/** * displayconfig.cpp * * Copyright (c) 2009-2010 Timothy Pearson * * 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, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #define PI 3.1415926535897932384626433832795028841971693993751058209749445923078164062862089986280348253421170679 #include "displayconfig.h" using namespace std; /**** DLL Interface ****/ typedef KGenericFactory KDisplayCFactory; K_EXPORT_COMPONENT_FACTORY( kcm_displayconfig, KDisplayCFactory("kcmdisplayconfig") ) KSimpleConfig *systemconfig; TQPoint moveTQRectOutsideTQRect(TQRect base, TQRect movable, int fallback_level = 0) { TQPoint final_result; double base_center_x = base.x() + (base.width()/2); double base_center_y = base.y() + (base.height()/2); double movable_center_x = movable.x() + (movable.width()/2); double movable_center_y = movable.y() + (movable.height()/2); double max_x_movement = (base.width()/2) + (movable.width()/2); double max_y_movement = (base.height()/2) + (movable.height()/2); double x_diff = abs(base_center_x-movable_center_x); double y_diff = abs(base_center_y-movable_center_y); int invert_movement; // Calculate the angles of the four corners of the base rectangle double angle_1 = atan2((base.height()/2), (base.width()/2)); double angle_2 = atan2((base.height()/2), (base.width()/2)*(-1)); double angle_3 = atan2((base.height()/2)*(-1), (base.width()/2)*(-1)); double angle_4 = atan2((base.height()/2)*(-1), (base.width()/2)); // Calculate the angle that the movable rectangle center is on double movable_angle = atan2(base_center_y-movable_center_y, movable_center_x-base_center_x); // Fix up coordinates if (angle_1 < 0) angle_1 = angle_1 + (2*PI); if (angle_2 < 0) angle_2 = angle_2 + (2*PI); if (angle_3 < 0) angle_3 = angle_3 + (2*PI); if (angle_4 < 0) angle_4 = angle_4 + (2*PI); if (movable_angle < 0) movable_angle = movable_angle + (2*PI); // Now calculate quadrant int quadrant; if ((movable_angle < angle_2) && (movable_angle >= angle_1)) { quadrant = 2; } else if ((movable_angle < angle_3) && (movable_angle >= angle_2)) { quadrant = 3; } else if ((movable_angle < angle_4) && (movable_angle >= angle_3)) { quadrant = 4; } else { quadrant = 1; } if (fallback_level == 0) { if ((quadrant == 2) || (quadrant == 4)) { // Move it in the Y direction if (movable_center_y < base_center_y) invert_movement = -1; else invert_movement = 1; final_result = TQPoint(0, (max_y_movement-y_diff)*invert_movement); } else { // Move it in the X direction if (movable_center_x < base_center_x) invert_movement = -1; else invert_movement = 1; final_result = TQPoint((max_x_movement-x_diff)*invert_movement, 0); } } if (fallback_level == 1) { if ((quadrant == 1) || (quadrant == 3)) { // Move it in the Y direction if (movable_center_y < base_center_y) invert_movement = -1; else invert_movement = 1; final_result = TQPoint(0, (max_y_movement-y_diff)*invert_movement); } else { // Move it in the X direction if (movable_center_x < base_center_x) invert_movement = -1; else invert_movement = 1; final_result = TQPoint((max_x_movement-x_diff)*invert_movement, 0); } } if (fallback_level == 2) { // Ooh, nasty, I need to move the rectangle the other (suboptimal) direction if ((quadrant == 2) || (quadrant == 4)) { // Move it in the Y direction if (movable_center_y >= base_center_y) invert_movement = -1; else invert_movement = 1; final_result = TQPoint(0, (max_y_movement+y_diff)*invert_movement); } else { // Move it in the X direction if (movable_center_x >= base_center_x) invert_movement = -1; else invert_movement = 1; final_result = TQPoint((max_x_movement+x_diff)*invert_movement, 0); } } if (fallback_level == 3) { // Ooh, nasty, I need to move the rectangle the other (suboptimal) direction if ((quadrant == 1) || (quadrant == 3)) { // Move it in the Y direction if (movable_center_y >= base_center_y) invert_movement = -1; else invert_movement = 1; final_result = TQPoint(0, (max_y_movement+y_diff)*invert_movement); } else { // Move it in the X direction if (movable_center_x >= base_center_x) invert_movement = -1; else invert_movement = 1; final_result = TQPoint((max_x_movement+x_diff)*invert_movement, 0); } } // Check for intersection TQRect test_rect = movable; test_rect.moveBy(final_result.x(), final_result.y()); if (test_rect.intersects(base)) { if (final_result.x() > 0) final_result.setX(final_result.x()+1); if (final_result.x() < 0) final_result.setX(final_result.x()-1); if (final_result.y() > 0) final_result.setY(final_result.y()+1); if (final_result.y() < 0) final_result.setY(final_result.y()-1); } return final_result; } TQPoint moveTQRectSoThatItTouchesTQRect(TQRect base, TQRect movable, int fallback_level = 0) { TQPoint final_result; double base_center_x = base.x() + (base.width()/2); double base_center_y = base.y() + (base.height()/2); double movable_center_x = movable.x() + (movable.width()/2); double movable_center_y = movable.y() + (movable.height()/2); double max_x_movement = (base.width()/2) + (movable.width()/2); double max_y_movement = (base.height()/2) + (movable.height()/2); double x_diff = abs(base_center_x-movable_center_x); double y_diff = abs(base_center_y-movable_center_y); int invert_movement; // Calculate the angles of the four corners of the base rectangle double angle_1 = atan2((base.height()/2), (base.width()/2)); double angle_2 = atan2((base.height()/2), (base.width()/2)*(-1)); double angle_3 = atan2((base.height()/2)*(-1), (base.width()/2)*(-1)); double angle_4 = atan2((base.height()/2)*(-1), (base.width()/2)); // Calculate the angle that the movable rectangle center is on double movable_angle = atan2(base_center_y-movable_center_y, movable_center_x-base_center_x); // Fix up coordinates if (angle_1 < 0) angle_1 = angle_1 + (2*PI); if (angle_2 < 0) angle_2 = angle_2 + (2*PI); if (angle_3 < 0) angle_3 = angle_3 + (2*PI); if (angle_4 < 0) angle_4 = angle_4 + (2*PI); if (movable_angle < 0) movable_angle = movable_angle + (2*PI); // Now calculate