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b16599bc8f
gecko-dev/layout/tables/nsTableRowGroupFrame.cpp
Morris Tseng b16599bc8f Bug 929484 - Draw each table's background on their own display item. r=mstange 
This patch do following things:
1. Create nsDisplayTableBorderCollapse that draws all collapse border of
table.
2. Don't use nsDisplayTableBorderBackground.
3. Let column and column group frame generate display items.
4. When traversing the table, also traverse the column and column group
frames.
5. For each type of table frame (col group, col, row group, row and
cell), draw their own background.

MozReview-Commit-ID: 1s2VLv6G8xi
2017-05-05 14:30:15 +08:00

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/* -*- 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/. */
#include "nsCOMPtr.h"
#include "nsTableRowGroupFrame.h"
#include "nsTableRowFrame.h"
#include "nsTableFrame.h"
#include "nsTableCellFrame.h"
#include "nsPresContext.h"
#include "nsStyleContext.h"
#include "nsStyleConsts.h"
#include "nsIContent.h"
#include "nsGkAtoms.h"
#include "nsIPresShell.h"
#include "nsCSSRendering.h"
#include "nsHTMLParts.h"
#include "nsCSSFrameConstructor.h"
#include "nsDisplayList.h"
#include "nsCellMap.h"//table cell navigation
#include <algorithm>
using namespace mozilla;
using namespace mozilla::layout;
namespace mozilla {
struct TableRowGroupReflowInput {
const ReflowInput& reflowInput; // Our reflow state
nsTableFrame* tableFrame;
// The available size (computed from the parent)
mozilla::LogicalSize availSize;
// Running block-offset
nscoord bCoord;
TableRowGroupReflowInput(const ReflowInput& aReflowInput,
nsTableFrame* aTableFrame)
: reflowInput(aReflowInput)
, tableFrame(aTableFrame)
, availSize(aReflowInput.GetWritingMode(),
aReflowInput.AvailableISize(),
aReflowInput.AvailableBSize())
, bCoord(0)
{
}
~TableRowGroupReflowInput() {}
};
} // namespace mozilla
nsTableRowGroupFrame::nsTableRowGroupFrame(nsStyleContext* aContext)
: nsContainerFrame(aContext, LayoutFrameType::TableRowGroup)
{
SetRepeatable(false);
}
nsTableRowGroupFrame::~nsTableRowGroupFrame()
{
}
void
nsTableRowGroupFrame::DestroyFrom(nsIFrame* aDestructRoot)
{
if (HasAnyStateBits(NS_FRAME_CAN_HAVE_ABSPOS_CHILDREN)) {
nsTableFrame::UnregisterPositionedTablePart(this, aDestructRoot);
}
nsContainerFrame::DestroyFrom(aDestructRoot);
}
NS_QUERYFRAME_HEAD(nsTableRowGroupFrame)
NS_QUERYFRAME_ENTRY(nsTableRowGroupFrame)
NS_QUERYFRAME_TAIL_INHERITING(nsContainerFrame)
int32_t
nsTableRowGroupFrame::GetRowCount()
{
#ifdef DEBUG
for (nsFrameList::Enumerator e(mFrames); !e.AtEnd(); e.Next()) {
NS_ASSERTION(e.get()->StyleDisplay()->mDisplay ==
mozilla::StyleDisplay::TableRow,
"Unexpected display");
NS_ASSERTION(e.get()->IsTableRowFrame(), "Unexpected frame type");
}
#endif
return mFrames.GetLength();
}
int32_t nsTableRowGroupFrame::GetStartRowIndex()
{
int32_t result = -1;
if (mFrames.NotEmpty()) {
NS_ASSERTION(mFrames.FirstChild()->IsTableRowFrame(),
"Unexpected frame type");
result = static_cast<nsTableRowFrame*>(mFrames.FirstChild())->GetRowIndex();
}
// if the row group doesn't have any children, get it the hard way
if (-1 == result) {
return GetTableFrame()->GetStartRowIndex(this);
}
return result;
}
void nsTableRowGroupFrame::AdjustRowIndices(int32_t aRowIndex,
int32_t anAdjustment)
{
for (nsIFrame* rowFrame : mFrames) {
if (mozilla::StyleDisplay::TableRow == rowFrame->StyleDisplay()->mDisplay) {
int32_t index = ((nsTableRowFrame*)rowFrame)->GetRowIndex();
if (index >= aRowIndex)
((nsTableRowFrame *)rowFrame)->SetRowIndex(index+anAdjustment);
}
}
}
int32_t
nsTableRowGroupFrame::GetAdjustmentForStoredIndex(int32_t aStoredIndex)
{
nsTableFrame* tableFrame = GetTableFrame();
return tableFrame->GetAdjustmentForStoredIndex(aStoredIndex);
}
void
nsTableRowGroupFrame::MarkRowsAsDeleted(nsTableRowFrame& aStartRowFrame,
int32_t aNumRowsToDelete)
{
nsTableRowFrame* currentRowFrame = &aStartRowFrame;
for (;;) {
// XXXneerja - Instead of calling AddDeletedRowIndex() per row frame
// it is possible to change AddDeleteRowIndex to instead take
// <start row index> and <num of rows to mark for deletion> as arguments.
// The problem that emerges here is mDeletedRowIndexRanges only stores
// disjoint index ranges and since AddDeletedRowIndex() must operate on
// the "stored" index, in some cases it is possible that the range
// of indices to delete becomes overlapping EG: Deleting rows 9 - 11 and
// then from the remaining rows deleting the *new* rows 7 to 20.
// Handling these overlapping ranges is much more complicated to
// implement and so I opted to add the deleted row index of one row at a
// time and maintain the invariant that the range of deleted row indices
// is always disjoint.
currentRowFrame->AddDeletedRowIndex();
if (--aNumRowsToDelete == 0) {
break;
}
currentRowFrame = do_QueryFrame(currentRowFrame->GetNextSibling());
if (!currentRowFrame) {
MOZ_ASSERT_UNREACHABLE("expected another row frame");
break;
}
}
}
void
nsTableRowGroupFrame::AddDeletedRowIndex(int32_t aDeletedRowStoredIndex)
{
nsTableFrame* tableFrame = GetTableFrame();
return tableFrame->AddDeletedRowIndex(aDeletedRowStoredIndex);
}
nsresult
nsTableRowGroupFrame::InitRepeatedFrame(nsTableRowGroupFrame* aHeaderFooterFrame)
{
nsTableRowFrame* copyRowFrame = GetFirstRow();
nsTableRowFrame* originalRowFrame = aHeaderFooterFrame->GetFirstRow();
AddStateBits(NS_REPEATED_ROW_OR_ROWGROUP);
while (copyRowFrame && originalRowFrame) {
copyRowFrame->AddStateBits(NS_REPEATED_ROW_OR_ROWGROUP);
int rowIndex = originalRowFrame->GetRowIndex();
copyRowFrame->SetRowIndex(rowIndex);
// For each table cell frame set its column index
nsTableCellFrame* originalCellFrame = originalRowFrame->GetFirstCell();
nsTableCellFrame* copyCellFrame = copyRowFrame->GetFirstCell();
while (copyCellFrame && originalCellFrame) {
NS_ASSERTION(originalCellFrame->GetContent() == copyCellFrame->GetContent(),
"cell frames have different content");
int32_t colIndex;
originalCellFrame->GetColIndex(colIndex);
copyCellFrame->SetColIndex(colIndex);
// Move to the next cell frame
copyCellFrame = copyCellFrame->GetNextCell();
originalCellFrame = originalCellFrame->GetNextCell();
}
// Move to the next row frame
originalRowFrame = originalRowFrame->GetNextRow();
copyRowFrame = copyRowFrame->GetNextRow();
}
return NS_OK;
}
/**
* We need a custom display item for table row backgrounds. This is only used
* when the table row is the root of a stacking context (e.g., has 'opacity').
* Table row backgrounds can extend beyond the row frame bounds, when
* the row contains row-spanning cells.
*/
class nsDisplayTableRowGroupBackground : public nsDisplayTableItem {
public:
nsDisplayTableRowGroupBackground(nsDisplayListBuilder* aBuilder,
nsTableRowGroupFrame* aFrame) :
nsDisplayTableItem(aBuilder, aFrame) {
MOZ_COUNT_CTOR(nsDisplayTableRowGroupBackground);
}
#ifdef NS_BUILD_REFCNT_LOGGING
virtual ~nsDisplayTableRowGroupBackground() {
MOZ_COUNT_DTOR(nsDisplayTableRowGroupBackground);
}
#endif
virtual void Paint(nsDisplayListBuilder* aBuilder,
nsRenderingContext* aCtx) override;
NS_DISPLAY_DECL_NAME("TableRowGroupBackground", TYPE_TABLE_ROW_GROUP_BACKGROUND)
};
void
nsDisplayTableRowGroupBackground::Paint(nsDisplayListBuilder* aBuilder,
nsRenderingContext* aCtx)
{
auto rgFrame = static_cast<nsTableRowGroupFrame*>(mFrame);
TableBackgroundPainter painter(rgFrame->GetTableFrame(),
TableBackgroundPainter::eOrigin_TableRowGroup,
mFrame->PresContext(), *aCtx,
mVisibleRect, ToReferenceFrame(),
aBuilder->GetBackgroundPaintFlags());
DrawResult result = painter.PaintRowGroup(rgFrame);
nsDisplayTableItemGeometry::UpdateDrawResult(this, result);
}
// Handle the child-traversal part of DisplayGenericTablePart
static void
DisplayRows(nsDisplayListBuilder* aBuilder, nsFrame* aFrame,
const nsRect& aDirtyRect, const nsDisplayListSet& aLists)
{
nscoord overflowAbove;
nsTableRowGroupFrame* f = static_cast<nsTableRowGroupFrame*>(aFrame);
// Don't try to use the row cursor if we have to descend into placeholders;
// we might have rows containing placeholders, where the row's overflow
// area doesn't intersect the dirty rect but we need to descend into the row
// to see out of flows.
