/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*- */
/*
* This file is part of the LibreOffice project.
*
* 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/.
*
* This file incorporates work covered by the following license notice:
*
* Licensed to the Apache Software Foundation (ASF) under one or more
* contributor license agreements. See the NOTICE file distributed
* with this work for additional information regarding copyright
* ownership. The ASF licenses this file to you under the Apache
* License, Version 2.0 (the "License"); you may not use this file
* except in compliance with the License. You may obtain a copy of
* the License at http://www.apache.org/licenses/LICENSE-2.0 .
*/
#include <com/sun/star/table/XMergeableCell.hpp>
#include <tools/gen.hxx>
#include <libxml/xmlwriter.h>
#include <cell.hxx>
#include "cellrange.hxx"
#include <o3tl/safeint.hxx>
#include <tablemodel.hxx>
#include "tablerow.hxx"
#include "tablerows.hxx"
#include "tablecolumn.hxx"
#include "tablecolumns.hxx"
#include "tablelayouter.hxx"
#include <svx/svdotable.hxx>
#include <editeng/borderline.hxx>
#include <editeng/boxitem.hxx>
#include <svx/svdmodel.hxx>
using ::editeng::SvxBorderLine;
using namespace ::com::sun::star::uno;
using namespace ::com::sun::star::lang;
using namespace ::com::sun::star::container;
using namespace ::com::sun::star::beans;
using namespace ::com::sun::star::table;
using namespace ::com::sun::star::text;
namespace sdr { namespace table {
static SvxBorderLine gEmptyBorder;
static const OUStringLiteral gsSize( "Size" );
TableLayouter::TableLayouter( const TableModelRef& xTableModel )
: mxTable( xTableModel )
{
}
TableLayouter::~TableLayouter()
{
ClearBorderLayout();
}
basegfx::B2ITuple TableLayouter::getCellSize( const CellRef& xCell, const CellPos& rPos ) const
{
sal_Int32 width = 0;
sal_Int32 height = 0;
try
{
if( xCell.is() && !xCell->isMerged() )
{
CellPos aPos( rPos );
sal_Int32 nRowCount = getRowCount();
sal_Int32 nRowSpan = std::max( xCell->getRowSpan(), sal_Int32(1) );
while( nRowSpan && (aPos.mnRow < nRowCount) )
{
if( static_cast<sal_Int32>(maRows.size()) <= aPos.mnRow )
break;
height = o3tl::saturating_add(height, maRows[aPos.mnRow++].mnSize);
nRowSpan--;
}
sal_Int32 nColCount = getColumnCount();
sal_Int32 nColSpan = std::max( xCell->getColumnSpan(), sal_Int32(1) );
while( nColSpan && (aPos.mnCol < nColCount ) )
{
if( static_cast<sal_Int32>(maColumns.size()) <= aPos.mnCol )
break;
width = o3tl::saturating_add(width, maColumns[aPos.mnCol++].mnSize);
nColSpan--;
}
}
}
catch( Exception& )
{
OSL_FAIL( "TableLayouter::getCellSize(), exception caught!" );
}
return basegfx::B2ITuple( width, height );
}
bool TableLayouter::getCellArea( const CellRef& xCell, const CellPos& rPos, basegfx::B2IRectangle& rArea ) const
{
try
{
if( xCell.is() && !xCell->isMerged() && isValid(rPos) )
{
const basegfx::B2ITuple aCellSize( getCellSize( xCell, rPos ) );
const bool bRTL = (mxTable->getSdrTableObj()->GetWritingMode() == WritingMode_RL_TB);
if( (rPos.mnCol < static_cast<sal_Int32>(maColumns.size())) && (rPos.mnRow < static_cast<sal_Int32>(maRows.size()) ) )
{
const sal_Int32 y = maRows[rPos.mnRow].mnPos;
sal_Int32 endy;
if (o3tl::checked_add(y, aCellSize.getY(), endy))
return false;
if(bRTL)
{
///For RTL Table Calculate the Right End of cell instead of Left
const sal_Int32 x = maColumns[rPos.mnCol].mnPos + maColumns[rPos.mnCol].mnSize;
sal_Int32 startx;
if (o3tl::checked_sub(x, aCellSize.getX(), startx))
return false;
rArea = basegfx::B2IRectangle(startx, y, x, endy);
}
else
{
const sal_Int32 x = maColumns[rPos.mnCol].mnPos;
sal_Int32 endx;
if (o3tl::checked_add(x, aCellSize.getX(), endx))
return false;
rArea = basegfx::B2IRectangle(x, y, endx, endy);
}
return true;
}
}
}
catch( Exception& )
{
