kwin/effects/magiclamp/magiclamp.cpp
Martin Gräßlin 76efe517a7 Turn built-in effects into a library kwin links against
As all effects have always been compiled into the same .so file it's
questionable whether resolving the effects through a library is useful
at all. By linking against the built-in effects we gain the following
advantages:
* don't have to load/unload the KLibrary
* don't have to resolve the create, supported and enabled functions
* no version check required
* no dependency resolving (effects don't use it)
* remove the KWIN_EFFECT macros from the effects

All the effects are now registered in an effects_builtins file which
maps the name to a factory method and supported or enabled by default
methods.

During loading the effects we first check whether there is a built-in
effect by the given name and make a shortcut to create it through that.
If that's not possible the normal plugin loading is used.

Completely unscientific testing [1] showed an improvement of almost 10
msec during loading all the effects I use.

[1] QElapsedTimer around the loading code, start kwin five times, take
average.

REVIEW: 115073
2014-01-24 14:13:59 +01:00

378 lines
18 KiB
C++

/********************************************************************
KWin - the KDE window manager
This file is part of the KDE project.
Copyright (C) 2008 Martin Gräßlin <mgraesslin@kde.org>
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/>.
*********************************************************************/
// based on minimize animation by Rivo Laks <rivolaks@hot.ee>
#include "magiclamp.h"
// KConfigSkeleton
#include "magiclampconfig.h"
#include <kwinconfig.h>
#include <kconfiggroup.h>
#include <QTimeLine>
#include <QtDebug>
namespace KWin
{
MagicLampEffect::MagicLampEffect()
{
mActiveAnimations = 0;
reconfigure(ReconfigureAll);
connect(effects, SIGNAL(windowDeleted(KWin::EffectWindow*)), this, SLOT(slotWindowDeleted(KWin::EffectWindow*)));
connect(effects, SIGNAL(windowMinimized(KWin::EffectWindow*)), this, SLOT(slotWindowMinimized(KWin::EffectWindow*)));
connect(effects, SIGNAL(windowUnminimized(KWin::EffectWindow*)), this, SLOT(slotWindowUnminimized(KWin::EffectWindow*)));
}
bool MagicLampEffect::supported()
{
return effects->isOpenGLCompositing();
}
void MagicLampEffect::reconfigure(ReconfigureFlags)
{
MagicLampConfig::self()->readConfig();
// TODO: rename animationDuration to duration
mAnimationDuration = animationTime(MagicLampConfig::animationDuration() != 0 ? MagicLampConfig::animationDuration() : 250);
KConfigGroup conf = effects->effectConfig(QStringLiteral("MagicLamp"));
conf = effects->effectConfig(QStringLiteral("Shadow"));
int v = conf.readEntry("Size", 5);
v += conf.readEntry("Fuzzyness", 10);
mShadowOffset[0] = mShadowOffset[1] = -v;
mShadowOffset[2] = mShadowOffset[3] = v;
v = conf.readEntry("XOffset", 0);
mShadowOffset[0] -= v;
mShadowOffset[2] += v;
v = conf.readEntry("YOffset", 3);
mShadowOffset[1] -= v;
mShadowOffset[3] += v;
}
void MagicLampEffect::prePaintScreen(ScreenPrePaintData& data, int time)
{
QHash< EffectWindow*, QTimeLine* >::iterator entry = mTimeLineWindows.begin();
bool erase = false;
while (entry != mTimeLineWindows.end()) {
QTimeLine *timeline = entry.value();
if (entry.key()->isMinimized()) {
timeline->setCurrentTime(timeline->currentTime() + time);
erase = (timeline->currentValue() >= 1.0f);
} else {
timeline->setCurrentTime(timeline->currentTime() - time);
erase = (timeline->currentValue() <= 0.0f);
}
if (erase) {
delete timeline;
entry = mTimeLineWindows.erase(entry);
} else
++entry;
}
mActiveAnimations = mTimeLineWindows.count();
