/*
 * 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, 2009, 2010 Apple Inc.
 *               All rights reserved.
 *
 * 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.
 */

#ifndef LayoutTable_h
#define LayoutTable_h

#include "core/CSSPropertyNames.h"
#include "core/CoreExport.h"
#include "core/layout/LayoutBlock.h"
#include "core/style/CollapsedBorderValue.h"
#include "wtf/Vector.h"
#include <memory>

namespace blink {

class LayoutTableCol;
class LayoutTableCaption;
class LayoutTableCell;
class LayoutTableSection;
class TableLayoutAlgorithm;

enum SkipEmptySectionsValue { DoNotSkipEmptySections, SkipEmptySections };

// LayoutTable is the LayoutObject associated with
// display: table or inline-table.
//
// LayoutTable is the master coordinator for determining the overall table
// structure. The reason is that LayoutTableSection children have a local
// view over what their structure is but don't account for other
// LayoutTableSection. Thus LayoutTable helps keep consistency across
// LayoutTableSection. See e.g. |m_effectiveColumns| below.
//
// LayoutTable expects only 3 types of children:
// - zero or more LayoutTableCol
// - zero or more LayoutTableCaption
// - zero or more LayoutTableSection
// This is aligned with what HTML5 expects:
// https://html.spec.whatwg.org/multipage/tables.html#the-table-element
// with one difference: we allow more than one caption as we follow what
// CSS expects (https://bugs.webkit.org/show_bug.cgi?id=69773).
// Those expectations are enforced by LayoutTable::addChild, that wraps unknown
// children into an anonymous LayoutTableSection. This is what the "generate
// missing child wrapper" step in CSS mandates in
// http://www.w3.org/TR/CSS21/tables.html#anonymous-boxes.
//
// LayoutTable assumes a pretty strict structure that is mandated by CSS:
// (note that this structure in HTML is enforced by the HTML5 Parser).
//
//                 LayoutTable
//                 |        |
//  LayoutTableSection    LayoutTableCaption
//                 |
//      LayoutTableRow
//                 |
//     LayoutTableCell
//
// This means that we have to generate some anonymous table wrappers in order to
// satisfy the structure. See again
// http://www.w3.org/TR/CSS21/tables.html#anonymous-boxes.
// The anonymous table wrappers are inserted in LayoutTable::addChild,
// LayoutTableSection::addChild, LayoutTableRow::addChild and
// LayoutObject::addChild.
//
// Note that this yields to interesting issues in the insertion code. The DOM
// code is unaware of the anonymous LayoutObjects and thus can insert
// LayoutObjects into a different part of the layout tree. An example is:
//
// <!DOCTYPE html>
// <style>
// tablerow { display: table-row; }
// tablecell { display: table-cell; border: 5px solid purple; }
// </style>
// <tablerow id="firstRow">
//     <tablecell>Short first row.</tablecell>
// </tablerow>
// <tablecell id="cell">Long second row, shows the table structure.</tablecell>
//
// The page generates a single anonymous table (LayoutTable) and table row group
// (LayoutTableSection) to wrap the <tablerow> (#firstRow) and an anonymous
// table row (LayoutTableRow) for the second <tablecell>.
// It is possible for JavaScript to insert a new element between these 2
// <tablecell> (using Node.insertBefore), requiring us to split the anonymous
// table (or the anonymous table row group) in 2. Also note that even
// though the second <tablecell> and <tablerow> are siblings in the DOM tree,
// they are not in the layout tree.
//
//
// Note about absolute column index vs effective column index:
//
// To save memory at the expense of massive code complexity, the code tries
// to coalesce columns. This means that we try to the wider column grouping
// seen over the LayoutTableSections.
//
// Note that this is also a defensive pattern as <td colspan="6666666666">
// only allocates a single entry in this Vector. This argument is weak
// though as we cap colspans in HTMLTableCellElement.
//
// The following example would have 2 entries [ 3, 2 ] in effectiveColumns():
// <table>
//   <tr>
//     <td colspan="3"></td>
//     <td colspan="2"></td>
//   </tr>
// </table>
//
// Columns can be split if we add a row with a different colspan structure.
// See splitEffectiveColumn() and appendEffectiveColumn() for operations
// over effectiveColumns() and effectiveColumnPositions().
//
// See absoluteColumnToEffectiveColumn() for converting an absolute column
// index into an index into effectiveColumns() and effectiveColumnPositions().

class CORE_EXPORT LayoutTable final : public LayoutBlock {
 public:
  explicit LayoutTable(Element*);
  ~LayoutTable() override;