OSL_FAIL( "TableLayouter::getCellSize(), exception caught!" );
}
return false;
}
sal_Int32 TableLayouter::getRowHeight( sal_Int32 nRow ) const
{
if( isValidRow(nRow) )
return maRows[nRow].mnSize;
else
return 0;
}
sal_Int32 TableLayouter::getColumnWidth( sal_Int32 nColumn ) const
{
if( isValidColumn(nColumn) )
return maColumns[nColumn].mnSize;
else
return 0;
}
bool TableLayouter::isEdgeVisible( sal_Int32 nEdgeX, sal_Int32 nEdgeY, bool bHorizontal ) const
{
const BorderLineMap& rMap = bHorizontal ? maHorizontalBorders : maVerticalBorders;
if( (nEdgeX >= 0) && (nEdgeX < sal::static_int_cast<sal_Int32>(rMap.size())) &&
(nEdgeY >= 0) && (nEdgeY < sal::static_int_cast<sal_Int32>(rMap[nEdgeX].size())) )
{
return rMap[nEdgeX][nEdgeY] != nullptr;
}
else
{
OSL_FAIL( "sdr::table::TableLayouter::getBorderLine(), invalid edge!" );
}
return false;
}
/** returns the requested borderline in rpBorderLine or a null pointer if there is no border at this edge */
SvxBorderLine* TableLayouter::getBorderLine( sal_Int32 nEdgeX, sal_Int32 nEdgeY, bool bHorizontal )const
{
SvxBorderLine* pLine = nullptr;
const BorderLineMap& rMap = bHorizontal ? maHorizontalBorders : maVerticalBorders;
if( (nEdgeX >= 0) && (nEdgeX < sal::static_int_cast<sal_Int32>(rMap.size())) &&
(nEdgeY >= 0) && (nEdgeY < sal::static_int_cast<sal_Int32>(rMap[nEdgeX].size())) )
{
pLine = rMap[nEdgeX][nEdgeY];
if( pLine == &gEmptyBorder )
pLine = nullptr;
}
else
{
OSL_FAIL( "sdr::table::TableLayouter::getBorderLine(), invalid edge!" );
}
return pLine;
}
sal_Int32 TableLayouter::getHorizontalEdge( int nEdgeY, sal_Int32* pnMin /*= 0*/, sal_Int32* pnMax /*= 0*/ )
{
sal_Int32 nRet = 0;
const sal_Int32 nRowCount = getRowCount();
if( (nEdgeY >= 0) && (nEdgeY <= nRowCount ) )
nRet = maRows[std::min(static_cast<sal_Int32>(nEdgeY),nRowCount-1)].mnPos;
if( nEdgeY == nRowCount )
nRet += maRows[nEdgeY - 1].mnSize;
if( pnMin )
{
if( (nEdgeY > 0) && (nEdgeY <= nRowCount ) )
{
*pnMin = maRows[nEdgeY-1].mnPos + 600; // todo
}
else
{
*pnMin = nRet;
}
}
if( pnMax )
{
*pnMax = 0x0fffffff;
}
return nRet;
}
sal_Int32 TableLayouter::getVerticalEdge( int nEdgeX, sal_Int32* pnMin /*= 0*/, sal_Int32* pnMax /*= 0*/ )
{
sal_Int32 nRet = 0;
const sal_Int32 nColCount = getColumnCount();
if( (nEdgeX >= 0) && (nEdgeX <= nColCount ) )
nRet = maColumns[std::min(static_cast<sal_Int32>(nEdgeX),nColCount-1)].mnPos;
const bool bRTL = (mxTable->getSdrTableObj()->GetWritingMode() == WritingMode_RL_TB);
if( bRTL )
{
if( (nEdgeX >= 0) && (nEdgeX < nColCount) )
nRet += maColumns[nEdgeX].mnSize;
}
else
{
if( nEdgeX == nColCount )
nRet += maColumns[nEdgeX - 1].mnSize;
}
if( pnMin )
{
*pnMin = nRet;
if( bRTL )
{
if( nEdgeX < nColCount )
*pnMin = nRet - maColumns[nEdgeX].mnSize + getMinimumColumnWidth(nEdgeX);
}
else
{
if( (nEdgeX > 0) && (nEdgeX <= nColCount ) )
*pnMin = maColumns[nEdgeX-1].mnPos + getMinimumColumnWidth( nEdgeX-1 );
}
}
if( pnMax )
{
*pnMax = 0x0fffffff; // todo
if( bRTL )
{
if( nEdgeX > 0 )
*pnMax = nRet + maColumns[nEdgeX-1].mnSize - getMinimumColumnWidth( nEdgeX-1 );
}
else
{
if( (nEdgeX >= 0) && (nEdgeX < nColCount ) )
*pnMax = maColumns[nEdgeX].mnPos + maColumns[nEdgeX].mnSize - getMinimumColumnWidth( nEdgeX );
}
}
return nRet;
}
static bool checkMergeOrigin( const TableModelRef& xTable, sal_Int32 nMergedX, sal_Int32 nMergedY, sal_Int32 nCellX, sal_Int32 nCellY, bool& bRunning )
{
Reference< XMergeableCell > xCell( xTable->getCellByPosition( nCellX, nCellY ), UNO_QUERY );
if( xCell.is() && !xCell->isMerged() )
{
const sal_Int32 nRight = xCell->getColumnSpan() + nCellX;
const sal_Int32 nBottom = xCell->getRowSpan() + nCellY;
if( (nMergedX < nRight) && (nMergedY < nBottom) )
return true;
bRunning = false;
}
return false;
}
/** returns true if the cell(nMergedX,nMergedY) is merged with other cells.
