def zapolnenie(world, n, mi, ma):
for i in range(n):
sphere = loader.loadModel("smiley.egg")
sphere.reparentTo(render)
r = randint(mi, ma)
sphere.setPos(
sin(i * 2 * pi / n) * r,
cos(i * 2 * pi / n) * r, r // 1.5)
sphereBody = OdeBody(world.myWorld)
sphereModel = OdeMass()
sphereModel.setSphere(1, 2)
sphereBody.setMass(sphereModel)
sphereBody.setPosition(
sin(i * 2 * pi / n) * r,
cos(i * 2 * pi / n) * r, r // 1.5)
world.spheres.append(sphereBody)
world.objs.append(sphere)
for i in range(n - 1):
sphereJoint = OdeBallJoint(world.myWorld)
sphereJoint.attach(world.spheres[i], world.spheres[i + 1])
sphereJoint.setAnchor(world.spheres[i].getPosition())
world.joints.append(sphereJoint)
sphereJoint = OdeBallJoint(world.myWorld)
sphereJoint.attach(world.spheres[-1], world.spheres[0])
sphereJoint.setAnchor(world.spheres[-1].getPosition())
world.joints.append(sphereJoint)
class MyApp(ShowBase):
def __init__(self):
ShowBase.__init__(self)
dlight = DirectionalLight('dlight')
dlight.setColor(VBase4(0.8, 0.8, 0.5, 1))
dlnp = self.render.attachNewNode(dlight)
dlnp.setHpr(0, -60, 0)
self.render.setLight(dlnp)
self.balls = [Ball(self) for x in range(NUMBALLS)]
# Setup our physics world and the body
self.world = OdeWorld()
self.world.setGravity(0, 0, -9.81)
if 0:
self.body = OdeBody(self.world)
M = OdeMass()
M.setSphere(7874, 1.0)
self.body.setMass(M)
self.body.setPosition(self.sphere.getPos(self.render))
self.body.setQuaternion(self.sphere.getQuat(self.render))
## Set the camera position
self.disableMouse()
self.angle = 0.0
self.camera.setPos(1000, 1000, 1000)
self.camera.lookAt(0, 0, 0)
#self.enableMouse()
# Create an accumulator to track the time since the sim
# has been running
self.deltaTimeAccumulator = 0.0
# This stepSize makes the simulation run at 60 frames per second
self.stepSize = 1.0 / 60.0
taskMgr.doMethodLater(1.0, self.simulationTask, "Physics Simulation")
def simulationTask(self, task):
if 0:
# Add the deltaTime for the task to the accumulator
self.deltaTimeAccumulator += globalClock.getDt()
while self.deltaTimeAccumulator > self.stepSize:
# Remove a stepSize from the accumulator until
# the accumulated time is less than the stepsize
self.deltaTimeAccumulator -= self.stepSize
# Step the simulation
self.world.quickStep(self.stepSize)
for ball in self.balls:
ball.evolve()
deltas = [ball.getdelta(self.balls) for ball in self.balls]
for i, ball in enumerate(self.balls):
dx, dy, dz = deltas[i]
ball.move(dx, dy, dz)
ball.update()
#print "moved"
self.camera.setPos(CX + 2500 * math.sin(self.angle),
CY + 2500 * math.cos(self.angle), CZ)
self.camera.lookAt(CX, CY, CZ)
self.angle += 0.01
return task.cont
class MyApp(ShowBase):
def __init__(self):
ShowBase.__init__(self)
dlight = DirectionalLight("dlight")
dlight.setColor(VBase4(0.8, 0.8, 0.5, 1))
dlnp = self.render.attachNewNode(dlight)
dlnp.setHpr(0, -60, 0)
self.render.setLight(dlnp)
self.balls = [Ball(self) for x in range(NUMBALLS)]
# Setup our physics world and the body
self.world = OdeWorld()
self.world.setGravity(0, 0, -9.81)
if 0:
self.body = OdeBody(self.world)
M = OdeMass()
M.setSphere(7874, 1.0)
self.body.setMass(M)
self.body.setPosition(self.sphere.getPos(self.render))
self.body.setQuaternion(self.sphere.getQuat(self.render))
## Set the camera position
self.disableMouse()
self.angle = 0.0
self.camera.setPos(1000, 1000, 1000)
self.camera.lookAt(0, 0, 0)