  // Per CSS 3 writing-mode: "The first and second values of the
  // 'border-spacing' property represent spacing between columns and rows
  // respectively, not necessarily the horizontal and vertical spacing
  // respectively".
  int hBorderSpacing() const { return m_hSpacing; }
  int vBorderSpacing() const { return m_vSpacing; }

  bool collapseBorders() const {
    return style()->borderCollapse() == EBorderCollapse::kCollapse;
  }

  int borderStart() const override { return m_borderStart; }
  int borderEnd() const override { return m_borderEnd; }
  int borderBefore() const override;
  int borderAfter() const override;

  int borderLeft() const override {
    if (style()->isHorizontalWritingMode())
      return style()->isLeftToRightDirection() ? borderStart() : borderEnd();
    return style()->isFlippedBlocksWritingMode() ? borderAfter()
                                                 : borderBefore();
  }

  int borderRight() const override {
    if (style()->isHorizontalWritingMode())
      return style()->isLeftToRightDirection() ? borderEnd() : borderStart();
    return style()->isFlippedBlocksWritingMode() ? borderBefore()
                                                 : borderAfter();
  }

  int borderTop() const override {
    if (style()->isHorizontalWritingMode())
      return style()->isFlippedBlocksWritingMode() ? borderAfter()
                                                   : borderBefore();
    return style()->isLeftToRightDirection() ? borderStart() : borderEnd();
  }

  int borderBottom() const override {
    if (style()->isHorizontalWritingMode())
      return style()->isFlippedBlocksWritingMode() ? borderBefore()
                                                   : borderAfter();
    return style()->isLeftToRightDirection() ? borderEnd() : borderStart();
  }

  int outerBorderBefore() const;
  int outerBorderAfter() const;
  int outerBorderStart() const;
  int outerBorderEnd() const;

  int outerBorderLeft() const {
    if (style()->isHorizontalWritingMode())
      return style()->isLeftToRightDirection() ? outerBorderStart()
                                               : outerBorderEnd();
    return style()->isFlippedBlocksWritingMode() ? outerBorderAfter()
                                                 : outerBorderBefore();
  }

  int outerBorderRight() const {
    if (style()->isHorizontalWritingMode())
      return style()->isLeftToRightDirection() ? outerBorderEnd()
                                               : outerBorderStart();
    return style()->isFlippedBlocksWritingMode() ? outerBorderBefore()
                                                 : outerBorderAfter();
  }

  int outerBorderTop() const {
    if (style()->isHorizontalWritingMode())
      return style()->isFlippedBlocksWritingMode() ? outerBorderAfter()
                                                   : outerBorderBefore();
    return style()->isLeftToRightDirection() ? outerBorderStart()
                                             : outerBorderEnd();
  }

  int outerBorderBottom() const {
    if (style()->isHorizontalWritingMode())
      return style()->isFlippedBlocksWritingMode() ? outerBorderBefore()
                                                   : outerBorderAfter();
    return style()->isLeftToRightDirection() ? outerBorderEnd()
                                             : outerBorderStart();
  }

  int calcBorderStart() const;
  int calcBorderEnd() const;
  void recalcBordersInRowDirection();

  void addChild(LayoutObject* child,
                LayoutObject* beforeChild = nullptr) override;

  struct ColumnStruct {
    DISALLOW_NEW_EXCEPT_PLACEMENT_NEW();
    explicit ColumnStruct(unsigned initialSpan = 1) : span(initialSpan) {}

    unsigned span;
  };

  void forceSectionsRecalc() {
    setNeedsSectionRecalc();
    recalcSections();
  }

  const Vector<ColumnStruct>& effectiveColumns() const {
    return m_effectiveColumns;
  }
  const Vector<int>& effectiveColumnPositions() const {
    return m_effectiveColumnPositions;
  }
  void setEffectiveColumnPosition(unsigned index, int position) {
    // Note that if our horizontal border-spacing changed, our position will
    // change but not our column's width. In practice, horizontal border-spacing
    // won't change often.
    m_columnLogicalWidthChanged |=
        m_effectiveColumnPositions[index] != position;
    m_effectiveColumnPositions[index] = position;
  }

  LayoutTableSection* header() const { return m_head; }
  LayoutTableSection* footer() const { return m_foot; }
  LayoutTableSection* firstBody() const { return m_firstBody; }

  void setRowOffsetFromRepeatingHeader(LayoutUnit offset) {
    m_rowOffsetFromRepeatingHeader = offset;
  }
  LayoutUnit rowOffsetFromRepeatingHeader() const {
    return m_rowOffsetFromRepeatingHeader;
  }