the returned cell( rOriginX, rOriginY ) is the origin( top left cell ) of the merge.
*/
bool findMergeOrigin( const TableModelRef& xTable, sal_Int32 nMergedX, sal_Int32 nMergedY, sal_Int32& rOriginX, sal_Int32& rOriginY )
{
rOriginX = nMergedX;
rOriginY = nMergedY;
if( xTable.is() ) try
{
// check if this cell already the origin or not merged at all
Reference< XMergeableCell > xCell( xTable->getCellByPosition( nMergedX, nMergedY ), UNO_QUERY_THROW );
if( !xCell->isMerged() )
return true;
bool bCheckVert = true;
bool bCheckHorz = true;
sal_Int32 nMinCol = 0;
sal_Int32 nMinRow = 0;
sal_Int32 nStep = 1, i;
sal_Int32 nRow, nCol;
do
{
if( bCheckVert )
{
nRow = nMergedY - nStep;
if( nRow >= nMinRow )
{
nCol = nMergedX;
for( i = 0; (i <= nStep) && (nCol >= nMinCol); i++, nCol-- )
{
if( checkMergeOrigin( xTable, nMergedX, nMergedY, nCol, nRow, bCheckVert ) )
{
rOriginX = nCol; rOriginY = nRow;
return true;
}
if( !bCheckVert )
{
if( nCol == nMergedX )
{
nMinRow = nRow+1;
}
else
{
bCheckVert = true;
}
break;
}
}
}
else
{
bCheckVert = false;
}
}
if( bCheckHorz )
{
nCol = nMergedX - nStep;
if( nCol >= nMinCol )
{
nRow = nMergedY;
for( i = 0; (i < nStep) && (nRow >= nMinRow); i++, nRow-- )
{
if( checkMergeOrigin( xTable, nMergedX, nMergedY, nCol, nRow, bCheckHorz ) )
{
rOriginX = nCol; rOriginY = nRow;
return true;
}
if( !bCheckHorz )
{
if( nRow == nMergedY )
{
nMinCol = nCol+1;
}
else
{
bCheckHorz = true;
}
break;
}
}
}
else
{
bCheckHorz = false;
}
}
nStep++;
}
while( bCheckVert || bCheckHorz );
}
catch( Exception& )
{
OSL_FAIL("sdr::table::TableLayouter::findMergeOrigin(), exception caught!");
}
return false;
}
sal_Int32 TableLayouter::getMinimumColumnWidth( sal_Int32 nColumn )
{
if( isValidColumn( nColumn ) )
{
return maColumns[nColumn].mnMinSize;
}
else
{
OSL_FAIL( "TableLayouter::getMinimumColumnWidth(), column out of range!" );
return 0;
}
}
sal_Int32 TableLayouter::distribute( LayoutVector& rLayouts, sal_Int32 nDistribute )
{
// break loops after 100 runs to avoid freezing office due to developer error
sal_Int32 nSafe = 100;
const std::size_t nCount = rLayouts.size();
std::size_t nIndex;
bool bConstrainsBroken = false;
do
{
bConstrainsBroken = false;
// first enforce minimum size constrains on all entities
for( nIndex = 0; nIndex < nCount; ++nIndex )
{
Layout& rLayout = rLayouts[nIndex];
if( rLayout.mnSize < rLayout.mnMinSize )
{
sal_Int32 nDiff(0);
bConstrainsBroken |= o3tl::checked_sub(rLayout.mnMinSize, rLayout.mnSize, nDiff);
bConstrainsBroken |= o3tl::checked_sub(nDistribute, nDiff, nDistribute);
rLayout.mnSize = rLayout.mnMinSize;
}
}
// calculate current width
// if nDistribute is < 0 (shrinking), entities that are already
// at minimum width are not counted
sal_Int32 nCurrentWidth = 0;
for( nIndex = 0; nIndex < nCount; ++nIndex )
{
Layout& rLayout = rLayouts[nIndex];
if( (nDistribute > 0) || (rLayout.mnSize > rLayout.mnMinSize) )
nCurrentWidth = o3tl::saturating_add(nCurrentWidth, rLayout.mnSize);
}
// now distribute over entities
if( (nCurrentWidth != 0) && (nDistribute != 0) )
{
sal_Int32 nDistributed = nDistribute;
for( nIndex = 0; nIndex < nCount; ++nIndex )
{
Layout& rLayout = rLayouts[nIndex];
if( (nDistribute > 0) || (rLayout.mnSize > rLayout.mnMinSize) )
{
sal_Int32 n(nDistributed); // for last entity use up rest
if (nIndex != (nCount-1))
{
bConstrainsBroken |= o3tl::checked_multiply(nDistribute, rLayout.mnSize, n);
n /= nCurrentWidth;
}
bConstrainsBroken |= o3tl::checked_add(rLayout.mnSize, n, rLayout.mnSize);
