Exemplo n.º 1
0
def test_get_steering():
    world = BulletWorld()
    # Chassis
    shape = BulletBoxShape(Vec3(0.6, 1.4, 0.5))
    body = BulletRigidBodyNode('Vehicle')
    body.addShape(shape)
    world.attach(body)
    # Vehicle
    vehicle = BulletVehicle(world, body)
    world.attachVehicle(vehicle)
    # Wheel
    wheel = vehicle.createWheel()
    wheel.setSteering(30.0)
    # Returns the steering angle in degrees.
    assert wheel.getSteering() == approx(30.0)
Exemplo n.º 2
0
class Drive(ShowBase):
	def __init__(self):
		ShowBase.__init__(self)
		
		#Setup
		scene = BulletWorld()
		scene.setGravity(Vec3(0, 0, -9.81))
		base.setBackgroundColor(0.6,0.9,0.9)
		fog = Fog("The Fog")
		fog.setColor(0.9,0.9,1.0)
		fog.setExpDensity(0.003)
		render.setFog(fog)
		#Lighting
		
		#Sun light
		sun = DirectionalLight("The Sun")
		sun_np = render.attachNewNode(sun)
		sun_np.setHpr(0,-60,0)
		render.setLight(sun_np)
		
		#Ambient light
		amb = AmbientLight("The Ambient Light")
		amb.setColor(VBase4(0.39,0.39,0.39, 1))
		amb_np = render.attachNewNode(amb)
		render.setLight(amb_np)
		
		#Variables
		self.gear = 0
		
		self.start = 0
		
		self.Pbrake = 0
		
		self.terrain_var = 1
		
		self.time = 0
		
		self.headlight_var = 0
		
		self.RPM = 0
		
		self.clutch = 0
		
		self.carmaxspeed = 100 #KPH
		
		self.carmaxreversespeed = -40 #KPH
		
		self.steering = 0
		
		
		#Functions
		def V1():
			camera.setPos(0.25,-1.2,0.5)
			camera.setHpr(0,-13,0)
			
		def V2():
			camera.setPos(0,-15,3)
			camera.setHpr(0,-10,0)
			
		def V3():
			camera.setPos(0,0,9)
			camera.setHpr(0,-90,0)
			
		def up():
			self.gear = self.gear -1
			if self.gear < -1:
				self.gear = -1
				
		def down():
			self.gear = self.gear +1
			if self.gear > 1:
				self.gear = 1
				
		def start_function():
			self.start = 1
			self.start_sound.play()
			self.engine_idle_sound.play()
			self.RPM = 1000
			
		def stop_function():
			self.start = 0
			self.engine_idle_sound.stop()
				
		def parkingbrake():
			self.Pbrake = (self.Pbrake + 1) % 2
			
		def rotate():
			Car_np.setHpr(0, 0, 0)
			
		def horn():
			self.horn_sound.play()
			
		def set_time():
			if self.time == -1:
				sun.setColor(VBase4(0.4, 0.3, 0.3, 1))
				base.setBackgroundColor(0.8,0.7,0.7)
			if self.time == 0:
				sun.setColor(VBase4(0.7, 0.7, 0.7, 1))
				base.setBackgroundColor(0.6,0.9,0.9)
			if self.time == 1:
				sun.setColor(VBase4(0.2, 0.2, 0.2, 1))
				base.setBackgroundColor(0.55,0.5,0.5)
			if self.time == 2:
				sun.setColor(VBase4(0.02, 0.02, 0.05, 1))
				base.setBackgroundColor(0.3,0.3,0.3)
				
			if self.time == -2:
				self.time = -1
			if self.time == 3:
				self.time = 2
			
		def time_forward():
			self.time = self.time + 1
			
		def time_backward():
			self.time = self.time -1
			
		def set_terrain():
			if self.terrain_var == 1:
				self.ground_model.setTexture(self.ground_tex, 1)
				self.ground_model.setScale(3)
			if self.terrain_var == 2:
				self.ground_model.setTexture(self.ground_tex2, 1)
				self.ground_model.setScale(3)
			if self.terrain_var == 3:
				self.ground_model.setTexture(self.ground_tex3, 1)
				self.ground_model.setScale(4)
				
			if self.terrain_var == 4:
				self.terrain_var = 1
			if self.terrain_var == 0:
				self.terrain_var = 3
			
