def handle(ea, aa, pObject, pNodeVisitor):
pViewer = dynamic_cast<osgViewer.Viewer*>(aa)
if not pViewer :
return False
if ea.getEventType()==osgGA.GUIEventAdapter.PUSH :
cams = osgViewer.ViewerBase.Cameras()
pViewer.getCameras( cams )
x = ea.getXnormalized()
y = ea.getYnormalized()
picker = osgUtil.LineSegmentIntersector( osgUtil.Intersector.PROJECTION, x, y )
iv = osgUtil.IntersectionVisitor( picker )
cams[0].accept( iv )
if picker.containsIntersections() :
intersection = picker.getFirstIntersection()
v = intersection.getWorldIntersectPoint()
m_rPatSphere.setPosition( v )
return True # return True, event handled
return False
def pick(ea, viewer):
scene = viewer.getSceneData()
if not scene : return
osg.notify(osg.NOTICE)
node = 0
parent = 0
if _usePolytopeIntersector :
picker = osgUtil.PolytopeIntersector*()
if _useWindowCoordinates :
# use window coordinates
# remap the mouse x,y into viewport coordinates.
viewport = viewer.getCamera().getViewport()
mx = viewport.x() + (int)((double )viewport.width()*(ea.getXnormalized()*0.5+0.5))
my = viewport.y() + (int)((double )viewport.height()*(ea.getYnormalized()*0.5+0.5))
# half width, height.
w = 5.0
h = 5.0
picker = osgUtil.PolytopeIntersector( osgUtil.Intersector.WINDOW, mx-w, my-h, mx+w, my+h )
else:
mx = ea.getXnormalized()
my = ea.getYnormalized()
w = 0.05
h = 0.05
picker = osgUtil.PolytopeIntersector( osgUtil.Intersector.PROJECTION, mx-w, my-h, mx+w, my+h )
iv = osgUtil.IntersectionVisitor(picker)
viewer.getCamera().accept(iv)
if picker.containsIntersections() :
intersection = picker.getFirstIntersection()
osg.notify(osg.NOTICE), "Picked ", intersection.localIntersectionPoint, " Distance to ref. plane ", intersection.distance, ", max. dist ", intersection.maxDistance, ", primitive index ", intersection.primitiveIndex, ", numIntersectionPoints ", intersection.numIntersectionPoints
nodePath = intersection.nodePath
node = nodePath[nodePath.size()-1] if ((nodePath.size()>=1)) else 0
parent = dynamic_cast<osg.Group*>(nodePath[nodePath.size()-2]) if ((nodePath.size()>=2)) else 0
if node : print " Hits ", node.className(), " nodePath size ", nodePath.size()
toggleScribe(parent, node)
def computeTerrainIntersection(subgraph, x, y):
bs = subgraph.getBound()
zMax = bs.center().z()+bs.radius()
zMin = bs.center().z()-bs.radius()
intersector = osgUtil.LineSegmentIntersector(osg.Vec3(x,y,zMin),osg.Vec3(x,y,zMax))
iv = osgUtil.IntersectionVisitor(intersector)
subgraph.accept(iv)
if intersector.containsIntersections() :
return intersector.getFirstIntersection().getWorldIntersectPoint()
return osg.Vec3(x,y,0.0)
def pick(self, x, y, viewer):
print "pick called"
g1 = osgUtil.IntersectorGroup()
l1 = osgUtil.LineSegmentIntersector(osgUtil.Intersector.PROJECTION, x,
y)
g1.addIntersector(l1)
iv = osgUtil.IntersectionVisitor(g1)
viewer.getCameraWithFocus().accept(iv)
#check for intersections
if l1.containsIntersections():
try:
intersection = l1.getFirstIntersection()
print 'World coordinates of intersection:'
print intersection.getWorldIntersectPoint()
print 'Local coordinates of intersection:'
print intersection.getLocalIntersectPoint()
