/* -*- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*- * * The contents of this file are subject to the Netscape Public License * Version 1.0 (the "NPL"); you may not use this file except in * compliance with the NPL. You may obtain a copy of the NPL at * http://www.mozilla.org/NPL/ * * Software distributed under the NPL is distributed on an "AS IS" basis, * WITHOUT WARRANTY OF ANY KIND, either express or implied. See the NPL * for the specific language governing rights and limitations under the * NPL. * * The Initial Developer of this code under the NPL is Netscape * Communications Corporation. Portions created by Netscape are * Copyright (C) 1998 Netscape Communications Corporation. All Rights * Reserved. */ #include "nsTableRowFrame.h" #include "nsIRenderingContext.h" #include "nsIPresShell.h" #include "nsIPresContext.h" #include "nsIStyleContext.h" #include "nsStyleConsts.h" #include "nsIHTMLAttributes.h" #include "nsHTMLAtoms.h" #include "nsIContent.h" #include "nsTableFrame.h" #include "nsTableCellFrame.h" #include "nsIView.h" #include "nsIPtr.h" #include "nsIReflowCommand.h" #include "nsCSSRendering.h" #include "nsHTMLIIDs.h" #include "nsLayoutAtoms.h" #include "nsHTMLParts.h" #include "nsTableColGroupFrame.h" #include "nsTableColFrame.h" #include "nsCOMPtr.h" // the following header files are required for style optimizations that work only when the child content is really a cell #include "nsIHTMLTableCellElement.h" static NS_DEFINE_IID(kIHTMLTableCellElementIID, NS_IHTMLTABLECELLELEMENT_IID); // end includes for style optimizations that require real content knowledge NS_DEF_PTR(nsIStyleContext); /* ----------- nsTableRowpFrame ---------- */ nsTableRowFrame::nsTableRowFrame() : nsHTMLContainerFrame(), mTallestCell(0), mCellMaxTopMargin(0), mCellMaxBottomMargin(0), mMinRowSpan(1), mInitializedChildren(PR_FALSE) { } NS_IMETHODIMP nsTableRowFrame::Init(nsIPresContext& aPresContext, nsIContent* aContent, nsIFrame* aParent, nsIStyleContext* aContext, nsIFrame* aPrevInFlow) { nsresult rv; // Let the the base class do its initialization rv = nsHTMLContainerFrame::Init(aPresContext, aContent, aParent, aContext, aPrevInFlow); if (aPrevInFlow) { // Set the row index nsTableRowFrame* rowFrame = (nsTableRowFrame*)aPrevInFlow; SetRowIndex(rowFrame->GetRowIndex()); } return rv; } // Helper function. It marks the table frame as dirty and generates // a reflow command nsresult nsTableRowFrame::AddTableDirtyReflowCommand(nsIPresContext& aPresContext, nsIPresShell& aPresShell, nsIFrame* aTableFrame) { nsFrameState frameState; nsIFrame* tableParentFrame; nsIReflowCommand* reflowCmd; nsresult rv; // Mark the table frame as dirty aTableFrame->GetFrameState(&frameState); frameState |= NS_FRAME_IS_DIRTY; aTableFrame->SetFrameState(frameState); // Target the reflow comamnd at its parent frame aTableFrame->GetParent(&tableParentFrame); rv = NS_NewHTMLReflowCommand(&reflowCmd, tableParentFrame, nsIReflowCommand::ReflowDirty); if (NS_SUCCEEDED(rv)) { // Add the reflow command rv = aPresShell.AppendReflowCommand(reflowCmd); NS_RELEASE(reflowCmd); } return rv; } NS_IMETHODIMP nsTableRowFrame::AppendFrames(nsIPresContext& aPresContext, nsIPresShell& aPresShell, nsIAtom* aListName, nsIFrame* aFrameList) { // Append the frames mFrames.AppendFrames(nsnull, aFrameList); // Add the new cell frames to the table nsTableFrame *tableFrame = nsnull; nsTableFrame::GetTableFrame(this, tableFrame); for (nsIFrame* childFrame = aFrameList; childFrame; childFrame->GetNextSibling(&childFrame)) { const nsStyleDisplay *display; childFrame->GetStyleData(eStyleStruct_Display, ((const nsStyleStruct *&)display)); if (NS_STYLE_DISPLAY_TABLE_CELL == display->mDisplay) { // Add the cell to the cell map PRInt32 colIndex = tableFrame->AddCellToTable((nsTableCellFrame*)childFrame, GetRowIndex()); // Initialize the cell frame and give it its column index ((nsTableCellFrame*)childFrame)->InitCellFrame(colIndex); } } // See if any implicit column frames need to be created as a result of // adding the new rows PRBool createdColFrames; tableFrame->EnsureColumns(aPresContext, createdColFrames); if (createdColFrames) { // We need to rebuild the column cache // XXX It would be nice if this could be done incrementally tableFrame->InvalidateColumnCache(); } // Reflow the new frames. They're already marked dirty, so generate a reflow // command that tells us to reflow our dirty child frames nsIReflowCommand* reflowCmd; if (NS_SUCCEEDED(NS_NewHTMLReflowCommand(&reflowCmd, this, nsIReflowCommand::ReflowDirty))) { aPresShell.AppendReflowCommand(reflowCmd); NS_RELEASE(reflowCmd); } return NS_OK; } NS_IMETHODIMP nsTableRowFrame::InsertFrames(nsIPresContext& aPresContext, nsIPresShell& aPresShell, nsIAtom* aListName, nsIFrame* aPrevFrame, nsIFrame* aFrameList) { // Get the table frame nsTableFrame* tableFrame = nsnull; nsTableFrame::GetTableFrame(this, tableFrame); // Insert the frames mFrames.InsertFrames(nsnull, aPrevFrame, aFrameList); // We need to rebuild the cell map, because currently we can't insert // new frames except at the end (append) tableFrame->InvalidateCellMap(); // We should try and avoid doing a pass1 reflow on all the cells and just // do it for the newly added frames, but we need to add these frames to the // cell map before we reflow them tableFrame->InvalidateFirstPassCache(); // Because the number of columns may have changed invalidate the column // cache. Note that this has the side effect of recomputing the column // widths, so we don't need to call InvalidateColumnWidths() tableFrame->InvalidateColumnCache(); // Generate a reflow command so we reflow the table itself. This will // do a pass-1 reflow of all the rows including any rows we just added AddTableDirtyReflowCommand(aPresContext, aPresShell, tableFrame); return NS_OK; } NS_IMETHODIMP nsTableRowFrame::RemoveFrame(nsIPresContext& aPresContext, nsIPresShell& aPresShell, nsIAtom* aListName, nsIFrame* aOldFrame) { // Get the table frame nsTableFrame* tableFrame=nsnull; nsTableFrame::GetTableFrame(this, tableFrame); #if 0 // XXX Currently we can't incrementally remove cells from the cell map PRInt32 colIndex; aDeletedFrame->GetColIndex(colIndex); tableFrame->RemoveCellFromTable(aOldFrame, GetRowIndex()); // Remove the frame and destroy it mFrames.DestroyFrame(aPresContext, (nsIFrame*)aOldFrame); // XXX