quadrant int quadrant; if ((movable_angle < angle_2) && (movable_angle >= angle_1)) { quadrant = 2; } else if ((movable_angle < angle_3) && (movable_angle >= angle_2)) { quadrant = 3; } else if ((movable_angle < angle_4) && (movable_angle >= angle_3)) { quadrant = 4; } else { quadrant = 1; } if (fallback_level == 0) { if ((quadrant == 2) || (quadrant == 4)) { // Move it in the Y direction if (movable_center_y < base_center_y) invert_movement = -1; else invert_movement = 1; final_result = TQPoint(0, (max_y_movement-y_diff)*invert_movement); } else { // Move it in the X direction if (movable_center_x < base_center_x) invert_movement = -1; else invert_movement = 1; final_result = TQPoint((max_x_movement-x_diff)*invert_movement, 0); } } // Check for intersection TQRect test_rect = movable; test_rect.moveBy(final_result.x(), final_result.y()); if (test_rect.intersects(base)) { if (final_result.x() > 0) final_result.setX(final_result.x()-1); if (final_result.x() < 0) final_result.setX(final_result.x()+1); if (final_result.y() > 0) final_result.setY(final_result.y()-1); if (final_result.y() < 0) final_result.setY(final_result.y()+1); } return final_result; } TQPoint moveTQRectOutsideMonitorRegion(TQRect rect, MonitorRegion region) { // This is a fun little class (not!) // It needs to move the TQRect so that it does not overlap any rectangles in the region long rect_center_x = rect.x() + (rect.width()/2); long rect_center_y = rect.y() + (rect.height()/2); // First, see if the rectangle actually overlaps the region if (!region.contains(rect)) return TQPoint(0,0); // Then, break the region into the series of source rectangles TQMemArray rectangles = region.rects(); // Next, find which rectangle is closest to the center of the TQRect int closest = 0; long distance = 16384*16384; int fallback_mode; long test_distance; long test_center_x; long test_center_y; for ( int i = 0; i < rectangles.size(); i++ ) { test_center_x = rectangles[i].x() + (rectangles[i].width()/2); test_center_y = rectangles[i].y() + (rectangles[i].height()/2); test_distance = pow(test_center_x-rect_center_x,2) + pow(test_center_y-rect_center_y,2); if (test_distance < distance) { // Make sure this is an outer rectangle; i,e. there is empty space where // we would want to move the TQRect... // To do that we will move the TQRect in all four possible directions, // and see if any put the TQRect in an empty location // If they do, then this current rectangle is considered usable // and it is added to the distance checking routine. TQPoint test_moveby = moveTQRectOutsideTQRect(rectangles[i], rect, 0); TQRect test_rect = rect; test_rect.moveBy(test_moveby.x(), test_moveby.y()); if (!region.contains(test_rect)) { closest = i; distance = test_distance; fallback_mode = 0; } else { test_moveby = moveTQRectOutsideTQRect(rectangles[i], rect, 1); test_rect = rect; test_rect.moveBy(test_moveby.x(), test_moveby.y()); if (!region.contains(test_rect)) { closest = i; distance = test_distance; fallback_mode = 1; } else { test_moveby = moveTQRectOutsideTQRect(rectangles[i], rect, 2); test_rect = rect; test_rect.moveBy(test_moveby.x(), test_moveby.y()); if (!region.contains(test_rect)) { closest = i; distance = test_distance; fallback_mode = 2; } else { test_moveby = moveTQRectOutsideTQRect(rectangles[i], rect, 3); test_rect = rect; test_rect.moveBy(test_moveby.x(), test_moveby.y()); if (!region.contains(test_rect)) { closest = i; distance = test_distance; fallback_mode = 3; } } } } } } // Finally, calculate the required translation to move the TQRect outside the MonitorRegion // so that it touches the closest line found above return moveTQRectOutsideTQRect(rectangles[closest], rect, fallback_mode); } TQPoint compressTQRectTouchingMonitorRegion(TQRect rect, MonitorRegion region, TQSize workspace) { // This is another fun little class (not!) // It needs to move the TQRect so that it touches the closest outside line of the MonitorRegion bool should_move; long rect_center_x = rect.x() + (rect.width()/2); long rect_center_y = rect.y() + (rect.height()/2); // First, break the region into the series of source rectangles TQMemArray rectangles = region.rects(); // Next, find which rectangle is closest to the center of the TQRect should_move = false; int closest = 0; long distance = 16384*16384; int fallback_mode; long test_distance; long test_center_x; long test_center_y; for ( int i = 0; i < rectangles.size(); i++ ) { test_center_x = rectangles[i].x() + (rectangles[i].width()/2); test_center_y = rectangles[i].y() + (rectangles[i].height()/2); test_distance = pow(test_center_x-rect_center_x,2) + pow(test_center_y-rect_center_y,2); if ( (abs(test_center_x-(workspace.width()/2))<2) && (abs(test_center_y-(workspace.height()/2))<2) ) { test_distance=0; // Give the primary monitor "gravity" so it can attract all other monitors to itself } if (test_distance < distance) { // Make sure this is an outer rectangle; i,e. there is empty space where // we would want to move the TQRect... // To do that we will move the TQRect in all four possible directions, // and see if any put the TQRect in an empty location // If they do, then this current rectangle is considered usable // and it is added to the distance checking routine. TQPoint test_moveby = moveTQRectSoThatItTouchesTQRect(rectangles[i], rect, 0); TQRect test_rect = rect; test_rect.moveBy(test_moveby.x(), test_moveby.y()); if (!region.contains(test_rect)) { closest = i; distance = test_distance; fallback_mode = 0; should_move = true; } } } // Finally, calculate the required translation to move the TQRect outside the MonitorRegion // so that it touches the closest line found above if (should_move) return moveTQRectSoThatItTouchesTQRect(rectangles[closest], rect, fallback_mode); else return TQPoint(0, 0); } void KDisplayConfig::updateDraggableMonitorInformation (int monitor_id) { updateDraggableMonitorInformationInternal(monitor_id, true); changed(); } void