// Note that we really want to check ShouldDescendIntoFrame for all
// the rows in |f|, but that's exactly what we're trying to avoid, so we
// approximate it by checking it for |f|: if it's true for any row
// in |f| then it's true for |f| itself.
nsIFrame* kid = aBuilder->ShouldDescendIntoFrame(f) ?
nullptr : f->GetFirstRowContaining(aDirtyRect.y, &overflowAbove);
if (kid) {
// have a cursor, use it
while (kid) {
if (kid->GetRect().y - overflowAbove >= aDirtyRect.YMost() &&
kid->GetNormalRect().y - overflowAbove >= aDirtyRect.YMost())
break;
f->BuildDisplayListForChild(aBuilder, kid, aDirtyRect, aLists);
kid = kid->GetNextSibling();
}
return;
}
// No cursor. Traverse children the hard way and build a cursor while we're at it
nsTableRowGroupFrame::FrameCursorData* cursor = f->SetupRowCursor();
kid = f->PrincipalChildList().FirstChild();
while (kid) {
f->BuildDisplayListForChild(aBuilder, kid, aDirtyRect, aLists);
if (cursor) {
if (!cursor->AppendFrame(kid)) {
f->ClearRowCursor();
return;
}
}
kid = kid->GetNextSibling();
}
if (cursor) {
cursor->FinishBuildingCursor();
}
}
void
nsTableRowGroupFrame::BuildDisplayList(nsDisplayListBuilder* aBuilder,
const nsRect& aDirtyRect,
const nsDisplayListSet& aLists)
{
nsTableFrame::DisplayGenericTablePart(aBuilder, this, aDirtyRect,
aLists, DisplayRows);
}
nsIFrame::LogicalSides
nsTableRowGroupFrame::GetLogicalSkipSides(const ReflowInput* aReflowInput) const
{
if (MOZ_UNLIKELY(StyleBorder()->mBoxDecorationBreak ==
StyleBoxDecorationBreak::Clone)) {
return LogicalSides();
}
LogicalSides skip;
if (nullptr != GetPrevInFlow()) {
skip |= eLogicalSideBitsBStart;
}
if (nullptr != GetNextInFlow()) {
skip |= eLogicalSideBitsBEnd;
}
return skip;
}
// Position and size aKidFrame and update our reflow state.
void
nsTableRowGroupFrame::PlaceChild(nsPresContext* aPresContext,
TableRowGroupReflowInput& aReflowInput,
nsIFrame* aKidFrame,
WritingMode aWM,
const LogicalPoint& aKidPosition,
const nsSize& aContainerSize,
ReflowOutput& aDesiredSize,
const nsRect& aOriginalKidRect,
const nsRect& aOriginalKidVisualOverflow)
{
bool isFirstReflow = aKidFrame->HasAnyStateBits(NS_FRAME_FIRST_REFLOW);
// Place and size the child
FinishReflowChild(aKidFrame, aPresContext, aDesiredSize, nullptr,
aWM, aKidPosition, aContainerSize, 0);
nsTableFrame::InvalidateTableFrame(aKidFrame, aOriginalKidRect,
aOriginalKidVisualOverflow, isFirstReflow);
// Adjust the running block-offset
aReflowInput.bCoord += aDesiredSize.BSize(aWM);
// If our block-size is constrained then update the available bsize
if (NS_UNCONSTRAINEDSIZE != aReflowInput.availSize.BSize(aWM)) {
aReflowInput.availSize.BSize(aWM) -= aDesiredSize.BSize(aWM);
}
}
void
nsTableRowGroupFrame::InitChildReflowInput(nsPresContext& aPresContext,
bool aBorderCollapse,
ReflowInput& aReflowInput)
{
nsMargin collapseBorder;
nsMargin padding(0,0,0,0);
nsMargin* pCollapseBorder = nullptr;
if (aBorderCollapse) {
nsTableRowFrame *rowFrame = do_QueryFrame(aReflowInput.mFrame);
if (rowFrame) {
WritingMode wm = GetWritingMode();
LogicalMargin border = rowFrame->GetBCBorderWidth(wm);
collapseBorder = border.GetPhysicalMargin(wm);
pCollapseBorder = &collapseBorder;
}
}
aReflowInput.Init(&aPresContext, nullptr, pCollapseBorder, &padding);
}
static void
CacheRowBSizesForPrinting(nsPresContext* aPresContext,
nsTableRowFrame* aFirstRow,
WritingMode aWM)
{
for (nsTableRowFrame* row = aFirstRow; row; row = row->GetNextRow()) {
if (!row->GetPrevInFlow()) {
row->SetHasUnpaginatedBSize(true);
row->SetUnpaginatedBSize(aPresContext, row->BSize(aWM));
}
}
}
void
nsTableRowGroupFrame::ReflowChildren(nsPresContext* aPresContext,
ReflowOutput& aDesiredSize,
TableRowGroupReflowInput& aReflowInput,
nsReflowStatus& aStatus,
bool* aPageBreakBeforeEnd)
{
if (aPageBreakBeforeEnd) {
*aPageBreakBeforeEnd = false;
}
WritingMode wm = aReflowInput.reflowInput.GetWritingMode();
nsTableFrame* tableFrame = GetTableFrame();
const bool borderCollapse = tableFrame->IsBorderCollapse();
// XXXldb Should we really be checking IsPaginated(),
// or should we *only* check available block-size?
// (Think about multi-column layout!)
bool isPaginated = aPresContext->IsPaginated() &&
NS_UNCONSTRAINEDSIZE != aReflowInput.availSize.BSize(wm);
bool haveRow = false;
bool reflowAllKids = aReflowInput.reflowInput.ShouldReflowAllKids() ||
tableFrame->IsGeometryDirty();
// in vertical-rl mode, we always need the row bsizes in order to
// get the necessary containerSize for placing our kids
bool needToCalcRowBSizes = reflowAllKids || wm.IsVerticalRL();
nsSize containerSize =
aReflowInput.reflowInput.ComputedSizeAsContainerIfConstrained();
nsIFrame *prevKidFrame = nullptr;
for (nsIFrame* kidFrame = mFrames.FirstChild(); kidFrame;
prevKidFrame = kidFrame, kidFrame = kidFrame->GetNextSibling()) {
nsTableRowFrame *rowFrame = do_QueryFrame(kidFrame);
if (!rowFrame) {
// XXXldb nsCSSFrameConstructor needs to enforce this!
NS_NOTREACHED("yikes, a non-row child");
continue;
}
nscoord cellSpacingB = tableFrame->GetRowSpacing(rowFrame->GetRowIndex());
haveRow = true;
// Reflow the row frame
if (reflowAllKids ||
NS_SUBTREE_DIRTY(kidFrame) ||
(aReflowInput.reflowInput.mFlags.mSpecialBSizeReflow &&
(isPaginated ||
kidFrame->HasAnyStateBits(NS_FRAME_CONTAINS_RELATIVE_BSIZE)))) {
LogicalRect oldKidRect = kidFrame->GetLogicalRect(wm, containerSize);
nsRect oldKidVisualOverflow = kidFrame->GetVisualOverflowRect();
// XXXldb We used to only pass aDesiredSize.mFlags through for the
// incremental reflow codepath.
ReflowOutput desiredSize(aReflowInput.reflowInput,
aDesiredSize.mFlags);
desiredSize.ClearSize();
// Reflow the child into the available space, giving it as much bsize as
// it wants. We'll deal with splitting later after we've computed the row
// bsizes, taking into account cells with row spans...
LogicalSize kidAvailSize = aReflowInput.availSize;
kidAvailSize.BSize(wm) = NS_UNCONSTRAINEDSIZE;
ReflowInput kidReflowInput(aPresContext, aReflowInput.reflowInput,
kidFrame, kidAvailSize,
nullptr,
ReflowInput::CALLER_WILL_INIT);
InitChildReflowInput(*aPresContext, borderCollapse, kidReflowInput);
// This can indicate that columns were resized.
if (aReflowInput.reflowInput.IsIResize()) {
kidReflowInput.SetIResize(true);
}
NS_ASSERTION(kidFrame == mFrames.FirstChild() || prevKidFrame,
"If we're not on the first frame, we should have a "
"previous sibling...");
// If prev row has nonzero YMost, then we can't be at the top of the page
if (prevKidFrame && prevKidFrame->GetNormalRect().YMost() > 0) {
kidReflowInput.mFlags.mIsTopOfPage = false;
}
LogicalPoint kidPosition(wm, 0, aReflowInput.bCoord);
ReflowChild(kidFrame, aPresContext, desiredSize, kidReflowInput,
wm, kidPosition, containerSize, 0, aStatus);
kidReflowInput.ApplyRelativePositioning(&kidPosition, containerSize);
// Place the child
PlaceChild(aPresContext, aReflowInput, kidFrame,
wm, kidPosition, containerSize,
desiredSize, oldKidRect.GetPhysicalRect(wm, containerSize),
oldKidVisualOverflow);
aReflowInput.bCoord += cellSpacingB;
if (!reflowAllKids) {
if (IsSimpleRowFrame(aReflowInput.tableFrame, rowFrame)) {
// Inform the row of its new bsize.