Reflow the row #else // Remove the frame and destroy it mFrames.DestroyFrame(aPresContext, aOldFrame); // We need to rebuild the cell map, because currently we can't incrementally // remove rows tableFrame->InvalidateCellMap(); // Because the number of columns may have changed invalidate the column // cache. Note that this has the side effect of recomputing the column // widths, so we don't need to call InvalidateColumnWidths() tableFrame->InvalidateColumnCache(); // Because we haven't added any new frames we don't need to do a pass1 // reflow. Just generate a reflow command so we reflow the table itself AddTableDirtyReflowCommand(aPresContext, aPresShell, tableFrame); #endif return NS_OK; } NS_IMETHODIMP nsTableRowFrame::InitChildrenWithIndex(PRInt32 aRowIndex) { nsTableFrame* table = nsnull; nsresult result=NS_OK; // each child cell can only be added to the table one time. // for now, we remember globally whether we've added all or none if (PR_FALSE==mInitializedChildren) { result = nsTableFrame::GetTableFrame(this, table); if ((NS_OK==result) && (table != nsnull)) { mInitializedChildren=PR_TRUE; SetRowIndex(aRowIndex); for (nsIFrame* kidFrame = mFrames.FirstChild(); nsnull != kidFrame; kidFrame->GetNextSibling(&kidFrame)) { const nsStyleDisplay *kidDisplay; kidFrame->GetStyleData(eStyleStruct_Display, ((const nsStyleStruct *&)kidDisplay)); if (NS_STYLE_DISPLAY_TABLE_CELL == kidDisplay->mDisplay) { // add the cell frame to the table's cell map and get its col index PRInt32 colIndex; colIndex = table->AddCellToTable((nsTableCellFrame *)kidFrame, aRowIndex); // what column does this cell belong to? // this sets the frame's notion of its column index ((nsTableCellFrame *)kidFrame)->InitCellFrame(colIndex); } } } } return NS_OK; } NS_IMETHODIMP nsTableRowFrame::InitChildren() { nsTableFrame* table = nsnull; nsresult result=NS_OK; // each child cell can only be added to the table one time. // for now, we remember globally whether we've added all or none if (PR_FALSE==mInitializedChildren) { result = nsTableFrame::GetTableFrame(this, table); if ((NS_OK==result) && (table != nsnull)) { PRInt32 rowIndex = table->GetNextAvailRowIndex(); InitChildrenWithIndex(rowIndex); } } return NS_OK; } /** * Post-reflow hook. This is where the table row does its post-processing */ void nsTableRowFrame::DidResize(nsIPresContext& aPresContext, const nsHTMLReflowState& aReflowState) { // Resize and re-align the cell frames based on our row height nscoord rowCellHeight = mRect.height - mCellMaxTopMargin - mCellMaxBottomMargin; nsTableFrame* tableFrame; nsTableFrame::GetTableFrame(this, tableFrame); nsTableIterator iter(*this, eTableDIR); nsIFrame* cellFrame = iter.First(); while (nsnull != cellFrame) { const nsStyleDisplay *kidDisplay; cellFrame->GetStyleData(eStyleStruct_Display, ((const nsStyleStruct *&)kidDisplay)); if (NS_STYLE_DISPLAY_TABLE_CELL == kidDisplay->mDisplay) { PRInt32 rowSpan = tableFrame->GetEffectiveRowSpan(mRowIndex, (nsTableCellFrame *)cellFrame); nscoord cellHeight = rowCellHeight; // add in height of rows spanned beyond the 1st one nsIFrame* nextRow = nsnull; GetNextSibling(&nextRow); for (int i = 1; ((i < rowSpan) && nextRow);) { const nsStyleDisplay *nextDisplay; nextRow->GetStyleData(eStyleStruct_Display, ((const nsStyleStruct *&)nextDisplay)); if (NS_STYLE_DISPLAY_TABLE_ROW == nextDisplay->mDisplay) { nsRect rect; nextRow->GetRect(rect); cellHeight += rect.height; i++; } nextRow->GetNextSibling(&nextRow); } // resize the cell's height nsSize cellFrameSize; cellFrame->GetSize(cellFrameSize); //if (cellFrameSize.height!=cellHeight) { cellFrame->SizeTo(cellFrameSize.width, cellHeight); // realign cell content based on the new height /*nsHTMLReflowMetrics desiredSize(nsnull); nsHTMLReflowState kidReflowState(aPresContext, aReflowState, cellFrame, nsSize(cellFrameSize.width, cellHeight), eReflowReason_Resize);*/ //XXX: the following reflow is necessary for any content of the cell // whose height is a percent of the cell's height (maybe indirectly.) // But some content crashes when this reflow is issued, to be investigated //XXX nsReflowStatus status; //ReflowChild(cellFrame, aPresContext, desiredSize, kidReflowState, status); ((nsTableCellFrame *)cellFrame)->VerticallyAlignChild(); /* if we're collapsing borders, notify the cell that the border edge length has changed */ if (NS_STYLE_BORDER_COLLAPSE == tableFrame->GetBorderCollapseStyle()) { ((nsTableCellFrame *)(cellFrame))->SetBorderEdgeLength(NS_SIDE_LEFT, GetRowIndex(), cellHeight); ((nsTableCellFrame *)(cellFrame))->SetBorderEdgeLength(NS_SIDE_RIGHT, GetRowIndex(), cellHeight); } } } // Get the next cell cellFrame = iter.Next(); } // Let our base class do the usual work } void nsTableRowFrame::ResetMaxChildHeight() { mTallestCell=0; mCellMaxTopMargin=0; mCellMaxBottomMargin=0; } void nsTableRowFrame::SetMaxChildHeight(nscoord aChildHeight, nscoord aTopMargin, nscoord aBottomMargin) { if (mTallestCellGetStyleData(eStyleStruct_Color); if (nsnull != myColor) { nsRect rect(0, 0, mRect.width, mRect.height); nsCSSRendering::PaintBackground(aPresContext, aRenderingContext, this, aDirtyRect, rect, *myColor); } */ static PRBool IsFirstRow(nsTableFrame& aTable, nsTableRowFrame& aRow) { nsIFrame* firstRowGroup = nsnull; aTable.FirstChild(nsnull, &firstRowGroup); nsIFrame* rowGroupFrame = nsnull; nsresult rv = aRow.GetParent(&rowGroupFrame); if (NS_SUCCEEDED(rv) && (rowGroupFrame == firstRowGroup)) { nsIFrame* firstRow; rowGroupFrame->FirstChild(nsnull, &firstRow); return (&aRow == firstRow); } return PR_FALSE; } NS_METHOD nsTableRowFrame::Paint(nsIPresContext& aPresContext, nsIRenderingContext& aRenderingContext, const nsRect& aDirtyRect, nsFramePaintLayer aWhichLayer) { nsresult rv; if (NS_FRAME_PAINT_LAYER_BACKGROUND == aWhichLayer) { nsCompatibility mode; aPresContext.GetCompatibilityMode(&mode); if (eCompatibility_Standard == mode) { const nsStyleDisplay* disp = (const nsStyleDisplay*)mStyleContext->GetStyleData(eStyleStruct_Display); if (disp->mVisible) { const nsStyleSpacing* spacing = (const nsStyleSpacing*)mStyleContext->GetStyleData(eStyleStruct_Spacing); const nsStyleColor* color = (const nsStyleColor*)mStyleContext->GetStyleData(eStyleStruct_Color); nsTableFrame* tableFrame = nsnull; rv = nsTableFrame::GetTableFrame(this, tableFrame); if (NS_FAILED(rv) || (nsnull == tableFrame)) { return rv; } nscoord cellSpacingX = tableFrame->GetCellSpacingX(); nscoord halfCellSpacingY = NSToCoordRound(((float)tableFrame->GetCellSpacingY()) / (float)2); // every row is short by the ending cell spacing X nsRect rect(0, 0, mRect.width + cellSpacingX, mRect.height); // first row may have gotten too much cell spacing Y if (tableFrame->GetRowCount() != 1) { if (IsFirstRow(*tableFrame, *this)) { rect.height -= halfCellSpacingY; } else { rect.height += halfCellSpacingY; rect.y -= halfCellSpacingY; } } nsCSSRendering::PaintBackground(aPresContext, aRenderingContext, this, aDirtyRect, rect, *color, *spacing, 0, 0); } } } // for debug... if ((NS_FRAME_PAINT_LAYER_DEBUG == aWhichLayer) && GetShowFrameBorders()) { aRenderingContext.SetColor(NS_RGB(0,255,0)); aRenderingContext.DrawRect(0, 0, mRect.width, mRect.height); } PaintChildren(aPresContext, aRenderingContext, aDirtyRect, aWhichLayer); return NS_OK; } PRIntn nsTableRowFrame::GetSkipSides() const { PRIntn skip = 0; if (nsnull != mPrevInFlow) { skip |= 1 << NS_SIDE_TOP; } if (nsnull != mNextInFlow) { skip |= 1 << NS_SIDE_BOTTOM; } return skip; } /** overloaded method from nsContainerFrame. The difference is that * we don't want to clip our children, so a cell can do a rowspan */ void nsTableRowFrame::PaintChildren(nsIPresContext& aPresContext, nsIRenderingContext& aRenderingContext, const nsRect& aDirtyRect, nsFramePaintLayer aWhichLayer) { nsIFrame* kid = mFrames.FirstChild(); while (nsnull != kid) { nsIView *pView; kid->GetView(&pView); if (nsnull == pView) { nsRect kidRect; kid->GetRect(kidRect); nsRect damageArea; PRBool overlap = damageArea.IntersectRect(aDirtyRect, kidRect); if (overlap) { PRBool clipState; // Translate damage area into kid's coordinate system nsRect kidDamageArea(damageArea.x - kidRect.x, damageArea.y - kidRect.y, damageArea.width, damageArea.height); aRenderingContext.PushState(); aRenderingContext.Translate(kidRect.x, kidRect.y); kid->Paint(aPresContext, aRenderingContext, kidDamageArea, aWhichLayer); if ((NS_FRAME_PAINT_LAYER_DEBUG == aWhichLayer) && GetShowFrameBorders()) { aRenderingContext.SetColor(NS_RGB(255,0,0)); aRenderingContext.DrawRect(0, 0, kidRect.width, kidRect.height); } aRenderingContext.PopState(clipState); } } kid->GetNextSibling(&kid); } } /** returns the height of the tallest child in this row (ignoring any cell with rowspans) */ nscoord nsTableRowFrame::GetTallestChild() const { return mTallestCell; } nscoord nsTableRowFrame::GetChildMaxTopMargin() const { return mCellMaxTopMargin; } nscoord nsTableRowFrame::GetChildMaxBottomMargin() const { return mCellMaxBottomMargin; } PRInt32 nsTableRowFrame::GetMaxColumns() const { int sum = 0; nsIFrame *cell=mFrames.FirstChild(); while (nsnull!=cell) { const nsStyleDisplay *kidDisplay; cell->GetStyleData(eStyleStruct_Display, ((const nsStyleStruct *&)kidDisplay)); if (NS_STYLE_DISPLAY_TABLE_CELL == kidDisplay->mDisplay) { sum += ((nsTableCellFrame *)cell)->GetColSpan(); } cell->GetNextSibling(&cell); } return sum; } /* GetMinRowSpan is needed for deviant cases where every cell in a row has a rowspan > 1. * It sets mMinRowSpan, which is used in FixMinCellHeight and PlaceChild */ void nsTableRowFrame::GetMinRowSpan(nsTableFrame *aTableFrame) { PRInt32 minRowSpan=-1; nsIFrame *frame=mFrames.FirstChild(); while (nsnull!=frame) { const nsStyleDisplay *kidDisplay; frame->GetStyleData(eStyleStruct_Display, ((const nsStyleStruct *&)kidDisplay)); if (NS_STYLE_DISPLAY_TABLE_CELL == kidDisplay->mDisplay) { PRInt32 rowSpan = aTableFrame->GetEffectiveRowSpan(mRowIndex, ((nsTableCellFrame *)frame)); if (-1==minRowSpan) minRowSpan = rowSpan; else if (minRowSpan>rowSpan) minRowSpan = rowSpan; } frame->GetNextSibling(&frame); } mMinRowSpan = minRowSpan; } void nsTableRowFrame::FixMinCellHeight(nsTableFrame *aTableFrame) { nsIFrame *frame=mFrames.FirstChild(); while (nsnull!=frame) { const nsStyleDisplay *kidDisplay; frame->GetStyleData(eStyleStruct_Display, ((const nsStyleStruct *&)kidDisplay)); if (NS_STYLE_DISPLAY_TABLE_CELL == kidDisplay->mDisplay) { PRInt32 rowSpan = aTableFrame->GetEffectiveRowSpan(mRowIndex, ((nsTableCellFrame *)frame)); if (mMinRowSpan==rowSpan) { nsRect rect; frame->GetRect(rect); if (rect.height > mTallestCell) mTallestCell = rect.height; } } frame->GetNextSibling(&frame); } } // Position and size aKidFrame and update our reflow state. The origin of // aKidRect is relative to the upper-left origin of our frame, and includes // any left/top margin. void nsTableRowFrame::PlaceChild(nsIPresContext& aPresContext, RowReflowState& aReflowState, nsIFrame* aKidFrame, const nsRect& aKidRect, nsSize* aMaxElementSize, nsSize* aKidMaxElementSize) { // Place and size the child aKidFrame->SetRect(aKidRect); // update the running total for the row width aReflowState.x += aKidRect.width; // Update the maximum element size PRInt32 rowSpan = aReflowState.tableFrame->GetEffectiveRowSpan((nsTableCellFrame*)aKidFrame); if (nsnull != aMaxElementSize) { aMaxElementSize->width += aKidMaxElementSize->width; if (1 == rowSpan) { aMaxElementSize->height = PR_MAX(aMaxElementSize->height, aKidMaxElementSize->height); } } // XXX this will be fixed when row spans deal with dead rows #if 0 // this accounts for cases where all cells in a row have a rowspan>1 // XXX "numColsInThisRow==numColsInTable" probably isn't the right metric to use here // the point is to skip a cell who's span effects another row, maybe use cellmap? PRInt32 numColsInThisRow = GetMaxColumns(); PRInt32 numColsInTable = aReflowState.tableFrame->GetColCount(); if ((1==rowSpan) || (mMinRowSpan == rowSpan && numColsInThisRow==numColsInTable)) { // Update maxCellHeight if (aKidRect.height > aReflowState.maxCellHeight) aReflowState.maxCellHeight = aKidRect.height; // Update maxCellVertSpace nsMargin margin; if (aReflowState.tableFrame->GetCellMarginData((nsTableCellFrame *)aKidFrame, margin) == NS_OK) { nscoord height = aKidRect.height + margin.top + margin.bottom; if (height > aReflowState.maxCellVertSpace) aReflowState.maxCellVertSpace = height; } } #else if (1 == rowSpan) { // Update maxCellHeight if (aKidRect.height > aReflowState.maxCellHeight) aReflowState.maxCellHeight = aKidRect.height; // Update maxCellVertSpace nsMargin margin; if (aReflowState.tableFrame->GetCellMarginData((nsTableCellFrame *)aKidFrame, margin) == NS_OK) { nscoord height = aKidRect.height + margin.top + margin.bottom; if (height > aReflowState.maxCellVertSpace) aReflowState.maxCellVertSpace = height; } } #endif } // Calculate the cell's actual size given its pass2 desired width and height. // Takes into account the specified height (in the style), and any special logic // needed for backwards compatibility. // Modifies the desired width and height that are passed in. nsresult nsTableRowFrame::CalculateCellActualSize(RowReflowState& aReflowState, nsIFrame* aCellFrame, nscoord& aDesiredWidth, nscoord& aDesiredHeight, nscoord aAvailWidth) { nscoord specifiedHeight = 0; const nsStylePosition* position; // Get the height specified in the style information aCellFrame->GetStyleData(eStyleStruct_Position, (const nsStyleStruct*&)position); switch (position->mHeight.GetUnit()) { case eStyleUnit_Coord: specifiedHeight = position->mHeight.GetCoordValue(); break; case eStyleUnit_Percent: { nsTableFrame* table = nsnull; nsTableFrame::GetTableFrame(this, table); if (table) { nscoord basis = table->GetPercentBasisForRows(); if (basis > 0) { float percent = position->mHeight.GetPercentValue(); specifiedHeight = NSToCoordRound(percent * ((float)basis)); } } break; } case eStyleUnit_Inherit: // XXX for now, do nothing default: case eStyleUnit_Auto: break; } // If the specified height is greater than the desired height, then use the // specified height if (specifiedHeight > aDesiredHeight) aDesiredHeight = specifiedHeight; // begin special Nav4 compatibility code for the width if (0 == aDesiredWidth) { aDesiredWidth = aAvailWidth; } // end special Nav4 compatibility code return NS_OK; } // Calculates the available width for the table cell based on the known // column widths taking into account column spans and column spacing nscoord nsTableRowFrame::CalculateCellAvailableWidth(nsTableFrame* aTableFrame, nsIFrame* aCellFrame, PRInt32 aCellColIndex, PRInt32 aNumColSpans, nscoord aCellSpacingX) { nscoord availWidth = 0; for (PRInt32 index = 0; index < aNumColSpans; index++) { // Add in the width of this column availWidth += aTableFrame->GetColumnWidth(aCellColIndex + index); // If the cell spans columns, then for all columns except the first column // add in the column spacing if ((index != 0) && (aTableFrame->GetNumCellsOriginatingInCol(aCellColIndex + index) > 0)) { availWidth += aCellSpacingX; } } return availWidth; } /** * Called for a resize reflow. Typically because the column widths have * changed. Reflows all the existing table cell frames unless aDirtyOnly * is PR_TRUE in which case only reflow the dirty frames */ NS_METHOD nsTableRowFrame::ResizeReflow(nsIPresContext& aPresContext, nsHTMLReflowMetrics& aDesiredSize, RowReflowState& aReflowState, nsReflowStatus& aStatus, PRBool aDirtyOnly) { aStatus = NS_FRAME_COMPLETE; if (nsnull == mFrames.FirstChild()) { return NS_OK; } nsresult rv=NS_OK; nsSize localKidMaxElementSize(0,0); nsSize* kidMaxElementSize = (aDesiredSize.maxElementSize) ? &localKidMaxElementSize : nsnull; nscoord maxCellTopMargin = 0; nscoord maxCellBottomMargin = 0; nscoord cellSpacingX = aReflowState.tableFrame->GetCellSpacingX(); PRInt32 cellColSpan=1; // must be defined here so it's set properly for non-cell kids PRInt32 prevColIndex; // remember the col index of the previous cell to handle rowspans into this row nsTableIteration dir = (aReflowState.reflowState.availableWidth == NS_UNCONSTRAINEDSIZE) ? eTableLTR : eTableDIR; nsTableIterator iter(*this, dir); if (iter.IsLeftToRight()) { prevColIndex = -1; } else { nsTableFrame* tableFrame = nsnull; rv = nsTableFrame::GetTableFrame(this, tableFrame); if (NS_FAILED(rv) || (nsnull == tableFrame)) { return rv; } prevColIndex = tableFrame->GetColCount(); } // Reflow each of our existing cell frames nsIFrame* kidFrame = iter.First(); while (nsnull != kidFrame) { // Get the frame state bits nsFrameState frameState; kidFrame->GetFrameState(&frameState); // See if we should only reflow the dirty child frames PRBool doReflowChild = PR_TRUE; if (aDirtyOnly) { if ((frameState & NS_FRAME_IS_DIRTY) == 0) { doReflowChild = PR_FALSE; } } // Reflow the child frame if (doReflowChild) { const nsStyleDisplay *kidDisplay; kidFrame->GetStyleData(eStyleStruct_Display, ((const nsStyleStruct *&)kidDisplay)); if (NS_STYLE_DISPLAY_TABLE_CELL == kidDisplay->mDisplay) { PRInt32 cellColIndex; ((nsTableCellFrame *)kidFrame)->GetColIndex(cellColIndex); cellColSpan = aReflowState.tableFrame->GetEffectiveColSpan(cellColIndex, ((nsTableCellFrame *)kidFrame)); nsMargin kidMargin; aReflowState.tableFrame->GetCellMarginData((nsTableCellFrame *)kidFrame,kidMargin); if (kidMargin.top > maxCellTopMargin) maxCellTopMargin = kidMargin.top; if (kidMargin.bottom > maxCellBottomMargin) maxCellBottomMargin = kidMargin.bottom; // Compute the x-origin for the child, taking into account straddlers (cells from prior // rows with rowspans > 1) // if this cell is not immediately adjacent to the previous cell, factor in missing col info if (iter.IsLeftToRight()) { if (prevColIndex != (cellColIndex - 1)) { for (PRInt32 colIndex = prevColIndex + 1; cellColIndex > colIndex; colIndex++) { aReflowState.x += aReflowState.tableFrame->GetColumnWidth(colIndex); if (aReflowState.tableFrame->GetNumCellsOriginatingInCol(colIndex) > 0) { aReflowState.x += cellSpacingX; } } } } else { if (prevColIndex != cellColIndex + cellColSpan) { PRInt32 lastCol = cellColIndex + cellColSpan - 1; for (PRInt32 colIndex = prevColIndex - 1; colIndex > lastCol; colIndex--) { aReflowState.x += aReflowState.tableFrame->GetColumnWidth(colIndex); if (aReflowState.tableFrame->GetNumCellsOriginatingInCol(colIndex) > 0) { aReflowState.x += cellSpacingX; } } } } aReflowState.x += cellSpacingX; // Calculate the available width for the table cell using the known // column widths nscoord availWidth; if (aDirtyOnly && (frameState & NS_FRAME_FIRST_REFLOW)) { // This is the initial reflow for the cell and so we do an unconstrained // reflow. // Note: don't assume that we have known column widths. If we don't, then // CalculateCellAvailableWidth() may assert if called now... availWidth = NS_UNCONSTRAINEDSIZE; } else { availWidth = CalculateCellAvailableWidth(aReflowState.tableFrame, kidFrame, cellColIndex, cellColSpan, cellSpacingX); } // remember the rightmost (ltr) or leftmost (rtl) column this cell spans into prevColIndex = (iter.IsLeftToRight()) ? cellColIndex + (cellColSpan - 1) : cellColIndex; nsHTMLReflowMetrics desiredSize(kidMaxElementSize); // If the available width is the same as last time we reflowed the cell, // then just use the previous desired size and max element size. // if we need the max-element-size we don't need to reflow. // we just grab it from the cell frame which remembers it (see the else clause below). // Note: we can't do that optimization if our height is constrained or the // cell frame has a next-in-flow nsIFrame* kidNextInFlow; kidFrame->GetNextInFlow(&kidNextInFlow); if ((aReflowState.reflowState.availableHeight != NS_UNCONSTRAINEDSIZE) || (availWidth != ((nsTableCellFrame *)kidFrame)->GetPriorAvailWidth()) || (nsnull != kidNextInFlow)) { // Reflow the cell to fit the available height nsSize kidAvailSize(availWidth, aReflowState.reflowState.availableHeight); // If it's a dirty frame, then check whether it's the initial reflow nsReflowReason reason = eReflowReason_Resize; if (aDirtyOnly) { if (frameState & NS_FRAME_FIRST_REFLOW) { // Newly inserted frame reason = eReflowReason_Initial; // Use an unconstrained width so we can get the child's maximum // width // XXX What about fixed layout tables? kidAvailSize.SizeTo(NS_UNCONSTRAINEDSIZE, NS_UNCONSTRAINEDSIZE); } } // Reflow the child nsHTMLReflowState kidReflowState(aPresContext, aReflowState.reflowState, kidFrame, kidAvailSize, reason); nsReflowStatus status; rv = ReflowChild(kidFrame, aPresContext, desiredSize, kidReflowState, status); #ifdef NS_DEBUG if (desiredSize.width > availWidth) { printf("WARNING: cell returned desired width %d given avail width %d\n", desiredSize.width, availWidth); } #endif if (eReflowReason_Initial == reason) { // Save the pass1 reflow information ((nsTableCellFrame *)kidFrame)->SetPass1DesiredSize(desiredSize); if (kidMaxElementSize) { ((nsTableCellFrame *)kidFrame)->SetPass1MaxElementSize(*kidMaxElementSize); } } // If any of the cells are not complete, then we're not complete if (NS_FRAME_IS_NOT_COMPLETE(status)) { aStatus = NS_FRAME_NOT_COMPLETE; } } else { nsSize priorSize = ((nsTableCellFrame *)kidFrame)->GetDesiredSize(); desiredSize.width = priorSize.width; desiredSize.height = priorSize.height; if (kidMaxElementSize) *kidMaxElementSize = ((nsTableCellFrame *)kidFrame)->GetPass1MaxElementSize(); } // Calculate the cell's actual size given its pass2 size. This function // takes into account the specified height (in the style), and any special // logic needed for backwards compatibility CalculateCellActualSize(aReflowState, kidFrame, desiredSize.width, desiredSize.height, availWidth); // Place the child nsRect kidRect (aReflowState.x, kidMargin.top, desiredSize.width, desiredSize.height); PlaceChild(aPresContext, aReflowState, kidFrame, kidRect, aDesiredSize.maxElementSize, kidMaxElementSize); } else {// it's an unknown frame type, give it a generic reflow and ignore the results nsHTMLReflowState kidReflowState(aPresContext, aReflowState.reflowState, kidFrame, nsSize(0,0), eReflowReason_Resize); nsHTMLReflowMetrics desiredSize(nsnull); nsReflowStatus status; ReflowChild(kidFrame, aPresContext, desiredSize, kidReflowState, status); } } kidFrame = iter.Next(); // Get the next child // if this was the last child, and it had a colspan>1, add in the cellSpacing for the colspan // if the last kid wasn't a colspan, then we still have the colspan of the last real cell if ((nsnull==kidFrame) && (cellColSpan>1)) aReflowState.x += cellSpacingX; } SetMaxChildHeight(aReflowState.maxCellHeight,maxCellTopMargin, maxCellBottomMargin); // remember height of tallest child who doesn't have a row span // Return our desired size. Note that our desired width is just whatever width // we were given by the row group frame aDesiredSize.width = aReflowState.x; aDesiredSize.height = aReflowState.maxCellVertSpace; #ifdef DEBUG nscoord overAllocated = aDesiredSize.width - aReflowState.reflowState.availableWidth; if (overAllocated > 0) { float p2t; aPresContext.GetScaledPixelsToTwips(&p2t); if (overAllocated > p2t) { printf("row over allocated by %d twips", overAllocated); } } #endif return rv; } /** * Called for the initial reflow. Creates each table cell frame, and * reflows it to gets its minimum and maximum sizes */ NS_METHOD nsTableRowFrame::InitialReflow(nsIPresContext& aPresContext, nsHTMLReflowMetrics& aDesiredSize, RowReflowState& aReflowState, nsReflowStatus& aStatus, nsTableCellFrame * aStartFrame, PRBool aDoSiblings) { // Place our children, one at a time, until we are out of children nsSize kidMaxElementSize(0,0); nscoord maxTopMargin = 0; nscoord maxBottomMargin = 0; nscoord x = 0; PRBool tableLayoutStrategy=NS_STYLE_TABLE_LAYOUT_AUTO; nsTableFrame* table = aReflowState.tableFrame; nsresult rv = NS_OK; const nsStyleTable* tableStyle; table->GetStyleData(eStyleStruct_Table, (const nsStyleStruct *&)tableStyle); tableLayoutStrategy = tableStyle->mLayoutStrategy; nsIFrame* kidFrame; if (nsnull==aStartFrame) kidFrame = mFrames.FirstChild(); else kidFrame = aStartFrame; for ( ; nsnull != kidFrame; kidFrame->GetNextSibling(&kidFrame)) { const nsStyleDisplay *kidDisplay; kidFrame->GetStyleData(eStyleStruct_Display, ((const nsStyleStruct *&)kidDisplay)); if (NS_STYLE_DISPLAY_TABLE_CELL == kidDisplay->mDisplay) { // Get the child's margins nsMargin margin; nscoord topMargin = 0; if (aReflowState.tableFrame->GetCellMarginData((nsTableCellFrame *)kidFrame, margin) == NS_OK) { topMargin = margin.top; } maxTopMargin = PR_MAX(margin.top, maxTopMargin); maxBottomMargin = PR_MAX(margin.bottom, maxBottomMargin); // get border padding values nsMargin borderPadding; const nsStyleSpacing* cellSpacingStyle; kidFrame->GetStyleData(eStyleStruct_Spacing , ((const nsStyleStruct *&)cellSpacingStyle)); cellSpacingStyle->CalcBorderPaddingFor(kidFrame, borderPadding); // For the initial reflow always allow the child to be as high as it // wants. The default available width is also unconstrained so we can // get the child's maximum width nsSize kidAvailSize; nsHTMLReflowMetrics kidSize(nsnull); if (NS_STYLE_TABLE_LAYOUT_AUTO==tableLayoutStrategy) { kidAvailSize.SizeTo(NS_UNCONSTRAINEDSIZE, NS_UNCONSTRAINEDSIZE); kidSize.maxElementSize=&kidMaxElementSize; } else { PRInt32 colIndex; ((nsTableCellFrame *)kidFrame)->GetColIndex(colIndex); kidAvailSize.SizeTo(table->GetColumnWidth(colIndex), NS_UNCONSTRAINEDSIZE); } nsHTMLReflowState kidReflowState(aPresContext, aReflowState.reflowState, kidFrame, kidAvailSize, eReflowReason_Initial); rv = ReflowChild(kidFrame, aPresContext, kidSize, kidReflowState, aStatus); // the following signals bugs in the content frames. if (kidMaxElementSize.width > kidSize.width) { printf("WARNING - table cell content max element width %d greater than desired width %d\n", kidMaxElementSize.width, kidSize.width); kidSize.width = kidMaxElementSize.width; } if (kidMaxElementSize.height > kidSize.height) { printf("Warning - table cell content max element height %d greater than desired height %d\n", kidMaxElementSize.height, kidSize.height); kidSize.height = kidMaxElementSize.height; } ((nsTableCellFrame *)kidFrame)->SetPass1DesiredSize(kidSize); ((nsTableCellFrame *)kidFrame)->SetPass1MaxElementSize(kidMaxElementSize); NS_ASSERTION(NS_FRAME_IS_COMPLETE(aStatus), "unexpected child reflow status"); // Place the child x += margin.left; nsRect kidRect(x, topMargin, kidSize.width, kidSize.height); PlaceChild(aPresContext, aReflowState, kidFrame, kidRect, aDesiredSize.maxElementSize, &kidMaxElementSize); x += kidSize.width + margin.right; } else {// it's an unknown frame type, give it a generic reflow and ignore the results nsHTMLReflowState kidReflowState(aPresContext, aReflowState.reflowState, kidFrame, nsSize(0,0), eReflowReason_Initial); nsHTMLReflowMetrics desiredSize(nsnull); ReflowChild(kidFrame, aPresContext, desiredSize, kidReflowState, aStatus); } if (PR_FALSE==aDoSiblings) break; } SetMaxChildHeight(aReflowState.maxCellHeight, maxTopMargin, maxBottomMargin); // remember height of tallest child who doesn't have a row span // Return our desired size aDesiredSize.width = x; aDesiredSize.height = aReflowState.maxCellVertSpace; return rv; } // Recover the reflow state to what it should be if aKidFrame is about // to be reflowed // // The things in the RowReflowState object we need to restore are: // - maxCellHeight // - maxVertCellSpace // - x NS_METHOD nsTableRowFrame::RecoverState(nsIPresContext& aPresContext, RowReflowState& aReflowState, nsIFrame* aKidFrame, nscoord& aMaxCellTopMargin, nscoord& aMaxCellBottomMargin, nsSize* aMaxElementSize) { // Initialize OUT parameters aMaxCellTopMargin = aMaxCellBottomMargin = 0; if (aMaxElementSize) { aMaxElementSize->width = 0; aMaxElementSize->height = 0; } // Walk the child frames (except aKidFrame) and find the table cell frames for (nsIFrame* frame = mFrames.FirstChild(); frame; frame->GetNextSibling(&frame)) { if (frame != aKidFrame) { // See if the frame is a table cell frame const nsStyleDisplay *kidDisplay; frame->GetStyleData(eStyleStruct_Display, ((const nsStyleStruct *&)kidDisplay)); if (NS_STYLE_DISPLAY_TABLE_CELL == kidDisplay->mDisplay) { nsMargin kidMargin; // Update the max top and bottom margins aReflowState.tableFrame->GetCellMarginData((nsTableCellFrame *)frame, kidMargin); if (kidMargin.top > aMaxCellTopMargin) aMaxCellTopMargin = kidMargin.top; if (kidMargin.bottom > aMaxCellBottomMargin) aMaxCellBottomMargin = kidMargin.bottom; // Update maxCellHeight and maxVertCellSpace. When determining this we // don't include cells that span rows PRInt32 rowSpan = aReflowState.tableFrame->GetEffectiveRowSpan(mRowIndex, ((nsTableCellFrame *)frame)); if (mMinRowSpan == rowSpan) { // Get the cell's desired height the last time it was reflowed nsSize desiredSize = ((nsTableCellFrame *)frame)->GetDesiredSize(); // See if it has a specified height that overrides the desired size. // Note: we don't care about the width so don't compute the column // width and just pass in the desired width for the available width CalculateCellActualSize(aReflowState, frame, desiredSize.width, desiredSize.height, desiredSize.width); // Update maxCellHeight if (desiredSize.height > aReflowState.maxCellHeight) { aReflowState.maxCellHeight = desiredSize.height; } // Update maxCellVertHeight nscoord vertHeight = desiredSize.height + kidMargin.top + kidMargin.bottom; if (vertHeight > aReflowState.maxCellVertSpace) { aReflowState.maxCellVertSpace = vertHeight; } } // Recover the max element size if requested if (aMaxElementSize) { nsSize kidMaxElementSize = ((nsTableCellFrame *)frame)->GetPass1MaxElementSize(); aMaxElementSize->width += kidMaxElementSize.width; if (1 == rowSpan) { aMaxElementSize->height = PR_MAX(aMaxElementSize->height, kidMaxElementSize.height); } } } } } // Update the running x-offset based on the frame's current x-origin nsPoint origin; aKidFrame->GetOrigin(origin); aReflowState.x = origin.x; return NS_OK; } NS_METHOD nsTableRowFrame::IncrementalReflow(nsIPresContext& aPresContext, nsHTMLReflowMetrics& aDesiredSize, RowReflowState& aReflowState, nsReflowStatus& aStatus) { nsresult rv = NS_OK; // determine if this frame is the target or not nsIFrame *target=nsnull; rv = aReflowState.reflowState.reflowCommand->GetTarget(target); if ((PR_TRUE==NS_SUCCEEDED(rv)) && (nsnull!=target)) { if (this==target) rv = IR_TargetIsMe(aPresContext, aDesiredSize, aReflowState, aStatus); else { // Get the next frame in the reflow chain nsIFrame* nextFrame; aReflowState.reflowState.reflowCommand->GetNext(nextFrame); rv = IR_TargetIsChild(aPresContext, aDesiredSize, aReflowState, aStatus, nextFrame); } } return rv; } NS_METHOD nsTableRowFrame::IR_TargetIsMe(nsIPresContext& aPresContext, nsHTMLReflowMetrics& aDesiredSize, RowReflowState& aReflowState, nsReflowStatus& aStatus) { nsresult rv = NS_FRAME_COMPLETE; nsIReflowCommand::ReflowType type; aReflowState.reflowState.reflowCommand->GetType(type); nsIFrame *objectFrame; aReflowState.reflowState.reflowCommand->GetChildFrame(objectFrame); const nsStyleDisplay *childDisplay=nsnull; if (nsnull!