KDisplayConfig::updateDraggableMonitorInformationInternal (int monitor_id, bool recurse) { int i; int j; DraggableMonitor *primary_monitor; DraggableMonitor *moved_monitor; SingleScreenData *screendata; TQObjectList monitors; // Find the moved draggable monitor object monitors = base->monitorPhyArrange->childrenListObject(); if ( monitors.count() ) { for ( i = 0; i < int(monitors.count()); ++i ) { if (::tqqt_cast(TQT_TQWIDGET(monitors.at( i )))) { DraggableMonitor *monitor = static_cast(TQT_TQWIDGET(monitors.at( i ))); if (monitor->screen_id == monitor_id) { moved_monitor = monitor; screendata = m_screenInfoArray.at(moved_monitor->screen_id); } } } } TQString rotationDesired = *screendata->rotations.at(screendata->current_rotation_index); bool isvisiblyrotated = ((rotationDesired == "Rotate 90 degrees") || (rotationDesired == "Rotate 270 degrees")); if (screendata->is_extended) { moved_monitor->show(); } else { moved_monitor->hide(); } // Handle resizing if (isvisiblyrotated) moved_monitor->setFixedSize(screendata->current_y_pixel_count*base->monitorPhyArrange->resize_factor, screendata->current_x_pixel_count*base->monitorPhyArrange->resize_factor); else moved_monitor->setFixedSize(screendata->current_x_pixel_count*base->monitorPhyArrange->resize_factor, screendata->current_y_pixel_count*base->monitorPhyArrange->resize_factor); // Find the primary monitor for (i=0;iis_primary) j=i; } monitors = base->monitorPhyArrange->childrenListObject(); primary_monitor = NULL; if ( monitors.count() ) { for ( i = 0; i < int(monitors.count()); ++i ) { if (::tqqt_cast(TQT_TQWIDGET(monitors.at( i )))) { DraggableMonitor *monitor = static_cast(TQT_TQWIDGET(monitors.at( i ))); if (monitor->screen_id == j) { primary_monitor = monitor; } } } } if (primary_monitor) { if (moved_monitor != primary_monitor) { // Run layout rules applyMonitorLayoutRules(moved_monitor); int toffset_x = moved_monitor->x() - ((base->monitorPhyArrange->width()/2)-(primary_monitor->width()/2)); int toffset_y = moved_monitor->y() - ((base->monitorPhyArrange->height()/2)-(primary_monitor->height()/2)); int offset_x = toffset_x / base->monitorPhyArrange->resize_factor; int offset_y = toffset_y / base->monitorPhyArrange->resize_factor; screendata = m_screenInfoArray.at(monitor_id); screendata->absolute_x_position = offset_x; screendata->absolute_y_position = offset_y; } else { // Reset the position of the primary monitor moveMonitor(primary_monitor, 0, 0); } } else { printf("[WARNING] Display layout broken...\n\r"); fflush(stdout); } layoutDragDropDisplay(); // // FIXME Yes, this should work. For some reason it creates big problems instead // // Run layout rules on all monitors // if (recurse == true) { // applyMonitorLayoutRules(); // } } bool KDisplayConfig::applyMonitorLayoutRules() { int i; for (i=0;imonitorPhyArrange->childrenListObject(); if ( monitors.count() ) { for ( i = 0; i < int(monitors.count()); ++i ) { if (::tqqt_cast(TQT_TQWIDGET(monitors.at( i )))) { DraggableMonitor *monitor = static_cast(TQT_TQWIDGET(monitors.at( i ))); if (monitor != monitor_to_move) { other_monitors = other_monitors.unite(MonitorRegion(monitor->geometry())); } } } } // Now get the required move X/Y direction TQPoint req_move = moveTQRectOutsideMonitorRegion(monitor_to_move->geometry(), other_monitors); // And move the monitor if (!monitor_to_move->isHidden()) monitor_to_move->move(monitor_to_move->x()+req_move.x(), monitor_to_move->y()+req_move.y()); else { req_move.setX(0); req_move.setY(0); monitor_to_move->move(base->monitorPhyArrange->width(), base->monitorPhyArrange->height()); } if ((req_move.x() != 0) || (req_move.y() != 0)) monitor_was_moved = true; // Handle 2) // Now we need to shrink the monitors so that no gaps appear between then // All shrinking must take place towards the nearest extant monitor edge // First, determine which rectangles touch the primary monitor, or touch rectangles that then // in turn touch the primary monitor // FIXME // Only run this routine if we don't touch the primary monitor, or touch any rectangles that // actually do touch the primary monitor (possible through other rectangles, etc.)... // This would be for efficiency // FIXME // if () { TQPoint req_move2(-1,-1); while ((req_move2.x() != 0) || (req_move2.y() != 0)) { // First, create a region from the monitor rectangles MonitorRegion other_monitors2; monitors = base->monitorPhyArrange->childrenListObject(); if ( monitors.count() ) { for ( i = 0; i < int(monitors.count()); ++i ) { if (::tqqt_cast(TQT_TQWIDGET(monitors.at( i )))) { DraggableMonitor *monitor = static_cast(TQT_TQWIDGET(monitors.at( i ))); if (monitor != monitor_to_move) { other_monitors2 = other_monitors2.unite(MonitorRegion(monitor->geometry())); } } } } // Now get the required move X/Y direction req_move2 = compressTQRectTouchingMonitorRegion(monitor_to_move->geometry(), other_monitors, base->monitorPhyArrange->size()); // And move the monitor if (!monitor_to_move->isHidden()) monitor_to_move->move(monitor_to_move->x()+req_move2.x(), monitor_to_move->y()+req_move2.y()); else { req_move2.setX(0); req_move2.setY(0); monitor_to_move->move(base->monitorPhyArrange->width(), base->monitorPhyArrange->height()); } if ((req_move2.x() != 0) || (req_move2.y() != 0)) monitor_was_moved = true; } // } return monitor_was_moved; } void KDisplayConfig::moveMonitor(DraggableMonitor* monitor, int realx, int realy) { int i; int j; bool primary_found; DraggableMonitor *primary_monitor; SingleScreenData *screendata; // Find the primary monitor primary_found = false; for (i=0;iis_primary) { j=i; primary_found = true; } } TQObjectList monitors = base->monitorPhyArrange->childrenListObject(); primary_monitor = NULL; if ( monitors.count() ) { for ( i = 0; i < int(monitors.count()); ++i ) { if (::tqqt_cast(TQT_TQWIDGET(monitors.at( i )))) { DraggableMonitor *monitor = static_cast(TQT_TQWIDGET(monitors.at( i ))); if (monitor->screen_id == j) primary_monitor = monitor; } } } if (primary_found && primary_monitor) { int tx = realx * base->monitorPhyArrange->resize_factor; int ty = realy * base->monitorPhyArrange->resize_factor; if (!monitor->isHidden()) monitor->move((base->monitorPhyArrange->width()/2)-(primary_monitor->width()/2)+tx,(base->monitorPhyArrange->height()/2)-(primary_monitor->height()/2)+ty); else monitor->move(base->monitorPhyArrange->width(), base->monitorPhyArrange->height()); } } // int KDisplayConfig::realResolutionSliderValue() { // return base->resolutionSlider->maxValue() - base->resolutionSlider->value(); // } // // void KDisplayConfig::setRealResolutionSliderValue(int index) { // base->resolutionSlider->setValue(base->resolutionSlider->maxValue() - index); // } TQStringList sortResolutions(TQStringList unsorted) { int i; int xres; int largest; TQStringList sorted; TQStringList::Iterator it; TQStringList::Iterator largestit; while (unsorted.count()) { largest = -1; for ( it = unsorted.begin(); it != unsorted.end(); ++it ) { TQString resolutionstring = *it; int separator_pos = resolutionstring.find(" x "); TQString x_res_string = resolutionstring.left(separator_pos); TQString y_res_string = resolutionstring.right(resolutionstring.length()-separator_pos-3); xres = x_res_string.toInt(); if (xres > largest) { largest = xres; largestit = it; } } sorted.prepend(*largestit); unsorted.remove(largestit); } return sorted; } int KDisplayConfig::realResolutionSliderValue() { int i; int j; SingleScreenData *screendata; screendata = m_screenInfoArray.at(base->monitorDisplaySelectDD->currentItem()); TQStringList sortedList = screendata->resolutions; sortedList = sortResolutions(sortedList); j=0; for (i=0; iresolutions.count(); i++) { if ((*sortedList.at(base->resolutionSlider->value())) == (*screendata->resolutions.at(i))) { j=i; } } return j; } void KDisplayConfig::setRealResolutionSliderValue(int index) { int i; int j; SingleScreenData *screendata; screendata = m_screenInfoArray.at(base->monitorDisplaySelectDD->currentItem()); TQStringList sortedList = screendata->resolutions; sortedList = sortResolutions(sortedList); j=0; for (i=0; iresolutions.count(); i++) { if ((*sortedList.at(i)) == (*screendata->resolutions.at(index))) { j=i; } } base->resolutionSlider->setValue(j); } /**** KDisplayConfig ****/ KDisplayConfig::KDisplayConfig(TQWidget *parent, const char *name, const TQStringList &) : KCModule(KDisplayCFactory::instance(), parent, name), m_randrsimple(0), m_gammaApplyTimer(0) { m_randrsimple = new KRandrSimpleAPI(); TQVBoxLayout *layout = new TQVBoxLayout(this, KDialog::marginHint(), KDialog::spacingHint()); systemconfig = new KSimpleConfig( TQString::tqfromLatin1( KDE_CONFDIR "/kdisplay/kdisplayconfigrc" )); KAboutData *about = new KAboutData(I18N_NOOP("kcmdisplayconfig"), I18N_NOOP("TDE Display Profile Control Module"), 0, 0, KAboutData::License_GPL, I18N_NOOP("(c) 2011 Timothy Pearson")); about->addAuthor("Timothy Pearson", 0, "kb9vqf@pearsoncomputing.net"); setAboutData( about ); m_gammaApplyTimer = new TQTimer(); connect(m_gammaApplyTimer, SIGNAL(timeout()), this, SLOT(applyGamma())); base = new DisplayConfigBase(this); layout->add(base); setRootOnlyMsg(i18n("The global display configuration is a system wide setting, and requires administrator access
To alter the system's global display configuration, click on the \"Administrator Mode\" button below.")); setUseRootOnlyMsg(true); connect(base->systemEnableSupport, TQT_SIGNAL(clicked()), TQT_SLOT(changed())); connect(base->systemEnableSupport, TQT_SIGNAL(clicked()), TQT_SLOT(processLockoutControls())); connect(base->monitorDisplaySelectDD, TQT_SIGNAL(activated(int)), TQT_SLOT(changed())); connect(base->gammamonitorDisplaySelectDD, TQT_SIGNAL(activated(int)), TQT_SLOT(changed())); connect(base->gammaTargetSelectDD, TQT_SIGNAL(activated(int)), TQT_SLOT(gammaTargetChanged(int))); connect(base->rotationSelectDD, TQT_SIGNAL(activated(int)), TQT_SLOT(rotationInfoChanged())); connect(base->refreshRateDD, TQT_SIGNAL(activated(int)), TQT_SLOT(refreshInfoChanged())); connect(base->orientationHFlip, TQT_SIGNAL(clicked()), TQT_SLOT(rotationInfoChanged())); connect(base->orientationVFlip, TQT_SIGNAL(clicked()), TQT_SLOT(rotationInfoChanged())); connect(base->resolutionSlider, TQT_SIGNAL(valueChanged(int)), TQT_SLOT(resolutionSliderChanged(int))); connect(base->gammaAllSlider, TQT_SIGNAL(valueChanged(int)), TQT_SLOT(gammaAllSliderChanged(int))); connect(base->gammaRedSlider, TQT_SIGNAL(valueChanged(int)), TQT_SLOT(gammaRedSliderChanged(int))); connect(base->gammaGreenSlider, TQT_SIGNAL(valueChanged(int)), TQT_SLOT(gammaGreenSliderChanged(int))); connect(base->gammaBlueSlider, TQT_SIGNAL(valueChanged(int)), TQT_SLOT(gammaBlueSliderChanged(int))); connect(base->monitorDisplaySelectDD, TQT_SIGNAL(activated(int)), TQT_SLOT(selectScreen(int))); connect(base->gammamonitorDisplaySelectDD, TQT_SIGNAL(activated(int)), TQT_SLOT(gammaselectScreen(int))); connect(base->systemEnableDPMS, TQT_SIGNAL(clicked()), TQT_SLOT(dpmsChanged())); connect(base->systemEnableDPMSStandby, TQT_SIGNAL(clicked()), TQT_SLOT(dpmsChanged())); connect(base->systemEnableDPMSSuspend, TQT_SIGNAL(clicked()), TQT_SLOT(dpmsChanged())); connect(base->systemEnableDPMSPowerDown, TQT_SIGNAL(clicked()), TQT_SLOT(dpmsChanged())); connect(base->dpmsStandbyTimeout, TQT_SIGNAL(valueChanged(int)), TQT_SLOT(dpmsChanged())); connect(base->dpmsSuspendTimeout, TQT_SIGNAL(valueChanged(int)), TQT_SLOT(dpmsChanged())); connect(base->dpmsPowerDownTimeout, TQT_SIGNAL(valueChanged(int)), TQT_SLOT(dpmsChanged())); connect(base->monitorPhyArrange, TQT_SIGNAL(workspaceRelayoutNeeded()), this, TQT_SLOT(layoutDragDropDisplay())); connect(base->isPrimaryMonitorCB, TQT_SIGNAL(clicked()), TQT_SLOT(changed())); connect(base->isPrimaryMonitorCB, TQT_SIGNAL(clicked()), TQT_SLOT(ensurePrimaryMonitorIsAvailable())); connect(base->isExtendedMonitorCB, TQT_SIGNAL(clicked()), TQT_SLOT(changed())); connect(base->isExtendedMonitorCB, TQT_SIGNAL(clicked()), TQT_SLOT(updateExtendedMonitorInformation())); connect(base->systemEnableSupport, TQT_SIGNAL(toggled(bool)), base->monitorDisplaySelectDD, TQT_SLOT(setEnabled(bool))); connect(base->rescanHardware, TQT_SIGNAL(clicked()), TQT_SLOT(rescanHardware())); connect(base->loadExistingProfile, TQT_SIGNAL(clicked()), TQT_SLOT(reloadProfile())); connect(base->previewConfiguration, TQT_SIGNAL(clicked()), TQT_SLOT(activatePreview())); connect(base->identifyMonitors, TQT_SIGNAL(clicked()), TQT_SLOT(identifyMonitors())); load(); addTab( "iccconfig", i18n( "Color