rowFrame->DidResize();
// the overflow area may have changed inflate the overflow area
const nsStylePosition *stylePos = StylePosition();
nsStyleUnit unit = stylePos->BSize(wm).GetUnit();
if (aReflowInput.tableFrame->IsAutoBSize(wm) &&
unit != eStyleUnit_Coord) {
// Because other cells in the row may need to be aligned
// differently, repaint the entire row
InvalidateFrame();
} else if (oldKidRect.BSize(wm) != desiredSize.BSize(wm)) {
needToCalcRowBSizes = true;
}
} else {
needToCalcRowBSizes = true;
}
}
if (isPaginated && aPageBreakBeforeEnd && !*aPageBreakBeforeEnd) {
nsTableRowFrame* nextRow = rowFrame->GetNextRow();
if (nextRow) {
*aPageBreakBeforeEnd = nsTableFrame::PageBreakAfter(kidFrame, nextRow);
}
}
} else {
SlideChild(aReflowInput, kidFrame);
// Adjust the running b-offset so we know where the next row should be placed
nscoord bSize = kidFrame->BSize(wm) + cellSpacingB;
aReflowInput.bCoord += bSize;
if (NS_UNCONSTRAINEDSIZE != aReflowInput.availSize.BSize(wm)) {
aReflowInput.availSize.BSize(wm) -= bSize;
}
}
ConsiderChildOverflow(aDesiredSize.mOverflowAreas, kidFrame);
}
if (haveRow) {
aReflowInput.bCoord -= tableFrame->GetRowSpacing(GetStartRowIndex() +
GetRowCount());
}
// Return our desired rect
aDesiredSize.ISize(wm) = aReflowInput.reflowInput.AvailableISize();
aDesiredSize.BSize(wm) = aReflowInput.bCoord;
if (aReflowInput.reflowInput.mFlags.mSpecialBSizeReflow) {
DidResizeRows(aDesiredSize);
if (isPaginated) {
CacheRowBSizesForPrinting(aPresContext, GetFirstRow(), wm);
}
}
else if (needToCalcRowBSizes) {
CalculateRowBSizes(aPresContext, aDesiredSize, aReflowInput.reflowInput);
if (!reflowAllKids) {
InvalidateFrame();
}
}
}
nsTableRowFrame*
nsTableRowGroupFrame::GetFirstRow()
{
for (nsIFrame* childFrame : mFrames) {
nsTableRowFrame* rowFrame = do_QueryFrame(childFrame);
if (rowFrame) {
return rowFrame;
}
}
return nullptr;
}
nsTableRowFrame*
nsTableRowGroupFrame::GetLastRow()
{
for (auto iter = mFrames.rbegin(), end = mFrames.rend(); iter != end; ++iter) {
nsTableRowFrame* rowFrame = do_QueryFrame(*iter);
if (rowFrame) {
return rowFrame;
}
}
return nullptr;
}
struct RowInfo {
RowInfo() { bSize = pctBSize = hasStyleBSize = hasPctBSize = isSpecial = 0; }
unsigned bSize; // content bsize or fixed bsize, excluding pct bsize
unsigned pctBSize:29; // pct bsize
unsigned hasStyleBSize:1;
unsigned hasPctBSize:1;
unsigned isSpecial:1; // there is no cell originating in the row with rowspan=1 and there are at
// least 2 cells spanning the row and there is no style bsize on the row
};
static void
UpdateBSizes(RowInfo& aRowInfo,
nscoord aAdditionalBSize,
nscoord& aTotal,
nscoord& aUnconstrainedTotal)
{
aRowInfo.bSize += aAdditionalBSize;
aTotal += aAdditionalBSize;
if (!aRowInfo.hasStyleBSize) {
aUnconstrainedTotal += aAdditionalBSize;
}
}
void
nsTableRowGroupFrame::DidResizeRows(ReflowOutput& aDesiredSize)
{
// Update the cells spanning rows with their new bsizes.
// This is the place where all of the cells in the row get set to the bsize
// of the row.
// Reset the overflow area.
aDesiredSize.mOverflowAreas.Clear();
for (nsTableRowFrame* rowFrame = GetFirstRow();
rowFrame; rowFrame = rowFrame->GetNextRow()) {
rowFrame->DidResize();
ConsiderChildOverflow(aDesiredSize.mOverflowAreas, rowFrame);
}
}
// This calculates the bsize of all the rows and takes into account
// style bsize on the row group, style bsizes on rows and cells, style bsizes on rowspans.
// Actual row bsizes will be adjusted later if the table has a style bsize.
// Even if rows don't change bsize, this method must be called to set the bsizes of each
// cell in the row to the bsize of its row.
void
nsTableRowGroupFrame::CalculateRowBSizes(nsPresContext* aPresContext,
ReflowOutput& aDesiredSize,
const ReflowInput& aReflowInput)
{
nsTableFrame* tableFrame = GetTableFrame();
const bool isPaginated = aPresContext->IsPaginated();
int32_t numEffCols = tableFrame->GetEffectiveColCount();
int32_t startRowIndex = GetStartRowIndex();
// find the row corresponding to the row index we just found
nsTableRowFrame* startRowFrame = GetFirstRow();
if (!startRowFrame) {
return;
}
// The current row group block-size is the block-origin of the 1st row
// we are about to calculate a block-size for.
WritingMode wm = aReflowInput.GetWritingMode();
nsSize containerSize; // actual value is unimportant as we're initially
// computing sizes, not physical positions
nscoord startRowGroupBSize =
startRowFrame->GetLogicalNormalPosition(wm, containerSize).B(wm);
int32_t numRows = GetRowCount() - (startRowFrame->GetRowIndex() - GetStartRowIndex());
// Collect the current bsize of each row.
if (numRows <= 0)
return;
nsTArray<RowInfo> rowInfo;
if (!rowInfo.AppendElements(numRows)) {
return;
}
bool hasRowSpanningCell = false;
nscoord bSizeOfRows = 0;
nscoord bSizeOfUnStyledRows = 0;
// Get the bsize of each row without considering rowspans. This will be the max of
// the largest desired bsize of each cell, the largest style bsize of each cell,
// the style bsize of the row.
nscoord pctBSizeBasis = GetBSizeBasis(aReflowInput);
int32_t rowIndex; // the index in rowInfo, not among the rows in the row group
nsTableRowFrame* rowFrame;
for (rowFrame = startRowFrame, rowIndex = 0; rowFrame; rowFrame = rowFrame->GetNextRow(), rowIndex++) {
nscoord nonPctBSize = rowFrame->GetContentBSize();
if (isPaginated) {
nonPctBSize = std::max(nonPctBSize, rowFrame->BSize(wm));
}
if (!rowFrame->GetPrevInFlow()) {
if (rowFrame->HasPctBSize()) {
rowInfo[rowIndex].hasPctBSize = true;
rowInfo[rowIndex].pctBSize = rowFrame->GetInitialBSize(pctBSizeBasis);
}
rowInfo[rowIndex].hasStyleBSize = rowFrame->HasStyleBSize();
nonPctBSize = std::max(nonPctBSize, rowFrame->GetFixedBSize());
}
UpdateBSizes(rowInfo[rowIndex], nonPctBSize, bSizeOfRows, bSizeOfUnStyledRows);
if (!rowInfo[rowIndex].hasStyleBSize) {
if (isPaginated || tableFrame->HasMoreThanOneCell(rowIndex + startRowIndex)) {
rowInfo[rowIndex].isSpecial = true;
// iteratate the row's cell frames to see if any do not have rowspan > 1
nsTableCellFrame* cellFrame = rowFrame->GetFirstCell();
while (cellFrame) {
int32_t rowSpan = tableFrame->GetEffectiveRowSpan(rowIndex + startRowIndex, *cellFrame);
if (1 == rowSpan) {
rowInfo[rowIndex].isSpecial = false;
break;
}
cellFrame = cellFrame->GetNextCell();
}
}
}
// See if a cell spans into the row. If so we'll have to do the next step
if (!hasRowSpanningCell) {
if (tableFrame->RowIsSpannedInto(rowIndex + startRowIndex, numEffCols)) {
hasRowSpanningCell = true;
}
}
}
if (hasRowSpanningCell) {
// Get the bsize of cells with rowspans and allocate any extra space to the rows they span
// iteratate the child frames and process the row frames among them
for (rowFrame = startRowFrame, rowIndex = 0; rowFrame; rowFrame = rowFrame->GetNextRow(), rowIndex++) {
// See if the row has an originating cell with rowspan > 1. We cannot determine this for a row in a
// continued row group by calling RowHasSpanningCells, because the row's fif may not have any originating
// cells yet the row may have a continued cell which originates in it.
if (GetPrevInFlow() || tableFrame->RowHasSpanningCells(startRowIndex + rowIndex, numEffCols)) {
nsTableCellFrame* cellFrame = rowFrame->GetFirstCell();
// iteratate the row's cell frames
while (cellFrame) {
nscoord cellSpacingB = tableFrame->GetRowSpacing(startRowIndex + rowIndex);
int32_t rowSpan = tableFrame->GetEffectiveRowSpan(rowIndex + startRowIndex, *cellFrame);
if ((rowIndex + rowSpan) > numRows) {
// there might be rows pushed already to the nextInFlow
rowSpan = numRows - rowIndex;
}
if (rowSpan > 1) { // a cell with rowspan > 1, determine the bsize of the rows it spans
nscoord bsizeOfRowsSpanned = 0;
nscoord bsizeOfUnStyledRowsSpanned = 0;
nscoord numSpecialRowsSpanned = 0;
nscoord cellSpacingTotal = 0;
int32_t spanX;
for (spanX = 0; spanX < rowSpan; spanX++) {
bsizeOfRowsSpanned += rowInfo[rowIndex + spanX].bSize;
if (!rowInfo[rowIndex + spanX].hasStyleBSize) {
bsizeOfUnStyledRowsSpanned += rowInfo[rowIndex + spanX].bSize;
}
if (0 != spanX) {
cellSpacingTotal += cellSpacingB;
}
if (rowInfo[rowIndex + spanX].isSpecial) {
numSpecialRowsSpanned++;
}
}
nscoord bsizeOfAreaSpanned = bsizeOfRowsSpanned + cellSpacingTotal;
// get the bsize of the cell
LogicalSize cellFrameSize = cellFrame->GetLogicalSize(wm);
LogicalSize cellDesSize = cellFrame->GetDesiredSize();
rowFrame->CalculateCellActualBSize(cellFrame, cellDesSize.BSize(wm), wm);
cellFrameSize.BSize(wm) = cellDesSize.BSize(wm);
if (cellFrame->HasVerticalAlignBaseline()) {
// to ensure that a spanning cell with a long descender doesn't
// collide with the next row, we need to take into account the shift
// that will be done to align the cell on the baseline of the row.
