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tdepim/kdgantt/KDGanttMinimizeSplitter.cpp

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/*
$Id$
*/
/****************************************************************************
** Copyright (C) 2002-2004 Klarälvdalens Datakonsult AB. All rights reserved.
**
** This file is part of the KDGantt library.
**
** This file may be distributed and/or modified under the terms of the
** GNU General Public License version 2 as published by the Free Software
** Foundation and appearing in the file LICENSE.GPL included in the
** packaging of this file.
**
** Licensees holding valid commercial KDGantt licenses may use this file in
** accordance with the KDGantt Commercial License Agreement provided with
** the Software.
**
** This file is provided AS IS with NO WARRANTY OF ANY KIND, INCLUDING THE
** WARRANTY OF DESIGN, MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE.
**
** See http://www.klaralvdalens-datakonsult.se/Public/products/ for
** information about KDGantt Commercial License Agreements.
**
** Contact info@klaralvdalens-datakonsult.se if any conditions of this
** licensing are not clear to you.
**
** As a special exception, permission is given to link this program
** with any edition of TQt, and distribute the resulting executable,
** without including the source code for TQt in the source distribution.
**
**********************************************************************/
#include "KDGanttMinimizeSplitter.h"
#ifndef TQT_NO_SPLITTER
#include "tqpainter.h"
#include "tqdrawutil.h"
#include "tqbitmap.h"
#include "tqptrlist.h"
#include "tqmemarray.h"
#include "tqlayout.h"
#include "tqlayoutengine_p.h"
#include "tqobjectlist.h"
#include "tqstyle.h"
#include "tqapplication.h" //sendPostedEvents
#include <tqvaluelist.h>
#include <tqcursor.h>
#include "KDGanttMinimizeSplitter.moc"
#ifndef DOXYGEN_SKIP_INTERNAL
static int mouseOffset;
static int opaqueOldPos = -1; //### there's only one mouse, but this is a bit risky
KDGanttSplitterHandle::KDGanttSplitterHandle( TQt::Orientation o,
KDGanttMinimizeSplitter *parent, const char * name )
: TQWidget( parent, name ), _activeButton( 0 ), _collapsed( false )
{
s = parent;
setOrientation(o);
setMouseTracking( true );
}
TQSize KDGanttSplitterHandle::sizeHint() const
{
return TQSize(8,8);
}
void KDGanttSplitterHandle::setOrientation( TQt::Orientation o )
{
orient = o;
#ifndef TQT_NO_CURSOR
if ( o == TQt::Horizontal )
setCursor( splitHCursor );
else
setCursor( splitVCursor );
#endif
}
void KDGanttSplitterHandle::mouseMoveEvent( TQMouseEvent *e )
{
updateCursor( e->pos() );
if ( !(e->state()&TQt::LeftButton) )
return;
if ( _activeButton != 0)
return;
TQCOORD pos = s->pick(parentWidget()->mapFromGlobal(e->globalPos()))
- mouseOffset;
if ( opaque() ) {
s->moveSplitter( pos, id() );
} else {
int min = pos; int max = pos;
s->getRange( id(), &min, &max );
s->setRubberband( TQMAX( min, TQMIN(max, pos )));
}
_collapsed = false;
}
void KDGanttSplitterHandle::mousePressEvent( TQMouseEvent *e )
{
if ( e->button() == TQt::LeftButton ) {
_activeButton = onButton( e->pos() );
mouseOffset = s->pick(e->pos());
if ( _activeButton != 0)
repaint();
updateCursor( e->pos() );
}
}
void KDGanttSplitterHandle::updateCursor( const TQPoint& p)
{
if ( onButton( p ) != 0 ) {
setCursor( arrowCursor );
}
else {
if ( orient == TQt::Horizontal )
setCursor( splitHCursor );
else
setCursor( splitVCursor );
}
}
void KDGanttSplitterHandle::mouseReleaseEvent( TQMouseEvent *e )
{
if ( _activeButton != 0 ) {
if ( onButton( e->pos() ) == _activeButton )
{
int pos;
int min, max;
if ( !_collapsed ) {
s->expandPos( id(), &min, &max );
if ( s->minimizeDirection() == KDGanttMinimizeSplitter::Left
|| s->minimizeDirection() == KDGanttMinimizeSplitter::Up ) {
pos = min;
}
else {
pos = max;
}
_origPos = s->pick(mapToParent( TQPoint( 0,0 ) ));
s->moveSplitter( pos, id() );
_collapsed = true;
}
else {
s->moveSplitter( _origPos, id() );
_collapsed = false;
}
}
_activeButton = 0;
updateCursor( e->pos() );
}
else {
if ( !opaque() && e->button() == TQt::LeftButton ) {
TQCOORD pos = s->pick(parentWidget()->mapFromGlobal(e->globalPos()))
- mouseOffset;
s->setRubberband( -1 );
s->moveSplitter( pos, id() );
}
}
repaint();
}
int KDGanttSplitterHandle::onButton( const TQPoint& p )
{
TQValueList<TQPointArray> list = buttonRegions();
int index = 1;
for( TQValueList<TQPointArray>::Iterator it = list.begin(); it != list.end(); ++it ) {
TQRect rect = (*it).boundingRect();
rect.setLeft( rect.left()- 4 );
rect.setRight( rect.right() + 4);
rect.setTop( rect.top()- 4 );
rect.setBottom( rect.bottom() + 4);
if ( rect.contains( p ) ) {
return index;
}
index++;
}
return 0;
}
TQValueList<TQPointArray> KDGanttSplitterHandle::buttonRegions()
{
TQValueList<TQPointArray> list;
int sw = 8;
int voffset[] = { (int) -sw*3, (int) sw*3 };
for ( int i = 0; i < 2; i++ ) {