except Exception, inst:
print inst
#find the first Transform node and make it the selected node
return False
deltaRow = osg.Vec3d( 0.0, 0.0, bs.radius()*0.01)
deltaColumn = osg.Vec3d( bs.radius()*0.01, 0.0, 0.0)
numRows = 20
numColumns = 20
intersectorGroup = osgUtil.IntersectorGroup()
for(unsigned int r=0 r<numRows ++r)
for(unsigned int c=0 c<numColumns ++c)
s = start + deltaColumn * double(c) + deltaRow * double(r)
e = end + deltaColumn * double(c) + deltaRow * double(r)
intersector = osgUtil.LineSegmentIntersector(s, e)
intersectorGroup.addIntersector( intersector )
intersectVisitor = osgUtil.IntersectionVisitor( intersectorGroup, MyReadCallback )()
scene.accept(intersectVisitor)
endTick = osg.Timer.instance().tick()
print "Completed in ", osg.Timer.instance().delta_s(startTick,endTick)
if intersectorGroup.containsIntersections() :
print "Found intersections "
intersectors = intersectorGroup.getIntersectors()
for(osgUtil.IntersectorGroup.Intersectors.iterator intersector_itr = intersectors.begin()
not = intersectors.end()
++intersector_itr)
lsi = dynamic_cast<osgUtil.LineSegmentIntersector*>(intersector_itr)
if lsi :
trees.reserve(trees.size()+numTreesToCreate)
for(unsigned int i=0i<numTreesToCreate++i)
tree = Tree()
tree._position.set(random(origin.x(),origin.x()+size.x()),random(origin.y(),origin.y()+size.y()),origin.z())
tree._color.set(random(128,255),random(128,255),random(128,255),255)
tree._width = random(min_TreeWidth,max_TreeWidth)
tree._height = random(min_TreeHeight,max_TreeHeight)
tree._type = 0
if terrain :
intersector = osgUtil.LineSegmentIntersector(tree._position,tree._position+osg.Vec3(0.0,0.0,size.z()))
iv = osgUtil.IntersectionVisitor(intersector)
terrain.accept(iv)
if intersector.containsIntersections() :
intersections = intersector.getIntersections()
for(osgUtil.LineSegmentIntersector.Intersections.iterator itr = intersections.begin()
not = intersections.end()
++itr)
intersection = *itr
tree._position = intersection.getWorldIntersectPoint()
trees.push_back(tree)
osg.Geometry* ForestTechniqueManager.createSprite( float w, float h, osg.Vec4ub color )
# set up the coords
class IntersectionUpdateCallback (osg.NodeCallback) :
virtual void operator()(osg.Node* #node, osg.NodeVisitor* nv)
if not root_ or not terrain_ or not ss_ or not intersectionGroup_ :
osg.notify(osg.NOTICE), "IntersectionUpdateCallback not set up correctly."
return
#traverse(node,nv)
frameCount_++
if frameCount_ > 200 :
# first we need find the transformation matrix that takes
# the terrain into the coordinate frame of the sphere segment.
terrainLocalToWorld = osg.Matrixd()
terrain_worldMatrices = terrain_.getWorldMatrices(root_)
if terrain_worldMatrices.empty() : terrainLocalToWorld.makeIdentity()
elif terrain_worldMatrices.size()==1 : terrainLocalToWorld = terrain_worldMatrices.front()
else:
osg.notify(osg.NOTICE), "IntersectionUpdateCallback: warning cannot interestect with multiple terrain instances, just uses first one."
terrainLocalToWorld = terrain_worldMatrices.front()
# sphere segment is easier as this callback is attached to the node, so the node visitor has the unique path to it already.