nDistributed -= n;
if( rLayout.mnSize < rLayout.mnMinSize )
bConstrainsBroken = true;
}
}
}
} while( bConstrainsBroken && --nSafe );
sal_Int32 nSize = 0;
for( nIndex = 0; nIndex < nCount; ++nIndex )
nSize = o3tl::saturating_add(nSize, rLayouts[nIndex].mnSize);
return nSize;
}
typedef std::vector< CellRef > MergeableCellVector;
typedef std::vector< MergeableCellVector > MergeVector;
void TableLayouter::LayoutTableWidth( tools::Rectangle& rArea, bool bFit )
{
const sal_Int32 nColCount = getColumnCount();
const sal_Int32 nRowCount = getRowCount();
if( nColCount == 0 )
return;
MergeVector aMergedCells( nColCount );
std::vector<sal_Int32> aOptimalColumns;
const OUString sOptimalSize("OptimalSize");
if( sal::static_int_cast< sal_Int32 >( maColumns.size() ) != nColCount )
maColumns.resize( nColCount );
Reference< XTableColumns > xCols( mxTable->getColumns(), UNO_QUERY_THROW );
// first calculate current width and initial minimum width per column,
// merged cells will be counted later
sal_Int32 nCurrentWidth = 0;
sal_Int32 nCol = 0, nRow = 0;
for( nCol = 0; nCol < nColCount; nCol++ )
{
sal_Int32 nMinWidth = 0;
bool bIsEmpty = true; // check if all cells in this column are merged
for( nRow = 0; nRow < nRowCount; ++nRow )
{
CellRef xCell( getCell( CellPos( nCol, nRow ) ) );
if( xCell.is() && !xCell->isMerged() )
{
bIsEmpty = false;
sal_Int32 nColSpan = xCell->getColumnSpan();
if( nColSpan > 1 )
{
// merged cells will be evaluated later
aMergedCells[nCol+nColSpan-1].push_back( xCell );
}
else
{
nMinWidth = std::max( nMinWidth, xCell->getMinimumWidth() );
}
}
}
maColumns[nCol].mnMinSize = nMinWidth;
if( bIsEmpty )
{
maColumns[nCol].mnSize = 0;
}
else
{
sal_Int32 nColWidth = 0;
Reference< XPropertySet > xColSet( xCols->getByIndex( nCol ), UNO_QUERY_THROW );
bool bOptimal = false;
xColSet->getPropertyValue( sOptimalSize ) >>= bOptimal;
if( bOptimal )
{
aOptimalColumns.push_back(nCol);
}
else
{
xColSet->getPropertyValue( gsSize ) >>= nColWidth;
}
maColumns[nCol].mnSize = nColWidth;
if( maColumns[nCol].mnSize < nMinWidth )
maColumns[nCol].mnSize = nMinWidth;
nCurrentWidth = o3tl::saturating_add(nCurrentWidth, maColumns[nCol].mnSize);
}
}
// if we have optimal sized rows, distribute what is given (left)
if( !bFit && !aOptimalColumns.empty() && (nCurrentWidth < rArea.getWidth()) )
{
sal_Int32 nLeft = rArea.getWidth() - nCurrentWidth;
sal_Int32 nDistribute = nLeft / aOptimalColumns.size();
auto iter( aOptimalColumns.begin() );
while( iter != aOptimalColumns.end() )
{
sal_Int32 nOptCol = (*iter++);
if( iter == aOptimalColumns.end() )
nDistribute = nLeft;
maColumns[nOptCol].mnSize += nDistribute;
nLeft -= nDistribute;
}
DBG_ASSERT( nLeft == 0, "svx::TableLayouter::LayoutTableWidtht(), layouting failed!" );
}
// now check if merged cells fit
for( nCol = 1; nCol < nColCount; ++nCol )
{
bool bChanges = false;
MergeableCellVector::iterator iter( aMergedCells[nCol].begin() );
const sal_Int32 nOldSize = maColumns[nCol].mnSize;
while( iter != aMergedCells[nCol].end() )
{
CellRef xCell( (*iter++) );
sal_Int32 nMinWidth = xCell->getMinimumWidth();
for( sal_Int32 nMCol = nCol - xCell->getColumnSpan() + 1; (nMCol > 0) && (nMCol < nCol); ++nMCol )
nMinWidth -= maColumns[nMCol].mnSize;
if( nMinWidth > maColumns[nCol].mnMinSize )
maColumns[nCol].mnMinSize = nMinWidth;
if( nMinWidth > maColumns[nCol].mnSize )
{
maColumns[nCol].mnSize = nMinWidth;
bChanges = true;
}
}
if( bChanges )
nCurrentWidth += maColumns[nCol].mnSize - nOldSize;
}
// now scale if wanted and needed