# self.enableMouse()
# Create an accumulator to track the time since the sim
# has been running
self.deltaTimeAccumulator = 0.0
# This stepSize makes the simulation run at 60 frames per second
self.stepSize = 1.0 / 60.0
taskMgr.doMethodLater(1.0, self.simulationTask, "Physics Simulation")
def simulationTask(self, task):
if 0:
# Add the deltaTime for the task to the accumulator
self.deltaTimeAccumulator += globalClock.getDt()
while self.deltaTimeAccumulator > self.stepSize:
# Remove a stepSize from the accumulator until
# the accumulated time is less than the stepsize
self.deltaTimeAccumulator -= self.stepSize
# Step the simulation
self.world.quickStep(self.stepSize)
for ball in self.balls:
ball.evolve()
deltas = [ball.getdelta(self.balls) for ball in self.balls]
for i, ball in enumerate(self.balls):
dx, dy, dz = deltas[i]
ball.move(dx, dy, dz)
ball.update()
# print "moved"
self.camera.setPos(CX + 2500 * math.sin(self.angle), CY + 2500 * math.cos(self.angle), CZ)
self.camera.lookAt(CX, CY, CZ)
self.angle += 0.01
return task.cont
def createBonded():
global world
electrons.append(
electron(random.randint(-10, 10), random.randint(-10, 10),
random.randint(-10, 10), True))
body = OdeBody(world)
M = OdeMass()
M.setSphere(7874, 1.0)
body.setMass(M)
bodies.append(body)
button4.setText(("Remove Bonded Pair", "Destroy", "Destroy", "disabled"))
def add_smiley(self, x, y, z):
sm = render.attachNewNode("smiley-instance")
sm.setPos(x, y, z)
self.smiley.instanceTo(sm)
body = OdeBody(self.world)
mass = OdeMass()
mass.setSphereTotal(10, 1)
body.setMass(mass)
body.setPosition(sm.getPos())
geom = OdeSphereGeom(self.space, 1)
geom.setBody(body)
sm.setPythonTag("body", body)
return body
def add_smiley(self, x, y, z):
sm = render.attachNewNode("smiley-instance")
sm.setPos(x, y, z)
self.smiley.instanceTo(sm)
body = OdeBody(self.world)
mass = OdeMass()
mass.setSphereTotal(10, 1)
body.setMass(mass)
body.setPosition(sm.getPos())
geom = OdeSphereGeom(self.space, 1)
geom.setBody(body)
sm.setPythonTag("body", body)
return body
def createTire(self, tireIndex):
if tireIndex < 0 or tireIndex >= len(self.tireMasks):
self.notify.error('invalid tireIndex %s' % tireIndex)
self.notify.debug('create tireindex %s' % tireIndex)
zOffset = 0
body = OdeBody(self.world)
mass = OdeMass()
mass.setSphere(self.tireDensity, IceGameGlobals.TireRadius)
body.setMass(mass)
body.setPosition(IceGameGlobals.StartingPositions[tireIndex][0],
IceGameGlobals.StartingPositions[tireIndex][1],
IceGameGlobals.StartingPositions[tireIndex][2])
body.setAutoDisableDefaults()
geom = OdeSphereGeom(self.space, IceGameGlobals.TireRadius)
self.space.setSurfaceType(geom, self.tireSurfaceType)
self.space.setCollideId(geom, self.tireCollideIds[tireIndex])
self.massList.append(mass)
self.geomList.append(geom)
geom.setCollideBits(self.allTiresMask | self.wallMask | self.floorMask
| self.obstacleMask)
geom.setCategoryBits(self.tireMasks[tireIndex])
geom.setBody(body)
if self.notify.getDebug():
self.notify.debug('tire geom id')
geom.write()
self.notify.debug(' -')
if self.canRender:
testTire = render.attachNewNode('tire holder %d' % tireIndex)
smileyModel = NodePath()
if not smileyModel.isEmpty():
smileyModel.setScale(IceGameGlobals.TireRadius)
smileyModel.reparentTo(testTire)
smileyModel.setAlphaScale(0.5)
smileyModel.setTransparency(1)
testTire.setPos(IceGameGlobals.StartingPositions[tireIndex])
tireModel = loader.loadModel(
'phase_4/models/minigames/ice_game_tire')
tireHeight = 1