ssWorldToLocal = osg.computeWorldToLocal(nv.getNodePath())
# now we can compute the terrain to ss transform
possie = terrainLocalToWorld*ssWorldToLocal
lines = ss_.computeIntersection(possie, terrain_)
if not lines.empty() :
if intersectionGroup_.valid() :
# now we need to place the intersections which are in the SphereSegmenet's coordinate frame into
# to the final position.
mt = osg.MatrixTransform()
mt.setMatrix(osg.computeLocalToWorld(nv.getNodePath()))
intersectionGroup_.addChild(mt)
# print "matrix = ", mt.getMatrix()
geode = osg.Geode()
mt.addChild(geode)
geode.getOrCreateStateSet().setMode(GL_LIGHTING,osg.StateAttribute.OFF)
for(osgSim.SphereSegment.LineList.iterator itr=lines.begin()
not = lines.end()
++itr)
geom = osg.Geometry()
geode.addDrawable(geom)
vertices = itr
geom.setVertexArray(vertices)
geom.addPrimitiveSet(osg.DrawArrays(GL_LINE_STRIP, 0, vertices.getNumElements()))
else:
osg.notify(osg.NOTICE), "No intersections found"
frameCount_ = 0
root_ = osg.observer_ptr<osg.Group>()
terrain_ = osg.observer_ptr<osg.Geode>()
ss_ = osg.observer_ptr<osgSim.SphereSegment>()
intersectionGroup_ = osg.observer_ptr<osg.Group>()
frameCount_ = unsigned()
class RotateUpdateCallback (osg.NodeCallback) :
RotateUpdateCallback() i=0
virtual void operator()(osg.Node* node, osg.NodeVisitor* nv)
ss = dynamic_cast<osgSim.SphereSegment *>(node)
if ss :
ss.setArea(osg.Vec3(cos(i/(2*osg.PI)),sin(i/(2*osg.PI)),0), osg.PI_2, osg.PI_2)
i += 0.1
i = float()
def createMovingModel(center, radius, terrainGeode, root, createMovingRadar):
animationLength = 10.0
animationPath = createAnimationPath(center,radius,animationLength)
model = osg.Group()
glider = osgDB.readNodeFile("glider.osgt")
if glider :
bs = glider.getBound()
size = radius/bs.radius()*0.3
positioned = osg.MatrixTransform()
positioned.setDataVariance(osg.Object.STATIC)
positioned.setMatrix(osg.Matrix.translate(-bs.center())*
osg.Matrix.scale(size,size,size)*
osg.Matrix.rotate(osg.inDegrees(-90.0),0.0,0.0,1.0))
positioned.addChild(glider)
xform = osg.PositionAttitudeTransform()
xform.getOrCreateStateSet().setMode(GL_NORMALIZE, osg.StateAttribute.ON)
xform.setUpdateCallback(osg.AnimationPathCallback(animationPath,0.0,1.0))
xform.addChild(positioned)
model.addChild(xform)
if createMovingRadar :