if (mActiveAnimations > 0)
// We need to mark the screen windows as transformed. Otherwise the
// whole screen won't be repainted, resulting in artefacts
data.mask |= PAINT_SCREEN_WITH_TRANSFORMED_WINDOWS;
effects->prePaintScreen(data, time);
}
void MagicLampEffect::prePaintWindow(EffectWindow* w, WindowPrePaintData& data, int time)
{
// Schedule window for transformation if the animation is still in
// progress
if (mTimeLineWindows.contains(w)) {
// We'll transform this window
data.setTransformed();
data.quads = data.quads.makeGrid(40);
w->enablePainting(EffectWindow::PAINT_DISABLED_BY_MINIMIZE);
}
effects->prePaintWindow(w, data, time);
}
void MagicLampEffect::paintWindow(EffectWindow* w, int mask, QRegion region, WindowPaintData& data)
{
if (mTimeLineWindows.contains(w)) {
// 0 = not minimized, 1 = fully minimized
float progress = mTimeLineWindows[w]->currentValue();
QRect geo = w->geometry();
QRect icon = w->iconGeometry();
IconPosition position = Top;
// If there's no icon geometry, minimize to the center of the screen
if (!icon.isValid()) {
QRect extG = geo.adjusted(mShadowOffset[0], mShadowOffset[1], mShadowOffset[2], mShadowOffset[3]);
QPoint pt = cursorPos();
// focussing inside the window is no good, leads to ugly artefacts, find nearest border
if (extG.contains(pt)) {
const int d[2][2] = { {pt.x() - extG.x(), extG.right() - pt.x()},
{pt.y() - extG.y(), extG.bottom() - pt.y()}
};
int di = d[1][0];
position = Top;
if (d[0][0] < di) {
di = d[0][0];
position = Left;
}
if (d[1][1] < di) {
di = d[1][1];
position = Bottom;
}
if (d[0][1] < di)
position = Right;
switch(position) {
case Top: pt.setY(extG.y()); break;
case Left: pt.setX(extG.x()); break;
case Bottom: pt.setY(extG.bottom()); break;
case Right: pt.setX(extG.right()); break;
}
} else {
if (pt.y() < geo.y())
position = Top;
else if (pt.x() < geo.x())
position = Left;
else if (pt.y() > geo.bottom())
position = Bottom;
else if (pt.x() > geo.right())
position = Right;
}
icon = QRect(pt, QSize(0, 0));
} else {
// Assumption: there is a panel containing the icon position
EffectWindow* panel = NULL;
foreach (EffectWindow * window, effects->stackingOrder()) {
if (!window->isDock())
continue;
// we have to use intersects as there seems to be a Plasma bug
// the published icon geometry might be bigger than the panel
if (window->geometry().intersects(icon)) {
panel = window;
break;
}
}
if (panel) {
// Assumption: width of horizonal panel is greater than its height and vice versa
// The panel has to border one screen edge, so get it's screen area
QRect panelScreen = effects->clientArea(ScreenArea, panel);
if (panel->width() >= panel->height()) {
// horizontal panel
if (panel->y() == panelScreen.y())
position = Top;
else
position = Bottom;
} else {
// vertical panel
if (panel->x() == panelScreen.x())
position = Left;
else
position = Right;
}
} else {
// we did not find a panel, so it might be autohidden
QRect iconScreen = effects->clientArea(ScreenArea, icon.topLeft(), effects->currentDesktop());
// as the icon geometry could be overlap a screen edge we use an intersection
QRect rect = iconScreen.intersected(icon);
// here we need a different assumption: icon geometry borders one screen edge
// this assumption might be wrong for e.g. task applet being the only applet in panel
// in this case the icon borders two screen edges
// there might be a wrong animation, but not distorted
if (rect.x() == iconScreen.x()) {
position = Left;
} else if (rect.x() + rect.width() == iconScreen.x() + iconScreen.width()) {
position = Right;
} else if (rect.y() == iconScreen.y()) {
position = Top;
} else {
position = Bottom;
}
}
}
