Exemplo n.º 1
0
void doSceneGraph( arMasterSlaveFramework &fw )
{
    static int loops = 0;
    static ar_timeval starttime = ar_time();
    static ar_timeval lastdrawtime = ar_time();
    ar_timeval now = ar_time();
    long long curtime = ( now.sec * 1000000 ) + now.usec, lasttime = ( lastdrawtime.sec * 1000000 ) + lastdrawtime.usec;
    long long sleeptime = 2000 - ( curtime - lasttime );
    ar_usleep( max( (int)sleeptime, 1 ) );

    fw.loadNavMatrix();
    glClearColor( 0, 0.749, 1, 0 );
    primary.draw();
    secondary.draw();
    sg->drawSceneGraph();
    if( menuOn )
        drawMenu( menu, fw );
        
    lastdrawtime = ar_time();
    loops++;
    if( lastdrawtime.sec > starttime.sec )
    {
        cout << "fps=" << loops << endl;
        starttime = lastdrawtime;
        loops = 0;
    }
}
Exemplo n.º 2
0
// draw callback
// Purposes:
//		- Load the navigation matrix to reflect frame's navigation
//		- Use OpenGL to generate computer graphics.
void draw(arMasterSlaveFramework& framework)
{
	// Load the navigation matrix.
	framework.loadNavMatrix();
	
	// Generate graphics.
	if(selectionMode == 2)
	{
		renderPrimitive(-2.5f); // draws square with quadrants
		drawObjects(-2.5f); // draw the mini versions
	}
	
	vector<arInteractable*>::iterator i;
	for(i=objects.begin(); i != objects.end(); ++i) 
	{
		Object* oby = ((Object*)(*i));
		oby->draw();
	}

	
	// Draw the effectors.
	rightHand.draw();
	leftHand.draw();

}
Exemplo n.º 3
0
void drawHelp( arMasterSlaveFramework &fw )
{
	static arTexture tex;
	static bool init = false;
	if( !init )
	{
		tex.readJPEG( "help.jpg" );
		init = true;
	}
	
	static float size = 4;
    static GLfloat v[4][3] =
    {
        { -size / 2, -size / 2, 0.0001 },
        { size / 2, -size / 2, 0.0001 },
        { size / 2, size / 2, 0.0001 },
        { -size / 2, size / 2, 0.0001 }
    };
	
	glPushMatrix();
		glMultMatrixf( ( ar_getNavMatrix() * fw.getMidEyeMatrix() * ar_TM( 0, 0, -5 ) ).v );
		
		glClearColor( 1, 1, 1, 0 );
		tex.activate();
		glBegin( GL_QUADS );
			glTexCoord2f( 0, 0 ); glVertex3fv( v[0] );
			glTexCoord2f( 1, 0 ); glVertex3fv( v[1] );
			glTexCoord2f( 1, 1 ); glVertex3fv( v[2] );
			glTexCoord2f( 0, 1 ); glVertex3fv( v[3] );
		glEnd();
		tex.deactivate();
	glPopMatrix();
}
Exemplo n.º 4
0
// postExchange callback
// Purposes:
//		- Update effectors based on input state transferred from master node.
//		- Synchronize slave nodes with master node based on transferred data. This is not necessary
//		  for our system, but here's an example for cluster-based systems.
void postExchange(arMasterSlaveFramework& framework)
{
	// Presumably the master node already is up-to-date, so we ignore it.
	if(!framework.getMaster()) {
		
		// Update effectors.
		rightHand.updateState(framework.getInputState());
		leftHand.updateState(framework.getInputState());
		
		// Synchronize shared memory.
		vector<arInteractable*>::iterator i;
		for(i=objects.begin(); i != objects.end(); ++i) 
		{
			Object* oby = ((Object*)(*i));
			oby->setMatrix(oby->matrix.v);
		}
	}

}
Exemplo n.º 5
0
// windowEvent callback
// Purposes:
//		- Process window events, such as resizing
// Notes:
//		The values are defined in src/graphics/arGUIDefines.h.
//		arGUIWindowInfo is in arGUIInfo.h.
//		The window manager is in arGUIWindowManager.h.
void windowEvent(arMasterSlaveFramework& framework, arGUIWindowInfo* windowInfo)
{
	// Process window events. Here, we handle window resizing.
	if(windowInfo->getState() == AR_WINDOW_RESIZE) {
		const int windowID = windowInfo->getWindowID();
#ifdef UNUSED
		const int x = windowInfo->getPosX();
		const int y = windowInfo->getPosY();
#endif
		const int width = windowInfo->getSizeX();
		const int height = windowInfo->getSizeY();
		framework.getWindowManager()->setWindowViewport(windowID, 0, 0, width, height);
	}