if( bFit && (nCurrentWidth != rArea.getWidth()) )
distribute( maColumns, rArea.getWidth() - nCurrentWidth );
// last step, update left edges
sal_Int32 nNewWidth = 0;
const bool bRTL = (mxTable->getSdrTableObj()->GetWritingMode() == WritingMode_RL_TB);
RangeIterator<sal_Int32> coliter( 0, nColCount, !bRTL );
while( coliter.next(nCol ) )
{
maColumns[nCol].mnPos = nNewWidth;
nNewWidth = o3tl::saturating_add(nNewWidth, maColumns[nCol].mnSize);
if( bFit )
{
Reference< XPropertySet > xColSet( xCols->getByIndex(nCol), UNO_QUERY_THROW );
xColSet->setPropertyValue( gsSize, Any( maColumns[nCol].mnSize ) );
}
}
rArea.SetSize( Size( nNewWidth, rArea.GetHeight() ) );
updateCells( rArea );
}
void TableLayouter::LayoutTableHeight( tools::Rectangle& rArea, bool bFit )
{
const sal_Int32 nColCount = getColumnCount();
const sal_Int32 nRowCount = getRowCount();
if( nRowCount == 0 )
return;
Reference< XTableRows > xRows( mxTable->getRows() );
MergeVector aMergedCells( nRowCount );
std::vector<sal_Int32> aOptimalRows;
const OUString sOptimalSize("OptimalSize");
// first calculate current height and initial minimum size per column,
// merged cells will be counted later
sal_Int32 nCurrentHeight = 0;
sal_Int32 nCol, nRow;
for( nRow = 0; nRow < nRowCount; ++nRow )
{
sal_Int32 nMinHeight = 0;
bool bIsEmpty = true; // check if all cells in this row are merged
bool bRowHasText = false;
for( nCol = 0; nCol < nColCount; ++nCol )
{
CellRef xCell( getCell( CellPos( nCol, nRow ) ) );
if( xCell.is() && !xCell->isMerged() )
{
bIsEmpty = false;
sal_Int32 nRowSpan = xCell->getRowSpan();
if( nRowSpan > 1 )
{
// merged cells will be evaluated later
aMergedCells[nRow+nRowSpan-1].push_back( xCell );
}
else
{
bool bCellHasText = xCell->hasText();
if ( (!bRowHasText && !bCellHasText) || ( bRowHasText && bCellHasText ) )
{
nMinHeight = std::max( nMinHeight, xCell->getMinimumHeight() );
}
else if ( !bRowHasText && bCellHasText )
{
bRowHasText = true;
nMinHeight = xCell->getMinimumHeight();
}
}
}
}
maRows[nRow].mnMinSize = nMinHeight;
if( bIsEmpty )
{
maRows[nRow].mnSize = 0;
}
else
{
sal_Int32 nRowHeight = 0;
Reference< XPropertySet > xRowSet( xRows->getByIndex(nRow), UNO_QUERY_THROW );
bool bOptimal = false;
xRowSet->getPropertyValue( sOptimalSize ) >>= bOptimal;
if( bOptimal )
{
aOptimalRows.push_back( nRow );
}
else
{
xRowSet->getPropertyValue( gsSize ) >>= nRowHeight;
}
maRows[nRow].mnSize = nRowHeight;
if( maRows[nRow].mnSize < nMinHeight )
maRows[nRow].mnSize = nMinHeight;
nCurrentHeight = o3tl::saturating_add(nCurrentHeight, maRows[nRow].mnSize);
}
}
// if we have optimal sized rows, distribute what is given (left)
if( !bFit && !aOptimalRows.empty() && (nCurrentHeight < rArea.getHeight()) )
{
sal_Int32 nLeft = rArea.getHeight() - nCurrentHeight;
sal_Int32 nDistribute = nLeft / aOptimalRows.size();
auto iter( aOptimalRows.begin() );
while( iter != aOptimalRows.end() )
{
sal_Int32 nOptRow = (*iter++);
if( iter == aOptimalRows.end() )
nDistribute = nLeft;
maRows[nOptRow].mnSize += nDistribute;
nLeft -= nDistribute;
}
DBG_ASSERT( nLeft == 0, "svx::TableLayouter::LayoutTableHeight(), layouting failed!" );
}
// now check if merged cells fit
for( nRow = 1; nRow < nRowCount; ++nRow )
{
bool bChanges = false;
sal_Int32 nOldSize = maRows[nRow].mnSize;
MergeableCellVector::iterator iter( aMergedCells[nRow].begin() );
while( iter != aMergedCells[nRow].end() )
{
CellRef xCell( (*iter++) );
sal_Int32 nMinHeight = xCell->getMinimumHeight();