#define SANITIZE_PROGRESS if (p_progress[0] < 0)\
p_progress[0] = -p_progress[0];\
if (p_progress[1] < 0)\
p_progress[1] = -p_progress[1]
#define SET_QUADS(_SET_A_, _A_, _DA_, _SET_B_, _B_, _O0_, _O1_, _O2_, _O3_) quad[0]._SET_A_((icon._A_() + icon._DA_()*(quad[0]._A_() / geo._DA_()) - (quad[0]._A_() + geo._A_()))*p_progress[_O0_] + quad[0]._A_());\
quad[1]._SET_A_((icon._A_() + icon._DA_()*(quad[1]._A_() / geo._DA_()) - (quad[1]._A_() + geo._A_()))*p_progress[_O1_] + quad[1]._A_());\
quad[2]._SET_A_((icon._A_() + icon._DA_()*(quad[2]._A_() / geo._DA_()) - (quad[2]._A_() + geo._A_()))*p_progress[_O2_] + quad[2]._A_());\
quad[3]._SET_A_((icon._A_() + icon._DA_()*(quad[3]._A_() / geo._DA_()) - (quad[3]._A_() + geo._A_()))*p_progress[_O3_] + quad[3]._A_());\
\
quad[0]._SET_B_(quad[0]._B_() + offset[_O0_]);\
quad[1]._SET_B_(quad[1]._B_() + offset[_O1_]);\
quad[2]._SET_B_(quad[2]._B_() + offset[_O2_]);\
quad[3]._SET_B_(quad[3]._B_() + offset[_O3_])
WindowQuadList newQuads;
float quadFactor; // defines how fast a quad is vertically moved: y coordinates near to window top are slowed down
// it is used as quadFactor^3/windowHeight^3
// quadFactor is the y position of the quad but is changed towards becomming the window height
// by that the factor becomes 1 and has no influence any more
float offset[2] = {0,0}; // how far has a quad to be moved? Distance between icon and window multiplied by the progress and by the quadFactor
float p_progress[2] = {0,0}; // the factor which defines how far the x values have to be changed
// factor is the current moved y value diveded by the distance between icon and window
WindowQuad lastQuad(WindowQuadError);
lastQuad[0].setX(-1);
lastQuad[0].setY(-1);
lastQuad[1].setX(-1);
lastQuad[1].setY(-1);
lastQuad[2].setX(-1);
lastQuad[2].setY(-1);
if (position == Bottom) {
float height_cube = float(geo.height()) * float(geo.height()) * float(geo.height());
foreach (WindowQuad quad, data.quads) { // krazy:exclude=foreach
if (quad[0].y() != lastQuad[0].y() || quad[2].y() != lastQuad[2].y()) {
quadFactor = quad[0].y() + (geo.height() - quad[0].y()) * progress;
offset[0] = (icon.y() + quad[0].y() - geo.y()) * progress * ((quadFactor * quadFactor * quadFactor) / height_cube);
quadFactor = quad[2].y() + (geo.height() - quad[2].y()) * progress;
offset[1] = (icon.y() + quad[2].y() - geo.y()) * progress * ((quadFactor * quadFactor * quadFactor) / height_cube);
p_progress[1] = qMin(offset[1] / (icon.y() + icon.height() - geo.y() - float(quad[2].y())), 1.0f);
p_progress[0] = qMin(offset[0] / (icon.y() + icon.height() - geo.y() - float(quad[0].y())), 1.0f);
} else
lastQuad = quad;
SANITIZE_PROGRESS;
// x values are moved towards the center of the icon
SET_QUADS(setX, x, width, setY, y, 0,0,1,1);
newQuads.append(quad);
}
} else if (position == Top) {
float height_cube = float(geo.height()) * float(geo.height()) * float(geo.height());
foreach (WindowQuad quad, data.quads) { // krazy:exclude=foreach
if (quad[0].y() != lastQuad[0].y() || quad[2].y() != lastQuad[2].y()) {
quadFactor = geo.height() - quad[0].y() + (quad[0].y()) * progress;
offset[0] = (geo.y() - icon.height() + geo.height() + quad[0].y() - icon.y()) * progress * ((quadFactor * quadFactor * quadFactor) / height_cube);
quadFactor = geo.height() - quad[2].y() + (quad[2].y()) * progress;
offset[1] = (geo.y() - icon.height() + geo.height() + quad[2].y() - icon.y()) * progress * ((quadFactor * quadFactor * quadFactor) / height_cube);
p_progress[0] = qMin(offset[0] / (geo.y() - icon.height() + geo.height() - icon.y() - float(geo.height() - quad[0].y())), 1.0f);
