/** * Copyright (C) 1997 Martin Jones (mjones@kde.org) * (C) 1997 Torben Weis (weis@kde.org) * (C) 1998 Waldo Bastian (bastian@kde.org) * (C) 1999 Lars Knoll (knoll@kde.org) * (C) 1999 Antti Koivisto (koivisto@kde.org) * Copyright (C) 2003, 2004, 2005, 2006, 2007 Apple Inc. All rights reserved. * Copyright (C) 2006 Alexey Proskuryakov (ap@nypop.com) * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Library General Public * License as published by the Free Software Foundation; either * version 2 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Library General Public License for more details. * * You should have received a copy of the GNU Library General Public License * along with this library; see the file COPYING.LIB. If not, write to * the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, * Boston, MA 02110-1301, USA. */ #include "config.h" #include "RenderTable.h" #include "AutoTableLayout.h" #include "DeleteButtonController.h" #include "Document.h" #include "FixedTableLayout.h" #include "FrameView.h" #include "HTMLNames.h" #include "RenderLayer.h" #include "RenderTableCell.h" #include "RenderTableCol.h" #include "RenderTableSection.h" #include "RenderView.h" #include "TextStream.h" using namespace std; namespace WebCore { using namespace HTMLNames; RenderTable::RenderTable(Node* node) : RenderBlock(node) , m_caption(0) , m_head(0) , m_foot(0) , m_firstBody(0) , m_tableLayout(0) , m_currentBorder(0) , m_frame(Void) , m_rules(None) , m_hasColElements(false) , m_padding(0) , m_needsSectionRecalc(0) , m_hSpacing(0) , m_vSpacing(0) , m_borderLeft(0) , m_borderRight(0) { m_columnPos.fill(0, 2); m_columns.fill(ColumnStruct(), 1); } RenderTable::~RenderTable() { delete m_tableLayout; } void RenderTable::setStyle(RenderStyle* newStyle) { ETableLayout oldTableLayout = style() ? style()->tableLayout() : TAUTO; RenderBlock::setStyle(newStyle); // In the collapsed border model, there is no cell spacing. m_hSpacing = collapseBorders() ? 0 : style()->horizontalBorderSpacing(); m_vSpacing = collapseBorders() ? 0 : style()->verticalBorderSpacing(); m_columnPos[0] = m_hSpacing; if (!m_tableLayout || style()->tableLayout() != oldTableLayout) { delete m_tableLayout; // According to the CSS2 spec, you only use fixed table layout if an // explicit width is specified on the table. Auto width implies auto table layout. if (style()->tableLayout() == TFIXED && !style()->width().isAuto()) m_tableLayout = new FixedTableLayout(this); else m_tableLayout = new AutoTableLayout(this); } } static inline void resetSectionPointerIfNotBefore(RenderTableSection*& ptr, RenderObject* before) { if (!before || !ptr) return; RenderObject* o = before->previousSibling(); while (o && o != ptr) o = o->previousSibling(); if (!o) ptr = 0; } void RenderTable::addChild(RenderObject* child, RenderObject* beforeChild) { // Make sure we don't append things after :after-generated content if we have it. if (!beforeChild && isAfterContent(lastChild())) beforeChild = lastChild(); bool wrapInAnonymousSection = true; bool isTableElement = element() && element()->hasTagName(tableTag); if (child->isRenderBlock() && child->style()->display() == TABLE_CAPTION) { // First caption wins. if (beforeChild && m_caption) { RenderObject* o = beforeChild->previousSibling(); while (o && o != m_caption) o = o->previousSibling(); if (!o) m_caption = 0; } if (!m_caption) m_caption = static_cast(child); wrapInAnonymousSection = false; } else if (child->isTableCol()) { m_hasColElements = true; wrapInAnonymousSection = false; } else if (child->isTableSection()) { switch (child->style()->display()) { case TABLE_HEADER_GROUP: if (child->isTableSection()) { resetSectionPointerIfNotBefore(m_head, beforeChild); if (!m_head) { m_head = static_cast(child); } else { resetSectionPointerIfNotBefore(m_firstBody, beforeChild); if (!m_firstBody) m_firstBody = static_cast(child); } } wrapInAnonymousSection = false; break; case TABLE_FOOTER_GROUP: if (child->isTableSection()) { resetSectionPointerIfNotBefore(m_foot, beforeChild); if (!m_foot) { m_foot = static_cast(child); wrapInAnonymousSection = false; break; } } // Fall through. case TABLE_ROW_GROUP: if (child->isTableSection()) { resetSectionPointerIfNotBefore(m_firstBody, beforeChild); if (!m_firstBody) m_firstBody = static_cast(child); } wrapInAnonymousSection = false; break; default: ASSERT_NOT_REACHED(); } } else if (child->isTableCell() || child->isTableRow()) { wrapInAnonymousSection = true; } else { // Allow a form to just sit at the top level. wrapInAnonymousSection = !isTableElement || !child->element() || !