# The IntersectionUpdateCallback has to have a safe place to put all its generated geometry into,
# and this group can't be in the parental chain of the callback otherwise we will end up invalidating
# traversal iterators.
intersectionGroup = osg.Group()
root.addChild(intersectionGroup)
xform = osg.PositionAttitudeTransform()
xform.setUpdateCallback(osg.AnimationPathCallback(animationPath,0.0,1.0))
ss = osgSim.SphereSegment(osg.Vec3d(0.0,0.0,0.0),
700.0, # radius
osg.DegreesToRadians(135.0),
osg.DegreesToRadians(240.0),
osg.DegreesToRadians(-60.0),
osg.DegreesToRadians(-40.0),
60)
iuc = IntersectionUpdateCallback()
iuc.frameCount_ = 0
iuc.root_ = root
iuc.terrain_ = terrainGeode
iuc.ss_ = ss
iuc.intersectionGroup_ = intersectionGroup
ss.setUpdateCallback(iuc)
ss.setAllColors(osg.Vec4(1.0,1.0,1.0,0.5))
ss.setSideColor(osg.Vec4(0.5,1.0,1.0,0.1))
xform.addChild(ss)
model.addChild(xform)
cessna = osgDB.readNodeFile("cessna.osgt")
if cessna :
bs = cessna.getBound()
text = osgText.Text()
size = radius/bs.radius()*0.3
text.setPosition(bs.center())
text.setText("Cessna")
text.setAlignment(osgText.Text.CENTER_CENTER)
text.setAxisAlignment(osgText.Text.SCREEN)
text.setCharacterSize(40.0)
text.setCharacterSizeMode(osgText.Text.OBJECT_COORDS)
geode = osg.Geode()
geode.addDrawable(text)
lod = osg.LOD()
lod.setRangeMode(osg.LOD.PIXEL_SIZE_ON_SCREEN)
lod.setRadius(cessna.getBound().radius())
lod.addChild(geode,0.0,100.0)
lod.addChild(cessna,100.0,10000.0)
positioned = osg.MatrixTransform()
positioned.getOrCreateStateSet().setMode(GL_NORMALIZE, osg.StateAttribute.ON)
positioned.setDataVariance(osg.Object.STATIC)
positioned.setMatrix(osg.Matrix.translate(-bs.center())*
osg.Matrix.scale(size,size,size)*
osg.Matrix.rotate(osg.inDegrees(180.0),0.0,0.0,1.0))
#positioned.addChild(cessna)
positioned.addChild(lod)
xform = osg.MatrixTransform()
xform.setUpdateCallback(osg.AnimationPathCallback(animationPath,0.0,2.0))
xform.addChild(positioned)
model.addChild(xform)
return model
def createOverlay(center, radius):
group = osg.Group()
# create a grid of lines.
geom = osg.Geometry()
num_rows = 10
left = center+osg.Vec3(-radius,-radius,0.0)
right = center+osg.Vec3(radius,-radius,0.0)
delta_row = osg.Vec3(0.0,2.0*radius/float(num_rows-1),0.0)
top = center+osg.Vec3(-radius,radius,0.0)
bottom = center+osg.Vec3(-radius,-radius,0.0)
delta_column = osg.Vec3(2.0*radius/float(num_rows-1),0.0,0.0)
vertices = osg.Vec3Array()
for(unsigned int i=0 i<num_rows ++i)
vertices.push_back(left)
vertices.push_back(right)
left += delta_row
right += delta_row
vertices.push_back(top)
vertices.push_back(bottom)
top += delta_column
bottom += delta_column
geom.setVertexArray(vertices)
color = *(osg.Vec4ubArray(1))
color[0].set(0,0,0,255)
geom.setColorArray(color, osg.Array.BIND_OVERALL)
geom.addPrimitiveSet(osg.DrawArrays(GL_LINES,0,vertices.getNumElements()))
geom.getOrCreateStateSet().setMode(GL_LIGHTING,osg.StateAttribute.OFF)
geode = osg.Geode()
geode.addDrawable(geom)
group.addChild(geode)
return group
def computeTerrainIntersection(subgraph, x, y):
bs = subgraph.getBound()
zMax = bs.center().z()+bs.radius()
zMin = bs.center().z()-bs.radius()
intersector = osgUtil.LineSegmentIntersector(osg.Vec3(x,y,zMin),osg.Vec3(x,y,zMax))
iv = osgUtil.IntersectionVisitor(intersector)
subgraph.accept(iv)
if intersector.containsIntersections() :
return intersector.getFirstIntersection().getWorldIntersectPoint()
return osg.Vec3(x,y,0.0)
#######################################
# MAIN SCENE GRAPH BUILDING FUNCTION
#######################################
def build_world(root, testCase, useOverlay, technique):
# create terrain
terrainGeode = 0
terrainGeode = osg.Geode()
stateset = osg.StateSet()
image = osgDB.readImageFile("Images/lz.rgb")
if image :
texture = osg.Texture2D()
texture.setImage(image)
stateset.setTextureAttributeAndModes(0,texture,osg.StateAttribute.ON)
terrainGeode.setStateSet( stateset )
numColumns = 38
numRows = 39
unsigned int r, c
origin = osg.Vec3(0.0,0.0,0.0)
size = osg.Vec3(1000.0,1000.0,250.0)
geometry = osg.Geometry()
v = *(osg.Vec3Array(numColumns*numRows))
tc = *(osg.Vec2Array(numColumns*numRows))
color = *(osg.Vec4ubArray(1))
color[0].set(255,255,255,255)
rowCoordDelta = size.y()/(float)(numRows-1)
columnCoordDelta = size.x()/(float)(numColumns-1)
rowTexDelta = 1.0/(float)(numRows-1)
columnTexDelta = 1.0/(float)(numColumns-1)