cellFrameSize.BSize(wm) += rowFrame->GetMaxCellAscent() -
cellFrame->GetCellBaseline();
}
if (bsizeOfAreaSpanned < cellFrameSize.BSize(wm)) {
// the cell's bsize is larger than the available space of the rows it
// spans so distribute the excess bsize to the rows affected
nscoord extra = cellFrameSize.BSize(wm) - bsizeOfAreaSpanned;
nscoord extraUsed = 0;
if (0 == numSpecialRowsSpanned) {
//NS_ASSERTION(bsizeOfRowsSpanned > 0, "invalid row span situation");
bool haveUnStyledRowsSpanned = (bsizeOfUnStyledRowsSpanned > 0);
nscoord divisor = (haveUnStyledRowsSpanned)
? bsizeOfUnStyledRowsSpanned : bsizeOfRowsSpanned;
if (divisor > 0) {
for (spanX = rowSpan - 1; spanX >= 0; spanX--) {
if (!haveUnStyledRowsSpanned || !rowInfo[rowIndex + spanX].hasStyleBSize) {
// The amount of additional space each row gets is proportional to its bsize
float percent = ((float)rowInfo[rowIndex + spanX].bSize) / ((float)divisor);
// give rows their percentage, except for the first row which gets the remainder
nscoord extraForRow = (0 == spanX) ? extra - extraUsed
: NSToCoordRound(((float)(extra)) * percent);
extraForRow = std::min(extraForRow, extra - extraUsed);
// update the row bsize
UpdateBSizes(rowInfo[rowIndex + spanX], extraForRow, bSizeOfRows, bSizeOfUnStyledRows);
extraUsed += extraForRow;
if (extraUsed >= extra) {
NS_ASSERTION((extraUsed == extra), "invalid row bsize calculation");
break;
}
}
}
}
else {
// put everything in the last row
UpdateBSizes(rowInfo[rowIndex + rowSpan - 1], extra, bSizeOfRows, bSizeOfUnStyledRows);
}
}
else {
// give the extra to the special rows
nscoord numSpecialRowsAllocated = 0;
for (spanX = rowSpan - 1; spanX >= 0; spanX--) {
if (rowInfo[rowIndex + spanX].isSpecial) {
// The amount of additional space each degenerate row gets is proportional to the number of them
float percent = 1.0f / ((float)numSpecialRowsSpanned);
// give rows their percentage, except for the first row which gets the remainder
nscoord extraForRow = (numSpecialRowsSpanned - 1 == numSpecialRowsAllocated)
? extra - extraUsed
: NSToCoordRound(((float)(extra)) * percent);
extraForRow = std::min(extraForRow, extra - extraUsed);
// update the row bsize
UpdateBSizes(rowInfo[rowIndex + spanX], extraForRow, bSizeOfRows, bSizeOfUnStyledRows);
extraUsed += extraForRow;
if (extraUsed >= extra) {
NS_ASSERTION((extraUsed == extra), "invalid row bsize calculation");
break;
}
}
}
}
}
} // if (rowSpan > 1)
cellFrame = cellFrame->GetNextCell();
} // while (cellFrame)
} // if (tableFrame->RowHasSpanningCells(startRowIndex + rowIndex) {
} // while (rowFrame)
}
// pct bsize rows have already got their content bsizes.
// Give them their pct bsizes up to pctBSizeBasis
nscoord extra = pctBSizeBasis - bSizeOfRows;
for (rowFrame = startRowFrame, rowIndex = 0; rowFrame && (extra > 0);
rowFrame = rowFrame->GetNextRow(), rowIndex++) {
RowInfo& rInfo = rowInfo[rowIndex];
if (rInfo.hasPctBSize) {
nscoord rowExtra = (rInfo.pctBSize > rInfo.bSize)
? rInfo.pctBSize - rInfo.bSize: 0;
rowExtra = std::min(rowExtra, extra);
UpdateBSizes(rInfo, rowExtra, bSizeOfRows, bSizeOfUnStyledRows);
extra -= rowExtra;
}
}
bool styleBSizeAllocation = false;
nscoord rowGroupBSize = startRowGroupBSize + bSizeOfRows +
tableFrame->GetRowSpacing(0, numRows-1);
// if we have a style bsize, allocate the extra bsize to unconstrained rows
if ((aReflowInput.ComputedBSize() > rowGroupBSize) &&
(NS_UNCONSTRAINEDSIZE != aReflowInput.ComputedBSize())) {
nscoord extraComputedBSize = aReflowInput.ComputedBSize() - rowGroupBSize;
nscoord extraUsed = 0;
bool haveUnStyledRows = (bSizeOfUnStyledRows > 0);
nscoord divisor = (haveUnStyledRows)
? bSizeOfUnStyledRows : bSizeOfRows;
if (divisor > 0) {
styleBSizeAllocation = true;
for (rowIndex = 0; rowIndex < numRows; rowIndex++) {
if (!haveUnStyledRows || !rowInfo[rowIndex].hasStyleBSize) {
// The amount of additional space each row gets is based on the
// percentage of space it occupies
float percent = ((float)rowInfo[rowIndex].bSize) / ((float)divisor);
// give rows their percentage, except for the last row which gets the remainder
nscoord extraForRow = (numRows - 1 == rowIndex)
? extraComputedBSize - extraUsed
: NSToCoordRound(((float)extraComputedBSize) * percent);
extraForRow = std::min(extraForRow, extraComputedBSize - extraUsed);
// update the row bsize
UpdateBSizes(rowInfo[rowIndex], extraForRow, bSizeOfRows, bSizeOfUnStyledRows);
extraUsed += extraForRow;
if (extraUsed >= extraComputedBSize) {
NS_ASSERTION((extraUsed == extraComputedBSize), "invalid row bsize calculation");
break;
}
}
}
}
rowGroupBSize = aReflowInput.ComputedBSize();
}
if (wm.IsVertical()) {
// we need the correct containerSize below for block positioning in
// vertical-rl writing mode
containerSize.width = rowGroupBSize;
}
nscoord bOrigin = startRowGroupBSize;
// update the rows with their (potentially) new bsizes
for (rowFrame = startRowFrame, rowIndex = 0; rowFrame;
rowFrame = rowFrame->GetNextRow(), rowIndex++) {
nsRect rowBounds = rowFrame->GetRect();
LogicalSize rowBoundsSize(wm, rowBounds.Size());
nsRect rowVisualOverflow = rowFrame->GetVisualOverflowRect();
nscoord deltaB =
bOrigin - rowFrame->GetLogicalNormalPosition(wm, containerSize).B(wm);
nscoord rowBSize = (rowInfo[rowIndex].bSize > 0) ? rowInfo[rowIndex].bSize : 0;
if (deltaB != 0 || (rowBSize != rowBoundsSize.BSize(wm))) {
// Resize/move the row to its final size and position
if (deltaB != 0) {
rowFrame->InvalidateFrameSubtree();
}
rowFrame->MovePositionBy(wm, LogicalPoint(wm, 0, deltaB));
rowFrame->SetSize(LogicalSize(wm, rowBoundsSize.ISize(wm), rowBSize));
nsTableFrame::InvalidateTableFrame(rowFrame, rowBounds, rowVisualOverflow,
false);
if (deltaB != 0) {
nsTableFrame::RePositionViews(rowFrame);
// XXXbz we don't need to update our overflow area?
}
}
bOrigin += rowBSize + tableFrame->GetRowSpacing(startRowIndex + rowIndex);
}
if (isPaginated && styleBSizeAllocation) {
// since the row group has a style bsize, cache the row bsizes,
// so next in flows can honor them
CacheRowBSizesForPrinting(aPresContext, GetFirstRow(), wm);
}
DidResizeRows(aDesiredSize);
aDesiredSize.BSize(wm) = rowGroupBSize; // Adjust our desired size
}
nscoord
nsTableRowGroupFrame::CollapseRowGroupIfNecessary(nscoord aBTotalOffset,
nscoord aISize,
WritingMode aWM)
{
nsTableFrame* tableFrame = GetTableFrame();
nsSize containerSize = tableFrame->GetSize();
const nsStyleVisibility* groupVis = StyleVisibility();
bool collapseGroup = (NS_STYLE_VISIBILITY_COLLAPSE == groupVis->mVisible);
if (collapseGroup) {
tableFrame->SetNeedToCollapse(true);
}
nsOverflowAreas overflow;
nsTableRowFrame* rowFrame = GetFirstRow();
bool didCollapse = false;
nscoord bGroupOffset = 0;
while (rowFrame) {
bGroupOffset += rowFrame->CollapseRowIfNecessary(bGroupOffset,
aISize, collapseGroup,
didCollapse);
ConsiderChildOverflow(overflow, rowFrame);
rowFrame = rowFrame->GetNextRow();
}
LogicalRect groupRect = GetLogicalRect(aWM, containerSize);
nsRect oldGroupRect = GetRect();
nsRect oldGroupVisualOverflow = GetVisualOverflowRect();
groupRect.BSize(aWM) -= bGroupOffset;
if (didCollapse) {
// add back the cellspacing between rowgroups
groupRect.BSize(aWM) += tableFrame->GetRowSpacing(GetStartRowIndex() +
GetRowCount());
}
groupRect.BStart(aWM) -= aBTotalOffset;
groupRect.ISize(aWM) = aISize;
if (aBTotalOffset != 0) {
InvalidateFrameSubtree();
}
SetRect(aWM, groupRect, containerSize);
overflow.UnionAllWith(nsRect(0, 0, groupRect.Width(aWM),
groupRect.Height(aWM)));
FinishAndStoreOverflow(overflow, groupRect.Size(aWM).GetPhysicalSize(aWM));
nsTableFrame::RePositionViews(this);
nsTableFrame::InvalidateTableFrame(this, oldGroupRect, oldGroupVisualOverflow,
false);
return bGroupOffset;
}
// Move a child that was skipped during a reflow.
void
nsTableRowGroupFrame::SlideChild(TableRowGroupReflowInput& aReflowInput,
nsIFrame* aKidFrame)
{
// Move the frame if we need to.
WritingMode wm = aReflowInput.reflowInput.GetWritingMode();
const nsSize containerSize =
aReflowInput.reflowInput.ComputedSizeAsContainerIfConstrained();
LogicalPoint oldPosition =
aKidFrame->GetLogicalNormalPosition(wm, containerSize);
LogicalPoint newPosition = oldPosition;
newPosition.B(wm) = aReflowInput.bCoord;
if (oldPosition.B(wm) != newPosition.B(wm)) {
aKidFrame->InvalidateFrameSubtree();
aReflowInput.reflowInput.ApplyRelativePositioning(&newPosition,
containerSize);
aKidFrame->SetPosition(wm, newPosition, containerSize);
nsTableFrame::RePositionViews(aKidFrame);
aKidFrame->InvalidateFrameSubtree();
}
}
// Create a continuing frame, add it to the child list, and then push it
// and the frames that follow
void
nsTableRowGroupFrame::CreateContinuingRowFrame(nsPresContext& aPresContext,
nsIFrame& aRowFrame,
nsIFrame** aContRowFrame)
{
// XXX what is the row index?