for( sal_Int32 nMRow = nRow - xCell->getRowSpan() + 1; (nMRow > 0) && (nMRow < nRow); ++nMRow )
nMinHeight -= maRows[nMRow].mnSize;
if( nMinHeight > maRows[nRow].mnMinSize )
maRows[nRow].mnMinSize = nMinHeight;
if( nMinHeight > maRows[nRow].mnSize )
{
maRows[nRow].mnSize = nMinHeight;
bChanges = true;
}
}
if( bChanges )
nCurrentHeight += maRows[nRow].mnSize - nOldSize;
}
// now scale if wanted and needed
if( bFit && nCurrentHeight != rArea.getHeight() )
distribute(maRows, o3tl::saturating_sub<sal_Int32>(rArea.getHeight(), nCurrentHeight));
// last step, update left edges
sal_Int32 nNewHeight = 0;
for( nRow = 0; nRow < nRowCount; ++nRow )
{
maRows[nRow].mnPos = nNewHeight;
nNewHeight = o3tl::saturating_add(nNewHeight, maRows[nRow].mnSize);
if( bFit )
{
Reference< XPropertySet > xRowSet( xRows->getByIndex(nRow), UNO_QUERY_THROW );
xRowSet->setPropertyValue( gsSize, Any( maRows[nRow].mnSize ) );
}
}
rArea.SetSize( Size( rArea.GetWidth(), nNewHeight ) );
updateCells( rArea );
}
/** try to fit the table into the given rectangle.
If the rectangle is to small, it will be grown to fit the table. */
void TableLayouter::LayoutTable( tools::Rectangle& rRectangle, bool bFitWidth, bool bFitHeight )
{
if( !mxTable.is() )
return;
const sal_Int32 nRowCount = mxTable->getRowCount();
const sal_Int32 nColCount = mxTable->getColumnCount();
if( (nRowCount != getRowCount()) || (nColCount != getColumnCount()) )
{
if( static_cast< sal_Int32 >( maRows.size() ) != nRowCount )
maRows.resize( nRowCount );
for( sal_Int32 nRow = 0; nRow < nRowCount; nRow++ )
maRows[nRow].clear();
if( static_cast< sal_Int32 >( maColumns.size() ) != nColCount )
maColumns.resize( nColCount );
for( sal_Int32 nCol = 0; nCol < nColCount; nCol++ )
maColumns[nCol].clear();
}
LayoutTableWidth( rRectangle, bFitWidth );
LayoutTableHeight( rRectangle, bFitHeight );
UpdateBorderLayout();
}
void TableLayouter::updateCells( tools::Rectangle const & rRectangle )
{
const sal_Int32 nColCount = getColumnCount();
const sal_Int32 nRowCount = getRowCount();
CellPos aPos;
for( aPos.mnRow = 0; aPos.mnRow < nRowCount; aPos.mnRow++ )
{
for( aPos.mnCol = 0; aPos.mnCol < nColCount; aPos.mnCol++ )
{
CellRef xCell( getCell( aPos ) );
if( xCell.is() )
{
basegfx::B2IRectangle aCellArea;
if( getCellArea( xCell, aPos, aCellArea ) )
{
tools::Rectangle aCellRect;
aCellRect.SetLeft( aCellArea.getMinX() );
aCellRect.SetRight( aCellArea.getMaxX() );
aCellRect.SetTop( aCellArea.getMinY() );
aCellRect.SetBottom( aCellArea.getMaxY() );
aCellRect.Move( rRectangle.Left(), rRectangle.Top() );
xCell->setCellRect( aCellRect );
}
}
}
}
}
CellRef TableLayouter::getCell( const CellPos& rPos ) const
{
CellRef xCell;
if( mxTable.is() ) try
{
xCell.set( dynamic_cast< Cell* >( mxTable->getCellByPosition( rPos.mnCol, rPos.mnRow ).get() ) );
}
catch( Exception& )
{
OSL_FAIL( "sdr::table::TableLayouter::getCell(), exception caught!" );
}
return xCell;
}
bool TableLayouter::HasPriority( const SvxBorderLine* pThis, const SvxBorderLine* pOther )
{
if (!pThis || ((pThis == &gEmptyBorder) && (pOther != nullptr)))
return false;
if (!pOther || (pOther == &gEmptyBorder))
return true;
sal_uInt16 nThisSize = pThis->GetScaledWidth();
sal_uInt16 nOtherSize = pOther->GetScaledWidth();
if (nThisSize > nOtherSize)
return true;
else if (nThisSize < nOtherSize)
{
return false;
}
else
{
if ( pOther->GetInWidth() && !pThis->GetInWidth() )
{
return true;
}
else if ( pThis->GetInWidth() && !pOther->GetInWidth() )
{
return false;
}
else
{
return true; //! ???