}
Exemplo n.º 6
0
// start callback
// Purposes:
// 		- Register shared memory by adding transfer fields. This is to syncronize cluster-based 
//		  systems, hence we don't need to do this. But there's a few examples anyway.
// 		- Set up navigation through the framework by specifying translation conditions, rotation
//		  conditions, translation speed, and rotation speed. We provide a couple examples here.
//		- Initialize any global variables specific to your application.
// Notes: 
//		DO NOT initialize OpenGL here. The start callback is called before window creation. 
//		Instead initialize OpenGL in the windowStartGL callback.
bool start(arMasterSlaveFramework& framework, arSZGClient& client )
{
	theMrCreepyBook7.setMatrix(ar_translationMatrix(-3,4,-7));
	objects.push_back(&theMrCreepyBook7);

	theMrBookshelf6.setMatrix(ar_translationMatrix(-3,3,-7));
	objects.push_back(&theMrBookshelf6);

	theMrDungeonRoom5.setMatrix(ar_translationMatrix(0,4,-5));
	objects.push_back(&theMrDungeonRoom5);

	// Register shared memory. Not needed for non-cluster-based systems.
	// framework.addTransferField(char* name, void* address, arDataType type, int numElements);
	vector<arInteractable*>::iterator i;
	for(i=objects.begin(); i != objects.end(); ++i) 
	{
		Object* obj = ((Object*)(*i));
		obj->loadedOBJ.normalizeModelSize();
		ostringstream ostr;
		ostr << "objMatrix" << &i;
		arMatrix4 obM = obj->matrix;
		framework.addTransferField(ostr.str(), &obM, AR_FLOAT, 16);
	}
	
	// Set up navigation.

	// A traditional pointing technique using the joystick with left and right rotating the scene.
	// Translate along Z-axis (forwards/backwards) if joystick is pressed more than 20% along axis 1.
	framework.setNavTransCondition('z', AR_EVENT_AXIS, 1, 0.2);

	// Rotate around Y-axis (vertical) if joystick is pressed more than 20% along axis 0.
	//framework.setNavRotCondition('y', AR_EVENT_AXIS, 0, 0.2);  //FOR ROTATE
	framework.setNavTransCondition('x', AR_EVENT_AXIS, 0, 0.2);  //FOR STRAFING

	// Set translation speed to 5 feet/second.
	framework.setNavTransSpeed(5.0);

	// Set rotation speed to 30 degrees/second.
	framework.setNavRotSpeed(30.0);

	
	
	// Initialize application variables here.
	
	// Move object's to initial positions.

	
	// Create sound transform.
	soundTransformID = dsTransform("world", framework.getNavNodeName(), ar_scaleMatrix(1.0));
	// Parameters are:
	//		name - string name for sound
	//		transformName - string name for dsTransform
	//		loopType - 1 for continuous, -1 for one-time, 0 to stop
	//		loudness - float from 0.0 (quiet) to 1.0 (max)
	//		positionVector - vector position of sound origin
	// Create loop for click sound.
	clickSound = dsLoop("click", "world", "click.mp3", 0, 1.0, arVector3(0, 0, 0));
	
	musicNotey.readOBJ("MusicNote.obj","data/obj");
	
	
	// Return true if everything is initialized correctly.
	return true;

}
Exemplo n.º 7
0
// preExchange callback
// Purposes:
//		- Handle navigation updates.
//		- Process user input.
//		- Set random variables.
//		- Update shared memory.
// Notes:
//		This is only called on the master node of the cluster and before shared memory is 
//		transferred to the slave nodes.
void preExchange(arMasterSlaveFramework& framework)
{
	// Handle navigation update. The resulting navigation matrix is automatically transferred
	// to the slave nodes.
	framework.navUpdate();
	
	currentTimeGlobal = framework.getTime();
	
	double currentTime = framework.getTime();
	
	// Process user input.
	
	
	// Update shared memory.
	
	// Transfer data about objects to slave nodes.