  // This function returns 0 if the table has no section.
  LayoutTableSection* topSection() const;
  LayoutTableSection* bottomSection() const;

  // This function returns 0 if the table has no non-empty sections.
  LayoutTableSection* topNonEmptySection() const;

  unsigned lastEffectiveColumnIndex() const {
    return numEffectiveColumns() - 1;
  }

  void splitEffectiveColumn(unsigned index, unsigned firstSpan);
  void appendEffectiveColumn(unsigned span);
  unsigned numEffectiveColumns() const { return m_effectiveColumns.size(); }
  unsigned spanOfEffectiveColumn(unsigned effectiveColumnIndex) const {
    return m_effectiveColumns[effectiveColumnIndex].span;
  }

  unsigned absoluteColumnToEffectiveColumn(unsigned absoluteColumnIndex) const {
    if (absoluteColumnIndex < m_noCellColspanAtLeast)
      return absoluteColumnIndex;

    unsigned effectiveColumn = m_noCellColspanAtLeast;
    unsigned numColumns = numEffectiveColumns();
    for (unsigned c = m_noCellColspanAtLeast;
         effectiveColumn < numColumns &&
         c + m_effectiveColumns[effectiveColumn].span - 1 < absoluteColumnIndex;
         ++effectiveColumn)
      c += m_effectiveColumns[effectiveColumn].span;
    return effectiveColumn;
  }

  unsigned effectiveColumnToAbsoluteColumn(
      unsigned effectiveColumnIndex) const {
    if (effectiveColumnIndex < m_noCellColspanAtLeast)
      return effectiveColumnIndex;

    unsigned c = m_noCellColspanAtLeast;
    for (unsigned i = m_noCellColspanAtLeast; i < effectiveColumnIndex; i++)
      c += m_effectiveColumns[i].span;
    return c;
  }

  LayoutUnit borderSpacingInRowDirection() const {
    if (unsigned effectiveColumnCount = numEffectiveColumns())
      return static_cast<LayoutUnit>(effectiveColumnCount + 1) *
             hBorderSpacing();

    return LayoutUnit();
  }

  // The collapsing border model dissallows paddings on table, which is why we
  // override those functions.
  // See http://www.w3.org/TR/CSS2/tables.html#collapsing-borders.
  LayoutUnit paddingTop() const override;
  LayoutUnit paddingBottom() const override;
  LayoutUnit paddingLeft() const override;
  LayoutUnit paddingRight() const override;

  // Override paddingStart/End to return pixel values to match behavor of
  // LayoutTableCell.
  LayoutUnit paddingEnd() const override {
    return LayoutUnit(LayoutBlock::paddingEnd().toInt());
  }
  LayoutUnit paddingStart() const override {
    return LayoutUnit(LayoutBlock::paddingStart().toInt());
  }

  LayoutUnit bordersPaddingAndSpacingInRowDirection() const {
    // 'border-spacing' only applies to separate borders (see 17.6.1 The
    // separated borders model).
    return borderStart() + borderEnd() +
           (collapseBorders() ? LayoutUnit() : (paddingStart() + paddingEnd() +
                                                borderSpacingInRowDirection()));
  }

  // Return the first column or column-group.
  LayoutTableCol* firstColumn() const;

  struct ColAndColGroup {
    ColAndColGroup()
        : col(nullptr),
          colgroup(nullptr),
          adjoinsStartBorderOfColGroup(false),
          adjoinsEndBorderOfColGroup(false) {}
    LayoutTableCol* col;
    LayoutTableCol* colgroup;
    bool adjoinsStartBorderOfColGroup;
    bool adjoinsEndBorderOfColGroup;
    LayoutTableCol* innermostColOrColGroup() { return col ? col : colgroup; }
  };
  ColAndColGroup colElementAtAbsoluteColumn(
      unsigned absoluteColumnIndex) const {
    // The common case is to not have col/colgroup elements, make that case
    // fast.
    if (!m_hasColElements)
      return ColAndColGroup();
    return slowColElementAtAbsoluteColumn(absoluteColumnIndex);
  }

  bool needsSectionRecalc() const { return m_needsSectionRecalc; }
  void setNeedsSectionRecalc() {
    if (documentBeingDestroyed())
      return;
    m_needsSectionRecalc = true;
    setNeedsLayoutAndFullPaintInvalidation(
        LayoutInvalidationReason::TableChanged);
  }