tireModel.setZ(-IceGameGlobals.TireRadius + 0.01)
tireModel.reparentTo(testTire)
self.odePandaRelationList.append((testTire, body))
else:
testTire = None
self.bodyList.append((None, body))
return (testTire, body, geom)
def createTire(self, tireIndex):
if tireIndex < 0 or tireIndex >= len(self.tireMasks):
self.notify.error('invalid tireIndex %s' % tireIndex)
self.notify.debug('create tireindex %s' % tireIndex)
zOffset = 0
body = OdeBody(self.world)
mass = OdeMass()
mass.setSphere(self.tireDensity, IceGameGlobals.TireRadius)
body.setMass(mass)
body.setPosition(IceGameGlobals.StartingPositions[tireIndex][0], IceGameGlobals.StartingPositions[tireIndex][1], IceGameGlobals.StartingPositions[tireIndex][2])
body.setAutoDisableDefaults()
geom = OdeSphereGeom(self.space, IceGameGlobals.TireRadius)
self.space.setSurfaceType(geom, self.tireSurfaceType)
self.space.setCollideId(geom, self.tireCollideIds[tireIndex])
self.massList.append(mass)
self.geomList.append(geom)
geom.setCollideBits(self.allTiresMask | self.wallMask | self.floorMask | self.obstacleMask)
geom.setCategoryBits(self.tireMasks[tireIndex])
geom.setBody(body)
if self.notify.getDebug():
self.notify.debug('tire geom id')
geom.write()
self.notify.debug(' -')
if self.canRender:
testTire = render.attachNewNode('tire holder %d' % tireIndex)
smileyModel = NodePath()
if not smileyModel.isEmpty():
smileyModel.setScale(IceGameGlobals.TireRadius)
smileyModel.reparentTo(testTire)
smileyModel.setAlphaScale(0.5)
smileyModel.setTransparency(1)
testTire.setPos(IceGameGlobals.StartingPositions[tireIndex])
tireModel = loader.loadModel('phase_4/models/minigames/ice_game_tire')
tireHeight = 1
tireModel.setZ(-IceGameGlobals.TireRadius + 0.01)
tireModel.reparentTo(testTire)
self.odePandaRelationList.append((testTire, body))
else:
testTire = None
self.bodyList.append((None, body))
return (testTire, body, geom)
# Add a random amount of boxes boxes = [] # Setup the geometry boxNP = box.copyTo(render) boxNP.setPos(randint(-10, 10), randint(-10, 10), 10 + random()) boxNP.setColor(random(), random(), random(), 1) boxNP.setHpr(0, 45, 0) # Create the body and set the mass boxBody = OdeBody(world) M = OdeMass() M.setBox(20, 1, 1, 1) boxBody.setMass(M) boxBody.setPosition(boxNP.getPos(render)) boxBody.setQuaternion(boxNP.getQuat(render)) # Create a BoxGeom boxGeom = OdeBoxGeom(space, 4, 4, 1) boxGeom.setCollideBits(BitMask32(0x00000002)) boxGeom.setCategoryBits(BitMask32(0x00000001)) boxGeom.setBody(boxBody) boxes.append((boxNP, boxBody)) boxNP2 = box.copyTo(render) boxNP2.reparentTo(boxNP) boxNP2.setPos(0.5, 0.5, 0) boxNP2.setScale(0.1, 0.1, 4)
sphere_b = cm.gen_sphere(radius=radius) sphere_b.set_pos([0, 1.25, -.7]) sphere_b.set_rgba([.3, .2, 1, 1]) sphere_b.attach_to(base) gm.gen_linesegs([[np.zeros(3), sphere_a.get_pos()]], thickness=.05, rgba=[0, 1, 0, 1]).attach_to(base) gm.gen_linesegs([[sphere_a.get_pos(), sphere_b.get_pos()]], thickness=.05, rgba=[0, 0, 1, 1]).attach_to(base) # Setup our physics world and the body world = OdeWorld() world.setGravity(0, 0, -9.81) body_sphere_a = OdeBody(world) M = OdeMass() M.setSphere(7874, radius) body_sphere_a.setMass(M) body_sphere_a.setPosition(da.npv3_to_pdv3(sphere_a.get_pos())) body_sphere_b = OdeBody(world) M = OdeMass() M.setSphere(7874, radius) body_sphere_b.setMass(M) body_sphere_b.setPosition(da.npv3_to_pdv3(sphere_b.get_pos())) # Create the joints earth_a_jnt = OdeBallJoint(world) earth_a_jnt.attach(body_sphere_a, None) # Attach it to the environment earth_a_jnt.setAnchor(0, 0, 0) earth_b_jnt = OdeBallJoint(world) earth_b_jnt.attach(body_sphere_a, body_sphere_b) earth_b_jnt.setAnchor(0, .3, -.3)