		def next_terrain():
			self.terrain_var = self.terrain_var + 1
			
		def previous_terrain():
			self.terrain_var = self.terrain_var - 1
			
		def show_menu():
			self.menu_win.show()
			self.a1.show()
			self.a2.show()
			self.a3.show()
			self.a4.show()
			self.t1.show()
			self.t2.show()
			self.ok.show()
			self.exit_button.show()
			
		def hide_menu():
			self.menu_win.hide()
			self.a1.hide()
			self.a2.hide()
			self.a3.hide()
			self.a4.hide()
			self.ok.hide()
			self.t1.hide()
			self.t2.hide()
			self.exit_button.hide()
		
		def Menu():
			self.menu_win = OnscreenImage(image = "Textures/menu.png", pos = (0.9,0,0), scale = (0.5))
			self.menu_win.setTransparency(TransparencyAttrib.MAlpha)
			
			#The Arrow Buttons
			self.a1 = DirectButton(text = "<", scale = 0.2, pos = (0.55,0,0.25), command = previous_terrain)
			self.a2 = DirectButton(text = ">", scale = 0.2, pos = (1.15,0,0.25), command = next_terrain)
			self.a3 = DirectButton(text = "<", scale = 0.2, pos = (0.55,0,0.0), command = time_backward)
			self.a4 = DirectButton(text = ">", scale = 0.2, pos = (1.15,0,0.0), command = time_forward)
			
			#The Text
			self.t1 = OnscreenText(text = "Terrain", pos = (0.85,0.25,0), scale = 0.1, fg = (0.4,0.4,0.5,1))
			self.t2 = OnscreenText(text = "Time", pos = (0.85,0,0), scale = 0.1, fg = (0.4,0.4,0.5,1))
			
			#The Buttons
			self.ok = DirectButton(text = "Okay", scale = 0.11, pos = (0.87,0,-0.25), command = hide_menu)
			self.exit_button = DirectButton(text = "Quit", scale = 0.11, pos = (0.87,0,-0.42), command = sys.exit)
			
		Menu()
		
		
		def take_screenshot():
			base.screenshot("Screenshot")
			
		def set_headlights():
			if self.headlight_var == 1:
				Headlight1.setColor(VBase4(9.0,8.9,8.9,1))
				Headlight2.setColor(VBase4(9.0,8.9,8.9,1))
			if self.headlight_var == 0:
				Headlight1.setColor(VBase4(0,0,0,1))
				Headlight2.setColor(VBase4(0,0,0,1))
			
		def headlights():
			self.headlight_var = (self.headlight_var + 1) % 2
			
		def update_rpm():
			
			#Simulate RPM
			if self.start == 1:
				if self.gear == 0:
					self.RPM = self.RPM - self.RPM / 400
				else:
					self.RPM = self.RPM + self.carspeed / 9
					self.RPM = self.RPM - self.RPM / 200
			
			#Reset RPM to 0 when engine is off
			if self.start == 0:
				if self.RPM > 0.0:
					self.RPM = self.RPM - 40
				if self.RPM < 10:
					self.RPM = 0.0
								
			#Idle RPM power
			if self.start == 1:
				if self.RPM < 650:
					self.RPM = self.RPM + 4
				if self.RPM < 600:
					self.clutch = 1
				else:
					self.clutch = 0
					
			#RPM limit		
			if self.RPM > 6000:
				self.RPM = 6000
				

		#Controls 
		inputState.watchWithModifiers("F", "arrow_up")
		inputState.watchWithModifiers("B", "arrow_down")
		inputState.watchWithModifiers("L", "arrow_left")
		inputState.watchWithModifiers("R", "arrow_right")
		
		do = DirectObject()
		
		do.accept("escape", show_menu)
		do.accept("1", V1)
		do.accept("2", V2)
		do.accept("3", V3)
		do.accept("page_up", up)
		do.accept("page_down", down)
		do.accept("x-repeat", start_function)
		do.accept("x", stop_function)
		do.accept("p", parkingbrake)
		do.accept("backspace", rotate)
		do.accept("enter", horn)
		do.accept("f12", take_screenshot)
		do.accept("h", headlights)
		
