not at the "
"top-of-page!");
floatRI->mFlags.mIsTopOfPage = false;
}
mBlock->ReflowFloat(*this, *floatRI, aFloat, reflowStatus);
}
if (aFloat->GetPrevInFlow()) {
floatMargin.BStart(wm) = 0;
}
if (reflowStatus.IsIncomplete()) {
floatMargin.BEnd(wm) = 0;
}
// If the float cannot fit (e.g. via fragmenting itself if applicable), or if
// we're forced to break before it for CSS break-* reasons, then it needs to
// be pushed in its entirety to the next column/page.
//
// Note we use the available block-size in floatRI rather than use
// availSize.BSize() because nsBlockReflowContext::ReflowBlock() might adjust
// floatRI's available size.
const nscoord availBSize = floatRI->AvailableSize(floatWM).BSize(floatWM);
const bool isTruncated =
availBSize != NS_UNCONSTRAINEDSIZE && aFloat->BSize(floatWM) > availBSize;
if ((!floatRI->mFlags.mIsTopOfPage && isTruncated) ||
reflowStatus.IsInlineBreakBefore()) {
PushFloatPastBreak(aFloat);
return PlaceFloatResult::ShouldPlaceInNextContinuation;
}
// We can't use aFloat->ShouldAvoidBreakInside(mReflowInput) here since
// its mIsTopOfPage may be true even though the float isn't at the
// top when floatPos.B(wm) > 0.
if (ContentBSize() != NS_UNCONSTRAINEDSIZE && !mustPlaceFloat &&
(!mReflowInput.mFlags.mIsTopOfPage || floatPos.B(wm) > 0) &&
StyleBreakWithin::Avoid == aFloat->StyleDisplay()->mBreakInside &&
(!reflowStatus.IsFullyComplete() ||
aFloat->BSize(wm) + floatMargin.BStartEnd(wm) >
ContentBEnd() - floatPos.B(wm)) &&
!aFloat->GetPrevInFlow()) {
PushFloatPastBreak(aFloat);
return PlaceFloatResult::ShouldPlaceInNextContinuation;
}
// Calculate the actual origin of the float frame's border rect
// relative to the parent block; the margin must be added in
// to get the border rect
LogicalPoint origin(wm, floatMargin.IStart(wm) + floatPos.I(wm),
floatMargin.BStart(wm) + floatPos.B(wm));
// If float is relatively positioned, factor that in as well
const LogicalMargin floatOffsets = floatRI->ComputedLogicalOffsets(wm);
ReflowInput::ApplyRelativePositioning(aFloat, wm, floatOffsets, &origin,
ContainerSize());
// Position the float and make sure and views are properly
// positioned. We need to explicitly position its child views as
// well, since we're moving the float after flowing it.
bool moved = aFloat->GetLogicalPosition(wm, ContainerSize()) != origin;
if (moved) {
aFloat->SetPosition(wm, origin, ContainerSize());
nsContainerFrame::PositionFrameView(aFloat);
nsContainerFrame::PositionChildViews(aFloat);
}
// Update the float combined area state
// XXX Floats should really just get invalidated here if necessary
mFloatOverflowAreas.UnionWith(aFloat->GetOverflowAreasRelativeToParent());
// Place the float in the float manager
// calculate region
LogicalRect region = nsFloatManager::CalculateRegionFor(
wm, aFloat, floatMargin, ContainerSize());
// if the float split, then take up all of the vertical height
if (reflowStatus.IsIncomplete() && (NS_UNCONSTRAINEDSIZE != ContentBSize())) {
region.BSize(wm) =
std::max(region.BSize(wm), ContentBSize() - floatPos.B(wm));
}
FloatManager()->AddFloat(aFloat, region, wm, ContainerSize());
// store region
nsFloatManager::StoreRegionFor(wm, aFloat, region, ContainerSize());
const bool invalidationDataNeeded =
ShapeInvalidationData::IsNeeded(*floatDisplay);
// If the float's dimensions or shape have changed, note the damage in the
// float manager.
if (!region.IsEqualEdges(oldRegion) ||
!!invalidationData != invalidationDataNeeded ||
(invalidationData && !invalidationData->Matches(*floatDisplay))) {
// XXXwaterson conservative: we could probably get away with noting
// less damage; e.g., if only height has changed, then only note the
// area into which the float has grown or from which the float has
// shrunk.