p_progress[1] = qMin(offset[1] / (geo.y() - icon.height() + geo.height() - icon.y() - float(geo.height() - quad[2].y())), 1.0f);
} else
lastQuad = quad;
offset[0] = -offset[0];
offset[1] = -offset[1];
SANITIZE_PROGRESS;
// x values are moved towards the center of the icon
SET_QUADS(setX, x, width, setY, y, 0,0,1,1);
newQuads.append(quad);
}
} else if (position == Left) {
float width_cube = float(geo.width()) * float(geo.width()) * float(geo.width());
foreach (WindowQuad quad, data.quads) { // krazy:exclude=foreach
if (quad[0].x() != lastQuad[0].x() || quad[1].x() != lastQuad[1].x()) {
quadFactor = geo.width() - quad[0].x() + (quad[0].x()) * progress;
offset[0] = (geo.x() - icon.width() + geo.width() + quad[0].x() - icon.x()) * progress * ((quadFactor * quadFactor * quadFactor) / width_cube);
quadFactor = geo.width() - quad[1].x() + (quad[1].x()) * progress;
offset[1] = (geo.x() - icon.width() + geo.width() + quad[1].x() - icon.x()) * progress * ((quadFactor * quadFactor * quadFactor) / width_cube);
p_progress[0] = qMin(offset[0] / (geo.x() - icon.width() + geo.width() - icon.x() - float(geo.width() - quad[0].x())), 1.0f);
p_progress[1] = qMin(offset[1] / (geo.x() - icon.width() + geo.width() - icon.x() - float(geo.width() - quad[1].x())), 1.0f);
} else
lastQuad = quad;
offset[0] = -offset[0];
offset[1] = -offset[1];
SANITIZE_PROGRESS;
// y values are moved towards the center of the icon
SET_QUADS(setY, y, height, setX, x, 0,1,1,0);
newQuads.append(quad);
}
} else if (position == Right) {
float width_cube = float(geo.width()) * float(geo.width()) * float(geo.width());
foreach (WindowQuad quad, data.quads) { // krazy:exclude=foreach
if (quad[0].x() != lastQuad[0].x() || quad[1].x() != lastQuad[1].x()) {
quadFactor = quad[0].x() + (geo.width() - quad[0].x()) * progress;
offset[0] = (icon.x() + quad[0].x() - geo.x()) * progress * ((quadFactor * quadFactor * quadFactor) / width_cube);
quadFactor = quad[1].x() + (geo.width() - quad[1].x()) * progress;
offset[1] = (icon.x() + quad[1].x() - geo.x()) * progress * ((quadFactor * quadFactor * quadFactor) / width_cube);
p_progress[0] = qMin(offset[0] / (icon.x() + icon.width() - geo.x() - float(quad[0].x())), 1.0f);
p_progress[1] = qMin(offset[1] / (icon.x() + icon.width() - geo.x() - float(quad[1].x())), 1.0f);
} else
lastQuad = quad;
SANITIZE_PROGRESS;
// y values are moved towards the center of the icon
SET_QUADS(setY, y, height, setX, x, 0,1,1,0);
newQuads.append(quad);
}
}
data.quads = newQuads;
}
// Call the next effect.
effects->paintWindow(w, mask, region, data);
}
void MagicLampEffect::postPaintScreen()
{
if (mActiveAnimations > 0)
// Repaint the workspace so that everything would be repainted next time
effects->addRepaintFull();
mActiveAnimations = mTimeLineWindows.count();
// Call the next effect.
effects->postPaintScreen();
}
void MagicLampEffect::slotWindowDeleted(EffectWindow* w)
{
delete mTimeLineWindows.take(w);
}
void MagicLampEffect::slotWindowMinimized(EffectWindow* w)
{
if (effects->activeFullScreenEffect())
return;
if (!mTimeLineWindows.contains(w)) {
mTimeLineWindows.insert(w, new QTimeLine(mAnimationDuration, this));
mTimeLineWindows[w]->setCurveShape(QTimeLine::LinearCurve);
}
mTimeLineWindows[w]->setCurrentTime(0);
}
void MagicLampEffect::slotWindowUnminimized(EffectWindow* w)
{
if (effects->activeFullScreenEffect())
return;
if (!mTimeLineWindows.contains(w)) {
mTimeLineWindows.insert(w, new QTimeLine(mAnimationDuration, this));
mTimeLineWindows[w]->setCurveShape(QTimeLine::LinearCurve);
}
mTimeLineWindows[w]->setCurrentTime(mAnimationDuration);
}
bool MagicLampEffect::isActive() const
{
return !mTimeLineWindows.isEmpty();
}
} // namespace