TQPointArray arr;
if ( !_collapsed && s->minimizeDirection() == KDGanttMinimizeSplitter::Right ||
_collapsed && s->minimizeDirection() == KDGanttMinimizeSplitter::Left) {
int mid = height()/2 + voffset[i];
arr.setPoints( 3,
1, mid - sw + 4,
sw-3, mid,
1, mid + sw -4);
}
else if ( !_collapsed && s->minimizeDirection() == KDGanttMinimizeSplitter::Left ||
_collapsed && s->minimizeDirection() == KDGanttMinimizeSplitter::Right ) {
int mid = height()/2 + voffset[i];
arr.setPoints( 3,
sw-4, mid - sw + 4,
0, mid,
sw-4, mid + sw - 4);
}
else if ( !_collapsed && s->minimizeDirection() == KDGanttMinimizeSplitter::Up ||
_collapsed && s->minimizeDirection() == KDGanttMinimizeSplitter::Down) {
int mid = width()/2 + voffset[i];
arr.setPoints( 3,
mid - sw + 4, sw-4,
mid, 0,
mid + sw - 4, sw-4 );
}
else if ( !_collapsed && s->minimizeDirection() == KDGanttMinimizeSplitter::Down ||
_collapsed && s->minimizeDirection() == KDGanttMinimizeSplitter::Up ) {
int mid = width()/2 + voffset[i];
arr.setPoints( 3,
mid - sw + 4, 1,
mid, sw-3,
mid + sw -4, 1);
}
list.append( arr );
}
return list;
}
void KDGanttSplitterHandle::paintEvent( TQPaintEvent * )
{
TQPixmap buffer( size() );
TQPainter p( &buffer );
// Draw the splitter rectangle
p.setBrush( colorGroup().background() );
p.setPen( colorGroup().foreground() );
p.drawRect( rect() );
parentWidget()->style().drawPrimitive( TQStyle::PE_Panel, &p, rect(),
parentWidget()->colorGroup());
int sw = 8; // Hardcoded, given I didn't use styles anymore, I didn't like to use their size
// arrow color
TQColor col = colorGroup().background().dark( 200 );
p.setBrush( col );
p.setPen( col );
TQValueList<TQPointArray> list = buttonRegions();
int index = 1;
for ( TQValueList<TQPointArray>::Iterator it = list.begin(); it != list.end(); ++it ) {
if ( index == _activeButton ) {
p.save();
p.translate( parentWidget()->style().pixelMetric( TQStyle::PM_ButtonShiftHorizontal ),
parentWidget()->style().pixelMetric( TQStyle::PM_ButtonShiftVertical ) );
p.drawPolygon( *it, true );
p.restore();
}
else {
p.drawPolygon( *it, true );
}
index++;
}
// Draw the lines between the arrows
if ( s->minimizeDirection() == KDGanttMinimizeSplitter::Left ||
s->minimizeDirection() == KDGanttMinimizeSplitter::Right ) {
int mid = height()/2;
p.drawLine ( 2, mid - sw, 2, mid + sw );
p.drawLine ( 4, mid - sw, 4, mid + sw );
}
else if ( s->minimizeDirection() == KDGanttMinimizeSplitter::Up ||
s->minimizeDirection() == KDGanttMinimizeSplitter::Down ) {
int mid = width()/2;
p.drawLine( mid -sw, 2, mid +sw, 2 );
p.drawLine( mid -sw, 4, mid +sw, 4 );
}
bitBlt( this, 0, 0, &buffer );
}
class TQSplitterLayoutStruct
{
public:
KDGanttMinimizeSplitter::ResizeMode mode;
TQCOORD sizer;
bool isSplitter;
TQWidget *wid;
};
class TQSplitterData
{
public:
TQSplitterData() : opaque( FALSE ), firstShow( TRUE ) {}
TQPtrList<TQSplitterLayoutStruct> list;
bool opaque;
bool firstShow;
};
void kdganttGeomCalc( TQMemArray<TQLayoutStruct> &chain, int start, int count, int pos,
int space, int spacer );
#endif // DOXYGEN_SKIP_INTERNAL
/*!
\class KDGanttMinimizeSplitter KDGanttMinimizeSplitter.h
\brief The KDGanttMinimizeSplitter class implements a splitter
widget with minimize buttons.
This class (and its documentation) is largely a copy of TQt's
TQSplitter; the copying was necessary because TQSplitter is not
extensible at all. TQSplitter and its documentation are licensed
according to the GPL and the TQt Professional License (if you hold
such a license) and are (C) Trolltech AS.
A splitter lets the user control the size of child widgets by
dragging the boundary between the children. Any number of widgets
may be controlled.
To show a TQListBox, a TQListView and a TQTextEdit side by side:
\code
KDGanttMinimizeSplitter *split = new KDGanttMinimizeSplitter( parent );
TQListBox *lb = new TQListBox( split );
TQListView *lv = new TQListView( split );
TQTextEdit *ed = new TQTextEdit( split );
\endcode
In KDGanttMinimizeSplitter, the boundary can be either horizontal or
vertical. The default is horizontal (the children are side by side)
but you can use setOrientation( TQSplitter::Vertical ) to set it to
vertical.
Use setResizeMode() to specify
that a widget should keep its size when the splitter is resized.
Although KDGanttMinimizeSplitter normally resizes the children only
at the end of a resize operation, if you call setOpaqueResize( TRUE
) the widgets are resized as often as possible.
The initial distribution of size between the widgets is determined
by the initial size of each widget. You can also use setSizes() to
set the sizes of all the widgets. The function sizes() returns the
sizes set by the user.
If you hide() a child, its space will be distributed among the other
children. It will be reinstated when you show() it again. It is also
possible to reorder the widgets within the splitter using
moveToFirst() and moveToLast().