Profiles" ) ); // [FIXME[ No way to save settings here yet processLockoutControls(); } KDisplayConfig::~KDisplayConfig() { delete systemconfig; if (m_gammaApplyTimer) { delete m_gammaApplyTimer; m_gammaApplyTimer = 0; } if (m_randrsimple) { delete m_randrsimple; m_randrsimple = 0; } } void KDisplayConfig::updateExtendedMonitorInformation () { SingleScreenData *screendata; screendata = m_screenInfoArray.at(base->monitorDisplaySelectDD->currentItem()); screendata->is_extended = base->isExtendedMonitorCB->isChecked(); refreshDisplayedInformation(); } void KDisplayConfig::rescanHardware (void) { m_randrsimple->destroyScreenInformationObject(m_screenInfoArray); m_screenInfoArray = m_randrsimple->readCurrentDisplayConfiguration(); m_randrsimple->ensureMonitorDataConsistency(m_screenInfoArray); numberOfScreens = m_screenInfoArray.count(); refreshDisplayedInformation(); } void KDisplayConfig::reloadProfile (void) { // FIXME m_randrsimple->destroyScreenInformationObject(m_screenInfoArray); m_screenInfoArray = m_randrsimple->loadSystemwideDisplayConfiguration("", KDE_CONFDIR); m_randrsimple->ensureMonitorDataConsistency(m_screenInfoArray); numberOfScreens = m_screenInfoArray.count(); refreshDisplayedInformation(); } void KDisplayConfig::identifyMonitors () { int i; TQLabel* idWidget; TQPtrList widgetList; Display *randr_display; ScreenInfo *randr_screen_info; XRROutputInfo *output_info; randr_display = qt_xdisplay(); randr_screen_info = m_randrsimple->read_screen_info(randr_display); for (i = 0; i < m_screenInfoArray.count(); i++) { output_info = randr_screen_info->outputs[i]->info; // Look for ON outputs... if (!randr_screen_info->outputs[i]->cur_crtc) { continue; } SingleScreenData *screendata = m_screenInfoArray.at(i); idWidget = new TQLabel(TQString("Screen\n%1").arg(i+1), (TQWidget*)0, "", Qt::WStyle_Customize | Qt::WStyle_NoBorder | Qt::WStyle_StaysOnTop | Qt::WX11BypassWM | Qt::WDestructiveClose); widgetList.append(idWidget); idWidget->resize(150, 100); idWidget->setAlignment(Qt::AlignCenter); TQFont font = idWidget->font(); font.setBold( true ); font.setPointSize(24); idWidget->setFont( font ); idWidget->setPaletteForegroundColor(Qt::white); idWidget->setPaletteBackgroundColor(Qt::black); idWidget->show(); KDialog::centerOnScreen(idWidget, i); TQTimer::singleShot(3000, idWidget, SLOT(close())); } m_randrsimple->freeScreenInfoStructure(randr_screen_info); } void KDisplayConfig::deleteProfile () { } void KDisplayConfig::renameProfile () { } void KDisplayConfig::addProfile () { } void KDisplayConfig::activatePreview() { m_randrsimple->applySystemwideDisplayConfiguration(m_screenInfoArray, TRUE); } void KDisplayConfig::load() { load( false ); } void KDisplayConfig::selectProfile (int slotNumber) { } void KDisplayConfig::selectScreen (int slotNumber) { base->monitorDisplaySelectDD->setCurrentItem(slotNumber); base->gammamonitorDisplaySelectDD->setCurrentItem(slotNumber); updateDisplayedInformation(); } void KDisplayConfig::updateArray (void) { m_screenInfoArray = m_randrsimple->readCurrentDisplayConfiguration(); m_randrsimple->ensureMonitorDataConsistency(m_screenInfoArray); numberOfScreens = m_screenInfoArray.count(); } void KDisplayConfig::updateDisplayedInformation () { // Insert data into the GUI int i; SingleScreenData *screendata; ensureMonitorDataConsistency(); screendata = m_screenInfoArray.at(base->monitorDisplaySelectDD->currentItem()); if (screendata->screen_connected) { base->resolutionSlider->setEnabled(true); base->refreshRateDD->setEnabled(true); base->rotationSelectDD->setEnabled(true); base->orientationHFlip->setEnabled(true); base->orientationVFlip->setEnabled(true); base->isPrimaryMonitorCB->setEnabled(true); base->isExtendedMonitorCB->setEnabled(true); } // Update the resolutions for the selected screen base->resolutionSlider->blockSignals(true); base->resolutionSlider->setMaxValue(screendata->resolutions.count()-1); setRealResolutionSliderValue(screendata->current_resolution_index); resolutionSliderTextUpdate(realResolutionSliderValue()); base->resolutionSlider->blockSignals(false); // Now the refresh rates for the selected screen base->refreshRateDD->blockSignals(true); base->refreshRateDD->clear(); for (i=0;irefresh_rates.count();i++) { base->refreshRateDD->insertItem(screendata->refresh_rates[i], i); } base->refreshRateDD->setCurrentItem(screendata->current_refresh_rate_index); base->refreshRateDD->blockSignals(false); // Now the rotations and transformations for the selected screen base->rotationSelectDD->blockSignals(true); base->orientationHFlip->blockSignals(true); base->orientationVFlip->blockSignals(true); base->rotationSelectDD->clear(); if (screendata->supports_transformations) { for (i=0;irotations.count();i++) { base->rotationSelectDD->insertItem(screendata->rotations[i], i); } base->rotationSelectDD->setCurrentItem(screendata->current_rotation_index); base->orientationHFlip->show(); base->orientationVFlip->show(); base->orientationHFlip->setChecked(screendata->has_x_flip); base->orientationVFlip->setChecked(screendata->has_y_flip); } else { base->rotationSelectDD->insertItem("Normal", 0); base->rotationSelectDD->setCurrentItem(0); base->orientationHFlip->hide(); base->orientationVFlip->hide(); } base->rotationSelectDD->blockSignals(false); base->orientationHFlip->blockSignals(false); base->orientationVFlip->blockSignals(false); base->isPrimaryMonitorCB->blockSignals(true); base->isExtendedMonitorCB->blockSignals(true); if (screendata->generic_screen_detected) { base->isPrimaryMonitorCB->setEnabled(false); base->isPrimaryMonitorCB->setChecked(true); base->isExtendedMonitorCB->setEnabled(false); base->isExtendedMonitorCB->setChecked(true); } else { base->isPrimaryMonitorCB->setEnabled(true); base->isPrimaryMonitorCB->setChecked(screendata->is_primary); if (screendata->is_primary) { base->isExtendedMonitorCB->setEnabled(false); base->isExtendedMonitorCB->setChecked(true); } else { base->isExtendedMonitorCB->setEnabled(true); base->isExtendedMonitorCB->setChecked(screendata->is_extended); } } base->isPrimaryMonitorCB->blockSignals(false); base->isExtendedMonitorCB->blockSignals(false); if (!screendata->screen_connected) { base->resolutionSlider->setEnabled(false); base->refreshRateDD->setEnabled(false); base->rotationSelectDD->setEnabled(false); base->orientationHFlip->setEnabled(false); base->orientationVFlip->setEnabled(false); base->isPrimaryMonitorCB->setEnabled(false); base->isExtendedMonitorCB->setEnabled(false); } } void KDisplayConfig::refreshDisplayedInformation () { // Insert data into the GUI int i; SingleScreenData *screendata; // First, the screens int currentScreenIndex = base->monitorDisplaySelectDD->currentItem(); base->monitorDisplaySelectDD->clear(); for (i=0;imonitorDisplaySelectDD->insertItem(screendata->screenFriendlyName, i); } base->monitorDisplaySelectDD->setCurrentItem(currentScreenIndex); base->gammamonitorDisplaySelectDD->clear(); for (i=0;igammamonitorDisplaySelectDD->insertItem(screendata->screenFriendlyName, i); } base->gammamonitorDisplaySelectDD->setCurrentItem(currentScreenIndex); updateDisplayedInformation(); updateDragDropDisplay(); screendata = m_screenInfoArray.at(0); base->systemEnableDPMS->setEnabled(screendata->has_dpms); base->systemEnableDPMS->setChecked(screendata->enable_dpms); base->systemEnableDPMSStandby->setChecked(screendata->dpms_standby_delay!=0); base->systemEnableDPMSSuspend->setChecked(screendata->dpms_suspend_delay!=0); base->systemEnableDPMSPowerDown->setChecked(screendata->dpms_off_delay!=0); base->dpmsStandbyTimeout->setValue(screendata->dpms_standby_delay/60); base->dpmsSuspendTimeout->setValue(screendata->dpms_suspend_delay/60); base->dpmsPowerDownTimeout->setValue(screendata->dpms_off_delay/60); processDPMSControls(); } void KDisplayConfig::updateDragDropDisplay() { // Insert data into the GUI int i; int j; int largest_x_pixels; int largest_y_pixels; TQObjectList monitors; SingleScreenData *screendata; // Clear any screens from the workspace monitors = base->monitorPhyArrange->childrenListObject(); if ( monitors.count() ) { for ( i = 0; i < int(monitors.count()); ++i ) { if (::tqqt_cast(TQT_TQWIDGET(monitors.at( i )))) { TQWidget *monitor = TQT_TQWIDGET(monitors.at( i )); if ( !monitor->close(TRUE) ) { Q_ASSERT("zombie monitor will not go away!"); } } } } int currentScreenIndex = base->monitorDisplaySelectDD->currentItem(); ensureMonitorDataConsistency(); // Add the screens to the workspace // Set the scaling small to start with base->monitorPhyArrange->resize_factor = 0.0625; // This always needs to divide by a multiple of 2 for (j=0;j<2;j++) { for (i=0;iis_primary==true)) || ((j==1) && (screendata->is_primary==false))) { // This ensures that the primary monitor is always the first one created and placed on the configuration widget TQString rotationDesired = *screendata->rotations.at(screendata->current_rotation_index); bool isvisiblyrotated = ((rotationDesired == "Rotate 90 degrees") || (rotationDesired == "Rotate 270 degrees")); DraggableMonitor *m = new DraggableMonitor( base->monitorPhyArrange, 0, WStyle_Customize | WDestructiveClose | WStyle_NoBorder | WX11BypassWM ); connect(m, TQT_SIGNAL(workspaceRelayoutNeeded()), this, TQT_SLOT(layoutDragDropDisplay())); connect(m, TQT_SIGNAL(monitorSelected(int)), this, TQT_SLOT(selectScreen(int))); connect(m, TQT_SIGNAL(monitorDragComplete(int)), this, TQT_SLOT(updateDraggableMonitorInformation(int))); m->screen_id = i; if (isvisiblyrotated) m->setFixedSize(screendata->current_y_pixel_count*base->monitorPhyArrange->resize_factor, screendata->current_x_pixel_count*base->monitorPhyArrange->resize_factor); else m->setFixedSize(screendata->current_x_pixel_count*base->monitorPhyArrange->resize_factor, screendata->current_y_pixel_count*base->monitorPhyArrange->resize_factor); m->setText(TQString("%1").arg(i+1)); m->show(); moveMonitor(m, screendata->absolute_x_position, screendata->absolute_y_position); updateDraggableMonitorInformation(i); // Make sure the new monitors don't overlap } } } layoutDragDropDisplay(); } void KDisplayConfig::layoutDragDropDisplay() { int i; int largest_x_pixels; int largest_y_pixels; TQObjectList monitors; SingleScreenData *screendata; // Ensure data is consistent ensureMonitorDataConsistency(); // Arrange the screens // First, center the primary monitor monitors = base->monitorPhyArrange->childrenListObject(); if ( monitors.count() ) { for ( i = 0; i < int(monitors.count()); ++i ) { if (::tqqt_cast(TQT_TQWIDGET(monitors.at( i )))) { DraggableMonitor *monitor = static_cast(TQT_TQWIDGET(monitors.at( i ))); screendata = m_screenInfoArray.at(monitor->screen_id); moveMonitor(monitor, screendata->absolute_x_position, screendata->absolute_y_position); } } } } void KDisplayConfig::ensureMonitorDataConsistency() { m_randrsimple->ensureMonitorDataConsistency(m_screenInfoArray); } void KDisplayConfig::resolutionSliderTextUpdate(int index) { SingleScreenData *screendata; screendata = m_screenInfoArray.at(base->monitorDisplaySelectDD->currentItem()); base->resolutionLabel->setText(screendata->resolutions[realResolutionSliderValue()] + TQString(" ") + i18n("pixels")); } void KDisplayConfig::resolutionSliderChanged(int index) { SingleScreenData *screendata; screendata = m_screenInfoArray.at(base->monitorDisplaySelectDD->currentItem()); screendata->current_resolution_index = realResolutionSliderValue(); updateDisplayedInformation(); updateDraggableMonitorInformation(base->monitorDisplaySelectDD->currentItem()); changed(); } void KDisplayConfig::rotationInfoChanged() { SingleScreenData *screendata; screendata = m_screenInfoArray.at(base->monitorDisplaySelectDD->currentItem()); screendata->current_rotation_index = base->rotationSelectDD->currentItem(); screendata->has_x_flip = base->orientationHFlip->isChecked(); screendata->has_y_flip = base->orientationVFlip->isChecked(); updateDisplayedInformation(); updateDraggableMonitorInformation(base->monitorDisplaySelectDD->currentItem()); changed(); } void KDisplayConfig::refreshInfoChanged() { SingleScreenData *screendata; screendata = m_screenInfoArray.at(base->monitorDisplaySelectDD->currentItem()); screendata->current_refresh_rate_index = base->refreshRateDD->currentItem(); updateDisplayedInformation(); updateDraggableMonitorInformation(base->monitorDisplaySelectDD->currentItem()); changed(); } TQString KDisplayConfig::extractFileName(TQString displayName, TQString profileName) { } void KDisplayConfig::ensurePrimaryMonitorIsAvailable() { // Ensure that only one monitor, and not less than one monitor, is marked as primary int i; SingleScreenData *screendata; // First, the screens int currentScreenIndex = base->monitorDisplaySelectDD->currentItem(); for (i=0;iis_primary = false; } screendata = m_screenInfoArray.at(currentScreenIndex); screendata->is_primary = true; screendata->is_extended = true; updateDragDropDisplay(); refreshDisplayedInformation(); } int KDisplayConfig::findProfileIndex(TQString profileName) { } int KDisplayConfig::findScreenIndex(TQString screenName) { } void KDisplayConfig::setGammaLabels() { SingleScreenData *screendata; screendata = m_screenInfoArray.at(base->gammamonitorDisplaySelectDD->currentItem()); // Round off the gammas to one decimal place screendata->gamma_red = floorf(screendata->gamma_red * 10 + 0.5) / 10; screendata->gamma_green = floorf(screendata->gamma_green * 10 + 0.5) / 10; screendata->gamma_blue = floorf(screendata->gamma_blue * 10 + 0.5) / 10; // Set the labels base->gammaAllLabel->setText(TQString("%1").tqarg(((float)base->gammaAllSlider->value())/10.0, 0, 'f', 1)); base->gammaRedLabel->setText(TQString("%1").tqarg(((float)base->gammaRedSlider->value())/10.0, 0, 'f', 1)); base->gammaGreenLabel->setText(TQString("%1").tqarg(((float)base->gammaGreenSlider->value())/10.0, 0, 'f', 1)); base->gammaBlueLabel->setText(TQString("%1").tqarg(((float)base->gammaBlueSlider->value())/10.0, 0, 'f', 1)); } void KDisplayConfig::gammaSetAverageAllSlider() { float average_gamma; SingleScreenData *screendata; screendata = m_screenInfoArray.at(base->gammamonitorDisplaySelectDD->currentItem()); average_gamma = (screendata->gamma_red+screendata->gamma_green+screendata->gamma_blue)/3.0; average_gamma = floorf(average_gamma* 10 + 0.5) / 10; // Round off the gamma to one decimal place base->gammaAllSlider->setValue(average_gamma*10.0); } void KDisplayConfig::gammaselectScreen (int slotNumber) { SingleScreenData *screendata; base->gammaAllSlider->blockSignals(true); base->gammaRedSlider->blockSignals(true); base->gammaGreenSlider->blockSignals(true); base->gammaBlueSlider->blockSignals(true); screendata = m_screenInfoArray.at(base->gammamonitorDisplaySelectDD->currentItem()); base->gammaRedSlider->setValue(screendata->gamma_red*10.0); base->gammaGreenSlider->setValue(screendata->gamma_green*10.0); base->gammaBlueSlider->setValue(screendata->gamma_blue*10.0); gammaSetAverageAllSlider(); setGammaLabels(); base->gammaAllSlider->blockSignals(false); base->gammaRedSlider->blockSignals(false); base->gammaGreenSlider->blockSignals(false); base->gammaBlueSlider->blockSignals(false); } void KDisplayConfig::gammaAllSliderChanged(int index) { SingleScreenData *screendata; base->gammaAllSlider->blockSignals(true); base->gammaRedSlider->blockSignals(true); base->gammaGreenSlider->blockSignals(true); base->gammaBlueSlider->blockSignals(true); screendata = m_screenInfoArray.at(base->gammamonitorDisplaySelectDD->currentItem()); base->gammaRedSlider->setValue(base->gammaAllSlider->value()); base->gammaGreenSlider->setValue(base->gammaAllSlider->value()); base->gammaBlueSlider->setValue(base->gammaAllSlider->value()); setGammaLabels(); screendata->gamma_red = ((float)base->gammaAllSlider->value())/10.0; screendata->gamma_green = ((float)base->gammaAllSlider->value())/10.0; screendata->gamma_blue = ((float)base->gammaAllSlider->value())/10.0; m_gammaApplyTimer->start(10, TRUE); base->gammaAllSlider->blockSignals(false); base->gammaRedSlider->blockSignals(false); base->gammaGreenSlider->blockSignals(false); base->gammaBlueSlider->blockSignals(false); changed(); } void KDisplayConfig::gammaRedSliderChanged(int index) { SingleScreenData *screendata; base->gammaAllSlider->blockSignals(true); base->gammaRedSlider->blockSignals(true); base->gammaGreenSlider->blockSignals(true); base->gammaBlueSlider->blockSignals(true); screendata = m_screenInfoArray.at(base->gammamonitorDisplaySelectDD->currentItem()); screendata->gamma_red = ((float)index)/10.0; gammaSetAverageAllSlider(); setGammaLabels(); m_gammaApplyTimer->start(10, TRUE); base->gammaAllSlider->blockSignals(false); base->gammaRedSlider->blockSignals(false); base->gammaGreenSlider->blockSignals(false); base->gammaBlueSlider->blockSignals(false); changed(); } void KDisplayConfig::gammaGreenSliderChanged(int index) { SingleScreenData *screendata; base->gammaAllSlider->blockSignals(true); base->gammaRedSlider->blockSignals(true); base->gammaGreenSlider->blockSignals(true); base->gammaBlueSlider->blockSignals(true); screendata = m_screenInfoArray.at(base->gammamonitorDisplaySelectDD->currentItem()); screendata->gamma_green = ((float)index)/10.0; gammaSetAverageAllSlider(); setGammaLabels(); m_gammaApplyTimer->start(10, TRUE); base->gammaAllSlider->blockSignals(false); base->gammaRedSlider->blockSignals(false); base->gammaGreenSlider->blockSignals(false); base->gammaBlueSlider->blockSignals(false); changed(); } void KDisplayConfig::gammaBlueSliderChanged(int index) { SingleScreenData *screendata; base->gammaAllSlider->blockSignals(true); base->gammaRedSlider->blockSignals(true); base->gammaGreenSlider->blockSignals(true); base->gammaBlueSlider->blockSignals(true); screendata = m_screenInfoArray.at(base->gammamonitorDisplaySelectDD->currentItem()); screendata->gamma_blue = ((float)index)/10.0; gammaSetAverageAllSlider(); setGammaLabels(); m_gammaApplyTimer->start(10, TRUE); base->gammaAllSlider->blockSignals(false); base->gammaRedSlider->blockSignals(false); base->gammaGreenSlider->blockSignals(false); base->gammaBlueSlider->blockSignals(false); changed(); } void KDisplayConfig::applyGamma() { m_randrsimple->applySystemwideDisplayGamma(m_screenInfoArray); } void KDisplayConfig::gammaTargetChanged (int slotNumber) { TQPixmap gammaPixmap( locate("data", TQString("kcontrol/pics/gamma%1.png").arg(base->gammaTargetSelectDD->text(slotNumber))) ); base->gammaTestImage->setBackgroundPixmap( gammaPixmap ); } void KDisplayConfig::dpmsChanged() { SingleScreenData *screendata; screendata = m_screenInfoArray.at(0); processDPMSControls(); screendata->enable_dpms = base->systemEnableDPMS->isChecked(); screendata->dpms_standby_delay = (base->systemEnableDPMSStandby->isChecked())?base->dpmsStandbyTimeout->value()*60:0; screendata->dpms_suspend_delay = (base->systemEnableDPMSSuspend->isChecked())?base->dpmsSuspendTimeout->value()*60:0; screendata->dpms_off_delay = (base->systemEnableDPMSPowerDown->isChecked())?base->dpmsPowerDownTimeout->value()*60:0; changed(); } void KDisplayConfig::processDPMSControls() { if (base->systemEnableDPMS->isChecked()) { base->systemEnableDPMSStandby->setEnabled(true); base->systemEnableDPMSSuspend->setEnabled(true); base->systemEnableDPMSPowerDown->setEnabled(true); base->dpmsStandbyTimeout->setEnabled(base->systemEnableDPMSStandby->isChecked()); base->dpmsSuspendTimeout->setEnabled(base->systemEnableDPMSSuspend->isChecked()); base->dpmsPowerDownTimeout->setEnabled(base->systemEnableDPMSPowerDown->isChecked()); } else { base->systemEnableDPMSStandby->setEnabled(false); base->systemEnableDPMSSuspend->setEnabled(false); base->systemEnableDPMSPowerDown->setEnabled(false); base->dpmsStandbyTimeout->setEnabled(false); base->dpmsSuspendTimeout->setEnabled(false); base->dpmsPowerDownTimeout->setEnabled(false); } if (base->systemEnableDPMSStandby->isChecked()) base->dpmsSuspendTimeout->setMinValue(base->dpmsStandbyTimeout->value()); else base->dpmsSuspendTimeout->setMinValue(1); if (base->systemEnableDPMSSuspend->isChecked()) base->dpmsPowerDownTimeout->setMinValue(base->dpmsSuspendTimeout->value()); else if (base->systemEnableDPMSStandby->isChecked()) base->dpmsPowerDownTimeout->setMinValue(base->dpmsStandbyTimeout->value()); else base->dpmsPowerDownTimeout->setMinValue(1); } void KDisplayConfig::processLockoutControls() { if (getuid() != 0 || !systemconfig->checkConfigFilesWritable( true )) { base->globalTab->setEnabled(false); base->resolutionTab->setEnabled(false); base->gammaTab->setEnabled(false); base->powerTab->setEnabled(false); } else { base->globalTab->setEnabled(true); if (base->systemEnableSupport->isChecked()) { base->resolutionTab->setEnabled(true); base->gammaTab->setEnabled(true); base->powerTab->setEnabled(true); } else { base->resolutionTab->setEnabled(false); base->gammaTab->setEnabled(false); base->powerTab->setEnabled(false); } } base->loadExistingProfile->setEnabled(false); // Disable this until it works properly! base->loadExistingProfile->hide(); // Same as above } void KDisplayConfig::addTab( const TQString name, const TQString label ) { // [FIXME] This is incomplete...Apply may not work... TQWidget *page = new TQWidget( base->mainTabContainerWidget, name.latin1() ); TQVBoxLayout *top = new TQVBoxLayout( page, KDialog::marginHint() ); KCModule *kcm = KCModuleLoader::loadModule( name, page ); if ( kcm ) { top->addWidget( kcm ); base->mainTabContainerWidget->addTab( page, label ); connect( kcm, TQT_SIGNAL( changed(bool) ), this, TQT_SLOT( changed() ) ); //m_modules.insert(kcm, false); } else { delete page; } } void KDisplayConfig::load(bool useDefaults ) { // Update the toggle buttons with the current configuration int i; int j; updateArray(); systemconfig->setGroup(NULL); base->systemEnableSupport->setChecked(systemconfig->readBoolEntry("EnableDisplayControl", false)); refreshDisplayedInformation(); gammaselectScreen(base->gammamonitorDisplaySelectDD->currentItem()); base->gammaTargetSelectDD->clear(); base->gammaTargetSelectDD->insertItem("1.4", 0); base->gammaTargetSelectDD->insertItem("1.6", 1); base->gammaTargetSelectDD->insertItem("1.8", 2); base->gammaTargetSelectDD->insertItem("2.0", 3); base->gammaTargetSelectDD->insertItem("2.2", 4); base->gammaTargetSelectDD->insertItem("2.4", 5); base->gammaTargetSelectDD->setCurrentItem(4); gammaTargetChanged(4); emit changed(useDefaults); } void KDisplayConfig::save() { if (m_randrsimple->applySystemwideDisplayConfiguration(m_screenInfoArray, TRUE)) { m_randrsimple->saveSystemwideDisplayConfiguration(base->systemEnableSupport->isChecked(), "", KDE_CONFDIR, m_screenInfoArray); // Write system configuration systemconfig->setGroup(NULL); systemconfig->writeEntry("EnableDisplayControl", base->systemEnableSupport->isChecked()); systemconfig->sync(); emit changed(false); } else { // Signal that settings were NOT applied TQTimer *t = new TQTimer( this ); connect(t, SIGNAL(timeout()), SLOT(changed()) ); t->start( 100, FALSE ); } } void KDisplayConfig::defaults() { load( true ); } TQString KDisplayConfig::quickHelp() const { return i18n("

Monitor & Display Configuration

This module allows you to configure monitors attached to your" " computer via TDE."); } #include "displayconfig.moc"