gecko-dev/layout/tables/celldata.h

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/* -*- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
#ifndef CellData_h__
#define CellData_h__
#include "nsISupports.h"
#include "nsITableCellLayout.h" // for MAX_COLSPAN / MAX_ROWSPAN
#include "nsCoord.h"
#include "mozilla/gfx/Types.h"
#include "mozilla/WritingModes.h"
#include <stdint.h>
class nsTableCellFrame;
class nsCellMap;
class BCCellData;
/**
* Data stored by nsCellMap to rationalize rowspan and colspan cells.
*/
class CellData {
public:
/** Initialize the mOrigCell pointer
* @param aOrigCell the table cell frame which will be stored in mOrigCell.
*/
void Init(nsTableCellFrame* aCellFrame);
/** does a cell originate from here
* @return is true if a cell corresponds to this cellmap entry
*/
bool IsOrig() const;
/** is the celldata valid
* @return is true if no cell originates and the cell is not spanned by
* a row- or colspan. mBits are 0 in this case and mOrigCell is
* nullptr
*/
bool IsDead() const;
/** is the entry spanned by row- or a colspan
* @return is true if the entry is spanned by a row- or colspan
*/
bool IsSpan() const;
/** is the entry spanned by rowspan
* @return is true if the entry is spanned by a rowspan
*/
bool IsRowSpan() const;
/** is the entry spanned by a zero rowspan
* zero rowspans span all cells starting from the originating cell down to
* the end of the rowgroup or a cell originating in the same column
* @return is true if the entry is spanned by a zero rowspan
*/
bool IsZeroRowSpan() const;
/** mark the current entry as spanned by a zero rowspan
* @param aIsZero if true mark the entry as covered by a zero rowspan
*/
void SetZeroRowSpan(bool aIsZero);
/** get the distance from the current entry to the corresponding origin of the
* rowspan
* @return containing the distance in the column to the originating cell
*/
uint32_t GetRowSpanOffset() const;
/** set the distance from the current entry to the corresponding origin of
* the rowspan
* @param the distance in the column to the originating cell
*/
void SetRowSpanOffset(uint32_t aSpan);
/** is the entry spanned by colspan
* @return is true if the entry is spanned by a colspan
*/
bool IsColSpan() const;
/** get the distance from the current entry to the corresponding origin of
* the colspan
* @return containing the distance in the row to the originating cell
*/
uint32_t GetColSpanOffset() const;
/** set the distance from the current entry to the corresponding origin of the
* colspan
* @param the distance in the column to the originating cell
*/
void SetColSpanOffset(uint32_t aSpan);
/** is the entry spanned by a row- and a colspan
* @return is true if the entry is spanned by a row- and a colspan
*/
bool IsOverlap() const;
/** mark the current entry as spanned by a row- and a colspan
* @param aOverlap if true mark the entry as covered by a row- and
* a colspan
*/
void SetOverlap(bool aOverlap);
/** get the table cell frame for this entry
* @return a pointer to the cellframe, this will be nullptr when the entry
* is only a spanned entry
*/
nsTableCellFrame* GetCellFrame() const;
private:
friend class nsCellMap;
friend class BCCellData;
/**
* Implemented in nsCellMap.cpp
*
* @param aOrigCell the table cell frame which will be stored in mOrigCell.
*/
explicit CellData(nsTableCellFrame* aOrigCell);
~CellData(); // implemented in nsCellMap.cpp
protected:
// this union relies on the assumption that an object (not primitive type)
// does not start on an odd bit boundary. If mSpan is 0 then mOrigCell is in
// effect and the data does not represent a span. If mSpan is 1, then mBits is
// in effect and the data represents a span. mBits must match the size of
// mOrigCell on both 32- and 64-bit platforms.
union {
nsTableCellFrame* mOrigCell;
uintptr_t mBits;
};
};
// Border Collapsing Cell Data
enum BCBorderOwner {
eTableOwner = 0,
eColGroupOwner = 1,
eAjaColGroupOwner = 2, // col group to the left
eColOwner = 3,
eAjaColOwner = 4, // col to the left
eRowGroupOwner = 5,
eAjaRowGroupOwner = 6, // row group above
eRowOwner = 7,
eAjaRowOwner = 8, // row above
eCellOwner = 9,
eAjaCellOwner = 10 // cell to the top or to the left
};
// BCPixelSize is in device pixels.
typedef uint16_t BCPixelSize;
// These are the max sizes that are stored. If they are exceeded, then the max
// is stored and the actual value is computed when needed.