if (!aContRowFrame) {NS_ASSERTION(false, "bad call"); return;}
// create the continuing frame which will create continuing cell frames
*aContRowFrame = aPresContext.PresShell()->FrameConstructor()->
CreateContinuingFrame(&aPresContext, &aRowFrame, this);
// Add the continuing row frame to the child list
mFrames.InsertFrame(nullptr, &aRowFrame, *aContRowFrame);
// Push the continuing row frame and the frames that follow
PushChildren(*aContRowFrame, &aRowFrame);
}
// Reflow the cells with rowspan > 1 which originate between aFirstRow
// and end on or after aLastRow. aFirstTruncatedRow is the highest row on the
// page that contains a cell which cannot split on this page
void
nsTableRowGroupFrame::SplitSpanningCells(nsPresContext& aPresContext,
const ReflowInput& aReflowInput,
nsTableFrame& aTable,
nsTableRowFrame& aFirstRow,
nsTableRowFrame& aLastRow,
bool aFirstRowIsTopOfPage,
nscoord aSpanningRowBEnd,
nsTableRowFrame*& aContRow,
nsTableRowFrame*& aFirstTruncatedRow,
nscoord& aDesiredBSize)
{
NS_ASSERTION(aSpanningRowBEnd >= 0, "Can't split negative bsizes");
aFirstTruncatedRow = nullptr;
aDesiredBSize = 0;
const bool borderCollapse = aTable.IsBorderCollapse();
int32_t lastRowIndex = aLastRow.GetRowIndex();
bool wasLast = false;
bool haveRowSpan = false;
// Iterate the rows between aFirstRow and aLastRow
for (nsTableRowFrame* row = &aFirstRow; !wasLast; row = row->GetNextRow()) {
wasLast = (row == &aLastRow);
int32_t rowIndex = row->GetRowIndex();
nsPoint rowPos = row->GetNormalPosition();
// Iterate the cells looking for those that have rowspan > 1
for (nsTableCellFrame* cell = row->GetFirstCell(); cell; cell = cell->GetNextCell()) {
int32_t rowSpan = aTable.GetEffectiveRowSpan(rowIndex, *cell);
// Only reflow rowspan > 1 cells which span aLastRow. Those which don't span aLastRow
// were reflowed correctly during the unconstrained bsize reflow.
if ((rowSpan > 1) && (rowIndex + rowSpan > lastRowIndex)) {
haveRowSpan = true;
nsReflowStatus status;
// Ask the row to reflow the cell to the bsize of all the rows it spans up through aLastRow
// cellAvailBSize is the space between the row group start and the end of the page
nscoord cellAvailBSize = aSpanningRowBEnd - rowPos.y;
NS_ASSERTION(cellAvailBSize >= 0, "No space for cell?");
bool isTopOfPage = (row == &aFirstRow) && aFirstRowIsTopOfPage;
nsRect rowRect = row->GetNormalRect();
nsSize rowAvailSize(aReflowInput.AvailableWidth(),
std::max(aReflowInput.AvailableHeight() - rowRect.y,
0));
// don't let the available height exceed what
// CalculateRowBSizes set for it
rowAvailSize.height = std::min(rowAvailSize.height, rowRect.height);
ReflowInput rowReflowInput(&aPresContext, aReflowInput, row,
LogicalSize(row->GetWritingMode(),
rowAvailSize),
nullptr,
ReflowInput::CALLER_WILL_INIT);
InitChildReflowInput(aPresContext, borderCollapse, rowReflowInput);
rowReflowInput.mFlags.mIsTopOfPage = isTopOfPage; // set top of page
nscoord cellBSize = row->ReflowCellFrame(&aPresContext, rowReflowInput,
isTopOfPage, cell,
cellAvailBSize, status);
aDesiredBSize = std::max(aDesiredBSize, rowPos.y + cellBSize);
if (status.IsComplete()) {
if (cellBSize > cellAvailBSize) {
aFirstTruncatedRow = row;
if ((row != &aFirstRow) || !aFirstRowIsTopOfPage) {
// return now, since we will be getting another reflow after either (1) row is
// moved to the next page or (2) the row group is moved to the next page
return;
}
}
}
else {
if (!aContRow) {
CreateContinuingRowFrame(aPresContext, aLastRow, (nsIFrame**)&aContRow);
}
if (aContRow) {
if (row != &aLastRow) {
// aContRow needs a continuation for cell, since cell spanned into aLastRow
// but does not originate there
nsTableCellFrame* contCell = static_cast<nsTableCellFrame*>(
aPresContext.PresShell()->FrameConstructor()->
CreateContinuingFrame(&aPresContext, cell, &aLastRow));
int32_t colIndex;
cell->GetColIndex(colIndex);
aContRow->InsertCellFrame(contCell, colIndex);
}
}
}
}
}
}
if (!haveRowSpan) {
aDesiredBSize = aLastRow.GetNormalRect().YMost();
}
}
// Remove the next-in-flow of the row, its cells and their cell blocks. This
// is necessary in case the row doesn't need a continuation later on or needs
// a continuation which doesn't have the same number of cells that now exist.
void
nsTableRowGroupFrame::UndoContinuedRow(nsPresContext* aPresContext,
nsTableRowFrame* aRow)
{
if (!aRow) return; // allow null aRow to avoid callers doing null checks
// rowBefore was the prev-sibling of aRow's next-sibling before aRow was created
nsTableRowFrame* rowBefore = (nsTableRowFrame*)aRow->GetPrevInFlow();
NS_PRECONDITION(mFrames.ContainsFrame(rowBefore),
"rowBefore not in our frame list?");
AutoFrameListPtr overflows(aPresContext, StealOverflowFrames());
if (!rowBefore || !overflows || overflows->IsEmpty() ||
overflows->FirstChild() != aRow) {
NS_ERROR("invalid continued row");
return;
}
// Destroy aRow, its cells, and their cell blocks. Cell blocks that have split
// will not have reflowed yet to pick up content from any overflow lines.
overflows->DestroyFrame(aRow);
// Put the overflow rows into our child list
if (!overflows->IsEmpty()) {
mFrames.InsertFrames(nullptr, rowBefore, *overflows);
}
}
static nsTableRowFrame*
GetRowBefore(nsTableRowFrame& aStartRow,
nsTableRowFrame& aRow)
{
nsTableRowFrame* rowBefore = nullptr;
for (nsTableRowFrame* sib = &aStartRow; sib && (sib != &aRow); sib = sib->GetNextRow()) {
rowBefore = sib;
}
return rowBefore;
}
nsresult
nsTableRowGroupFrame::SplitRowGroup(nsPresContext* aPresContext,
ReflowOutput& aDesiredSize,
const ReflowInput& aReflowInput,
nsTableFrame* aTableFrame,
nsReflowStatus& aStatus,
bool aRowForcedPageBreak)
{
NS_PRECONDITION(aPresContext->IsPaginated(), "SplitRowGroup currently supports only paged media");
nsTableRowFrame* prevRowFrame = nullptr;
aDesiredSize.Height() = 0;
nscoord availWidth = aReflowInput.AvailableWidth();
nscoord availHeight = aReflowInput.AvailableHeight();
const bool borderCollapse = aTableFrame->IsBorderCollapse();
// get the page height
nscoord pageHeight = aPresContext->GetPageSize().height;
NS_ASSERTION(pageHeight != NS_UNCONSTRAINEDSIZE,
"The table shouldn't be split when there should be space");
bool isTopOfPage = aReflowInput.mFlags.mIsTopOfPage;
nsTableRowFrame* firstRowThisPage = GetFirstRow();
// Need to dirty the table's geometry, or else the row might skip
// reflowing its cell as an optimization.
aTableFrame->SetGeometryDirty();
// Walk each of the row frames looking for the first row frame that doesn't fit
// in the available space
for (nsTableRowFrame* rowFrame = firstRowThisPage; rowFrame; rowFrame = rowFrame->GetNextRow()) {
bool rowIsOnPage = true;
nscoord cellSpacingB = aTableFrame->GetRowSpacing(rowFrame->GetRowIndex());
nsRect rowRect = rowFrame->GetNormalRect();
// See if the row fits on this page
if (rowRect.YMost() > availHeight) {
nsTableRowFrame* contRow = nullptr;
// Reflow the row in the availabe space and have it split if it is the 1st
// row (on the page) or there is at least 5% of the current page available
// XXX this 5% should be made a preference
if (!prevRowFrame || (availHeight - aDesiredSize.Height() > pageHeight / 20)) {
nsSize availSize(availWidth, std::max(availHeight - rowRect.y, 0));
// don't let the available height exceed what CalculateRowHeights set for it
availSize.height = std::min(availSize.height, rowRect.height);
ReflowInput rowReflowInput(aPresContext, aReflowInput, rowFrame,
LogicalSize(rowFrame->GetWritingMode(),
availSize),
nullptr,
ReflowInput::CALLER_WILL_INIT);
InitChildReflowInput(*aPresContext, borderCollapse, rowReflowInput);
rowReflowInput.mFlags.mIsTopOfPage = isTopOfPage; // set top of page
ReflowOutput rowMetrics(aReflowInput);
// Get the old size before we reflow.
nsRect oldRowRect = rowFrame->GetRect();
nsRect oldRowVisualOverflow = rowFrame->GetVisualOverflowRect();
// Reflow the cell with the constrained height. A cell with rowspan >1 will get this
// reflow later during SplitSpanningCells.
ReflowChild(rowFrame, aPresContext, rowMetrics, rowReflowInput,
0, 0, NS_FRAME_NO_MOVE_FRAME, aStatus);
rowFrame->SetSize(nsSize(rowMetrics.Width(), rowMetrics.Height()));
rowFrame->DidReflow(aPresContext, nullptr, nsDidReflowStatus::FINISHED);
rowFrame->DidResize();
if (!aRowForcedPageBreak && !aStatus.IsFullyComplete() &&
ShouldAvoidBreakInside(aReflowInput)) {
aStatus.SetInlineLineBreakBeforeAndReset();
break;
}
nsTableFrame::InvalidateTableFrame(rowFrame, oldRowRect,
oldRowVisualOverflow,
false);
if (aStatus.IsIncomplete()) {
// The row frame is incomplete and all of the rowspan 1 cells' block frames split
if ((rowMetrics.Height() <= rowReflowInput.AvailableHeight()) || isTopOfPage) {
// The row stays on this page because either it split ok or we're on the top of page.
