kwin/effects/cylinder.cpp

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/********************************************************************
KWin - the KDE window manager
This file is part of the KDE project.
Copyright (C) 2008 Martin Gräßlin <ubuntu@martin-graesslin.com>
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 2 of the License, or
(at your option) any later version.
This program 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 General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see <http://www.gnu.org/licenses/>.
*********************************************************************/
#include "cube.h"
#include "cylinder.h"
#include <kdebug.h>
#include <KStandardDirs>
#include <math.h>
#include <GL/gl.h>
namespace KWin
{
KWIN_EFFECT( cylinder, CylinderEffect )
KWIN_EFFECT_SUPPORTED( cylinder, CylinderEffect::supported() )
CylinderEffect::CylinderEffect()
: CubeEffect()
, mInited( false )
, mValid( true )
, mShader( 0 )
{
if( wallpaper )
wallpaper->discard();
loadConfig( "Cylinder" );
animateDesktopChange = false;
bigCube = true;
}
CylinderEffect::~CylinderEffect()
{
delete mShader;
}
bool CylinderEffect::supported()
{
return GLRenderTarget::supported() &&
GLShader::fragmentShaderSupported() &&
(effects->compositingType() == OpenGLCompositing);
}
bool CylinderEffect::loadData()
{
mInited = true;
QString fragmentshader = KGlobal::dirs()->findResource("data", "kwin/cylinder.frag");
QString vertexshader = KGlobal::dirs()->findResource("data", "kwin/cylinder.vert");
if(fragmentshader.isEmpty() || vertexshader.isEmpty())
{
kError() << "Couldn't locate shader files" << endl;
return false;
}
mShader = new GLShader(vertexshader, fragmentshader);
if(!mShader->isValid())
{
kError() << "The shader failed to load!" << endl;
return false;
}
else
{
mShader->bind();
mShader->setUniform( "winTexture", 0 );
mShader->setUniform( "opacity", cubeOpacity );
QRect rect = effects->clientArea( FullScreenArea, activeScreen, effects->currentDesktop());
if( effects->numScreens() > 1 && (slide || bigCube ) )
rect = effects->clientArea( FullArea, activeScreen, effects->currentDesktop() );
mShader->setUniform( "width", (float)rect.width() );
mShader->unbind();
}
return true;
}
void CylinderEffect::paintScene( int mask, QRegion region, ScreenPaintData& data )
{
glPushMatrix();
QRect rect = effects->clientArea( FullArea, activeScreen, effects->currentDesktop());
float cubeAngle = (effects->numberOfDesktops() - 2 )/(float)effects->numberOfDesktops() * 180.0f;
float radian = (cubeAngle*0.5)*M_PI/180;
// height of the triangle compound of one side of the cube and the two bisecting lines
float midpoint = rect.width()*0.5*tan(radian);
// radius of the circle
float radius = (rect.width()*0.5)/cos(radian);
glTranslatef( 0.0, 0.0, midpoint - radius );
CubeEffect::paintScene( mask, region, data );
glPopMatrix();
}
void CylinderEffect::prePaintWindow( EffectWindow* w, WindowPrePaintData& data, int time )
{
if( activated )
{
if( cube_painting )
{
if( w->isOnDesktop( painting_desktop ))
{
data.quads = data.quads.makeGrid( 40 );
QRect rect = effects->clientArea( FullArea, activeScreen, painting_desktop );
if( w->x() < rect.width()/2 && w->x() + w->width() > rect.width()/ 2 )
data.quads = data.quads.splitAtX( rect.width()/2 - w->x() );
w->enablePainting( EffectWindow::PAINT_DISABLED_BY_DESKTOP );
}
else
{
w->disablePainting( EffectWindow::PAINT_DISABLED_BY_DESKTOP );
}
}
}
effects->prePaintWindow( w, data, time );
}
void CylinderEffect::paintWindow( EffectWindow* w, int mask, QRegion region, WindowPaintData& data )
{
if( activated && cube_painting )
{
if( mValid && !mInited )
mValid = loadData();
bool useShader = mValid;
if( useShader )
{
mShader->bind();
mShader->setUniform( "windowWidth", (float)w->width() );
mShader->setUniform( "windowHeight", (float)w->height() );
mShader->setUniform( "xCoord", (float)w->x() );
mShader->setUniform( "cubeAngle", (effects->numberOfDesktops() - 2 )/(float)effects->numberOfDesktops() * 180.0f );
data.shader = mShader;
}
CubeEffect::paintWindow( w, mask, region, data );
if( useShader )
{
mShader->unbind();
}
}
else
effects->paintWindow( w, mask, region, data );
}
void CylinderEffect::desktopChanged( int old )
{
// cylinder effect is not useful to slide
}
void CylinderEffect::paintCap( float z, float zTexture )
{
if( ( !paintCaps ) || effects->numberOfDesktops() <= 2 )
return;
CubeEffect::paintCap( z, zTexture );
QRect rect = effects->clientArea( FullArea, activeScreen, painting_desktop );
float cubeAngle = (effects->numberOfDesktops() - 2 )/(float)effects->numberOfDesktops() * 180.0f;
float radian = (cubeAngle*0.5)*M_PI/180;
// height of the triangle compound of one side of the cube and the two bisecting lines
float midpoint = rect.width()*0.5*tan(radian);
// radius of the circle
float radius = (rect.width()*0.5)/cos(radian);
// paint round part of the cap
glPushMatrix();
float zTranslate = zPosition + zoom;
if( start )
zTranslate *= timeLine.value();
if( stop )
zTranslate *= ( 1.0 - timeLine.value() );
glTranslatef( 0.0, 0.0, -zTranslate );
float triangleWidth = 40.0;
for( int i=0; i<effects->numberOfDesktops(); i++ )
{
glPushMatrix();
glTranslatef( rect.width()/2, 0.0, -z );
glRotatef( i*(360.0f/effects->numberOfDesktops()), 0.0, 1.0, 0.0 );
glTranslatef( -rect.width()/2, 0.0, z );
glBegin( GL_TRIANGLE_STRIP );
for( int j=0; j<rect.width()/triangleWidth; j++ )
{
float zValue = 0.0;
// distance from midpoint of desktop to x coord
// calculation is same as in shader -> see comments
float distance = rect.width()*0.5 - (j*triangleWidth);
if( (j*triangleWidth) > rect.width()*0.5 )
{
distance = (j*triangleWidth) - rect.width()*0.5;
}
// distance in correct format
float angle = acos( distance/radius );
float h = radius;
// if distance == 0 -> angle=90 -> tan(90) singularity
if( distance != 0.0 )
h = tan( angle ) * distance;
zValue = h - midpoint;
glVertex3f( j*triangleWidth, 0.0, zValue );
glVertex3f( (j+1)*triangleWidth, 0.0, 0.0 );
}
glEnd();
glPopMatrix();
}
glPopMatrix();
}
} // namespace