# compute z range of z values of grid data so we can scale it.
min_z = FLT_MAX
max_z = -FLT_MAX
for(r=0r<numRows++r)
for(c=0c<numColumns++c)
min_z = osg.minimum(min_z,vertex[r+c*numRows][2])
max_z = osg.maximum(max_z,vertex[r+c*numRows][2])
scale_z = size.z()/(max_z-min_z)
pos = origin
tex = osg.Vec2(0.0,0.0)
vi = 0
for(r=0r<numRows++r)
pos.x() = origin.x()
tex.x() = 0.0
for(c=0c<numColumns++c)
v[vi].set(pos.x(),pos.y(),pos.z()+(vertex[r+c*numRows][2]-min_z)*scale_z)
tc[vi] = tex
pos.x()+=columnCoordDelta
tex.x()+=columnTexDelta
++vi
pos.y() += rowCoordDelta
tex.y() += rowTexDelta
geometry.setVertexArray(v)
geometry.setTexCoordArray(0, tc)
geometry.setColorArray(color, osg.Array.BIND_OVERALL)
for(r=0r<numRows-1++r)
drawElements = *(osg.DrawElementsUShort(GL_QUAD_STRIP,2*numColumns))
geometry.addPrimitiveSet(drawElements)
ei = 0
for(c=0c<numColumns++c)
drawElements[ei++] = (r+1)*numColumns+c
drawElements[ei++] = (r)*numColumns+c
smoother = osgUtil.SmoothingVisitor()
smoother.smooth(*geometry)
terrainGeode.addDrawable(geometry)
# create sphere segment
ss = 0
terrainToSS = osg.Matrix()
switch(testCase)
case(0):
ss = osgSim.SphereSegment(
computeTerrainIntersection(terrainGeode,550.0,780.0), # center
510.0, # radius
osg.DegreesToRadians(135.0),
osg.DegreesToRadians(240.0),
osg.DegreesToRadians(-10.0),
osg.DegreesToRadians(30.0),
60)
root.addChild(ss)
break
case(1):
ss = osgSim.SphereSegment(
computeTerrainIntersection(terrainGeode,550.0,780.0), # center
510.0, # radius
osg.DegreesToRadians(45.0),
osg.DegreesToRadians(240.0),
osg.DegreesToRadians(-10.0),
osg.DegreesToRadians(30.0),
60)
root.addChild(ss)
break
case(2):
ss = osgSim.SphereSegment(
computeTerrainIntersection(terrainGeode,550.0,780.0), # center
510.0, # radius
osg.DegreesToRadians(5.0),
osg.DegreesToRadians(355.0),
osg.DegreesToRadians(-10.0),
osg.DegreesToRadians(30.0),
60)
root.addChild(ss)
break
case(3):
ss = osgSim.SphereSegment(
computeTerrainIntersection(terrainGeode,550.0,780.0), # center
510.0, # radius
osg.DegreesToRadians(0.0),
osg.DegreesToRadians(360.0),
osg.DegreesToRadians(-10.0),
osg.DegreesToRadians(30.0),
60)
root.addChild(ss)
break
case(4):
ss = osgSim.SphereSegment(osg.Vec3d(0.0,0.0,0.0),
700.0, # radius
osg.DegreesToRadians(135.0),
osg.DegreesToRadians(240.0),
osg.DegreesToRadians(-60.0),
osg.DegreesToRadians(-40.0),
60)
mt = osg.MatrixTransform()
mt.setMatrix(osg.Matrix(-0.851781, 0.156428, -0.5, 0,
-0.180627, -0.983552, -6.93889e-18, 0,
-0.491776, 0.0903136, 0.866025, 0,
598.217, 481.957, 100, 1))
mt.addChild(ss)
terrainToSS.invert(mt.getMatrix())