=objectFrame) objectFrame->GetStyleData(eStyleStruct_Display, ((const nsStyleStruct *&)childDisplay)); switch (type) { case nsIReflowCommand::ReflowDirty: { // Reflow the dirty child frames. Typically this is newly added frames. // XXX What we really should do is do a pass-1 reflow of newly added // frames (only if necessary, i.e., the table isn't fixed layout), then // see if column widtsh changed and decide whether to do the pass-2 reflow // of just the dirty rows or have the table rebalance column widths and // do a pass-2 reflow of all rows rv = ResizeReflow(aPresContext, aDesiredSize, aReflowState, aStatus, PR_TRUE); // If any column widths have to change due to this, rebalance column widths. // XXX need to calculate this, but for now just do it aReflowState.tableFrame->InvalidateColumnWidths(); break; } case nsIReflowCommand::StyleChanged : rv = IR_StyleChanged(aPresContext, aDesiredSize, aReflowState, aStatus); break; case nsIReflowCommand::ContentChanged : NS_ASSERTION(PR_FALSE, "illegal reflow type: ContentChanged"); rv = NS_ERROR_ILLEGAL_VALUE; break; default: NS_NOTYETIMPLEMENTED("unexpected reflow command type"); rv = NS_ERROR_NOT_IMPLEMENTED; break; } return rv; } NS_METHOD nsTableRowFrame::IR_StyleChanged(nsIPresContext& aPresContext, nsHTMLReflowMetrics& aDesiredSize, RowReflowState& aReflowState, nsReflowStatus& aStatus) { nsresult rv = NS_OK; // we presume that all the easy optimizations were done in the nsHTMLStyleSheet before we were called here // XXX: we can optimize this when we know which style attribute changed aReflowState.tableFrame->InvalidateFirstPassCache(); return rv; } NS_METHOD nsTableRowFrame::IR_TargetIsChild(nsIPresContext& aPresContext, nsHTMLReflowMetrics& aDesiredSize, RowReflowState& aReflowState, nsReflowStatus& aStatus, nsIFrame * aNextFrame) { nsresult rv; const nsStyleDisplay *childDisplay; aNextFrame->GetStyleData(eStyleStruct_Display, ((const nsStyleStruct *&)childDisplay)); if (NS_STYLE_DISPLAY_TABLE_CELL == childDisplay->mDisplay) { // Recover our reflow state nscoord maxCellTopMargin, maxCellBottomMargin; RecoverState(aPresContext, aReflowState, aNextFrame, maxCellTopMargin, maxCellBottomMargin, aDesiredSize.maxElementSize); // Get the frame's margins nsMargin kidMargin; aReflowState.tableFrame->GetCellMarginData((nsTableCellFrame *)aNextFrame, kidMargin); if (kidMargin.top > maxCellTopMargin) maxCellTopMargin = kidMargin.top; if (kidMargin.bottom > maxCellBottomMargin) maxCellBottomMargin = kidMargin.bottom; // At this point, we know the column widths. Compute the cell available width PRInt32 cellColIndex; ((nsTableCellFrame *)aNextFrame)->GetColIndex(cellColIndex); PRInt32 cellColSpan = aReflowState.tableFrame->GetEffectiveColSpan(cellColIndex, ((nsTableCellFrame *)aNextFrame)); nscoord cellSpacingX = aReflowState.tableFrame->GetCellSpacingX(); nscoord cellAvailWidth = CalculateCellAvailableWidth(aReflowState.tableFrame, aNextFrame, cellColIndex, cellColSpan, cellSpacingX); // Always let the cell be as high as it wants. We ignore the height that's // passed in and always place the entire row. Let the row group decide // whether we fit or wehther the entire row is pushed nsSize kidAvailSize(cellAvailWidth, NS_UNCONSTRAINEDSIZE); // Pass along the reflow command nsSize kidMaxElementSize; nsHTMLReflowMetrics desiredSize(&kidMaxElementSize); nsHTMLReflowState kidReflowState(aPresContext, aReflowState.reflowState, aNextFrame, kidAvailSize); // Remember the current desired size, we'll need it later nsSize oldMinSize = ((nsTableCellFrame*)aNextFrame)->GetPass1MaxElementSize(); nsSize oldDesiredSize = ((nsTableCellFrame*)aNextFrame)->GetPass1DesiredSize(); // Reflow the cell passing it the incremental reflow command. We can't pass // in a max width of NS_UNCONSTRAINEDSIZE, because the max width must match // the width of the previous reflow... rv = ReflowChild(aNextFrame, aPresContext, desiredSize, kidReflowState, aStatus); //XXX: this is a hack, shouldn't it be the case that a min size is // never larger than a desired size? #if 0 if (kidMaxElementSize.width>desiredSize.width) desiredSize.width = kidMaxElementSize.width; if (kidMaxElementSize.height>desiredSize.height) desiredSize.height = kidMaxElementSize.height; #endif // Update the cell layout data. ((nsTableCellFrame *)aNextFrame)->SetPass1MaxElementSize(kidMaxElementSize); // Now see if we need to do the regular pass 1 reflow and gather the preferred // width. If the new minimum width is different from the old minimum width, // then we should consider the max element size if (aReflowState.tableFrame->ColumnsCanBeInvalidatedBy(*(nsTableCellFrame*)aNextFrame, oldMinSize.width != kidMaxElementSize.width)) { // For fixed-layout tables we don't need to know the preferred width if (aReflowState.tableFrame->RequiresPass1Layout()) { #ifdef DEBUG_troy // Changes to the cell frame could require the columns to be rebalanced. // XXX We don't really need to compute the max element size again, we just // computed it above. However, for the time being do compute it again and // make sure it's consistent... nscoord prevMaxElementWidth = kidMaxElementSize.width; #endif // Do the unconstrained reflow and get the pass1 information // XXX Why the reflow reason of eReflowReason_Initial? kidReflowState.reason = eReflowReason_Initial; kidReflowState.reflowCommand = nsnull; kidReflowState.availableWidth = NS_UNCONSTRAINEDSIZE; rv = ReflowChild(aNextFrame, aPresContext, desiredSize, kidReflowState, aStatus); //XXX: this is a hack, shouldn't it be the case that a min size is // never larger than a desired size? if (kidMaxElementSize.width>desiredSize.width) desiredSize.width = kidMaxElementSize.width; if (kidMaxElementSize.height>desiredSize.height) desiredSize.height = kidMaxElementSize.height; #ifdef DEBUG_troy // XXX See above NS_ASSERTION(prevMaxElementWidth == kidMaxElementSize.width, "different max element width!"); #else ((nsTableCellFrame *)aNextFrame)->SetPass1MaxElementSize(kidMaxElementSize); #endif // Update the cell layout data. ((nsTableCellFrame *)aNextFrame)->SetPass1DesiredSize(desiredSize); } // Now that we know the minimum and preferred widths see if the column // widths need to be rebalanced if (aReflowState.tableFrame->ColumnsAreValidFor(*(nsTableCellFrame*)aNextFrame, oldMinSize.width, oldDesiredSize.width)) { // The column widths don't need to be rebalanced. Now reflow the cell // again this time constraining the width back to the column width again kidReflowState.reason = eReflowReason_Resize; kidReflowState.availableWidth = cellAvailWidth; rv = ReflowChild(aNextFrame, aPresContext, desiredSize, kidReflowState, aStatus); } else { // The column widths need to be rebalanced, so don't waste time reflowing // the cell again. Tell the table to rebalance the column widths aReflowState.tableFrame->InvalidateColumnWidths(); } } // Calculate the cell's actual size given its pass2 