*/
static TQSize minSize( const TQWidget* /*w*/ )
{
return TQSize(0,0);
}
// This is the original version of minSize
static TQSize minSizeHint( const TQWidget* w )
{
TQSize min = w->minimumSize();
TQSize s;
if ( min.height() <= 0 || min.width() <= 0 )
s = w->minimumSizeHint();
if ( min.height() > 0 )
s.setHeight( min.height() );
if ( min.width() > 0 )
s.setWidth( min.width() );
return s.expandedTo(TQSize(0,0));
}
/*!
Constructs a horizontal splitter with the \a parent and \a
name arguments being passed on to the TQFrame constructor.
*/
KDGanttMinimizeSplitter::KDGanttMinimizeSplitter( TQWidget *parent, const char *name )
:TQFrame(parent,name,WPaintUnclipped)
{
orient = TQt::Horizontal;
init();
}
/*!
Constructs a splitter with orientation \a o with the \a parent
and \a name arguments being passed on to the TQFrame constructor.
*/
KDGanttMinimizeSplitter::KDGanttMinimizeSplitter( TQt::Orientation o, TQWidget *parent, const char *name )
:TQFrame(parent,name,WPaintUnclipped)
{
orient = o;
init();
}
/*!
Destroys the splitter and any children.
*/
KDGanttMinimizeSplitter::~KDGanttMinimizeSplitter()
{
data->list.setAutoDelete( TRUE );
delete data;
}
void KDGanttMinimizeSplitter::init()
{
data = new TQSplitterData;
if ( orient == TQt::Horizontal )
setSizePolicy( TQSizePolicy(TQSizePolicy::Expanding,TQSizePolicy::Minimum) );
else
setSizePolicy( TQSizePolicy(TQSizePolicy::Minimum,TQSizePolicy::Expanding) );
}
/*!
\brief the orientation of the splitter
By default the orientation is horizontal (the widgets are side by side).
The possible orientations are TQt:Vertical and TQt::Horizontal (the default).
*/
void KDGanttMinimizeSplitter::setOrientation( TQt::Orientation o )
{
if ( orient == o )
return;
orient = o;
if ( orient == TQt::Horizontal )
setSizePolicy( TQSizePolicy( TQSizePolicy::Expanding, TQSizePolicy::Minimum ) );
else
setSizePolicy( TQSizePolicy( TQSizePolicy::Minimum, TQSizePolicy::Expanding ) );
TQSplitterLayoutStruct *s = data->list.first();
while ( s ) {
if ( s->isSplitter )
((KDGanttSplitterHandle*)s->wid)->setOrientation( o );
s = data->list.next(); // ### next at end of loop, no iterator
}
recalc( isVisible() );
}
/*!
Reimplemented from superclass.
*/
void KDGanttMinimizeSplitter::resizeEvent( TQResizeEvent * )
{
doResize();
}
/*
Inserts the widget \a w at the end (or at the beginning if \a first
is TRUE) of the splitter's list of widgets.
It is the responsibility of the caller of this function to make sure
that \a w is not already in the splitter and to call recalcId if
needed. (If \a first is TRUE, then recalcId is very probably
needed.)
*/
TQSplitterLayoutStruct *KDGanttMinimizeSplitter::addWidget( TQWidget *w, bool first )
{
TQSplitterLayoutStruct *s;
KDGanttSplitterHandle *newHandle = 0;
if ( data->list.count() > 0 ) {
s = new TQSplitterLayoutStruct;
s->mode = KeepSize;
TQString tmp = "qt_splithandle_";
tmp += w->name();
newHandle = new KDGanttSplitterHandle( orientation(), this, tmp.latin1() );
s->wid = newHandle;
newHandle->setId(data->list.count());
s->isSplitter = TRUE;
s->sizer = pick( newHandle->sizeHint() );
if ( first )
data->list.insert( 0, s );
else
data->list.append( s );
}
s = new TQSplitterLayoutStruct;
s->mode = Stretch;
s->wid = w;
if ( !testWState( WState_Resized ) && w->sizeHint().isValid() )
s->sizer = pick( w->sizeHint() );
else
s->sizer = pick( w->size() );
s->isSplitter = FALSE;
if ( first )
data->list.insert( 0, s );
else
data->list.append( s );
if ( newHandle && isVisible() )
newHandle->show(); //will trigger sending of post events
return s;
}
/*!
Tells the splitter that a child widget has been inserted or removed.
The event is passed in \a c.
*/
void KDGanttMinimizeSplitter::childEvent( TQChildEvent *c )
{
if ( c->type() == TQEvent::ChildInserted ) {
if ( !c->child()->isWidgetType() )
return;
if ( ((TQWidget*)c->child())->testWFlags( WType_TopLevel ) )
return;
TQSplitterLayoutStruct *s = data->list.first();
while ( s ) {
if ( s->wid == c->child() )
return;
s = data->list.next();
}
addWidget( (TQWidget*)c->child() );
recalc( isVisible() );
} else if ( c->type() == TQEvent::ChildRemoved ) {
TQSplitterLayoutStruct *p = 0;
if ( data->list.count() > 1 )
p = data->list.at(1); //remove handle _after_ first widget.
TQSplitterLayoutStruct *s = data->list.first();
while ( s ) {
if ( s->wid == c->child() ) {
data->list.removeRef( s );
delete s;
if ( p && p->isSplitter ) {
data->list.removeRef( p );
delete p->wid; //will call childEvent
delete p;
}
recalcId();
doResize();
return;
}
p = s;
s = data->list.next();
}
}
}
/*!
Shows a rubber band at position \a p. If \a p is negative, the
rubber band is removed.