(child->element()->hasTagName(formTag) && document()->isHTMLDocument()); // FIXME: Allow the delete button container element to sit at the top level. This is needed until http://bugs.webkit.org/show_bug.cgi?id=11363 is fixed. if (wrapInAnonymousSection && child->element() && child->element()->isHTMLElement() && static_cast(child->element())->id() == DeleteButtonController::containerElementIdentifier) wrapInAnonymousSection = false; } if (!wrapInAnonymousSection) { // If the next renderer is actually wrapped in an anonymous table section, we need to go up and find that. while (beforeChild && !beforeChild->isTableSection() && !beforeChild->isTableCol() && beforeChild->style()->display() != TABLE_CAPTION) beforeChild = beforeChild->parent(); RenderContainer::addChild(child, beforeChild); return; } if (!beforeChild && lastChild() && lastChild()->isTableSection() && lastChild()->isAnonymous()) { lastChild()->addChild(child); return; } RenderObject* lastBox = beforeChild; while (lastBox && lastBox->parent()->isAnonymous() && !lastBox->isTableSection() && lastBox->style()->display() != TABLE_CAPTION) lastBox = lastBox->parent(); if (lastBox && lastBox->isAnonymous() && !isAfterContent(lastBox)) { lastBox->addChild(child, beforeChild); return; } if (beforeChild && !beforeChild->isTableSection() && beforeChild->style()->display() != TABLE_CAPTION) beforeChild = 0; RenderTableSection* section = new (renderArena()) RenderTableSection(document() /* anonymous */); RenderStyle* newStyle = new (renderArena()) RenderStyle(); newStyle->inheritFrom(style()); newStyle->setDisplay(TABLE_ROW_GROUP); section->setStyle(newStyle); addChild(section, beforeChild); section->addChild(child); } void RenderTable::calcWidth() { if (isPositioned()) calcAbsoluteHorizontal(); RenderBlock* cb = containingBlock(); int availableWidth = cb->availableWidth(); LengthType widthType = style()->width().type(); if (widthType > Relative && style()->width().isPositive()) { // Percent or fixed table m_width = style()->width().calcMinValue(availableWidth); m_width = max(minPrefWidth(), m_width); } else { // An auto width table should shrink to fit within the line width if necessary in order to // avoid overlapping floats. availableWidth = cb->lineWidth(m_y); // Subtract out any fixed margins from our available width for auto width tables. int marginTotal = 0; if (!style()->marginLeft().isAuto()) marginTotal += style()->marginLeft().calcValue(availableWidth); if (!style()->marginRight().isAuto()) marginTotal += style()->marginRight().calcValue(availableWidth); // Subtract out our margins to get the available content width. int availContentWidth = max(0, availableWidth - marginTotal); // Ensure we aren't bigger than our max width or smaller than our min width. m_width = min(availContentWidth, maxPrefWidth()); } m_width = max(m_width, minPrefWidth()); // Finally, with our true width determined, compute our margins for real. m_marginRight = 0; m_marginLeft = 0; calcHorizontalMargins(style()->marginLeft(), style()->marginRight(), availableWidth); } void RenderTable::layout() { ASSERT(needsLayout()); if (layoutOnlyPositionedObjects()) return; recalcSectionsIfNeeded(); IntRect oldBounds; IntRect oldOutlineBox; bool checkForRepaint = checkForRepaintDuringLayout(); if (checkForRepaint) { oldBounds = absoluteClippedOverflowRect(); oldOutlineBox = absoluteOutlineBox(); } view()->pushLayoutState(this, IntSize(m_x, m_y)); m_height = 0; m_overflowHeight = 0; m_overflowTop = 0; initMaxMarginValues(); int oldWidth = m_width; calcWidth(); if (m_caption && m_width != oldWidth) m_caption->setNeedsLayout(true, false); // FIXME: The optimisation below doesn't work since the internal table // layout could have changed. we need to add a flag to the table // layout that tells us if something has changed in the min max // calculations to do it correctly. // if ( oldWidth != m_width || columns.size() + 1 != columnPos.size() ) m_tableLayout->layout(); setCellWidths(); // layout child objects int calculatedHeight = 0; int oldTableTop = m_caption ? m_caption->height() + m_caption->marginTop() + m_caption->marginBottom() : 0; RenderObject* child = firstChild(); while (child) { // FIXME: What about a form that has a display value that makes it a table section? if (child->needsLayout() && !(child->element() && child->element()->hasTagName(formTag))) child->layout(); if (child->isTableSection()) { static_cast(child)->calcRowHeight(); calculatedHeight += static_cast(child)->layoutRows(0); } child = child->nextSibling(); } m_overflowWidth = m_width + (collapseBorders() ? outerBorderRight() - borderRight() : 0); m_overflowLeft = collapseBorders() ? borderLeft() - outerBorderLeft() : 0; // If any table section moved vertically, we will just repaint everything from that // section down (it is quite unlikely that any of the following sections // did not shift). bool sectionMoved = false; int movedSectionTop = 0; // FIXME: Collapse caption margin. if (m_caption && m_caption->style()->captionSide() != CAPBOTTOM) { IntRect captionRect(m_caption->xPos(), m_caption->yPos(), m_caption->width(), m_caption->height()); m_caption->setPos(m_caption->marginLeft(), m_height); if (!selfNeedsLayout() && m_caption->checkForRepaintDuringLayout()) m_caption->repaintDuringLayoutIfMoved(captionRect); m_height += m_caption->height() + m_caption->marginTop() + m_caption->marginBottom(); m_overflowLeft = min(m_overflowLeft, m_caption->xPos() + m_caption->overflowLeft(false)); m_overflowWidth = max(m_overflowWidth, m_caption->xPos() + m_caption->overflowWidth(false)); m_overflowTop = min(m_overflowTop, m_caption->yPos() + m_caption->overflowTop(false)); m_overflowHeight = max(m_overflowHeight, m_caption->yPos() + m_caption->overflowHeight(false)); if (m_height != oldTableTop) { sectionMoved = true; movedSectionTop = min(m_height, oldTableTop); } } int bpTop = borderTop() + (collapseBorders() ? 0 : paddingTop()); int bpBottom = borderBottom() + (collapseBorders() ? 0 : paddingBottom()); m_height += bpTop; int oldHeight = m_height; if (!isPositioned()) calcHeight(); m_height = oldHeight; Length h = style()->height(); int th = 0; if (h.isFixed()) // Tables size as though CSS height includes border/padding. th = h.value() - (bpTop + bpBottom); else if (h.isPercent()) th = calcPercentageHeight(h); th = max(0, th); // layout rows if (th > calculatedHeight) { // we have to redistribute that height to get the constraint correctly // just force the first body to the height needed // FIXME: This should take height constraints on all table sections into account and distribute // accordingly. For now this should be good enough. if (m_firstBody) { m_firstBody->calcRowHeight(); m_firstBody->layoutRows(th - calculatedHeight); } else if (!style()->htmlHacks()) // Completely empty tables (with no sections or anything) should at least honor specified height // in strict mode. m_height += th; } int bl = borderLeft(); if (!collapseBorders()) bl += paddingLeft(); // position the table sections RenderTableSection* section = m_head ? m_head : (m_firstBody ? m_firstBody : m_foot); while (section) { if (!sectionMoved && section->yPos() != m_height) { sectionMoved = true; movedSectionTop = min(m_height, section->yPos()) + section->overflowTop(false); } section->setPos(bl, m_height); m_height += section->height(); m_overflowLeft = min(m_overflowLeft, section->xPos() + section->overflowLeft(false)); m_overflowWidth = max(m_overflowWidth, section->xPos() + section->overflowWidth(false)); m_overflowTop = min(m_overflowTop, section->yPos() + section->overflowTop(false)); m_overflowHeight = max(m_overflowHeight, section->yPos() + section->overflowHeight(false)); section = sectionBelow(section); } m_height += bpBottom; if (m_caption && m_caption->style()->captionSide() == CAPBOTTOM) { IntRect captionRect(m_caption->xPos(), m_caption->yPos(), m_caption->width(), m_caption->height()); m_caption->setPos(m_caption->marginLeft(), m_height); if (!selfNeedsLayout() && m_caption->checkForRepaintDuringLayout()) m_caption->repaintDuringLayoutIfMoved(captionRect); m_height += m_caption->height() + m_caption->marginTop() + m_caption->marginBottom(); m_overflowLeft = min(m_overflowLeft, m_caption->xPos() + m_caption->overflowLeft(false)); m_overflowWidth = max(m_overflowWidth, m_caption->xPos() + m_caption->overflowWidth(false)); } if (isPositioned()) calcHeight(); m_overflowHeight = max(m_overflowHeight, m_height); // table can be containing block of positioned elements. // FIXME: Only pass true if width or height changed. layoutPositionedObjects(true); if (!hasOverflowClip()) { if (ShadowData* boxShadow = style()->boxShadow()) { m_overflowLeft = min(m_overflowLeft, boxShadow->x - boxShadow->blur); m_overflowWidth = max(m_overflowWidth, m_width + boxShadow->x + boxShadow->blur); m_overflowTop = min(m_overflowTop, boxShadow->y - boxShadow->blur); m_overflowHeight = max(m_overflowHeight, m_height + boxShadow->y + boxShadow->blur); } } view()->popLayoutState(); bool didFullRepaint = true; // Repaint with our new bounds if they are different from our old bounds. if (checkForRepaint) didFullRepaint = repaintAfterLayoutIfNeeded(oldBounds, oldOutlineBox); if (!didFullRepaint && sectionMoved) { IntRect repaintRect(m_overflowLeft, movedSectionTop, m_overflowWidth - m_overflowLeft, m_overflowHeight - movedSectionTop); if (FrameView* frameView = view()->frameView()) frameView->addRepaintInfo(this, repaintRect); } setNeedsLayout(false); } void RenderTable::setCellWidths() { for (RenderObject* child = firstChild(); child; child = child->nextSibling()) { if (child->isTableSection()) static_cast(child)->setCellWidths(); } } void RenderTable::paint(PaintInfo& paintInfo, int tx, int ty) { tx += xPos(); ty += yPos(); PaintPhase paintPhase = paintInfo.phase; int os = 2 * maximalOutlineSize(paintPhase); if (ty + overflowTop(false) >= paintInfo.rect.bottom() + os || ty + overflowHeight(false) <= paintInfo.rect.y() - os) return; if (tx + overflowLeft(false) >= paintInfo.rect.right() + os || tx + overflowWidth(false) <= paintInfo.rect.x() - os) return; if ((paintPhase == PaintPhaseBlockBackground || paintPhase == PaintPhaseChildBlockBackground) && hasBoxDecorations() && style()->visibility() == VISIBLE) paintBoxDecorations(paintInfo, tx, ty); // We're done. We don't bother painting any children. if (paintPhase == PaintPhaseBlockBackground) return; // We don't paint our own background, but we do let the kids paint their backgrounds. if (paintPhase == PaintPhaseChildBlockBackgrounds) paintPhase = PaintPhaseChildBlockBackground; PaintInfo info(paintInfo); info.phase = paintPhase; info.paintingRoot = paintingRootForChildren(paintInfo); for (RenderObject* child = firstChild(); child; child = child->nextSibling()) { if (!child->hasLayer() && (child->isTableSection() || child == m_caption)) child->paint(info, tx, ty); } if (collapseBorders() && paintPhase == PaintPhaseChildBlockBackground && style()->visibility() == VISIBLE) { // Collect all the unique border styles that we want to paint in a sorted list. Once we // have all the styles sorted, we then do individual passes, painting each style of border // from lowest precedence to highest precedence. info.phase = PaintPhaseCollapsedTableBorders; RenderTableCell::CollapsedBorderStyles borderStyles; RenderObject* stop = nextInPreOrderAfterChildren(); for (RenderObject* o = firstChild(); o && o != stop; o = o->nextInPreOrder()) if (o->isTableCell()) static_cast(o)->collectBorderStyles(borderStyles); RenderTableCell::sortBorderStyles(borderStyles); size_t count = borderStyles.size(); for (size_t i = 0; i < count; ++i) { m_currentBorder = &borderStyles[i]; for (RenderObject* child = firstChild(); child; child = child->nextSibling()) if (child->isTableSection()) child->paint(info, tx, ty); } m_currentBorder = 0; } } void RenderTable::paintBoxDecorations(PaintInfo& paintInfo, int tx, int ty) { int w = width(); int h = height(); // Account for the caption. if (m_caption) { int captionHeight = (m_caption->height() + m_caption->marginBottom() + m_caption->marginTop()); h -= captionHeight; if (m_caption->style()->captionSide() != CAPBOTTOM) ty += captionHeight; } int my = max(ty, paintInfo.rect.y()); int mh; if (ty < paintInfo.rect.y()) mh = max(0, h - (paintInfo.rect.y() - ty)); else mh = min(paintInfo.rect.height(), h); paintBoxShadow(paintInfo.context, tx, ty, w, h, style()); paintBackground(paintInfo.context, style()->backgroundColor(), style()->backgroundLayers(), my, mh, tx, ty, w, h); if (style()->hasBorder() && !collapseBorders()) paintBorder(paintInfo.context, tx, ty, w, h, style()); } void RenderTable::calcPrefWidths() { ASSERT(prefWidthsDirty()); recalcSectionsIfNeeded(); recalcHorizontalBorders(); m_tableLayout->calcPrefWidths(m_minPrefWidth, m_maxPrefWidth); if (m_caption) m_minPrefWidth = max(m_minPrefWidth, m_caption->minPrefWidth()); setPrefWidthsDirty(false); } void RenderTable::splitColumn(int pos, int firstSpan) { // we need to add a new columnStruct int oldSize = m_columns.size(); m_columns.resize(oldSize + 1); int oldSpan = m_columns[pos].span; ASSERT(oldSpan > firstSpan); m_columns[pos].span = firstSpan; memmove(m_columns.data() + pos + 1, m_columns.data() + pos, (oldSize - pos) * sizeof(ColumnStruct)); m_columns[pos + 1].span = oldSpan - firstSpan; // change width of all rows. for (RenderObject* child = firstChild(); child; child = child->nextSibling()) { if (child->isTableSection()) static_cast(child)->splitColumn(pos, oldSize + 1); } m_columnPos.resize(numEffCols() + 1); setNeedsLayoutAndPrefWidthsRecalc(); } void RenderTable::appendColumn(int span) { // easy case. int pos = m_columns.size(); int newSize = pos + 1; m_columns.resize(newSize); m_columns[pos].span = span; // change width of all rows. for (RenderObject* child = firstChild(); child; child = child->nextSibling()) { if (child->isTableSection()) static_cast(child)->appendColumn(pos); } m_columnPos.resize(numEffCols() + 1); setNeedsLayoutAndPrefWidthsRecalc(); } RenderTableCol* RenderTable::colElement(int col, bool* startEdge, bool* endEdge) const { if (!m_hasColElements) return 0; RenderObject* child = firstChild(); int cCol = 0; while (child) { if (child->isTableCol()) { RenderTableCol* colElem = static_cast(child); int span = colElem->span(); if (!colElem->firstChild()) { int startCol = cCol; int endCol = cCol + span - 1; cCol += span; if (cCol > col) { if (startEdge) *startEdge = startCol == col; if (endEdge) *endEdge = endCol == col; return colElem; } } RenderObject* next = child->firstChild(); if (!next) next = child->nextSibling(); if (!next && child->parent()->isTableCol()) next = child->parent()->nextSibling(); child = next; } else if (child == m_caption) child = child->nextSibling(); else break; } return 0; } void RenderTable::recalcSections() const { m_caption = 0; m_head = 0; m_foot = 0; m_firstBody = 0; m_hasColElements = false; // We need to get valid pointers to caption, head, foot and first body again for (RenderObject* child = firstChild(); child; child = child->nextSibling()) { switch (child->style()->display()) { case TABLE_CAPTION: if (!m_caption && child->isRenderBlock()) { m_caption = static_cast(child); m_caption->setNeedsLayout(true); } break; case TABLE_COLUMN: case TABLE_COLUMN_GROUP: m_hasColElements = true; break; case TABLE_HEADER_GROUP: if (child->isTableSection()) { RenderTableSection* section = static_cast(child); if (!m_head) m_head = section; else if (!m_firstBody) m_firstBody = section; section->recalcCellsIfNeeded(); } break; case TABLE_FOOTER_GROUP: if (child->isTableSection()) { RenderTableSection* section = static_cast(child); if (!m_foot) m_foot = section; else if (!m_firstBody) m_firstBody = section; section->recalcCellsIfNeeded(); } break; case TABLE_ROW_GROUP: if (child->isTableSection()) { RenderTableSection* section = static_cast(child); if (!m_firstBody) m_firstBody = section; section->recalcCellsIfNeeded(); } break; default: break; } } // repair column count (addChild can grow it too much, because it always adds elements to the last row of a section) int maxCols = 0; for (RenderObject* child = firstChild(); child; child = child->nextSibling()) { if (child->isTableSection()) { RenderTableSection* section = static_cast(child); int sectionCols = section->numColumns(); if (sectionCols > maxCols) maxCols = sectionCols; } } m_columns.resize(maxCols); m_columnPos.resize(maxCols + 1); ASSERT(selfNeedsLayout()); m_needsSectionRecalc = false; } RenderObject* RenderTable::removeChildNode(RenderObject* child, bool fullRemove) { setNeedsSectionRecalc(); return RenderContainer::removeChildNode(child, fullRemove); } int RenderTable::calcBorderLeft() const { if (collapseBorders()) { // Determined by the first cell of the first row. See the CSS 2.1 spec, section 17.6.2. if (!numEffCols()) return 0; unsigned borderWidth = 0; const BorderValue& tb = style()->borderLeft(); if (tb.style() == BHIDDEN) return 0; if (tb.style() > BHIDDEN) borderWidth = tb.width; int leftmostColumn = style()->direction() == RTL ? numEffCols() - 1 : 0; RenderTableCol* colGroup = colElement(leftmostColumn); if (colGroup) { const BorderValue& gb = style()->borderLeft(); if (gb.style() == BHIDDEN) return 0; if (gb.style() > BHIDDEN) borderWidth = max(borderWidth, static_cast(gb.width)); } RenderTableSection* firstNonEmptySection = m_head ? m_head : (m_firstBody ? m_firstBody : m_foot); if (firstNonEmptySection && !firstNonEmptySection->numRows()) firstNonEmptySection = sectionBelow(firstNonEmptySection, true); if (firstNonEmptySection) { const BorderValue& sb = firstNonEmptySection->style()->borderLeft(); if (sb.style() == BHIDDEN) return 0; if (sb.style() > BHIDDEN) borderWidth = max(borderWidth, static_cast(sb.width)); const RenderTableSection::CellStruct& cs = firstNonEmptySection->cellAt(0, leftmostColumn); if (cs.cell) { const BorderValue& cb = cs.cell->style()->borderLeft(); if (cb.style() == BHIDDEN) return 0; const BorderValue& rb = cs.cell->parent()->style()->borderLeft(); if (rb.style() == BHIDDEN) return 0; if (cb.style() > BHIDDEN) borderWidth = max(borderWidth, static_cast(cb.width)); if (rb.style() > BHIDDEN) borderWidth = max(borderWidth, static_cast(rb.width)); } } return borderWidth / 2; } return RenderBlock::borderLeft(); } int RenderTable::calcBorderRight() const { if (collapseBorders()) { // Determined by the last cell of the first row. See the CSS 2.1 spec, section 17.6.2. if (!numEffCols()) return 0; unsigned borderWidth = 0; const BorderValue& tb = style()->borderRight(); if (tb.style() == BHIDDEN) return 0; if (tb.style() > BHIDDEN) borderWidth = tb.width; int rightmostColumn = style()->direction() == RTL ? 0 : numEffCols() - 1; RenderTableCol* colGroup = colElement(rightmostColumn); if (colGroup) { const BorderValue& gb = style()->borderRight(); if (gb.style() == BHIDDEN) return 0; if (gb.style() > BHIDDEN) borderWidth = max(borderWidth, static_cast(gb.width)); } RenderTableSection* firstNonEmptySection = m_head ? m_head : (m_firstBody ? m_firstBody : m_foot); if (firstNonEmptySection && !firstNonEmptySection->numRows()) firstNonEmptySection = sectionBelow(firstNonEmptySection, true); if (firstNonEmptySection) { const BorderValue& sb = firstNonEmptySection->style()->borderRight(); if (sb.style() == BHIDDEN) return 0; if (sb.style() > BHIDDEN) borderWidth = max(borderWidth, static_cast(sb.width)); const RenderTableSection::CellStruct& cs = firstNonEmptySection->cellAt(0, rightmostColumn); if (cs.cell) { const BorderValue& cb = cs.cell->style()->borderRight(); if (cb.style() == BHIDDEN) return 0; const BorderValue& rb = cs.cell->parent()->style()->borderRight(); if (rb.style() == BHIDDEN) return 0; if (cb.style() > BHIDDEN) borderWidth = max(borderWidth, static_cast(cb.width)); if (rb.style() > BHIDDEN) borderWidth = max(borderWidth, static_cast(rb.width)); } } return (borderWidth + 1) / 2; } return RenderBlock::borderRight(); } void RenderTable::recalcHorizontalBorders() { m_borderLeft = calcBorderLeft(); m_borderRight = calcBorderRight(); } int RenderTable::borderTop() const { if (collapseBorders()) return outerBorderTop(); return RenderBlock::borderTop(); } int RenderTable::borderBottom() const { if (collapseBorders()) return outerBorderBottom(); return RenderBlock::borderBottom(); } int RenderTable::outerBorderTop() const { if (!collapseBorders()) return 0; int borderWidth = 0; RenderTableSection* topSection; if (m_head) topSection = m_head; else if (m_firstBody) topSection = m_firstBody; else if (m_foot) topSection = m_foot; else topSection = 0; if (topSection) { borderWidth = topSection->outerBorderTop(); if (borderWidth == -1) return 0; // Overridden by hidden } const BorderValue& tb = style()->borderTop(); if (tb.style() == BHIDDEN) return 0; if (tb.style() > BHIDDEN) borderWidth = max(borderWidth, static_cast(tb.width / 2)); return borderWidth; } int RenderTable::outerBorderBottom() const { if (!collapseBorders()) return 0; int borderWidth = 0; RenderTableSection* bottomSection; if (m_foot) bottomSection = m_foot; else { RenderObject* child; for (child = lastChild(); child && !child->isTableSection(); child = child->previousSibling()) ; bottomSection = child ? static_cast(child) : 0; } if (bottomSection) { borderWidth = bottomSection->outerBorderBottom(); if (borderWidth == -1) return 0; // Overridden by hidden } const BorderValue& tb = style()->borderBottom(); if (tb.style() == BHIDDEN) return 0; if (tb.style() > BHIDDEN) borderWidth = max(borderWidth, static_cast((tb.width + 1) / 2)); return borderWidth; } int RenderTable::outerBorderLeft() const { if (!collapseBorders()) return 0; int borderWidth = 0; const BorderValue& tb = style()->borderLeft(); if (tb.style() == BHIDDEN) return 0; if (tb.style() > BHIDDEN) borderWidth = tb.width / 2; bool allHidden = true; for (RenderObject* child = firstChild(); child; child = child->nextSibling()) { if (!child->isTableSection()) continue; int sw = static_cast(child)->outerBorderLeft(); if (sw == -1) continue; else allHidden = false; borderWidth = max(borderWidth, sw); } if (allHidden) return 0; return borderWidth; } int RenderTable::outerBorderRight() const { if (!collapseBorders()) return 0; int borderWidth = 0; const BorderValue& tb = style()->borderRight(); if (tb.style() == BHIDDEN) return 0; if (tb.style() > BHIDDEN) borderWidth = (tb.width + 1) / 2; bool allHidden = true; for (RenderObject* child = firstChild(); child; child = child->nextSibling()) { if (!child->isTableSection()) continue; int sw = static_cast(child)->outerBorderRight(); if (sw == -1) continue; else allHidden = false; borderWidth = max(borderWidth, sw); } if (allHidden) return 0; return borderWidth; } RenderTableSection* RenderTable::sectionAbove(const RenderTableSection* section, bool skipEmptySections) const { recalcSectionsIfNeeded(); if (section == m_head) return 0; RenderObject* prevSection = section == m_foot ? lastChild() : section->previousSibling(); while (prevSection) { if (prevSection->isTableSection() && prevSection != m_head && prevSection != m_foot && (!skipEmptySections || static_cast(prevSection)->numRows())) break; prevSection = prevSection->previousSibling(); } if (!prevSection && m_head && (!skipEmptySections || m_head->numRows())) prevSection = m_head; return static_cast(prevSection); } RenderTableSection* RenderTable::sectionBelow(const RenderTableSection* section, bool skipEmptySections) const { recalcSectionsIfNeeded(); if (section == m_foot) return 0; RenderObject* nextSection = section == m_head ? firstChild() : section->nextSibling(); while (nextSection) { if (nextSection->isTableSection() && nextSection != m_head && nextSection != m_foot && (!skipEmptySections || static_cast(nextSection)->numRows())) break; nextSection = nextSection->nextSibling(); } if (!nextSection && m_foot && (!skipEmptySections || m_foot->numRows())) nextSection = m_foot; return static_cast(nextSection); } RenderTableCell* RenderTable::cellAbove(const RenderTableCell* cell) const { recalcSectionsIfNeeded(); // Find the section and row to look in int r = cell->row(); RenderTableSection* section = 0; int rAbove = 0; if (r > 0) { // cell is not in the first row, so use the above row in its own section section = cell->section(); rAbove = r - 1; } else { section = sectionAbove(cell->section(), true); if (section) rAbove = section->numRows() - 1; } // Look up the cell in the section's grid, which requires effective col index if (section) { int effCol = colToEffCol(cell->col()); RenderTableSection::CellStruct aboveCell; // If we hit a span back up to a real cell. do { aboveCell = section->cellAt(rAbove, effCol); effCol--; } while (!aboveCell.cell && aboveCell.inColSpan && effCol >= 0); return aboveCell.cell; } else return 0; } RenderTableCell* RenderTable::cellBelow(const RenderTableCell* cell) const { recalcSectionsIfNeeded(); // Find the section and row to look in int r = cell->row() + cell->rowSpan() - 1; RenderTableSection* section = 0; int rBelow = 0; if (r < cell->section()->numRows() - 1) { // The cell is not in the last row, so use the next row in the section. section = cell->section(); rBelow = r + 1; } else { section = sectionBelow(cell->section(), true); if (section) rBelow = 0; } // Look up the cell in the section's grid, which requires effective col index if (section) { int effCol = colToEffCol(cell->col()); RenderTableSection::CellStruct belowCell; // If we hit a colspan back up to a real cell. do { belowCell = section->cellAt(rBelow, effCol); effCol--; } while (!belowCell.cell && belowCell.inColSpan && effCol >= 0); return belowCell.cell; } else return 0; } RenderTableCell* RenderTable::cellBefore(const RenderTableCell* cell) const { recalcSectionsIfNeeded(); RenderTableSection* section = cell->section(); int effCol = colToEffCol(cell->col()); if (!effCol) return 0; // If we hit a colspan back up to a real cell. RenderTableSection::CellStruct prevCell; do { prevCell = section->cellAt(cell->row(), effCol - 1); effCol--; } while (!prevCell.cell && prevCell.inColSpan && effCol >= 0); return prevCell.cell; } RenderTableCell* RenderTable::cellAfter(const RenderTableCell* cell) const { recalcSectionsIfNeeded(); int effCol = colToEffCol(cell->col() + cell->colSpan()); if (effCol >= numEffCols()) return 0; return cell->section()->cellAt(cell->row(), effCol).cell; } RenderBlock* RenderTable::firstLineBlock() const { return 0; } void RenderTable::updateFirstLetter() { } IntRect RenderTable::getOverflowClipRect(int tx, int ty) { IntRect rect = RenderBlock::getOverflowClipRect(tx, ty); // If we have a caption, expand the clip to include the caption. // FIXME: Technically this is wrong, but it's virtually impossible to fix this // for real until captions have been re-written. // FIXME: This code assumes (like all our other caption code) that only top/bottom are // supported. When we actually support left/right and stop mapping them to top/bottom, // we might have to hack this code first (depending on what order we do these bug fixes in). if (m_caption) { rect.setHeight(height()); rect.setY(ty); } return rect; } #ifndef NDEBUG void RenderTable::dump(TextStream* stream, DeprecatedString ind) const { if (m_caption) *stream << " tCaption"; if (m_head) *stream << " head"; if (m_foot) *stream << " foot"; *stream << endl << ind << "cspans:"; for (unsigned i = 0; i < m_columns.size(); i++) *stream << " " << m_columns[i].span; *stream << endl << ind; RenderBlock::dump(stream, ind); } #endif }