		#The ground
		self.ground = BulletPlaneShape(Vec3(0, 0, 1,), 1)
		self.ground_node = BulletRigidBodyNode("The ground")
		self.ground_node.addShape(self.ground)
		self.ground_np = render.attachNewNode(self.ground_node)
		self.ground_np.setPos(0, 0, -2)
		scene.attachRigidBody(self.ground_node)
		
		self.ground_model = loader.loadModel("Models/plane.egg")
		self.ground_model.reparentTo(render)
		self.ground_model.setPos(0,0,-1)
		self.ground_model.setScale(3)
		self.ground_tex = loader.loadTexture("Textures/ground.png")
		self.ground_tex2 = loader.loadTexture("Textures/ground2.png")
		self.ground_tex3 = loader.loadTexture("Textures/ground3.png")
		self.ground_model.setTexture(self.ground_tex, 1)
		
		#The car
		Car_shape = BulletBoxShape(Vec3(1, 2.0, 1.0))
		Car_node = BulletRigidBodyNode("The Car")
		Car_node.setMass(1200.0)
		Car_node.addShape(Car_shape)
		Car_np = render.attachNewNode(Car_node)
		Car_np.setPos(0,0,3)
		Car_np.setHpr(0,0,0)
		Car_np.node().setDeactivationEnabled(False)
		scene.attachRigidBody(Car_node)
		
		Car_model = loader.loadModel("Models/Car.egg")
		Car_model.reparentTo(Car_np)
		Car_tex = loader.loadTexture("Textures/Car1.png")
		Car_model.setTexture(Car_tex, 1)
		
		self.Car_sim = BulletVehicle(scene, Car_np.node())
		self.Car_sim.setCoordinateSystem(ZUp)
		scene.attachVehicle(self.Car_sim)
		
		#The inside of the car
		Car_int = loader.loadModel("Models/inside.egg")
		Car_int.reparentTo(Car_np)
		Car_int_tex = loader.loadTexture("Textures/inside.png")
		Car_int.setTexture(Car_int_tex, 1)
		Car_int.setTransparency(TransparencyAttrib.MAlpha)
		
		#The steering wheel
		Sw = loader.loadModel("Models/Steering wheel.egg")
		Sw.reparentTo(Car_np)
		Sw.setPos(0.25,0,-0.025)
		
		#The first headlight
		Headlight1 = Spotlight("Headlight1")
		lens = PerspectiveLens()
		lens.setFov(180)
		Headlight1.setLens(lens)
		Headlight1np = render.attachNewNode(Headlight1)
		Headlight1np.reparentTo(Car_np)
		Headlight1np.setPos(-0.8,2.5,-0.5)
		Headlight1np.setP(-15)
		render.setLight(Headlight1np)
		
		#The second headlight
		Headlight2 = Spotlight("Headlight2")
		Headlight2.setLens(lens)
		Headlight2np = render.attachNewNode(Headlight2)
		Headlight2np.reparentTo(Car_np)
		Headlight2np.setPos(0.8,2.5,-0.5)
		Headlight2np.setP(-15)
		render.setLight(Headlight2np)
		
		#Sounds
		self.horn_sound = loader.loadSfx("Sounds/horn.ogg")
		self.start_sound = loader.loadSfx("Sounds/enginestart.ogg")
		self.engine_idle_sound = loader.loadSfx("Sounds/engineidle.ogg")
		self.engine_idle_sound.setLoop(True)
		self.accelerate_sound = loader.loadSfx("Sounds/enginethrottle.ogg")
				
		#Camera
		base.disableMouse()
		camera.reparentTo(Car_np)
		camera.setPos(0,-15,3)
		camera.setHpr(0,-10,0)
		
		#Wheel function
		def Wheel(pos, np, r, f):
			w = self.Car_sim.createWheel()
			w.setNode(np.node())
			w.setChassisConnectionPointCs(pos)
			w.setFrontWheel(f)
			w.setWheelDirectionCs(Vec3(0, 0, -1))
			w.setWheelAxleCs(Vec3(1, 0, 0))
			w.setWheelRadius(r)
			w.setMaxSuspensionTravelCm(40)
			w.setSuspensionStiffness(120)
			w.setWheelsDampingRelaxation(2.3)
			w.setWheelsDampingCompression(4.4)
			w.setFrictionSlip(50)
			w.setRollInfluence(0.1)
		