*/
void KDGanttMinimizeSplitter::setRubberband( int p )
{
TQPainter paint( this );
paint.setPen( gray );
paint.setBrush( gray );
paint.setRasterOp( XorROP );
TQRect r = contentsRect();
const int rBord = 3; //Themable????
int sw = style().pixelMetric(TQStyle::PM_SplitterWidth, this);
if ( orient == TQt::Horizontal ) {
if ( opaqueOldPos >= 0 )
paint.drawRect( opaqueOldPos + sw/2 - rBord , r.y(),
2*rBord, r.height() );
if ( p >= 0 )
paint.drawRect( p + sw/2 - rBord, r.y(), 2*rBord, r.height() );
} else {
if ( opaqueOldPos >= 0 )
paint.drawRect( r.x(), opaqueOldPos + sw/2 - rBord,
r.width(), 2*rBord );
if ( p >= 0 )
paint.drawRect( r.x(), p + sw/2 - rBord, r.width(), 2*rBord );
}
opaqueOldPos = p;
}
/*! Reimplemented from superclass. */
bool KDGanttMinimizeSplitter::event( TQEvent *e )
{
if ( e->type() == TQEvent::LayoutHint || ( e->type() == TQEvent::Show && data->firstShow ) ) {
recalc( isVisible() );
if ( e->type() == TQEvent::Show )
data->firstShow = FALSE;
}
return TQWidget::event( e );
}
/*!
\obsolete
Draws the splitter handle in the rectangle described by \a x, \a y,
\a w, \a h using painter \a p.
\sa TQStyle::drawPrimitive()
*/
void KDGanttMinimizeSplitter::drawSplitter( TQPainter *p,
TQCOORD x, TQCOORD y, TQCOORD w, TQCOORD h )
{
style().drawPrimitive(TQStyle::PE_Splitter, p, TQRect(x, y, w, h), colorGroup(),
(orientation() == TQt::Horizontal ?
TQStyle::Style_Horizontal : 0));
}
/*!
Returns the id of the splitter to the right of or below the widget \a w,
or 0 if there is no such splitter
(i.e. it is either not in this KDGanttMinimizeSplitter or it is at the end).
*/
int KDGanttMinimizeSplitter::idAfter( TQWidget* w ) const
{
TQSplitterLayoutStruct *s = data->list.first();
bool seen_w = FALSE;
while ( s ) {
if ( s->isSplitter && seen_w )
return data->list.at();
if ( !s->isSplitter && s->wid == w )
seen_w = TRUE;
s = data->list.next();
}
return 0;
}
/*!
Moves the left/top edge of the splitter handle with id \a id as
close as possible to position \a p, which is the distance from the
left (or top) edge of the widget.
For Arabic and Hebrew the layout is reversed, and using this
function to set the position of the splitter might lead to
unexpected results, since in Arabic and Hebrew the position of
splitter one is to the left of the position of splitter zero.
\sa idAfter()
*/
void KDGanttMinimizeSplitter::moveSplitter( TQCOORD p, int id )
{
p = adjustPos( p, id );
TQSplitterLayoutStruct *s = data->list.at(id);
int oldP = orient == TQt::Horizontal ? s->wid->x() : s->wid->y();
bool upLeft;
if ( TQApplication::reverseLayout() && orient == TQt::Horizontal ) {
p += s->wid->width();
upLeft = p > oldP;
} else
upLeft = p < oldP;
moveAfter( p, id, upLeft );
moveBefore( p-1, id-1, upLeft );
storeSizes();
}
void KDGanttMinimizeSplitter::setG( TQWidget *w, int p, int s, bool isSplitter )
{
if ( orient == TQt::Horizontal ) {
if ( TQApplication::reverseLayout() && orient == TQt::Horizontal && !isSplitter )
p = contentsRect().width() - p - s;
w->setGeometry( p, contentsRect().y(), s, contentsRect().height() );
} else
w->setGeometry( contentsRect().x(), p, contentsRect().width(), s );
}
/*
Places the right/bottom edge of the widget at \a id at position \a pos.
\sa idAfter()
*/
void KDGanttMinimizeSplitter::moveBefore( int pos, int id, bool upLeft )
{
if( id < 0 )
return;
TQSplitterLayoutStruct *s = data->list.at(id);
if ( !s )
return;
TQWidget *w = s->wid;
if ( w->isHidden() ) {
moveBefore( pos, id-1, upLeft );
} else if ( s->isSplitter ) {
int pos1, pos2;
int dd = s->sizer;
if( TQApplication::reverseLayout() && orient == TQt::Horizontal ) {
pos1 = pos;
pos2 = pos + dd;
} else {
pos2 = pos - dd;
pos1 = pos2 + 1;
}
if ( upLeft ) {
setG( w, pos1, dd, TRUE );
moveBefore( pos2, id-1, upLeft );
} else {
moveBefore( pos2, id-1, upLeft );
setG( w, pos1, dd, TRUE );
}
} else {
int dd, newLeft, nextPos;
if( TQApplication::reverseLayout() && orient == TQt::Horizontal ) {
dd = w->geometry().right() - pos;
dd = TQMAX( pick(minSize(w)), TQMIN(dd, pick(w->maximumSize())));
newLeft = pos+1;
nextPos = newLeft + dd;
} else {
dd = pos - pick( w->pos() ) + 1;
dd = TQMAX( pick(minSize(w)), TQMIN(dd, pick(w->maximumSize())));
newLeft = pos-dd+1;
nextPos = newLeft - 1;
}
setG( w, newLeft, dd, TRUE );
moveBefore( nextPos, id-1, upLeft );
}
}
/*
Places the left/top edge of the widget at \a id at position \a pos.