#define MAX_BORDER_WIDTH nscoord((1u << (sizeof(BCPixelSize) * 8)) - 1)
// The half of border on inline/block-axis start side
static inline BCPixelSize BC_BORDER_START_HALF(BCPixelSize px) {
return px - px / 2;
}
// The half of border on inline/block-axis end side
static inline BCPixelSize BC_BORDER_END_HALF(BCPixelSize px) { return px / 2; }
static inline nscoord BC_BORDER_START_HALF_COORD(int32_t d2a, BCPixelSize px) {
return BC_BORDER_START_HALF(px) * d2a;
}
static inline nscoord BC_BORDER_END_HALF_COORD(int32_t d2a, BCPixelSize px) {
return BC_BORDER_END_HALF(px) * d2a;
}
// BCData stores the bstart and istart border info and the corner connecting the
// two.
class BCData {
public:
BCData();
~BCData();
nscoord GetIStartEdge(BCBorderOwner& aOwner, bool& aStart) const;
void SetIStartEdge(BCBorderOwner aOwner, nscoord aSize, bool aStart);
nscoord GetBStartEdge(BCBorderOwner& aOwner, bool& aStart) const;
void SetBStartEdge(BCBorderOwner aOwner, nscoord aSize, bool aStart);
BCPixelSize GetCorner(mozilla::LogicalSide& aCornerOwner, bool& aBevel) const;
void SetCorner(BCPixelSize aSubSize, mozilla::LogicalSide aOwner,
bool aBevel);
inline bool IsIStartStart() const { return (bool)mIStartStart; }
inline void SetIStartStart(bool aValue) { mIStartStart = aValue; }
inline bool IsBStartStart() const { return (bool)mBStartStart; }
inline void SetBStartStart(bool aValue) { mBStartStart = aValue; }
protected:
BCPixelSize mIStartSize; // size in pixels of iStart border
BCPixelSize mBStartSize; // size in pixels of bStart border
BCPixelSize mCornerSubSize; // size of the largest border not in the
// dominant plane (for example, if corner is
// owned by the segment to its bStart or bEnd,
// then the size is the max of the border
// sizes of the segments to its iStart or iEnd.
unsigned mIStartOwner : 4; // owner of iStart border
unsigned mBStartOwner : 4; // owner of bStart border
unsigned mIStartStart : 1; // set if this is the start of a block-dir border
// segment
unsigned mBStartStart : 1; // set if this is the start of an inline-dir
// border segment
unsigned mCornerSide : 2; // LogicalSide of the owner of the bStart-iStart
// corner relative to the corner
unsigned mCornerBevel : 1; // is the corner beveled (only two segments,
// perpendicular, not dashed or dotted).
};
// BCCellData entries replace CellData entries in the cell map if the border
// collapsing model is in effect. BCData for a row and col entry contains the
// left and top borders of cell at that row and col and the corner connecting
// the two. The right borders of the cells in the last col and the bottom
// borders of the last row are stored in separate BCData entries in the cell
// map.
class BCCellData : public CellData {
public:
explicit BCCellData(nsTableCellFrame* aOrigCell);
~BCCellData();
BCData mData;
};
// The layout of a celldata is as follows. The top 10 bits are the colspan
// offset (which is enough to represent our allowed values 1-1000 for colspan).
// Then there are two bits of flags.
// XXXmats Then one unused bit that we should decide how to use in bug 862624.
// Then 16 bits of rowspan offset (which
// lets us represent numbers up to 65535. Then another 3 bits of flags.
// num bits to shift right to get right aligned col span
#define COL_SPAN_SHIFT 22
// num bits to shift right to get right aligned row span
#define ROW_SPAN_SHIFT 3
// the col offset to the data containing the original cell.