  LayoutTableSection* sectionAbove(
      const LayoutTableSection*,
      SkipEmptySectionsValue = DoNotSkipEmptySections) const;
  LayoutTableSection* sectionBelow(
      const LayoutTableSection*,
      SkipEmptySectionsValue = DoNotSkipEmptySections) const;

  LayoutTableCell* cellAbove(const LayoutTableCell*) const;
  LayoutTableCell* cellBelow(const LayoutTableCell*) const;
  LayoutTableCell* cellBefore(const LayoutTableCell*) const;
  LayoutTableCell* cellAfter(const LayoutTableCell*) const;

  typedef Vector<CollapsedBorderValue> CollapsedBorderValues;
  void invalidateCollapsedBorders();

  bool hasSections() const { return m_head || m_foot || m_firstBody; }

  void recalcSectionsIfNeeded() const {
    if (m_needsSectionRecalc)
      recalcSections();
  }

  static LayoutTable* createAnonymousWithParent(const LayoutObject*);
  LayoutBox* createAnonymousBoxWithSameTypeAs(
      const LayoutObject* parent) const override {
    return createAnonymousWithParent(parent);
  }

  const BorderValue& tableStartBorderAdjoiningCell(
      const LayoutTableCell*) const;
  const BorderValue& tableEndBorderAdjoiningCell(const LayoutTableCell*) const;

  void addCaption(const LayoutTableCaption*);
  void removeCaption(const LayoutTableCaption*);
  void addColumn(const LayoutTableCol*);
  void removeColumn(const LayoutTableCol*);

  void paintBoxDecorationBackground(const PaintInfo&,
                                    const LayoutPoint&) const final;

  void paintMask(const PaintInfo&, const LayoutPoint&) const final;

  const CollapsedBorderValues& collapsedBorders() const {
    ASSERT(m_collapsedBordersValid);
    return m_collapsedBorders;
  }

  void subtractCaptionRect(LayoutRect&) const;

  bool isLogicalWidthAuto() const;

  // When table headers are repeated, we need to know the offset from the block
  // start of the fragmentation context to the first occurrence of the table
  // header.
  LayoutUnit blockOffsetToFirstRepeatableHeader() const {
    return m_blockOffsetToFirstRepeatableHeader;
  }

  const char* name() const override { return "LayoutTable"; }

  // Whether a table has opaque foreground depends on many factors, e.g. border
  // spacing, missing cells, etc. For simplicity, just conservatively assume
  // foreground of all tables are not opaque.
  bool foregroundIsKnownToBeOpaqueInRect(const LayoutRect&,
                                         unsigned) const override {
    return false;
  }

  enum WhatToMarkAllCells { MarkDirtyOnly, MarkDirtyAndNeedsLayout };
  void markAllCellsWidthsDirtyAndOrNeedsLayout(WhatToMarkAllCells);

 protected:
  void styleDidChange(StyleDifference, const ComputedStyle* oldStyle) override;
  void simplifiedNormalFlowLayout() override;
  bool recalcChildOverflowAfterStyleChange() override;
  void ensureIsReadyForPaintInvalidation() override;
  PaintInvalidationReason invalidatePaintIfNeeded(
      const PaintInvalidationState&) override;
  PaintInvalidationReason invalidatePaintIfNeeded(
      const PaintInvalidatorContext&) const override;

 private:
  bool isOfType(LayoutObjectType type) const override {
    return type == LayoutObjectTable || LayoutBlock::isOfType(type);
  }

  void paintObject(const PaintInfo&, const LayoutPoint&) const override;
  void layout() override;
  void computeIntrinsicLogicalWidths(LayoutUnit& minWidth,
                                     LayoutUnit& maxWidth) const override;
  void computePreferredLogicalWidths() override;
  bool nodeAtPoint(HitTestResult&,
                   const HitTestLocation& locationInContainer,
                   const LayoutPoint& accumulatedOffset,
                   HitTestAction) override;

  int baselinePosition(
      FontBaseline,
      bool firstLine,
      LineDirectionMode,
      LinePositionMode = PositionOnContainingLine) const override;
  int firstLineBoxBaseline() const override;
  int inlineBlockBaseline(LineDirectionMode) const override;

  ColAndColGroup slowColElementAtAbsoluteColumn(unsigned col) const;

  void updateColumnCache() const;
  void invalidateCachedColumns();

  void updateLogicalWidth() override;