\sa idAfter()
*/
void KDGanttMinimizeSplitter::moveAfter( int pos, int id, bool upLeft )
{
TQSplitterLayoutStruct *s = id < int(data->list.count()) ?
data->list.at(id) : 0;
if ( !s )
return;
TQWidget *w = s->wid;
if ( w->isHidden() ) {
moveAfter( pos, id+1, upLeft );
} else if ( pick( w->pos() ) == pos ) {
//No need to do anything if it's already there.
return;
} else if ( s->isSplitter ) {
int dd = s->sizer;
int pos1, pos2;
if( TQApplication::reverseLayout() && orient == TQt::Horizontal ) {
pos2 = pos - dd;
pos1 = pos2 + 1;
} else {
pos1 = pos;
pos2 = pos + dd;
}
if ( upLeft ) {
setG( w, pos1, dd, TRUE );
moveAfter( pos2, id+1, upLeft );
} else {
moveAfter( pos2, id+1, upLeft );
setG( w, pos1, dd, TRUE );
}
} else {
int left = pick( w->pos() );
int right, dd,/* newRight,*/ newLeft, nextPos;
if ( TQApplication::reverseLayout() && orient == TQt::Horizontal ) {
dd = pos - left + 1;
dd = TQMAX( pick(minSize(w)), TQMIN(dd, pick(w->maximumSize())));
newLeft = pos-dd+1;
nextPos = newLeft - 1;
} else {
right = pick( w->geometry().bottomRight() );
dd = right - pos + 1;
dd = TQMAX( pick(minSize(w)), TQMIN(dd, pick(w->maximumSize())));
/*newRight = pos+dd-1;*/
newLeft = pos;
nextPos = newLeft + dd;
}
setG( w, newLeft, dd, TRUE );
/*if( right != newRight )*/
moveAfter( nextPos, id+1, upLeft );
}
}
void KDGanttMinimizeSplitter::expandPos( int id, int* min, int* max )
{
TQSplitterLayoutStruct *s = data->list.at(id-1);
TQWidget* w = s->wid;
*min = pick( w->mapToParent( TQPoint(0,0) ) );
if ( (uint) id == data->list.count() ) {
pick( size() );
}
else {
TQSplitterLayoutStruct *s = data->list.at(id+1);
TQWidget* w = s->wid;
*max = pick( w->mapToParent( TQPoint( w->width(), w->height() ) ) ) -8;
}
}
/*!
Returns the valid range of the splitter with id \a id in \a *min and \a *max.
\sa idAfter()
*/
void KDGanttMinimizeSplitter::getRange( int id, int *min, int *max )
{
int minB = 0; //before
int maxB = 0;
int minA = 0;
int maxA = 0; //after
int n = data->list.count();
if ( id < 0 || id >= n )
return;
int i;
for ( i = 0; i < id; i++ ) {
TQSplitterLayoutStruct *s = data->list.at(i);
if ( s->wid->isHidden() ) {
//ignore
} else if ( s->isSplitter ) {
minB += s->sizer;
maxB += s->sizer;
} else {
minB += pick( minSize(s->wid) );
maxB += pick( s->wid->maximumSize() );
}
}
for ( i = id; i < n; i++ ) {
TQSplitterLayoutStruct *s = data->list.at(i);
if ( s->wid->isHidden() ) {
//ignore
} else if ( s->isSplitter ) {
minA += s->sizer;
maxA += s->sizer;
} else {
minA += pick( minSize(s->wid) );
maxA += pick( s->wid->maximumSize() );
}
}
TQRect r = contentsRect();
if ( orient == TQt::Horizontal && TQApplication::reverseLayout() ) {
int splitterWidth = style().pixelMetric(TQStyle::PM_SplitterWidth, this);
if ( min )
*min = pick(r.topRight()) - TQMIN( maxB, pick(r.size())-minA ) - splitterWidth;
if ( max )
*max = pick(r.topRight()) - TQMAX( minB, pick(r.size())-maxA ) - splitterWidth;
} else {
if ( min )
*min = pick(r.topLeft()) + TQMAX( minB, pick(r.size())-maxA );
if ( max )
*max = pick(r.topLeft()) + TQMIN( maxB, pick(r.size())-minA );
}
}
/*!
Returns the closest legal position to \a p of the splitter with id \a id.
\sa idAfter()
*/
int KDGanttMinimizeSplitter::adjustPos( int p, int id )
{
int min = 0;
int max = 0;
getRange( id, &min, &max );
p = TQMAX( min, TQMIN( p, max ) );
return p;
}
void KDGanttMinimizeSplitter::doResize()
{
TQRect r = contentsRect();
int i;
int n = data->list.count();
TQMemArray<TQLayoutStruct> a( n );
for ( i = 0; i< n; i++ ) {
a[i].init();
TQSplitterLayoutStruct *s = data->list.at(i);
if ( s->wid->isHidden() ) {
a[i].stretch = 0;
a[i].sizeHint = a[i].minimumSize = 0;
a[i].maximumSize = 0;
} else if ( s->isSplitter ) {
a[i].stretch = 0;
a[i].sizeHint = a[i].minimumSize = a[i].maximumSize = s->sizer;
a[i].empty = FALSE;
} else if ( s->mode == KeepSize ) {
a[i].stretch = 0;
a[i].minimumSize = pick( minSize(s->wid) );
a[i].sizeHint = s->sizer;
a[i].maximumSize = pick( s->wid->maximumSize() );
a[i].empty = FALSE;
} else if ( s->mode == FollowSizeHint ) {
a[i].stretch = 0;
a[i].minimumSize = a[i].sizeHint = pick( s->wid->sizeHint() );
a[i].maximumSize = pick( s->wid->maximumSize() );
a[i].empty = FALSE;
} else { //proportional
a[i].stretch = s->sizer;
a[i].maximumSize = pick( s->wid->maximumSize() );
a[i].sizeHint = a[i].minimumSize = pick( minSize(s->wid) );
a[i].empty = FALSE;
}
}
kdganttGeomCalc( a, 0, n, pick( r.topLeft() ), pick( r.size() ), 0 );
for ( i = 0; i< n; i++ ) {
TQSplitterLayoutStruct *s = data->list.at(i);
setG( s->wid, a[i].pos, a[i].size );
}
}
void KDGanttMinimizeSplitter::recalc( bool update )
{
int fi = 2*frameWidth();
int maxl = fi;
int minl = fi;
int maxt = TQWIDGETSIZE_MAX;
int mint = fi;
int n = data->list.count();
bool first = TRUE;
/*
The splitter before a hidden widget is always hidden.