#define COL_SPAN_OFFSET (0x3FF << COL_SPAN_SHIFT)
// the row offset to the data containing the original cell
#define ROW_SPAN_OFFSET (0xFFFF << ROW_SPAN_SHIFT)
// And the flags
#define SPAN 0x00000001 // there a row or col span
#define ROW_SPAN 0x00000002 // there is a row span
#define ROW_SPAN_0 0x00000004 // the row span is 0
#define COL_SPAN (1 << (COL_SPAN_SHIFT - 2)) // there is a col span
#define OVERLAP \
(1 << (COL_SPAN_SHIFT - 1)) // there is a row span and
// col span but not by
// same cell
inline nsTableCellFrame* CellData::GetCellFrame() const {
if (SPAN != (SPAN & mBits)) {
return mOrigCell;
}
return nullptr;
}
inline void CellData::Init(nsTableCellFrame* aCellFrame) {
mOrigCell = aCellFrame;
}
inline bool CellData::IsOrig() const {
return ((nullptr != mOrigCell) && (SPAN != (SPAN & mBits)));
}
inline bool CellData::IsDead() const { return (0 == mBits); }
inline bool CellData::IsSpan() const { return (SPAN == (SPAN & mBits)); }
inline bool CellData::IsRowSpan() const {
return (SPAN == (SPAN & mBits)) && (ROW_SPAN == (ROW_SPAN & mBits));
}
inline bool CellData::IsZeroRowSpan() const {
return (SPAN == (SPAN & mBits)) && (ROW_SPAN == (ROW_SPAN & mBits)) &&
(ROW_SPAN_0 == (ROW_SPAN_0 & mBits));
}
inline void CellData::SetZeroRowSpan(bool aIsZeroSpan) {
if (SPAN == (SPAN & mBits)) {
if (aIsZeroSpan) {
mBits |= ROW_SPAN_0;
} else {
mBits &= ~ROW_SPAN_0;
}
}
}
inline uint32_t CellData::GetRowSpanOffset() const {
if ((SPAN == (SPAN & mBits)) && ((ROW_SPAN == (ROW_SPAN & mBits)))) {
return (uint32_t)((mBits & ROW_SPAN_OFFSET) >> ROW_SPAN_SHIFT);
}
return 0;
}
inline void CellData::SetRowSpanOffset(uint32_t aSpan) {
mBits &= ~ROW_SPAN_OFFSET;
mBits |= (aSpan << ROW_SPAN_SHIFT);
mBits |= SPAN;
mBits |= ROW_SPAN;
}
inline bool CellData::IsColSpan() const {
return (SPAN == (SPAN & mBits)) && (COL_SPAN == (COL_SPAN & mBits));
}
inline uint32_t CellData::GetColSpanOffset() const {
if ((SPAN == (SPAN & mBits)) && ((COL_SPAN == (COL_SPAN & mBits)))) {
return (uint32_t)((mBits & COL_SPAN_OFFSET) >> COL_SPAN_SHIFT);
}
return 0;
}
inline void CellData::SetColSpanOffset(uint32_t aSpan) {
mBits &= ~COL_SPAN_OFFSET;
mBits |= (aSpan << COL_SPAN_SHIFT);
mBits |= SPAN;
mBits |= COL_SPAN;
}
inline bool CellData::IsOverlap() const {
return (SPAN == (SPAN & mBits)) && (OVERLAP == (OVERLAP & mBits));
}
inline void CellData::SetOverlap(bool aOverlap) {
if (SPAN == (SPAN & mBits)) {
if (aOverlap) {
mBits |= OVERLAP;
} else {
mBits &= ~OVERLAP;
}
}
}
inline BCData::BCData() {
mIStartOwner = mBStartOwner = eCellOwner;
SetBStartStart(true);
SetIStartStart(true);
mIStartSize = mCornerSubSize = mBStartSize = 0;
mCornerSide = mozilla::eLogicalSideBStart;
mCornerBevel = false;
}
inline BCData::~BCData() {}
inline nscoord BCData::GetIStartEdge(BCBorderOwner& aOwner,
bool& aStart) const {
aOwner = (BCBorderOwner)mIStartOwner;
aStart = IsIStartStart();
return (nscoord)mIStartSize;
}
inline void BCData::SetIStartEdge(BCBorderOwner aOwner, nscoord aSize,
bool aStart) {
mIStartOwner = aOwner;
mIStartSize = (aSize > MAX_BORDER_WIDTH) ? MAX_BORDER_WIDTH : aSize;
SetIStartStart(aStart);
}
inline nscoord BCData::GetBStartEdge(BCBorderOwner& aOwner,
bool& aStart) const {
aOwner = (BCBorderOwner)mBStartOwner;
aStart = IsBStartStart();
return (nscoord)mBStartSize;
}
inline void BCData::SetBStartEdge(BCBorderOwner aOwner, nscoord aSize,
bool aStart) {
mBStartOwner = aOwner;
mBStartSize = (aSize > MAX_BORDER_WIDTH) ? MAX_BORDER_WIDTH : aSize;
SetBStartStart(aStart);
}
inline BCPixelSize BCData::GetCorner(mozilla::LogicalSide& aOwnerSide,
bool& aBevel) const {
aOwnerSide = mozilla::LogicalSide(mCornerSide);
aBevel = (bool)mCornerBevel;
return mCornerSubSize;
}
inline void BCData::SetCorner(BCPixelSize aSubSize,
mozilla::LogicalSide aOwnerSide, bool aBevel) {
mCornerSubSize = aSubSize;
mCornerSide = aOwnerSide;
mCornerBevel = aBevel;
}
#endif