// If top of page and the height exceeded the avail height, then there will be data loss
NS_ASSERTION(rowMetrics.Height() <= rowReflowInput.AvailableHeight(),
"data loss - incomplete row needed more height than available, on top of page");
CreateContinuingRowFrame(*aPresContext, *rowFrame, (nsIFrame**)&contRow);
if (contRow) {
aDesiredSize.Height() += rowMetrics.Height();
if (prevRowFrame)
aDesiredSize.Height() += cellSpacingB;
}
else return NS_ERROR_NULL_POINTER;
}
else {
// Put the row on the next page to give it more height
rowIsOnPage = false;
}
}
else {
// The row frame is complete because either (1) its minimum height is greater than the
// available height we gave it, or (2) it may have been given a larger height through
// style than its content, or (3) it contains a rowspan >1 cell which hasn't been
// reflowed with a constrained height yet (we will find out when SplitSpanningCells is
// called below)
if (rowMetrics.Height() > availSize.height ||
(aStatus.IsInlineBreakBefore() && !aRowForcedPageBreak)) {
// cases (1) and (2)
if (isTopOfPage) {
// We're on top of the page, so keep the row on this page. There will be data loss.
// Push the row frame that follows
nsTableRowFrame* nextRowFrame = rowFrame->GetNextRow();
if (nextRowFrame) {
aStatus.Reset();
aStatus.SetIncomplete();
}
aDesiredSize.Height() += rowMetrics.Height();
if (prevRowFrame)
aDesiredSize.Height() += cellSpacingB;
NS_WARNING("data loss - complete row needed more height than available, on top of page");
}
else {
// We're not on top of the page, so put the row on the next page to give it more height
rowIsOnPage = false;
}
}
}
} //if (!prevRowFrame || (availHeight - aDesiredSize.Height() > pageHeight / 20))
else {
// put the row on the next page to give it more height
rowIsOnPage = false;
}
nsTableRowFrame* lastRowThisPage = rowFrame;
nscoord spanningRowBottom = availHeight;
if (!rowIsOnPage) {
NS_ASSERTION(!contRow, "We should not have created a continuation if none of this row fits");
if (!aRowForcedPageBreak && ShouldAvoidBreakInside(aReflowInput)) {
aStatus.SetInlineLineBreakBeforeAndReset();
break;
}
if (prevRowFrame) {
spanningRowBottom = prevRowFrame->GetNormalRect().YMost();
lastRowThisPage = prevRowFrame;
isTopOfPage = (lastRowThisPage == firstRowThisPage) && aReflowInput.mFlags.mIsTopOfPage;
aStatus.Reset();
aStatus.SetIncomplete();
}
else {
// We can't push children, so let our parent reflow us again with more space
aDesiredSize.Height() = rowRect.YMost();
aStatus.Reset();
break;
}
}
// reflow the cells with rowspan >1 that occur on the page
nsTableRowFrame* firstTruncatedRow;
nscoord bMost;
SplitSpanningCells(*aPresContext, aReflowInput, *aTableFrame, *firstRowThisPage,
*lastRowThisPage, aReflowInput.mFlags.mIsTopOfPage, spanningRowBottom, contRow,
firstTruncatedRow, bMost);
if (firstTruncatedRow) {
// A rowspan >1 cell did not fit (and could not split) in the space we gave it
if (firstTruncatedRow == firstRowThisPage) {
if (aReflowInput.mFlags.mIsTopOfPage) {
NS_WARNING("data loss in a row spanned cell");
}
else {
// We can't push children, so let our parent reflow us again with more space
aDesiredSize.Height() = rowRect.YMost();
aStatus.Reset();
UndoContinuedRow(aPresContext, contRow);
contRow = nullptr;
}
}
else { // (firstTruncatedRow != firstRowThisPage)
// Try to put firstTruncateRow on the next page
nsTableRowFrame* rowBefore = ::GetRowBefore(*firstRowThisPage, *firstTruncatedRow);
nscoord oldSpanningRowBottom = spanningRowBottom;
spanningRowBottom = rowBefore->GetNormalRect().YMost();
UndoContinuedRow(aPresContext, contRow);
contRow = nullptr;
nsTableRowFrame* oldLastRowThisPage = lastRowThisPage;
lastRowThisPage = rowBefore;
aStatus.Reset();
aStatus.SetIncomplete();
// Call SplitSpanningCells again with rowBefore as the last row on the page
SplitSpanningCells(*aPresContext, aReflowInput, *aTableFrame,
*firstRowThisPage, *rowBefore, aReflowInput.mFlags.mIsTopOfPage,
spanningRowBottom, contRow, firstTruncatedRow, aDesiredSize.Height());
if (firstTruncatedRow) {
if (aReflowInput.mFlags.mIsTopOfPage) {
// We were better off with the 1st call to SplitSpanningCells, do it again
UndoContinuedRow(aPresContext, contRow);
contRow = nullptr;
lastRowThisPage = oldLastRowThisPage;
spanningRowBottom = oldSpanningRowBottom;
SplitSpanningCells(*aPresContext, aReflowInput, *aTableFrame, *firstRowThisPage,
*lastRowThisPage, aReflowInput.mFlags.mIsTopOfPage, spanningRowBottom, contRow,
firstTruncatedRow, aDesiredSize.Height());
NS_WARNING("data loss in a row spanned cell");
}
else {
// Let our parent reflow us again with more space
aDesiredSize.Height() = rowRect.YMost();
aStatus.Reset();
UndoContinuedRow(aPresContext, contRow);
contRow = nullptr;
}
}
} // if (firstTruncatedRow == firstRowThisPage)
} // if (firstTruncatedRow)
else {
aDesiredSize.Height() = std::max(aDesiredSize.Height(), bMost);
if (contRow) {
aStatus.Reset();
aStatus.SetIncomplete();
}
}
if (aStatus.IsIncomplete() && !contRow) {
nsTableRowFrame* nextRow = lastRowThisPage->GetNextRow();
if (nextRow) {
PushChildren(nextRow, lastRowThisPage);
}
}
break;
} // if (rowRect.YMost() > availHeight)
else {
aDesiredSize.Height() = rowRect.YMost();
prevRowFrame = rowFrame;
// see if there is a page break after the row
nsTableRowFrame* nextRow = rowFrame->GetNextRow();
if (nextRow && nsTableFrame::PageBreakAfter(rowFrame, nextRow)) {
PushChildren(nextRow, rowFrame);
aStatus.Reset();
aStatus.SetIncomplete();
break;
}
}
// after the 1st row that has a height, we can't be on top
// of the page anymore.
isTopOfPage = isTopOfPage && rowRect.YMost() == 0;
}
return NS_OK;
}
/** Layout the entire row group.
* This method stacks rows vertically according to HTML 4.0 rules.
* Rows are responsible for layout of their children.
*/
void
nsTableRowGroupFrame::Reflow(nsPresContext* aPresContext,
ReflowOutput& aDesiredSize,
const ReflowInput& aReflowInput,
nsReflowStatus& aStatus)
{
MarkInReflow();
DO_GLOBAL_REFLOW_COUNT("nsTableRowGroupFrame");
DISPLAY_REFLOW(aPresContext, this, aReflowInput, aDesiredSize, aStatus);
aStatus.Reset();
// Row geometry may be going to change so we need to invalidate any row cursor.
ClearRowCursor();
// see if a special bsize reflow needs to occur due to having a pct bsize
nsTableFrame::CheckRequestSpecialBSizeReflow(aReflowInput);
nsTableFrame* tableFrame = GetTableFrame();
TableRowGroupReflowInput state(aReflowInput, tableFrame);
const nsStyleVisibility* groupVis = StyleVisibility();
bool collapseGroup = (NS_STYLE_VISIBILITY_COLLAPSE == groupVis->mVisible);
if (collapseGroup) {
tableFrame->SetNeedToCollapse(true);
}
// Check for an overflow list
MoveOverflowToChildList();
// Reflow the existing frames.
bool splitDueToPageBreak = false;
ReflowChildren(aPresContext, aDesiredSize, state, aStatus,
&splitDueToPageBreak);
// See if all the frames fit. Do not try to split anything if we're
// not paginated ... we can't split across columns yet.
if (aReflowInput.mFlags.mTableIsSplittable &&
NS_UNCONSTRAINEDSIZE != aReflowInput.AvailableHeight() &&
(aStatus.IsIncomplete() || splitDueToPageBreak ||
aDesiredSize.Height() > aReflowInput.AvailableHeight())) {
// Nope, find a place to split the row group
bool specialReflow = (bool)aReflowInput.mFlags.mSpecialBSizeReflow;
((ReflowInput::ReflowInputFlags&)aReflowInput.mFlags).mSpecialBSizeReflow = false;
SplitRowGroup(aPresContext, aDesiredSize, aReflowInput, tableFrame, aStatus,
splitDueToPageBreak);
((ReflowInput::ReflowInputFlags&)aReflowInput.mFlags).mSpecialBSizeReflow = specialReflow;
}
// XXXmats The following is just bogus. We leave it here for now because
// ReflowChildren should pull up rows from our next-in-flow before returning
// a Complete status, but doesn't (bug 804888).
if (GetNextInFlow() && GetNextInFlow()->PrincipalChildList().FirstChild()) {
aStatus.SetIncomplete();
}
SetHasStyleBSize((NS_UNCONSTRAINEDSIZE != aReflowInput.ComputedBSize()) &&
(aReflowInput.ComputedBSize() > 0));
// Just set our isize to what was available.
// The table will calculate the isize and not use our value.
WritingMode wm = aReflowInput.GetWritingMode();
aDesiredSize.ISize(wm) = aReflowInput.AvailableISize();
aDesiredSize.UnionOverflowAreasWithDesiredBounds();
// If our parent is in initial reflow, it'll handle invalidating our
// entire overflow rect.
if (!GetParent()->HasAnyStateBits(NS_FRAME_FIRST_REFLOW) &&
nsSize(aDesiredSize.Width(), aDesiredSize.Height()) != mRect.Size()) {
InvalidateFrame();
}
FinishAndStoreOverflow(&aDesiredSize);
// Any absolutely-positioned children will get reflowed in
// nsFrame::FixupPositionedTableParts in another pass, so propagate our
// dirtiness to them before our parent clears our dirty bits.
PushDirtyBitToAbsoluteFrames();
NS_FRAME_SET_TRUNCATION(aStatus, aReflowInput, aDesiredSize);
}
bool
nsTableRowGroupFrame::ComputeCustomOverflow(nsOverflowAreas& aOverflowAreas)
{
// Row cursor invariants depend on the visual overflow area of the rows,
// which may have changed, so we need to clear the cursor now.