The splitter before the first visible widget is hidden.
The splitter before any other visible widget is visible.
*/
for ( int i = 0; i< n; i++ ) {
TQSplitterLayoutStruct *s = data->list.at(i);
if ( !s->isSplitter ) {
TQSplitterLayoutStruct *p = (i > 0) ? data->list.at( i-1 ) : 0;
if ( p && p->isSplitter )
if ( first || s->wid->isHidden() )
p->wid->hide(); //may trigger new recalc
else
p->wid->show(); //may trigger new recalc
if ( !s->wid->isHidden() )
first = FALSE;
}
}
bool empty=TRUE;
for ( int j = 0; j< n; j++ ) {
TQSplitterLayoutStruct *s = data->list.at(j);
if ( !s->wid->isHidden() ) {
empty = FALSE;
if ( s->isSplitter ) {
minl += s->sizer;
maxl += s->sizer;
} else {
TQSize minS = minSize(s->wid);
minl += pick( minS );
maxl += pick( s->wid->maximumSize() );
mint = TQMAX( mint, trans( minS ));
int tm = trans( s->wid->maximumSize() );
if ( tm > 0 )
maxt = TQMIN( maxt, tm );
}
}
}
if ( empty ) {
if ( parentWidget() != 0 && parentWidget()->inherits("KDGanttMinimizeSplitter") ) {
// nested splitters; be nice
maxl = maxt = 0;
} else {
// KDGanttMinimizeSplitter with no children yet
maxl = TQWIDGETSIZE_MAX;
}
} else {
maxl = TQMIN( maxl, TQWIDGETSIZE_MAX );
}
if ( maxt < mint )
maxt = mint;
if ( orient == TQt::Horizontal ) {
setMaximumSize( maxl, maxt );
setMinimumSize( minl, mint );
} else {
setMaximumSize( maxt, maxl );
setMinimumSize( mint, minl );
}
if ( update )
doResize();
}
/*!
Sets resize mode of \a w to \a mode.
\sa ResizeMode
*/
void KDGanttMinimizeSplitter::setResizeMode( TQWidget *w, ResizeMode mode )
{
processChildEvents();
TQSplitterLayoutStruct *s = data->list.first();
while ( s ) {
if ( s->wid == w ) {
s->mode = mode;
return;
}
s = data->list.next();
}
s = addWidget( w, TRUE );
s->mode = mode;
}
/*!
Returns TRUE if opaque resize is on; otherwise returns FALSE.
\sa setOpaqueResize()
*/
bool KDGanttMinimizeSplitter::opaqueResize() const
{
return data->opaque;
}
/*!
If \a on is TRUE then opaque resizing is turned on; otherwise
opaque resizing is turned off.
Opaque resizing is initially turned off.
\sa opaqueResize()
*/
void KDGanttMinimizeSplitter::setOpaqueResize( bool on )
{
data->opaque = on;
}
/*!
Moves widget \a w to the leftmost/top position.
*/
void KDGanttMinimizeSplitter::moveToFirst( TQWidget *w )
{
processChildEvents();
bool found = FALSE;
TQSplitterLayoutStruct *s = data->list.first();
while ( s ) {
if ( s->wid == w ) {
found = TRUE;
TQSplitterLayoutStruct *p = data->list.prev();
if ( p ) { // not already at first place
data->list.take(); //take p
data->list.take(); // take s
data->list.insert( 0, p );
data->list.insert( 0, s );
}
break;
}
s = data->list.next();
}
if ( !found )
addWidget( w, TRUE );
recalcId();
}
/*!
Moves widget \a w to the rightmost/bottom position.
*/
void KDGanttMinimizeSplitter::moveToLast( TQWidget *w )
{
processChildEvents();
bool found = FALSE;
TQSplitterLayoutStruct *s = data->list.first();
while ( s ) {
if ( s->wid == w ) {
found = TRUE;
data->list.take(); // take s
TQSplitterLayoutStruct *p = data->list.current();
if ( p ) { // the splitter handle after s
data->list.take(); //take p
data->list.append( p );
}
data->list.append( s );
break;
}
s = data->list.next();
}
if ( !found )
addWidget( w);
recalcId();
}
void KDGanttMinimizeSplitter::recalcId()
{
int n = data->list.count();
for ( int i = 0; i < n; i++ ) {
TQSplitterLayoutStruct *s = data->list.at(i);
if ( s->isSplitter )
((KDGanttSplitterHandle*)s->wid)->setId(i);
}
}
/*! Reimplemented from superclass.
*/
TQSize KDGanttMinimizeSplitter::sizeHint() const
{
constPolish();
int l = 0;
int t = 0;
if ( !childrenListObject().isEmpty() ) {
const TQObjectList c = childrenListObject();
TQObjectListIt it( c );
TQObject * o;
while( (o=it.current()) != 0 ) {
++it;
if ( o->isWidgetType() &&
!((TQWidget*)o)->isHidden() ) {
TQSize s = ((TQWidget*)o)->sizeHint();
if ( s.isValid() ) {
l += pick( s );
t = TQMAX( t, trans( s ) );
}
}
}
}
return orientation() == TQt::Horizontal ? TQSize( l, t ) : TQSize( t, l );
}
/*!