size. This function // takes into account the specified height (in the style), and any special // logic needed for backwards compatibility CalculateCellActualSize(aReflowState, aNextFrame, desiredSize.width, desiredSize.height, cellAvailWidth); // Now place the child nsRect kidRect (aReflowState.x, kidMargin.top, desiredSize.width, desiredSize.height); PlaceChild(aPresContext, aReflowState, aNextFrame, kidRect, aDesiredSize.maxElementSize, &kidMaxElementSize); SetMaxChildHeight(aReflowState.maxCellHeight, maxCellTopMargin, maxCellBottomMargin); // Return our desired size. Note that our desired width is just whatever width // we were given by the row group frame aDesiredSize.width = aReflowState.availSize.width; aDesiredSize.height = aReflowState.maxCellVertSpace; } else { // pass reflow to unknown frame child // aDesiredSize does not change } return rv; } /** Layout the entire row. * This method stacks cells horizontally according to HTML 4.0 rules. */ NS_METHOD nsTableRowFrame::Reflow(nsIPresContext& aPresContext, nsHTMLReflowMetrics& aDesiredSize, const nsHTMLReflowState& aReflowState, nsReflowStatus& aStatus) { if (nsDebugTable::gRflRow) nsTableFrame::DebugReflow("TR::Rfl en", this, &aReflowState, nsnull); nsresult rv = NS_OK; // Initialize 'out' parameters (aStatus set below, undefined if rv returns an error) if (nsnull != aDesiredSize.maxElementSize) { aDesiredSize.maxElementSize->width = 0; aDesiredSize.maxElementSize->height = 0; } // Initialize our internal data ResetMaxChildHeight(); // Create a reflow state nsTableFrame *tableFrame=nsnull; rv = nsTableFrame::GetTableFrame(this, tableFrame); if (NS_FAILED(rv) || nsnull==tableFrame) return rv; RowReflowState state(aReflowState, tableFrame); // Do the reflow // XXX If the width is unconstrained, then treat it like we would treat the // initial reflow instead. This needs to be cleaned up nsReflowReason reason = aReflowState.reason; if (NS_UNCONSTRAINEDSIZE == aReflowState.availableWidth) { reason = eReflowReason_Initial; } switch (reason) { case eReflowReason_Initial: rv = InitialReflow(aPresContext, aDesiredSize, state, aStatus, nsnull, PR_TRUE); if (PR_FALSE==tableFrame->RequiresPass1Layout()) { // this resize reflow is necessary to place the cells correctly in the case of rowspans and colspans. // It is very efficient. It does not actually need to pass a reflow down to the cells. nsSize availSpace(aReflowState.availableWidth, aReflowState.availableHeight); nsHTMLReflowState resizeReflowState(aPresContext, (const nsHTMLReflowState&)(*(aReflowState.parentReflowState)), (nsIFrame *)this, availSpace, eReflowReason_Resize); RowReflowState rowResizeReflowState(resizeReflowState, tableFrame); rv = ResizeReflow(aPresContext, aDesiredSize, rowResizeReflowState, aStatus); } GetMinRowSpan(tableFrame); FixMinCellHeight(tableFrame); aStatus = NS_FRAME_COMPLETE; break; case eReflowReason_Resize: case eReflowReason_StyleChange: rv = ResizeReflow(aPresContext, aDesiredSize, state, aStatus); break; case eReflowReason_Incremental: rv = IncrementalReflow(aPresContext, aDesiredSize, state, aStatus); break; } // If we computed our max element element size, then cache it so we can return // it later when asked if (aDesiredSize.maxElementSize) { mMaxElementSize = *aDesiredSize.maxElementSize; } if (nsDebugTable::gRflRow) nsTableFrame::DebugReflow("TR::Rfl ex", this, nsnull, &aDesiredSize); return rv; } /* we overload this here because rows have children that can span outside of themselves. * so the default "get the child rect, see if it contains the event point" action isn't * sufficient. We have to ask the row if it has a child that contains the point. */ PRBool nsTableRowFrame::Contains(const nsPoint& aPoint) { PRBool result = PR_FALSE; // first, check the row rect and see if the point is in their if (mRect.Contains(aPoint)) { result = PR_TRUE; } // if that fails, check the cells, they might span outside the row rect else { nsIFrame* kid; FirstChild(nsnull, &kid); while (nsnull != kid) { nsRect kidRect; kid->GetRect(kidRect); nsPoint point(aPoint); point.MoveBy(-mRect.x, -mRect.y); // offset the point to check by the row container if (kidRect.Contains(point)) { result = PR_TRUE; break; } kid->GetNextSibling(&kid); } } return result; } /** * This function is called by the row group frame's SplitRowGroup() code when * pushing a row frame that has cell frames that span into it. The cell frame * should be reflowed with the specified height */ void nsTableRowFrame::ReflowCellFrame(nsIPresContext& aPresContext, const nsHTMLReflowState& aReflowState, nsTableCellFrame* aCellFrame, nscoord aAvailableHeight, nsReflowStatus& aStatus) { // Reflow the cell frame with the specified height. Use the existing width nsSize cellSize; aCellFrame->GetSize(cellSize); nsSize availSize(cellSize.width, aAvailableHeight); nsHTMLReflowState cellReflowState(aPresContext, aReflowState, aCellFrame, availSize, eReflowReason_Resize); nsHTMLReflowMetrics desiredSize(nsnull); ReflowChild(aCellFrame, aPresContext, desiredSize, cellReflowState, aStatus); aCellFrame->SizeTo(cellSize.width, aAvailableHeight); aCellFrame->VerticallyAlignChild(); } /** * This function is called by the row group frame's SplitRowGroup() code when * it creates a continuing cell frame and wants to insert it into the row's * child list */ void nsTableRowFrame::InsertCellFrame(nsTableCellFrame* aFrame, nsTableCellFrame* aPrevSibling) { mFrames.InsertFrame(nsnull, aPrevSibling, aFrame); } NS_IMETHODIMP nsTableRowFrame::GetFrameType(nsIAtom** aType) const { NS_PRECONDITION(nsnull != aType, "null OUT parameter pointer"); *aType = nsLayoutAtoms::tableRowFrame; NS_ADDREF(*aType); return NS_OK; } /* ----- global methods ----- */ nsresult NS_NewTableRowFrame(nsIFrame** aNewFrame) { NS_PRECONDITION(aNewFrame, "null OUT ptr"); if (nsnull == aNewFrame) { return NS_ERROR_NULL_POINTER; } nsTableRowFrame* it = new nsTableRowFrame; if (nsnull == it) { return NS_ERROR_OUT_OF_MEMORY; } *aNewFrame = it; return NS_OK; } NS_IMETHODIMP nsTableRowFrame::GetFrameName(nsString& aResult) const { return MakeFrameName("TableRow", aResult); } #ifdef DEBUG NS_IMETHODIMP nsTableRowFrame::SizeOf(nsISizeOfHandler* aHandler, PRUint32* aResult) const { if (!aResult) { return NS_ERROR_NULL_POINTER; } PRUint32 sum = sizeof(*this); *aResult = sum; return NS_OK; } #endif