  LayoutUnit convertStyleLogicalWidthToComputedWidth(
      const Length& styleLogicalWidth,
      LayoutUnit availableWidth) const;
  LayoutUnit convertStyleLogicalHeightToComputedHeight(
      const Length& styleLogicalHeight) const;

  LayoutRect overflowClipRect(
      const LayoutPoint& location,
      OverlayScrollbarClipBehavior = IgnoreOverlayScrollbarSize) const override;

  void addOverflowFromChildren() override;

  void recalcSections() const;
  void layoutCaption(LayoutTableCaption&, SubtreeLayoutScope&);
  void layoutSection(LayoutTableSection&,
                     SubtreeLayoutScope&,
                     LayoutUnit logicalLeft);

  // Return the logical height based on the height, min-height and max-height
  // properties from CSS. Will return 0 if auto.
  LayoutUnit logicalHeightFromStyle() const;

  void distributeExtraLogicalHeight(int extraLogicalHeight);

  void recalcCollapsedBordersIfNeeded();

  // TODO(layout-dev): All mutables in this class are lazily updated by
  // recalcSections() which is called by various getter methods (e.g.
  // borderBefore(), borderAfter()).
  // They allow dirty layout even after DocumentLifecycle::LayoutClean which
  // seems not proper. crbug.com/538236.

  // Holds spans (number of absolute columns) of effective columns.
  // See "absolute column index vs effective column index" in comments of
  // LayoutTable.
  mutable Vector<ColumnStruct> m_effectiveColumns;

  // Holds the logical layout positions of effective columns, and the last item
  // (whose index is numEffectiveColumns()) holds the position of the imaginary
  // column after the last column.
  // Because of the last item, m_effectiveColumnPositions.size() is always
  // numEffectiveColumns() + 1.
  mutable Vector<int> m_effectiveColumnPositions;

  // The captions associated with this object.
  mutable Vector<LayoutTableCaption*> m_captions;

  // Holds pointers to LayoutTableCol objects for <col>s and <colgroup>s under
  // this table.
  // There is no direct relationship between the size of and index into this
  // vector and those of m_effectiveColumns because they hold different things.
  mutable Vector<LayoutTableCol*> m_columnLayoutObjects;

  mutable LayoutTableSection* m_head;
  mutable LayoutTableSection* m_foot;
  mutable LayoutTableSection* m_firstBody;

  // The layout algorithm used by this table.
  //
  // CSS 2.1 defines 2 types of table layouts toggled with 'table-layout':
  // fixed (TableLayoutAlgorithmFixed) and auto (TableLayoutAlgorithmAuto).
  // See http://www.w3.org/TR/CSS21/tables.html#width-layout.
  //
  // The layout algorithm is delegated to TableLayoutAlgorithm. This enables
  // changing 'table-layout' without having to reattach the <table>.
  //
  // As the algorithm is dependent on the style, this field is nullptr before
  // the first style is applied in styleDidChange().
  std::unique_ptr<TableLayoutAlgorithm> m_tableLayout;

  // A sorted list of all unique border values that we want to paint.
  //
  // Collapsed borders are SUPER EXPENSIVE to compute. The reason is that we
  // need to compare a cells border against all the adjoining cells, rows,
  // row groups, column, column groups and table. Thus we cache them in this
  // field.
  CollapsedBorderValues m_collapsedBorders;
  bool m_collapsedBordersValid : 1;

  mutable bool m_hasColElements : 1;
  mutable bool m_needsSectionRecalc : 1;

  bool m_columnLogicalWidthChanged : 1;
  mutable bool m_columnLayoutObjectsValid : 1;
  mutable unsigned m_noCellColspanAtLeast;
  unsigned calcNoCellColspanAtLeast() const {
    for (unsigned c = 0; c < numEffectiveColumns(); c++) {
      if (m_effectiveColumns[c].span > 1)
        return c;
    }
    return numEffectiveColumns();
  }

  short m_hSpacing;
  short m_vSpacing;
  int m_borderStart;
  int m_borderEnd;

  LayoutUnit m_blockOffsetToFirstRepeatableHeader;
  LayoutUnit m_rowOffsetFromRepeatingHeader;
};

inline LayoutTableSection* LayoutTable::topSection() const {
  ASSERT(!needsSectionRecalc());
  if (m_head)
    return m_head;
  if (m_firstBody)
    return m_firstBody;
  return m_foot;
}

DEFINE_LAYOUT_OBJECT_TYPE_CASTS(LayoutTable, isTable());

}  // namespace blink

#endif  // LayoutTable_h