\reimp
*/
TQSize KDGanttMinimizeSplitter::minimumSizeHint() const
{
constPolish();
int l = 0;
int t = 0;
if ( !childrenListObject().isEmpty() ) {
const TQObjectList c = childrenListObject();
TQObjectListIt it( c );
TQObject * o;
while( (o=it.current()) != 0 ) {
++it;
if ( o->isWidgetType() &&
!((TQWidget*)o)->isHidden() ) {
TQSize s = minSizeHint((TQWidget*)o);
if ( s.isValid() ) {
l += pick( s );
t = TQMAX( t, trans( s ) );
}
}
}
}
return orientation() == TQt::Horizontal ? TQSize( l, t ) : TQSize( t, l );
}
/*
Calculates stretch parameters from current sizes
*/
void KDGanttMinimizeSplitter::storeSizes()
{
TQSplitterLayoutStruct *s = data->list.first();
while ( s ) {
if ( !s->isSplitter )
s->sizer = pick( s->wid->size() );
s = data->list.next();
}
}
#if 0 // ### remove this code ASAP
/*!
Hides \a w if \a hide is TRUE and updates the splitter.
\warning Due to a limitation in the current implementation,
calling TQWidget::hide() will not work.
*/
void KDGanttMinimizeSplitter::setHidden( TQWidget *w, bool hide )
{
if ( w == w1 ) {
w1show = !hide;
} else if ( w == w2 ) {
w2show = !hide;
} else {
#ifdef TQT_CHECK_RANGE
tqWarning( "KDGanttMinimizeSplitter::setHidden(), unknown widget" );
#endif
return;
}
if ( hide )
w->hide();
else
w->show();
recalc( TRUE );
}
/*!
Returns the hidden status of \a w
*/
bool KDGanttMinimizeSplitter::isHidden( TQWidget *w ) const
{
if ( w == w1 )
return !w1show;
else if ( w == w2 )
return !w2show;
#ifdef TQT_CHECK_RANGE
else
tqWarning( "KDGanttMinimizeSplitter::isHidden(), unknown widget" );
#endif
return FALSE;
}
#endif
/*!
Returns a list of the size parameters of all the widgets in this
splitter.
Giving the values to another splitter's setSizes() function will
produce a splitter with the same layout as this one.
Note that if you want to iterate over the list, you should
iterate over a copy, e.g.
\code
TQValueList<int> list = mySplitter.sizes();
TQValueList<int>::Iterator it = list.begin();
while( it != list.end() ) {
myProcessing( *it );
++it;
}
\endcode
\sa setSizes()
*/
TQValueList<int> KDGanttMinimizeSplitter::sizes() const
{
if ( !testWState(WState_Polished) ) {
TQWidget* that = (TQWidget*) this;
that->polish();
}
TQValueList<int> list;
TQSplitterLayoutStruct *s = data->list.first();
while ( s ) {
if ( !s->isSplitter )
list.append( s->sizer );
s = data->list.next();
}
return list;
}
/*!
Sets the size parameters to the values given in \a list.
If the splitter is horizontal, the values set the sizes from
left to right. If it is vertical, the sizes are applied from
top to bottom.
Extra values in \a list are ignored.
If \a list contains too few values, the result is undefined
but the program will still be well-behaved.
\sa sizes()
*/
void KDGanttMinimizeSplitter::setSizes( TQValueList<int> list )
{
processChildEvents();
TQValueList<int>::Iterator it = list.begin();
TQSplitterLayoutStruct *s = data->list.first();
while ( s && it != list.end() ) {
if ( !s->isSplitter ) {
s->sizer = *it;
++it;
}
s = data->list.next();
}
doResize();
}
/*!
Gets all posted child events, ensuring that the internal state of
the splitter is consistent.
*/
void KDGanttMinimizeSplitter::processChildEvents()
{
TQApplication::sendPostedEvents( this, TQEvent::ChildInserted );
}
/*!
Reimplemented from superclass.
*/
void KDGanttMinimizeSplitter::styleChange( TQStyle& old )
{
int sw = style().pixelMetric(TQStyle::PM_SplitterWidth, this);
TQSplitterLayoutStruct *s = data->list.first();
while ( s ) {
if ( s->isSplitter )
s->sizer = sw;
s = data->list.next();
}
doResize();
TQFrame::styleChange( old );
}
/*!
Specifies the direction of the minimize buttons.
If the orientation of the splitter is horizontal then with
KDGanttMinimizeSplitter::Left or KDGanttMinimizeSplitter::Right should be used,
otherwise either KDGanttMinimizeSplitter::Up or KDGanttMinimizeSplitter::Down
should be used.
*/
void KDGanttMinimizeSplitter::setMinimizeDirection( Direction direction )
{
_direction = direction;
}
/*!
Returns the direction of the minimize buttons.
*/
KDGanttMinimizeSplitter::Direction KDGanttMinimizeSplitter::minimizeDirection() const
{
return _direction;
}
/*
This is a copy of qGeomCalc() in qlayoutengine.cpp which
unfortunately isn't exported.
*/
static inline int toFixed( int i ) { return i * 256; }
static inline int fRound( int i ) {
return ( i % 256 < 128 ) ? i / 256 : 1 + i / 256;
}
void kdganttGeomCalc( TQMemArray<TQLayoutStruct> &chain, int start, int count, int pos,
int space, int spacer )
{
typedef int fixed;
int cHint = 0;
int cMin = 0;
int cMax = 0;
int sumStretch = 0;
int spacerCount = 0;
bool wannaGrow = FALSE; // anyone who really wants to grow?