root.addChild(mt)
break
case(5):
ss = osgSim.SphereSegment(osg.Vec3d(0.0,0.0,0.0),
700.0, # radius
osg.DegreesToRadians(35.0),
osg.DegreesToRadians(135.0),
osg.DegreesToRadians(-60.0),
osg.DegreesToRadians(-40.0),
60)
mt = osg.MatrixTransform()
mt.setMatrix(osg.Matrix(-0.851781, 0.156428, -0.5, 0,
-0.180627, -0.983552, -6.93889e-18, 0,
-0.491776, 0.0903136, 0.866025, 0,
598.217, 481.957, 100, 1))
mt.addChild(ss)
terrainToSS.invert(mt.getMatrix())
root.addChild(mt)
break
case(6):
ss = osgSim.SphereSegment(osg.Vec3d(0.0,0.0,0.0),
700.0, # radius
osg.DegreesToRadians(-45.0),
osg.DegreesToRadians(45.0),
osg.DegreesToRadians(-60.0),
osg.DegreesToRadians(-40.0),
60)
mt = osg.MatrixTransform()
mt.setMatrix(osg.Matrix(-0.851781, 0.156428, -0.5, 0,
-0.180627, -0.983552, -6.93889e-18, 0,
-0.491776, 0.0903136, 0.866025, 0,
598.217, 481.957, 100, 1))
mt.addChild(ss)
terrainToSS.invert(mt.getMatrix())
root.addChild(mt)
break
case(7):
ss = osgSim.SphereSegment(
computeTerrainIntersection(terrainGeode,550.0,780.0), # center
510.0, # radius
osg.DegreesToRadians(-240.0),
osg.DegreesToRadians(-135.0),
osg.DegreesToRadians(-10.0),
osg.DegreesToRadians(30.0),
60)
ss.setUpdateCallback(RotateUpdateCallback())
root.addChild(ss)
break
if ss.valid() :
ss.setAllColors(osg.Vec4(1.0,1.0,1.0,0.5))
ss.setSideColor(osg.Vec4(0.0,1.0,1.0,0.1))
if not ss.getParents().empty() :
ss.getParent(0).addChild(ss.computeIntersectionSubgraph(terrainToSS, terrainGeode))
if useOverlay :
overlayNode = osgSim.OverlayNode(technique)
overlayNode.getOrCreateStateSet().setTextureAttribute(1, osg.TexEnv(osg.TexEnv.DECAL))
bs = terrainGeode.getBound()
overlaySubgraph = createOverlay(bs.center(), bs.radius()*0.5)
overlaySubgraph.addChild(ss)
overlayNode.setOverlaySubgraph(overlaySubgraph)
overlayNode.setOverlayTextureSizeHint(1024)
overlayNode.setOverlayBaseHeight(0.0)
overlayNode.addChild(terrainGeode)
root.addChild(overlayNode)
else:
root.addChild(terrainGeode)
# create particle effects
position = computeTerrainIntersection(terrainGeode,100.0,100.0)
explosion = osgParticle.ExplosionEffect(position, 10.0)
smoke = osgParticle.SmokeEffect(position, 10.0)
fire = osgParticle.FireEffect(position, 10.0)
root.addChild(explosion)
root.addChild(smoke)
root.addChild(fire)
# create particle effects
position = computeTerrainIntersection(terrainGeode,200.0,100.0)
explosion = osgParticle.ExplosionEffect(position, 1.0)
smoke = osgParticle.SmokeEffect(position, 1.0)
fire = osgParticle.FireEffect(position, 1.0)
root.addChild(explosion)
root.addChild(smoke)
root.addChild(fire)