	// Detect right hand collisions.
	rightHand.detectCollisions(rightHand, objects);

	// Extend left ray to collision point.
	leftHand.extend(leftHand, objects);

	// Update input state (placement matrix & button states) of our effectors.
	rightHand.updateState(framework.getInputState());
	leftHand.updateState(framework.getInputState());
	// Handle any interaction with the objects (see interaction/arInteractionUtilities.h).
	
	list<arInteractable*> objectlist;
	std::copy(objects.begin (), objects.end (), std::back_inserter(objectlist));
	
	ar_pollingInteraction(rightHand, objectlist);
	ar_pollingInteraction(leftHand, objectlist);
	
	
	// Play click sound if right hand has grabbed an object.
	if(rightHand.getGrabbedObject() != 0) 
	{
		dsLoop(clickSound, "click.mp3", -1, 1.0, arVector3(0, 0, 0));
	}
	// Or reset the trigger
	else 
	{
		dsLoop(clickSound, "click.mp3", 0, 1.0, arVector3(0, 0, 0));
	}
	
	
	
	// Update shared memory.
	
	// Transfer data about objects to slave nodes.

	vector<arInteractable*>::iterator i;
	for(i=objects.begin(); i != objects.end(); ++i) 
	{
		Object* oby = ((Object*)(*i));
		oby->matrix = oby->getMatrix();
	}

	
	arMatrix4 navMatrix = ar_getNavMatrix();

}
Exemplo n.º 8
0
void onPreExchange( arMasterSlaveFramework &fw )
{
    fw.navUpdate();
    // update the input state (placement matrix & button states) of our effector.
    primary.updateState( fw.getInputState() );
    secondary.updateState( fw.getInputState() );
	
	if( primary.getButton( WiiMote::HOME ) && secondary.getButton( WiiMote::HOME ) )
	{
		helpOn = true;
		setMenuOff();
		fw.setDrawCallback( drawHelp );
	}
	
	if( helpOn )
	{
		if( primary.getButton( WiiMote::A ) || secondary.getButton( WiiMote::A ) )
		{
			helpOn = false;
			fw.setDrawCallback( doSceneGraph );
			return;
		}
	}
	else
	{

		//used for scale the world (and possibly other scales later)
		WiiMote::updateTipDistance(primary, secondary);
		scaleWorld();
		moveWorld( fw );
		
		std::map<WiiMote::button_t, std::list<WiiMote*> > buttonMap;
		WiiMote::ButtonList buttons = secondary.getDownButtons();
		for( WiiMote::ButtonList::iterator it = buttons.begin(); it != buttons.end(); ++it )
		{  // Process all butons just pressed on secondary
			if( buttonMap.find( *it ) == buttonMap.end() )
				buttonMap.insert( std::make_pair( *it, std::list<WiiMote*>( 1, &secondary ) ) );
			else
				buttonMap[*it].push_back( &secondary );
		}
		
		buttons = primary.getDownButtons();
		for( WiiMote::ButtonList::iterator it = buttons.begin(); it != buttons.end(); ++it )
		{   // Process all butons just pressed on primary
			if( buttonMap.find( *it ) == buttonMap.end() )
				buttonMap.insert( std::make_pair( *it, std::list<WiiMote*>( 1, &primary ) ) );
			else
				buttonMap[*it].push_back( &primary );
		}
	
        buttons = primary.getUpButtons();
        for( WiiMote::ButtonList::iterator it = buttons.begin(); it != buttons.end(); ++it )
        {
            switch( *it )
            {
            case WiiMote::A:
            case WiiMote::B:
                if( primary.getGrabbedObject() )
                    primary.requestUngrab( primary.getGrabbedObject() );
                break;
            default:
                break;
            }
        }
        
        buttons = secondary.getUpButtons();
        for( WiiMote::ButtonList::iterator it = buttons.begin(); it != buttons.end(); ++it )
        {
            switch( *it )
            {
            case WiiMote::A:
            case WiiMote::B:
                if( secondary.getGrabbedObject() )
                    secondary.requestUngrab( secondary.getGrabbedObject() );
                break;
            default:
                break;
            }
        }
		
		for( std::map<WiiMote::button_t, std::list<WiiMote*> >::iterator it = buttonMap.begin(); it != buttonMap.end(); ++it )
		{
			switch( it->first )
			{
			case WiiMote::HOME:
				toggleMenu();
				break;
			case WiiMote::DOWN:
				if( menuOn )
					menu->pressedDown();
				break;
			case WiiMote::RIGHT:
				if( menuOn )
					menu->pressedRight();
				break;
			case WiiMote::LEFT:
				if( menuOn )
					menu->pressedLeft();
				break;
			case WiiMote::UP:
				if( menuOn )
					menu->pressedUp();
				break;
			case WiiMote::MINUS:
				cout << "MINUS was pressed" << endl;
				if( !menuOn )
				{
					iSelectMenuObj = 1;
					for( std::list<arInteractable*>::iterator it = SelectedObjects.begin(); it != SelectedObjects.end(); ++it )
						if( Node *n = dynamic_cast<Node*>( *it ) )
							n->setSelected( false );
					SelectedObjects.clear();
				}
				break;
			case WiiMote::PLUS:
				cout << "PLUS was pressed" << endl;
				if( !menuOn )
					iSelectMenuObj = 2;
				break;
			case WiiMote::A:
				iSelectMenuObj = 0;
				if( menuOn )
				{
					switch( menu->pressedA() )
					{
					case REDRAW:
						setMenuOff();
						setMenuOn();
						break;
					case CLOSE:
						setMenuOff();
						break;
					default:
						break;
					}
				}
				break;
			case WiiMote::ONE:
				for(std::list<WiiMote*>::iterator itt = it->second.begin(); itt != it->second.end(); ++itt)
				{
					(*itt)->toggleLightSaber();
				}
				break;
			default:
				break;
			}
		}
		