// bool canShrink = FALSE; // anyone who could be persuaded to shrink?
int i;
for ( i = start; i < start + count; i++ ) {
chain[i].done = FALSE;
cHint += chain[i].sizeHint;
cMin += chain[i].minimumSize;
cMax += chain[i].maximumSize;
sumStretch += chain[i].stretch;
if ( !chain[i].empty )
spacerCount++;
wannaGrow = wannaGrow || chain[i].expansive;
}
int extraspace = 0;
if ( spacerCount )
spacerCount--; // only spacers between things
if ( space < cMin + spacerCount * spacer ) {
// tqDebug("not enough space");
for ( i = start; i < start+count; i++ ) {
chain[i].size = chain[i].minimumSize;
chain[i].done = TRUE;
}
} else if ( space < cHint + spacerCount*spacer ) {
// Less space than sizeHint, but more than minimum.
// Currently take space equally from each, like in TQt 2.x.
// Commented-out lines will give more space to stretchier items.
int n = count;
int space_left = space - spacerCount*spacer;
int overdraft = cHint - space_left;
//first give to the fixed ones:
for ( i = start; i < start+count; i++ ) {
if ( !chain[i].done && chain[i].minimumSize >= chain[i].sizeHint) {
chain[i].size = chain[i].sizeHint;
chain[i].done = TRUE;
space_left -= chain[i].sizeHint;
// sumStretch -= chain[i].stretch;
n--;
}
}
bool finished = n == 0;
while ( !finished ) {
finished = TRUE;
fixed fp_over = toFixed( overdraft );
fixed fp_w = 0;
for ( i = start; i < start+count; i++ ) {
if ( chain[i].done )
continue;
// if ( sumStretch <= 0 )
fp_w += fp_over / n;
// else
// fp_w += (fp_over * chain[i].stretch) / sumStretch;
int w = fRound( fp_w );
chain[i].size = chain[i].sizeHint - w;
fp_w -= toFixed( w ); //give the difference to the next
if ( chain[i].size < chain[i].minimumSize ) {
chain[i].done = TRUE;
chain[i].size = chain[i].minimumSize;
finished = FALSE;
overdraft -= chain[i].sizeHint - chain[i].minimumSize;
// sumStretch -= chain[i].stretch;
n--;
break;
}
}
}
} else { //extra space
int n = count;
int space_left = space - spacerCount*spacer;
// first give to the fixed ones, and handle non-expansiveness
for ( i = start; i < start + count; i++ ) {
if ( !chain[i].done && (chain[i].maximumSize <= chain[i].sizeHint
|| wannaGrow && !chain[i].expansive) ) {
chain[i].size = chain[i].sizeHint;
chain[i].done = TRUE;
space_left -= chain[i].sizeHint;
sumStretch -= chain[i].stretch;
n--;
}
}
extraspace = space_left;
/*
Do a trial distribution and calculate how much it is off.
If there are more deficit pixels than surplus pixels, give
the minimum size items what they need, and repeat.
Otherwise give to the maximum size items, and repeat.
I have a wonderful mathematical proof for the correctness
of this principle, but unfortunately this comment is too
small to contain it.
*/
int surplus, deficit;
do {
surplus = deficit = 0;
fixed fp_space = toFixed( space_left );
fixed fp_w = 0;
for ( i = start; i < start+count; i++ ) {
if ( chain[i].done )
continue;
extraspace = 0;
if ( sumStretch <= 0 )
fp_w += fp_space / n;
else
fp_w += (fp_space * chain[i].stretch) / sumStretch;
int w = fRound( fp_w );
chain[i].size = w;
fp_w -= toFixed( w ); // give the difference to the next
if ( w < chain[i].sizeHint ) {
deficit += chain[i].sizeHint - w;
} else if ( w > chain[i].maximumSize ) {
surplus += w - chain[i].maximumSize;
}
}
if ( deficit > 0 && surplus <= deficit ) {
// give to the ones that have too little
for ( i = start; i < start+count; i++ ) {
if ( !chain[i].done &&
chain[i].size < chain[i].sizeHint ) {
chain[i].size = chain[i].sizeHint;
chain[i].done = TRUE;
space_left -= chain[i].sizeHint;
sumStretch -= chain[i].stretch;
n--;
}
}
}
if ( surplus > 0 && surplus >= deficit ) {
// take from the ones that have too much
for ( i = start; i < start+count; i++ ) {
if ( !chain[i].done &&
chain[i].size > chain[i].maximumSize ) {
chain[i].size = chain[i].maximumSize;
chain[i].done = TRUE;
space_left -= chain[i].maximumSize;
sumStretch -= chain[i].stretch;
n--;
}
}
}
} while ( n > 0 && surplus != deficit );
if ( n == 0 )
extraspace = space_left;
}
// as a last resort, we distribute the unwanted space equally
// among the spacers (counting the start and end of the chain).
//### should do a sub-pixel allocation of extra space
int extra = extraspace / ( spacerCount + 2 );
int p = pos + extra;
for ( i = start; i < start+count; i++ ) {
chain[i].pos = p;
p = p + chain[i].size;
if ( !chain[i].empty )
p += spacer+extra;
}
}
#endif
/*!
\enum KDGanttMinimizeSplitter::Direction
The values of this enumeration describe into which direction the
splitter will collapse its child widgets. By extension, it also
specifies the orientation of the splitter; collapsing to the left or
to the right results in a horizontal splitter, collapsing to the top
or bottom in a vertical splitter.
*/
/*!
\fn TQt::Orientation KDGanttMinimizeSplitter::orientation() const
Returns the orientation of the splitter.
*/
/*! \enum KDGanttMinimizeSplitter::ResizeMode
This enum type describes how KDGanttMinimizeSplitter will resize each of its child widgets. The currently defined values are:
Stretch: the widget will be resized when the splitter
itself is resized.
KeepSize: KDGanttMinimizeSplitter will try to keep this widget's size
unchanged.
FollowSizeHint: KDGanttMinimizeSplitter will resize the widget when the
widget's size hint changes.
*/