nscoord blockStart = std::min(region.BStart(wm), oldRegion.BStart(wm));
nscoord blockEnd = std::max(region.BEnd(wm), oldRegion.BEnd(wm));
FloatManager()->IncludeInDamage(blockStart, blockEnd);
}
if (invalidationDataNeeded) {
if (invalidationData) {
invalidationData->Update(*floatDisplay);
} else {
aFloat->SetProperty(ShapeInvalidationDataProperty(),
new ShapeInvalidationData(*floatDisplay));
}
} else if (invalidationData) {
invalidationData = nullptr;
aFloat->RemoveProperty(ShapeInvalidationDataProperty());
}
if (!reflowStatus.IsFullyComplete()) {
mBlock->SplitFloat(*this, aFloat, reflowStatus);
} else {
MOZ_ASSERT(!aFloat->GetNextInFlow());
}
#ifdef DEBUG
if (nsBlockFrame::gNoisyFloatManager) {
nscoord tI, tB;
FloatManager()->GetTranslation(tI, tB);
mBlock->ListTag(stdout);
printf(": FlowAndPlaceFloat: AddFloat: tIB=%d,%d (%d,%d) {%d,%d,%d,%d}\n",
tI, tB, mFloatManagerI, mFloatManagerB, region.IStart(wm),
region.BStart(wm), region.ISize(wm), region.BSize(wm));
}
if (nsBlockFrame::gNoisyReflow) {
nsRect r = aFloat->GetRect();
nsIFrame::IndentBy(stdout, nsBlockFrame::gNoiseIndent);
printf("placed float: ");
aFloat->ListTag(stdout);
printf(" %d,%d,%d,%d\n", r.x, r.y, r.width, r.height);
}
#endif
return PlaceFloatResult::Placed;
}
void BlockReflowState::PushFloatPastBreak(nsIFrame* aFloat) {
// This ensures that we:
// * don't try to place later but smaller floats (which CSS says
// must have their tops below the top of this float)
// * don't waste much time trying to reflow this float again until
// after the break
WritingMode wm = mReflowInput.GetWritingMode();
UsedFloat floatStyle = aFloat->StyleDisplay()->UsedFloat(wm);
if (floatStyle == UsedFloat::Left) {
FloatManager()->SetPushedLeftFloatPastBreak();
} else {
MOZ_ASSERT(floatStyle == UsedFloat::Right, "Unexpected float value!");
FloatManager()->SetPushedRightFloatPastBreak();
}
// Put the float on the pushed floats list, even though it
// isn't actually a continuation.
mBlock->StealFrame(aFloat);
AppendPushedFloatChain(aFloat);
mReflowStatus.SetOverflowIncomplete();
}
/**
* Place below-current-line floats.
*/
void BlockReflowState::PlaceBelowCurrentLineFloats(nsLineBox* aLine) {
MOZ_ASSERT(!mBelowCurrentLineFloats.IsEmpty());
nsTArray<nsIFrame*> floatsPlacedInLine;
for (nsIFrame* f : mBelowCurrentLineFloats) {
#ifdef DEBUG
if (nsBlockFrame::gNoisyReflow) {
nsIFrame::IndentBy(stdout, nsBlockFrame::gNoiseIndent);
printf("placing bcl float: ");
f->ListTag(stdout);
printf("\n");
}
#endif
// Place the float
PlaceFloatResult result = FlowAndPlaceFloat(f);
MOZ_ASSERT(result != PlaceFloatResult::ShouldPlaceBelowCurrentLine,
"We are already dealing with below current line floats!");
if (result == PlaceFloatResult::Placed) {
floatsPlacedInLine.AppendElement(f);
}
}
if (floatsPlacedInLine.Length() != mBelowCurrentLineFloats.Length()) {
// We have some floats having ShouldPlaceInNextContinuation result.
aLine->SetHadFloatPushed();
}
aLine->AppendFloats(std::move(floatsPlacedInLine));
mBelowCurrentLineFloats.Clear();
}
std::tuple<nscoord, BlockReflowState::ClearFloatsResult>
BlockReflowState::ClearFloats(nscoord aBCoord, UsedClear aClearType,
nsIFrame* aFloatAvoidingBlock) {
#ifdef DEBUG
if (nsBlockFrame::gNoisyReflow) {
nsIFrame::IndentBy(stdout, nsBlockFrame::gNoiseIndent);
printf("clear floats: in: aBCoord=%d\n", aBCoord);
}
#endif
if (!FloatManager()->HasAnyFloats()) {
return {aBCoord, ClearFloatsResult::BCoordNoChange};
}
nscoord newBCoord = aBCoord;
if (aClearType != UsedClear::None) {
newBCoord = FloatManager()->ClearFloats(newBCoord, aClearType);
if (FloatManager()->ClearContinues(aClearType)) {
return {newBCoord, ClearFloatsResult::FloatsPushedOrSplit};
}
}
if (aFloatAvoidingBlock) {
auto cbWM = aFloatAvoidingBlock->GetContainingBlock()->GetWritingMode();
for (;;) {
nsFlowAreaRect floatAvailableSpace =
GetFloatAvailableSpace(cbWM, newBCoord);
if (FloatAvoidingBlockFitsInAvailSpace(aFloatAvoidingBlock,
floatAvailableSpace)) {
break;
}
// See the analogous code for inlines in
// nsBlockFrame::DoReflowInlineFrames
if (!AdvanceToNextBand(floatAvailableSpace.mRect, &newBCoord)) {
// Stop trying to clear here; we'll just get pushed to the
// next column or page and try again there.
break;
}
}
}
#ifdef DEBUG
if (nsBlockFrame::gNoisyReflow) {
nsIFrame::IndentBy(stdout, nsBlockFrame::gNoiseIndent);
printf("clear floats: out: y=%d\n", newBCoord);
}
#endif
ClearFloatsResult result = newBCoord == aBCoord
? ClearFloatsResult::BCoordNoChange
: ClearFloatsResult::BCoordAdvanced;
return {newBCoord, result};
}