		// do ray-casting after menu actions
		if ( !menuOn ) {
			rightClosest = primary.closestObject(interactableObjects);
			leftClosest = secondary.closestObject(interactableObjects);
		}
		
		if( rightClosest )
		{
			rightClosest->touch( primary );
			
			if( primary.getButton( WiiMote::A ) && primary.getButton( WiiMote::B ) )
			{
				primary.requestScaleGrab( rightClosest );
			}
			else if( primary.getButton( WiiMote::A ) )
			{
				primary.requestPosGrab( rightClosest );
			}
			else if( primary.getButton( WiiMote::B ) )
			{
				primary.requestRotGrab( rightClosest );
			}
			else if(((primary.getButton( WiiMote::PLUS )) || (primary.getButton( WiiMote::MINUS ))) && ((iSelectMenuObj == 1) || (iSelectMenuObj == 2)))
			{
				bool found = false;
				std::list<arInteractable*> tempSelectedObjects;
				while (!SelectedObjects.empty())
				{
					if ( SelectedObjects.front() == rightClosest )
					{
						cout << "Removing right hand object to selected list" << endl;
						rightClosest->setSelected( false );
						SelectedObjects.pop_front();
						found = true;
						iSelectMenuObj = 0;
						break;
					}
					else
					{
						tempSelectedObjects.push_back( SelectedObjects.front() );
						SelectedObjects.pop_front();
					}
				}
				
				while (!tempSelectedObjects.empty())
				{
					SelectedObjects.push_back( tempSelectedObjects.front() );
					if( Node *n = dynamic_cast<Node*>( tempSelectedObjects.front() ) )
						n->setSelected( true );
					tempSelectedObjects.pop_front();
				}
				
				if (!found)
				{
					cout << "Adding right hand object to selected list" << endl;
					SelectedObjects.push_back( rightClosest );
					rightClosest->setSelected( true );
					iSelectMenuObj = 0;
				}
			}
		}
			
		if( leftClosest )
		{
			leftClosest->touch( secondary );
			if( secondary.getButton( WiiMote::A ) && secondary.getButton( WiiMote::B ) )
			{
				secondary.requestScaleGrab( leftClosest );
			}
			else if( secondary.getButton( WiiMote::A ) )
			{
				secondary.requestPosGrab( leftClosest );
			}
			else if( secondary.getButton( WiiMote::B ) )
			{
				secondary.requestRotGrab( leftClosest );
			}
			else if(((secondary.getButton( WiiMote::PLUS )) || (secondary.getButton( WiiMote::MINUS ))) && ((iSelectMenuObj == 1) || (iSelectMenuObj == 2)))
			{
				bool found = false;
				std::list<arInteractable*> tempSelectedObjects;
				while (!SelectedObjects.empty())
				{
					if ( SelectedObjects.front() == leftClosest )
					{
						cout << "Removing left hand object to selected list" << endl;
						leftClosest->setSelected( false );
						SelectedObjects.pop_front();
						found = true;
						iSelectMenuObj = 0;
						break;
					}
					else
					{
						tempSelectedObjects.push_back( SelectedObjects.front() );
						SelectedObjects.pop_front();
					}
				}
				
				while (!tempSelectedObjects.empty())
				{
					SelectedObjects.push_back( tempSelectedObjects.front() );
					if( Node *n = dynamic_cast<Node*>( tempSelectedObjects.front() ) )
						n->setSelected( true );
					tempSelectedObjects.pop_front();
				}
				
				if (!found)
				{
					cout << "Adding left hand object to selected list" << endl;
					SelectedObjects.push_back( leftClosest );
					leftClosest->setSelected( true );
					iSelectMenuObj = 0;
				}
			}
		}
	}
	
}