class Physical(Touchable):
"""
The Physical class is the base class for anything that responds to physics
"""
def __init__(self, world, mass, geom, model, loc = Point3(), rot = True):
super(Physical, self).__init__(world, geom, model, loc)
self.toRevert['rot'] = self.setRot
self.toSave['rot'] = self.getRot
self.toRevert['vel'] = self.setVel
self.toSave['vel'] = self.getVel
self.toRevert['angVel'] = self.setAngVel
self.toSave['angVel'] = self.getAngVel
self.setRevertable(True)
self.body = OdeBody(world.world)
self.mass = mass
self.body.setMass(self.mass)
self.body.setPosition(self.model.getPos())
self.body.setQuaternion(self.model.getQuat())
self.geom.setBody(self.body)
self.rot = rot
def constrainQuat(self):
"""keep the object rotating in the correct plane"""
#FIXME is there a better way than fixing at every instant?
if not self.rot:
self.body.setQuaternion(Quat.identQuat())
return
q = self.body.getQuaternion()
q[1] = 0
q[2] = 0
q.normalize()
self.body.setQuaternion(Quat(q))
def getPos(self):
return self.body.getPosition()
def setPos(self, pos):
return self.body.setPosition(pos)
def setRot(self, rot):
self.body.setQuaternion(Quat(rot))
def getRot(self):
return self.body.getQuaternion()
def setVel(self, vel):
self.body.setLinearVel(vel)
def getVel(self):
return self.body.getLinearVel()
def setAngVel(self, angVel):
self.body.setAngularVel(angVel)
def getAngVel(self):
return self.body.getAngularVel()
box.setTextureOff()
# Add a random amount of boxes
boxes = []
for i in range(randint(5, 10)):
# Setup the geometry
boxNP = box.copyTo(render)
# boxNP.setPos(randint(-10, 10), randint(-10, 10), 10 + random())
boxNP.setPos(random() * 10, random() * 10, 10 + random())
boxNP.setColor(random(), random(), random(), 1)
boxNP.setHpr(randint(-45, 45), randint(-45, 45), randint(-45, 45))
# Create the body and set the mass
boxBody = OdeBody(world)
M = OdeMass()
M.setBox(5, 1, 1, 1)
boxBody.setMass(M)
boxBody.setPosition(boxNP.getPos(render))
boxBody.setQuaternion(boxNP.getQuat(render))
# Create a BoxGeom
boxGeom = OdeBoxGeom(space, 1, 1, 1)
# boxGeom = OdeTriMeshGeom(space, OdeTriMeshData(boxNP, True))
boxGeom.setCollideBits(BitMask32(0x00000002))
boxGeom.setCategoryBits(BitMask32(0x00000001))
boxGeom.setBody(boxBody)
boxes.append((boxNP, boxBody))
# Add a plane to collide with
cm = CardMaker("ground")
cm.setFrame(-20, 20, -20, 20)
ground = render.attachNewNode(cm.generate())
ground.setPos(0, 0, 0)
cube.setColor(0.2, 0, 0.7)
cube.setScale(20)
# Load the smiley model which will act as our iron ball
sphere = loader.loadModel("smiley.egg")
sphere.reparentTo(render)
sphere.setPos(10, 1, 21)
sphere.setColor(0.7, 0.4, 0.4)
# Setup our physics world and the body
world = OdeWorld()
world.setGravity(0, 0, -9.81)
body = OdeBody(world)
M = OdeMass()
M.setSphere(7874, 1.0)
body.setMass(M)
body.setPosition(sphere.getPos())
body.setQuaternion(sphere.getQuat())
# Set the camera position
base.disableMouse()
base.camera.setPos(80, -20, 40)
base.camera.lookAt(0, 0, 10)
# Create an accumulator to track the time since the sim
# has been running
deltaTimeAccumulator = 0.0
# This stepSize makes the simulation run at 90 frames per second
stepSize = 1.0 / 90.0
# The task for our simulation