}
}
}
void TableLayouter::SetBorder( sal_Int32 nCol, sal_Int32 nRow, bool bHorizontal, const SvxBorderLine* pLine )
{
if (!pLine)
pLine = &gEmptyBorder;
BorderLineMap& rMap = bHorizontal ? maHorizontalBorders : maVerticalBorders;
if( (nCol >= 0) && (nCol < sal::static_int_cast<sal_Int32>(rMap.size())) &&
(nRow >= 0) && (nRow < sal::static_int_cast<sal_Int32>(rMap[nCol].size())) )
{
SvxBorderLine *pOld = rMap[nCol][nRow];
if (HasPriority(pLine, pOld))
{
if (pOld && pOld != &gEmptyBorder)
delete pOld;
SvxBorderLine* pNew = (pLine != &gEmptyBorder) ? new SvxBorderLine(*pLine) : &gEmptyBorder;
rMap[nCol][nRow] = pNew;
}
}
else
{
OSL_FAIL( "sdr::table::TableLayouter::SetBorder(), invalid border!" );
}
}
void TableLayouter::ClearBorderLayout()
{
ClearBorderLayout(maHorizontalBorders);
ClearBorderLayout(maVerticalBorders);
}
void TableLayouter::ClearBorderLayout(BorderLineMap& rMap)
{
const sal_Int32 nColCount = rMap.size();
for( sal_Int32 nCol = 0; nCol < nColCount; nCol++ )
{
const sal_Int32 nRowCount = rMap[nCol].size();
for( sal_Int32 nRow = 0; nRow < nRowCount; nRow++ )
{
SvxBorderLine* pLine = rMap[nCol][nRow];
if( pLine )
{
if( pLine != &gEmptyBorder )
delete pLine;
rMap[nCol][nRow] = nullptr;
}
}
}
}
void TableLayouter::ResizeBorderLayout()
{
ClearBorderLayout();
ResizeBorderLayout(maHorizontalBorders);
ResizeBorderLayout(maVerticalBorders);
}
void TableLayouter::ResizeBorderLayout( BorderLineMap& rMap )
{
const sal_Int32 nColCount = getColumnCount() + 1;
const sal_Int32 nRowCount = getRowCount() + 1;
if( sal::static_int_cast<sal_Int32>(rMap.size()) != nColCount )
rMap.resize( nColCount );
for( sal_Int32 nCol = 0; nCol < nColCount; nCol++ )
{
if( sal::static_int_cast<sal_Int32>(rMap[nCol].size()) != nRowCount )
rMap[nCol].resize( nRowCount );
}
}
void TableLayouter::UpdateBorderLayout()
{
// make sure old border layout is cleared and border maps have correct size
ResizeBorderLayout();
const sal_Int32 nColCount = getColumnCount();
const sal_Int32 nRowCount = getRowCount();
CellPos aPos;
for( aPos.mnRow = 0; aPos.mnRow < nRowCount; aPos.mnRow++ )
{
for( aPos.mnCol = 0; aPos.mnCol < nColCount; aPos.mnCol++ )
{
CellRef xCell( getCell( aPos ) );
if( !xCell.is() )
continue;
const SvxBoxItem* pThisAttr = xCell->GetItemSet().GetItem<SvxBoxItem>( SDRATTR_TABLE_BORDER );
OSL_ENSURE(pThisAttr,"sdr::table::TableLayouter::UpdateBorderLayout(), no border attribute?");
if( !pThisAttr )
continue;
const sal_Int32 nLastRow = xCell->getRowSpan() + aPos.mnRow;
const sal_Int32 nLastCol = xCell->getColumnSpan() + aPos.mnCol;
for( sal_Int32 nRow = aPos.mnRow; nRow < nLastRow; nRow++ )
{
SetBorder( aPos.mnCol, nRow, false, pThisAttr->GetLeft() );
SetBorder( nLastCol, nRow, false, pThisAttr->GetRight() );
}
for( sal_Int32 nCol = aPos.mnCol; nCol < nLastCol; nCol++ )
{
SetBorder( nCol, aPos.mnRow, true, pThisAttr->GetTop() );
SetBorder( nCol, nLastRow, true, pThisAttr->GetBottom() );
}
}
}
}
void TableLayouter::DistributeColumns( ::tools::Rectangle& rArea, sal_Int32 nFirstCol, sal_Int32 nLastCol )
{
if( mxTable.is() ) try
{
const sal_Int32 nColCount = getColumnCount();