createMovingRadar = True
# create the moving models.
root.addChild(createMovingModel(osg.Vec3(500.0,500.0,500.0),100.0, terrainGeode, root, createMovingRadar))
#######################################
# main()
#######################################
def main(argv):
# use an ArgumentParser object to manage the program arguments.
arguments = osg.ArgumentParser(argv)
# set up the usage document, in case we need to print out how to use this program.
arguments.getApplicationUsage().setDescription(arguments.getApplicationName()+" is the example which demonstrates use of particle systems.")
arguments.getApplicationUsage().setCommandLineUsage(arguments.getApplicationName()+" [options] image_file_left_eye image_file_right_eye")
arguments.getApplicationUsage().addCommandLineOption("-h or --help","Display this information")
# construct the viewer.
viewer = osgViewer.Viewer(arguments)
# if user request help write it out to cout.
testCase = 0
while arguments.read("-t", testCase) :
useOverlay = False
technique = osgSim.OverlayNode.OBJECT_DEPENDENT_WITH_ORTHOGRAPHIC_OVERLAY
while arguments.read("--object") : useOverlay = True technique = osgSim.OverlayNode.OBJECT_DEPENDENT_WITH_ORTHOGRAPHIC_OVERLAY
while arguments.read("--ortho") or arguments.read("--orthographic") : useOverlay = True technique = osgSim.OverlayNode.VIEW_DEPENDENT_WITH_ORTHOGRAPHIC_OVERLAY
while arguments.read("--persp") or arguments.read("--perspective") : useOverlay = True technique = osgSim.OverlayNode.VIEW_DEPENDENT_WITH_PERSPECTIVE_OVERLAY
# if user request help write it out to cout.
if arguments.read("-h") or arguments.read("--help") :
arguments.getApplicationUsage().write(std.cout)
return 1
# any option left unread are converted into errors to write out later.
arguments.reportRemainingOptionsAsUnrecognized()
# report any errors if they have occurred when parsing the program arguments.
if arguments.errors() :
arguments.writeErrorMessages(std.cout)
return 1
root = osg.Group()
build_world(root, testCase, useOverlay, technique)
# add a viewport to the viewer and attach the scene graph.
viewer.setSceneData(root)
return viewer.run()
if __name__ == "__main__":
main(sys.argv)
if node : print " Hits ", node.className(), " nodePath size ", nodePath.size()
toggleScribe(parent, node)
else:
picker = osgUtil.LineSegmentIntersector*()
if not _useWindowCoordinates :
# use non dimensional coordinates - in projection/clip space
picker = osgUtil.LineSegmentIntersector( osgUtil.Intersector.PROJECTION, ea.getXnormalized(),ea.getYnormalized() )
else:
# use window coordinates
# remap the mouse x,y into viewport coordinates.
viewport = viewer.getCamera().getViewport()
mx = viewport.x() + (int)((float)viewport.width()*(ea.getXnormalized()*0.5+0.5))
my = viewport.y() + (int)((float)viewport.height()*(ea.getYnormalized()*0.5+0.5))
picker = osgUtil.LineSegmentIntersector( osgUtil.Intersector.WINDOW, mx, my )
iv = osgUtil.IntersectionVisitor(picker)
viewer.getCamera().accept(iv)
if picker.containsIntersections() :
intersection = picker.getFirstIntersection()
osg.notify(osg.NOTICE), "Picked ", intersection.localIntersectionPoint
nodePath = intersection.nodePath
node = nodePath[nodePath.size()-1] if ((nodePath.size()>=1)) else 0
parent = dynamic_cast<osg.Group*>(nodePath[nodePath.size()-2]) if ((nodePath.size()>=2)) else 0
if node : print " Hits ", node.className(), " nodePath size", nodePath.size()
toggleScribe(parent, node)
# now we try to decorate the hit node by the osgFX.Scribe to show that its been "picked"