ClearRowCursor();
return nsContainerFrame::ComputeCustomOverflow(aOverflowAreas);
}
/* virtual */ void
nsTableRowGroupFrame::DidSetStyleContext(nsStyleContext* aOldStyleContext)
{
nsContainerFrame::DidSetStyleContext(aOldStyleContext);
if (!aOldStyleContext) //avoid this on init
return;
nsTableFrame* tableFrame = GetTableFrame();
if (tableFrame->IsBorderCollapse() &&
tableFrame->BCRecalcNeeded(aOldStyleContext, StyleContext())) {
TableArea damageArea(0, GetStartRowIndex(), tableFrame->GetColCount(),
GetRowCount());
tableFrame->AddBCDamageArea(damageArea);
}
}
void
nsTableRowGroupFrame::AppendFrames(ChildListID aListID,
nsFrameList& aFrameList)
{
NS_ASSERTION(aListID == kPrincipalList, "unexpected child list");
DrainSelfOverflowList(); // ensure the last frame is in mFrames
ClearRowCursor();
// collect the new row frames in an array
// XXXbz why are we doing the QI stuff? There shouldn't be any non-rows here.
AutoTArray<nsTableRowFrame*, 8> rows;
for (nsFrameList::Enumerator e(aFrameList); !e.AtEnd(); e.Next()) {
nsTableRowFrame *rowFrame = do_QueryFrame(e.get());
NS_ASSERTION(rowFrame, "Unexpected frame; frame constructor screwed up");
if (rowFrame) {
NS_ASSERTION(mozilla::StyleDisplay::TableRow ==
e.get()->StyleDisplay()->mDisplay,
"wrong display type on rowframe");
rows.AppendElement(rowFrame);
}
}
int32_t rowIndex = GetRowCount();
// Append the frames to the sibling chain
mFrames.AppendFrames(nullptr, aFrameList);
if (rows.Length() > 0) {
nsTableFrame* tableFrame = GetTableFrame();
tableFrame->AppendRows(this, rowIndex, rows);
PresContext()->PresShell()->
FrameNeedsReflow(this, nsIPresShell::eTreeChange,
NS_FRAME_HAS_DIRTY_CHILDREN);
tableFrame->SetGeometryDirty();
}
}
void
nsTableRowGroupFrame::InsertFrames(ChildListID aListID,
nsIFrame* aPrevFrame,
nsFrameList& aFrameList)
{
NS_ASSERTION(aListID == kPrincipalList, "unexpected child list");
NS_ASSERTION(!aPrevFrame || aPrevFrame->GetParent() == this,
"inserting after sibling frame with different parent");
DrainSelfOverflowList(); // ensure aPrevFrame is in mFrames
ClearRowCursor();
// collect the new row frames in an array
// XXXbz why are we doing the QI stuff? There shouldn't be any non-rows here.
nsTableFrame* tableFrame = GetTableFrame();
nsTArray<nsTableRowFrame*> rows;
bool gotFirstRow = false;
for (nsFrameList::Enumerator e(aFrameList); !e.AtEnd(); e.Next()) {
nsTableRowFrame *rowFrame = do_QueryFrame(e.get());
NS_ASSERTION(rowFrame, "Unexpected frame; frame constructor screwed up");
if (rowFrame) {
NS_ASSERTION(mozilla::StyleDisplay::TableRow ==
e.get()->StyleDisplay()->mDisplay,
"wrong display type on rowframe");
rows.AppendElement(rowFrame);
if (!gotFirstRow) {
rowFrame->SetFirstInserted(true);
gotFirstRow = true;
tableFrame->SetRowInserted(true);
}
}
}
int32_t startRowIndex = GetStartRowIndex();
// Insert the frames in the sibling chain
mFrames.InsertFrames(nullptr, aPrevFrame, aFrameList);
int32_t numRows = rows.Length();
if (numRows > 0) {
nsTableRowFrame* prevRow = (nsTableRowFrame *)nsTableFrame::GetFrameAtOrBefore(this, aPrevFrame, LayoutFrameType::TableRow);
int32_t rowIndex = (prevRow) ? prevRow->GetRowIndex() + 1 : startRowIndex;
tableFrame->InsertRows(this, rows, rowIndex, true);
PresContext()->PresShell()->
FrameNeedsReflow(this, nsIPresShell::eTreeChange,
NS_FRAME_HAS_DIRTY_CHILDREN);
tableFrame->SetGeometryDirty();
}
}
void
nsTableRowGroupFrame::RemoveFrame(ChildListID aListID,
nsIFrame* aOldFrame)
{
NS_ASSERTION(aListID == kPrincipalList, "unexpected child list");
ClearRowCursor();
// XXX why are we doing the QI stuff? There shouldn't be any non-rows here.
nsTableRowFrame* rowFrame = do_QueryFrame(aOldFrame);
if (rowFrame) {
nsTableFrame* tableFrame = GetTableFrame();
// remove the rows from the table (and flag a rebalance)
tableFrame->RemoveRows(*rowFrame, 1, true);
PresContext()->PresShell()->
FrameNeedsReflow(this, nsIPresShell::eTreeChange,
NS_FRAME_HAS_DIRTY_CHILDREN);
tableFrame->SetGeometryDirty();
}
mFrames.DestroyFrame(aOldFrame);
}
/* virtual */ nsMargin
nsTableRowGroupFrame::GetUsedMargin() const
{
return nsMargin(0,0,0,0);
}
/* virtual */ nsMargin
nsTableRowGroupFrame::GetUsedBorder() const
{
return nsMargin(0,0,0,0);
}
/* virtual */ nsMargin
nsTableRowGroupFrame::GetUsedPadding() const
{
return nsMargin(0,0,0,0);
}
nscoord
nsTableRowGroupFrame::GetBSizeBasis(const ReflowInput& aReflowInput)
{
nscoord result = 0;
nsTableFrame* tableFrame = GetTableFrame();
int32_t startRowIndex = GetStartRowIndex();
if ((aReflowInput.ComputedBSize() > 0) && (aReflowInput.ComputedBSize() < NS_UNCONSTRAINEDSIZE)) {
nscoord cellSpacing = tableFrame->GetRowSpacing(startRowIndex,
std::max(startRowIndex,
startRowIndex + GetRowCount() - 1));
result = aReflowInput.ComputedBSize() - cellSpacing;
}
else {
const ReflowInput* parentRI = aReflowInput.mParentReflowInput;
if (parentRI && (tableFrame != parentRI->mFrame)) {
parentRI = parentRI->mParentReflowInput;
}
if (parentRI && (tableFrame == parentRI->mFrame) &&
(parentRI->ComputedBSize() > 0) && (parentRI->ComputedBSize() < NS_UNCONSTRAINEDSIZE)) {
nscoord cellSpacing = tableFrame->GetRowSpacing(-1, tableFrame->GetRowCount());
result = parentRI->ComputedBSize() - cellSpacing;
}
}
return result;
}
bool
nsTableRowGroupFrame::IsSimpleRowFrame(nsTableFrame* aTableFrame,
nsTableRowFrame* aRowFrame)
{
int32_t rowIndex = aRowFrame->GetRowIndex();
// It's a simple row frame if there are no cells that span into or
// across the row
int32_t numEffCols = aTableFrame->GetEffectiveColCount();
if (!aTableFrame->RowIsSpannedInto(rowIndex, numEffCols) &&
!aTableFrame->RowHasSpanningCells(rowIndex, numEffCols)) {
return true;
}
return false;
}
/** find page break before the first row **/
bool
nsTableRowGroupFrame::HasInternalBreakBefore() const
{
nsIFrame* firstChild = mFrames.FirstChild();
if (!firstChild)
return false;
return firstChild->StyleDisplay()->mBreakBefore;
}
/** find page break after the last row **/
bool
nsTableRowGroupFrame::HasInternalBreakAfter() const
{
nsIFrame* lastChild = mFrames.LastChild();
if (!lastChild)
return false;
return lastChild->StyleDisplay()->mBreakAfter;
}
/* ----- global methods ----- */
nsTableRowGroupFrame*
NS_NewTableRowGroupFrame(nsIPresShell* aPresShell, nsStyleContext* aContext)
{
return new (aPresShell) nsTableRowGroupFrame(aContext);
}
NS_IMPL_FRAMEARENA_HELPERS(nsTableRowGroupFrame)
#ifdef DEBUG_FRAME_DUMP
nsresult
nsTableRowGroupFrame::GetFrameName(nsAString& aResult) const
{
return MakeFrameName(NS_LITERAL_STRING("TableRowGroup"), aResult);
}
#endif
LogicalMargin
nsTableRowGroupFrame::GetBCBorderWidth(WritingMode aWM)
{
LogicalMargin border(aWM);
nsTableRowFrame* firstRowFrame = nullptr;
nsTableRowFrame* lastRowFrame = nullptr;
for (nsTableRowFrame* rowFrame = GetFirstRow(); rowFrame; rowFrame = rowFrame->GetNextRow()) {
if (!firstRowFrame) {
firstRowFrame = rowFrame;
}
lastRowFrame = rowFrame;
}
if (firstRowFrame) {
border.BStart(aWM) = nsPresContext::
CSSPixelsToAppUnits(firstRowFrame->GetBStartBCBorderWidth());
border.BEnd(aWM) = nsPresContext::
CSSPixelsToAppUnits(lastRowFrame->GetBEndBCBorderWidth());
}
return border;
}
void nsTableRowGroupFrame::SetContinuousBCBorderWidth(LogicalSide aForSide,
BCPixelSize aPixelValue)
{
switch (aForSide) {
case eLogicalSideIEnd:
mIEndContBorderWidth = aPixelValue;
return;
case eLogicalSideBEnd:
mBEndContBorderWidth = aPixelValue;
return;
case eLogicalSideIStart:
mIStartContBorderWidth = aPixelValue;
return;
default:
NS_ERROR("invalid LogicalSide argument");
}
}
//nsILineIterator methods
int32_t
nsTableRowGroupFrame::GetNumLines()
{
return GetRowCount();
}
bool
nsTableRowGroupFrame::GetDirection()
{
return (NS_STYLE_DIRECTION_RTL ==
GetTableFrame()->StyleVisibility()->mDirection);
}
NS_IMETHODIMP
nsTableRowGroupFrame::GetLine(int32_t aLineNumber,
nsIFrame** aFirstFrameOnLine,
int32_t* aNumFramesOnLine,
nsRect& aLineBounds)
{
NS_ENSURE_ARG_POINTER(aFirstFrameOnLine);
NS_ENSURE_ARG_POINTER(aNumFramesOnLine);
nsTableFrame* table = GetTableFrame();
nsTableCellMap* cellMap = table->GetCellMap();
*aFirstFrameOnLine = nullptr;
*aNumFramesOnLine = 0;