if( (nFirstCol < 0) || (nFirstCol>= nLastCol) || (nLastCol >= nColCount) )
return;
sal_Int32 nAllWidth = 0;
for( sal_Int32 nCol = nFirstCol; nCol <= nLastCol; ++nCol )
nAllWidth += getColumnWidth(nCol);
sal_Int32 nWidth = nAllWidth / (nLastCol-nFirstCol+1);
Reference< XTableColumns > xCols( mxTable->getColumns(), UNO_QUERY_THROW );
for( sal_Int32 nCol = nFirstCol; nCol <= nLastCol; ++nCol )
{
if( nCol == nLastCol )
nWidth = nAllWidth; // last column get round errors
Reference< XPropertySet > xColSet( xCols->getByIndex( nCol ), UNO_QUERY_THROW );
xColSet->setPropertyValue( gsSize, Any( nWidth ) );
nAllWidth -= nWidth;
}
LayoutTable( rArea, true, false );
}
catch( Exception& )
{
OSL_FAIL("sdr::table::TableLayouter::DistributeColumns(), exception caught!");
}
}
void TableLayouter::DistributeRows( ::tools::Rectangle& rArea, sal_Int32 nFirstRow, sal_Int32 nLastRow )
{
if( mxTable.is() ) try
{
const sal_Int32 nRowCount = mxTable->getRowCount();
if( (nFirstRow < 0) || (nFirstRow>= nLastRow) || (nLastRow >= nRowCount) )
return;
sal_Int32 nAllHeight = 0;
sal_Int32 nMinHeight = 0;
for( sal_Int32 nRow = nFirstRow; nRow <= nLastRow; ++nRow )
{
nMinHeight = std::max( maRows[nRow].mnMinSize, nMinHeight );
nAllHeight += maRows[nRow].mnSize;
}
const sal_Int32 nRows = (nLastRow-nFirstRow+1);
sal_Int32 nHeight = nAllHeight / nRows;
if( nHeight < nMinHeight )
{
sal_Int32 nNeededHeight = nRows * nMinHeight;
rArea.AdjustBottom(nNeededHeight - nAllHeight );
nHeight = nMinHeight;
nAllHeight = nRows * nMinHeight;
}
Reference< XTableRows > xRows( mxTable->getRows(), UNO_QUERY_THROW );
for( sal_Int32 nRow = nFirstRow; nRow <= nLastRow; ++nRow )
{
if( nRow == nLastRow )
nHeight = nAllHeight; // last row get round errors
Reference< XPropertySet > xRowSet( xRows->getByIndex( nRow ), UNO_QUERY_THROW );
xRowSet->setPropertyValue( gsSize, Any( nHeight ) );
nAllHeight -= nHeight;
}
LayoutTable( rArea, false, true );
}
catch( Exception& )
{
OSL_FAIL("sdr::table::TableLayouter::DistributeRows(), exception caught!");
}
}
void TableLayouter::dumpAsXml(xmlTextWriterPtr pWriter) const
{
xmlTextWriterStartElement(pWriter, BAD_CAST("TableLayouter"));
xmlTextWriterStartElement(pWriter, BAD_CAST("columns"));
for (const auto& rColumn : maColumns)
rColumn.dumpAsXml(pWriter);
xmlTextWriterEndElement(pWriter);
xmlTextWriterStartElement(pWriter, BAD_CAST("rows"));
for (const auto& rRow : maRows)
rRow.dumpAsXml(pWriter);
xmlTextWriterEndElement(pWriter);
xmlTextWriterEndElement(pWriter);
}
void TableLayouter::Layout::dumpAsXml(xmlTextWriterPtr pWriter) const
{
xmlTextWriterStartElement(pWriter, BAD_CAST("TableLayouter_Layout"));
xmlTextWriterWriteAttribute(pWriter, BAD_CAST("pos"), BAD_CAST(OString::number(mnPos).getStr()));
xmlTextWriterWriteAttribute(pWriter, BAD_CAST("size"), BAD_CAST(OString::number(mnSize).getStr()));
xmlTextWriterWriteAttribute(pWriter, BAD_CAST("minSize"), BAD_CAST(OString::number(mnMinSize).getStr()));
xmlTextWriterEndElement(pWriter);
}
} }
/* vim:set shiftwidth=4 softtabstop=4 expandtab: */
↑ V728 An excessive check can be simplified. The '(A && B) || (!A && !B)' expression is equivalent to the 'bool(A) == bool(B)' expression.