aLineBounds.SetRect(0, 0, 0, 0);
if ((aLineNumber < 0) || (aLineNumber >= GetRowCount())) {
return NS_OK;
}
aLineNumber += GetStartRowIndex();
*aNumFramesOnLine = cellMap->GetNumCellsOriginatingInRow(aLineNumber);
if (*aNumFramesOnLine == 0) {
return NS_OK;
}
int32_t colCount = table->GetColCount();
for (int32_t i = 0; i < colCount; i++) {
CellData* data = cellMap->GetDataAt(aLineNumber, i);
if (data && data->IsOrig()) {
*aFirstFrameOnLine = (nsIFrame*)data->GetCellFrame();
nsIFrame* parent = (*aFirstFrameOnLine)->GetParent();
aLineBounds = parent->GetRect();
return NS_OK;
}
}
NS_ERROR("cellmap is lying");
return NS_ERROR_FAILURE;
}
int32_t
nsTableRowGroupFrame::FindLineContaining(nsIFrame* aFrame, int32_t aStartLine)
{
NS_ENSURE_TRUE(aFrame, -1);
nsTableRowFrame *rowFrame = do_QueryFrame(aFrame);
NS_ASSERTION(rowFrame, "RowGroup contains a frame that is not a row");
int32_t rowIndexInGroup = rowFrame->GetRowIndex() - GetStartRowIndex();
return rowIndexInGroup >= aStartLine ? rowIndexInGroup : -1;
}
NS_IMETHODIMP
nsTableRowGroupFrame::CheckLineOrder(int32_t aLine,
bool *aIsReordered,
nsIFrame **aFirstVisual,
nsIFrame **aLastVisual)
{
*aIsReordered = false;
*aFirstVisual = nullptr;
*aLastVisual = nullptr;
return NS_OK;
}
NS_IMETHODIMP
nsTableRowGroupFrame::FindFrameAt(int32_t aLineNumber,
nsPoint aPos,
nsIFrame** aFrameFound,
bool* aPosIsBeforeFirstFrame,
bool* aPosIsAfterLastFrame)
{
nsTableFrame* table = GetTableFrame();
nsTableCellMap* cellMap = table->GetCellMap();
WritingMode wm = table->GetWritingMode();
nsSize containerSize = table->GetSize();
LogicalPoint pos(wm, aPos, containerSize);
*aFrameFound = nullptr;
*aPosIsBeforeFirstFrame = true;
*aPosIsAfterLastFrame = false;
aLineNumber += GetStartRowIndex();
int32_t numCells = cellMap->GetNumCellsOriginatingInRow(aLineNumber);
if (numCells == 0) {
return NS_OK;
}
nsIFrame* frame = nullptr;
int32_t colCount = table->GetColCount();
for (int32_t i = 0; i < colCount; i++) {
CellData* data = cellMap->GetDataAt(aLineNumber, i);
if (data && data->IsOrig()) {
frame = (nsIFrame*)data->GetCellFrame();
break;
}
}
NS_ASSERTION(frame, "cellmap is lying");
bool isRTL = (NS_STYLE_DIRECTION_RTL ==
table->StyleVisibility()->mDirection);
nsIFrame* closestFromStart = nullptr;
nsIFrame* closestFromEnd = nullptr;
int32_t n = numCells;
nsIFrame* firstFrame = frame;
while (n--) {
LogicalRect rect = frame->GetLogicalRect(wm, containerSize);
if (rect.ISize(wm) > 0) {
// If pos.I() is inside this frame - this is it
if (rect.IStart(wm) <= pos.I(wm) && rect.IEnd(wm) > pos.I(wm)) {
closestFromStart = closestFromEnd = frame;
break;
}
if (rect.IStart(wm) < pos.I(wm)) {
if (!closestFromStart ||
rect.IEnd(wm) > closestFromStart->
GetLogicalRect(wm, containerSize).IEnd(wm))
closestFromStart = frame;
}
else {
if (!closestFromEnd ||
rect.IStart(wm) < closestFromEnd->
GetLogicalRect(wm, containerSize).IStart(wm))
closestFromEnd = frame;
}
}
frame = frame->GetNextSibling();
}
if (!closestFromStart && !closestFromEnd) {
// All frames were zero-width. Just take the first one.
closestFromStart = closestFromEnd = firstFrame;
}
*aPosIsBeforeFirstFrame = isRTL ? !closestFromEnd : !closestFromStart;
*aPosIsAfterLastFrame = isRTL ? !closestFromStart : !closestFromEnd;
if (closestFromStart == closestFromEnd) {
*aFrameFound = closestFromStart;
}
else if (!closestFromStart) {
*aFrameFound = closestFromEnd;
}
else if (!closestFromEnd) {
*aFrameFound = closestFromStart;
}
else { // we're between two frames
nscoord delta =
closestFromEnd->GetLogicalRect(wm, containerSize).IStart(wm) -
closestFromStart->GetLogicalRect(wm, containerSize).IEnd(wm);
if (pos.I(wm) < closestFromStart->
GetLogicalRect(wm, containerSize).IEnd(wm) + delta/2) {
*aFrameFound = closestFromStart;
} else {
*aFrameFound = closestFromEnd;
}
}
return NS_OK;
}
NS_IMETHODIMP
nsTableRowGroupFrame::GetNextSiblingOnLine(nsIFrame*& aFrame,
int32_t aLineNumber)
{
NS_ENSURE_ARG_POINTER(aFrame);
aFrame = aFrame->GetNextSibling();
return NS_OK;
}
//end nsLineIterator methods
NS_DECLARE_FRAME_PROPERTY_DELETABLE(RowCursorProperty,
nsTableRowGroupFrame::FrameCursorData)
void
nsTableRowGroupFrame::ClearRowCursor()
{
if (!HasAnyStateBits(NS_ROWGROUP_HAS_ROW_CURSOR)) {
return;
}
RemoveStateBits(NS_ROWGROUP_HAS_ROW_CURSOR);
Properties().Delete(RowCursorProperty());
}
nsTableRowGroupFrame::FrameCursorData*
nsTableRowGroupFrame::SetupRowCursor()
{
if (HasAnyStateBits(NS_ROWGROUP_HAS_ROW_CURSOR)) {
// We already have a valid row cursor. Don't waste time rebuilding it.
return nullptr;
}
nsIFrame* f = mFrames.FirstChild();
int32_t count;
for (count = 0; f && count < MIN_ROWS_NEEDING_CURSOR; ++count) {
f = f->GetNextSibling();
}
if (!f) {
// Less than MIN_ROWS_NEEDING_CURSOR rows, so just don't bother
return nullptr;
}
FrameCursorData* data = new FrameCursorData();
if (!data)
return nullptr;
Properties().Set(RowCursorProperty(), data);
AddStateBits(NS_ROWGROUP_HAS_ROW_CURSOR);
return data;
}
nsIFrame*
nsTableRowGroupFrame::GetFirstRowContaining(nscoord aY, nscoord* aOverflowAbove)
{
if (!HasAnyStateBits(NS_ROWGROUP_HAS_ROW_CURSOR)) {
return nullptr;
}
FrameCursorData* property = Properties().Get(RowCursorProperty());
uint32_t cursorIndex = property->mCursorIndex;
uint32_t frameCount = property->mFrames.Length();
if (cursorIndex >= frameCount)
return nullptr;
nsIFrame* cursorFrame = property->mFrames[cursorIndex];
// The cursor's frame list excludes frames with empty overflow-area, so
// we don't need to check that here.
// We use property->mOverflowBelow here instead of computing the frame's
// true overflowArea.YMost(), because it is essential for the thresholds
// to form a monotonically increasing sequence. Otherwise we would break
// encountering a row whose overflowArea.YMost() is <= aY but which has
// a row above it containing cell(s) that span to include aY.
while (cursorIndex > 0 &&
cursorFrame->GetNormalRect().YMost() + property->mOverflowBelow > aY) {
--cursorIndex;
cursorFrame = property->mFrames[cursorIndex];
}
while (cursorIndex + 1 < frameCount &&
cursorFrame->GetNormalRect().YMost() + property->mOverflowBelow <= aY) {
++cursorIndex;
cursorFrame = property->mFrames[cursorIndex];
}
property->mCursorIndex = cursorIndex;
*aOverflowAbove = property->mOverflowAbove;
return cursorFrame;
}
bool
nsTableRowGroupFrame::FrameCursorData::AppendFrame(nsIFrame* aFrame)
{
// Relative positioning can cause table parts to move, but we will still paint
// the backgrounds for the parts under them at their 'normal' position. That
// means that we must consider the overflow rects at both positions. For
// example, if we use relative positioning to move a row-spanning cell, we
// will still paint the row background for that cell at its normal position,
// which will overflow the row.
// XXX(seth): This probably isn't correct in the presence of transforms.
nsRect positionedOverflowRect = aFrame->GetVisualOverflowRect();
nsPoint positionedToNormal = aFrame->GetNormalPosition() - aFrame->GetPosition();
nsRect normalOverflowRect = positionedOverflowRect + positionedToNormal;
nsRect overflowRect = positionedOverflowRect.Union(normalOverflowRect);
if (overflowRect.IsEmpty())
return true;
nscoord overflowAbove = -overflowRect.y;
nscoord overflowBelow = overflowRect.YMost() - aFrame->GetSize().height;
mOverflowAbove = std::max(mOverflowAbove, overflowAbove);
mOverflowBelow = std::max(mOverflowBelow, overflowBelow);
return mFrames.AppendElement(aFrame) != nullptr;
}
void
nsTableRowGroupFrame::InvalidateFrame(uint32_t aDisplayItemKey)
{
nsIFrame::InvalidateFrame(aDisplayItemKey);
GetParent()->InvalidateFrameWithRect(GetVisualOverflowRect() + GetPosition(), aDisplayItemKey);
}
void
nsTableRowGroupFrame::InvalidateFrameWithRect(const nsRect& aRect, uint32_t aDisplayItemKey)
{
nsIFrame::InvalidateFrameWithRect(aRect, aDisplayItemKey);
// If we have filters applied that would affects our bounds, then
// we get an inactive layer created and this is computed
// within FrameLayerBuilder
GetParent()->InvalidateFrameWithRect(aRect + GetPosition(), aDisplayItemKey);
}
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