		#Wheels	
		w1_np = loader.loadModel("Models/Lwheel")
		w1_np.reparentTo(render)
		w1_np.setColorScale(0,6)
		Wheel(Point3(-1,1,-0.6), w1_np, 0.4, False)
		
		w2_np = loader.loadModel("Models/Rwheel")
		w2_np.reparentTo(render)
		w2_np.setColorScale(0,6)
		Wheel(Point3(-1.1,-1.2,-0.6), w2_np, 0.4, True)
		
		w3_np = loader.loadModel("Models/Lwheel")
		w3_np.reparentTo(render)
		w3_np.setColorScale(0,6)
		Wheel(Point3(1.1,-1,-0.6), w3_np, 0.4, True)
		
		w4_np = loader.loadModel("Models/Rwheel")
		w4_np.reparentTo(render)
		w4_np.setColorScale(0,6)
		Wheel(Point3(1,1,-0.6), w4_np, 0.4, False)
		

		
		#The engine and steering
		def processInput(dt):
			
			#Vehicle properties
			self.steeringClamp = 35.0
			self.steeringIncrement = 70
			engineForce = 0.0
			brakeForce = 0.0
			
			
			#Get the vehicle's current speed
			self.carspeed = self.Car_sim.getCurrentSpeedKmHour()
			
			
			#Engage clutch when in gear 0
			if self.gear == 0:
				self.clutch = 1
			
			
			#Slow the steering when at higher speeds
			self.steeringIncrement = self.steeringIncrement - self.carspeed / 1.5
			
			
			#Reset the steering
			if not inputState.isSet("L") and not inputState.isSet("R"):
				
				if self.steering < 0.00:
					self.steering = self.steering + 0.6
				if self.steering > 0.00:
					self.steering = self.steering - 0.6
					
				if self.steering < 1.0 and self.steering > -1.0:
					self.steering = 0
			
			
			#Slow the car down while it's moving
			if self.clutch == 0:
				brakeForce = brakeForce + self.carspeed / 5
			else:
				brakeForce = brakeForce + self.carspeed / 15
		
			
			#Forward
			if self.start == 1:
				if inputState.isSet("F"):
					self.RPM = self.RPM + 35
					self.accelerate_sound.play()
				if self.clutch == 0:
					
					if self.gear == -1:
						if self.carspeed > self.carmaxreversespeed:	
							engineForce = -self.RPM / 3
							
					if self.gear == 1:
						if self.carspeed < self.carmaxspeed:
							engineForce = self.RPM / 1

			
			#Brake	
			if inputState.isSet("B"):
				engineForce = 0.0
				brakeForce = 12.0
				if self.gear != 0 and self.clutch == 0:
					self.RPM = self.RPM - 20
				
			#Left	
			if inputState.isSet("L"):
				if self.steering < 0.0:
					#This makes the steering reset at the correct speed when turning from right to left
					self.steering += dt * self.steeringIncrement + 0.6
					self.steering = min(self.steering, self.steeringClamp)
				else:
					#Normal steering
					self.steering += dt * self.steeringIncrement
					self.steering = min(self.steering, self.steeringClamp)
			
			#Right	
			if inputState.isSet("R"):
				if self.steering > 0.0:
					#This makes the steering reset at the correct speed when turning from left to right
					self.steering -= dt * self.steeringIncrement + 0.6
					self.steering = max(self.steering, -self.steeringClamp)
				else:
					#Normal steering
					self.steering -= dt * self.steeringIncrement
					self.steering = max(self.steering, -self.steeringClamp)
			
			#Park
			if self.Pbrake == 1:
				brakeForce = 10.0
				if self.gear != 0 and self. clutch == 0:
					self.RPM = self.RPM - 20
				
				
			#Apply forces to wheels	
			self.Car_sim.applyEngineForce(engineForce, 0);
			self.Car_sim.applyEngineForce(engineForce, 3);
			self.Car_sim.setBrake(brakeForce, 1);
			self.Car_sim.setBrake(brakeForce, 2);
			self.Car_sim.setSteeringValue(self.steering, 0);
			self.Car_sim.setSteeringValue(self.steering, 3);
			
			#Steering wheel
			Sw.setHpr(0,0,-self.steering*10)
		
		
		#The HUD
		self.gear_hud = OnscreenImage(image = "Textures/gear_hud.png", pos = (-1,0,-0.85), scale = (0.2))
		self.gear_hud.setTransparency(TransparencyAttrib.MAlpha)
		
		self.gear2_hud = OnscreenImage(image = "Textures/gear2_hud.png", pos = (-1,0,-0.85), scale = (0.2))
		self.gear2_hud.setTransparency(TransparencyAttrib.MAlpha)
		
		self.starter = OnscreenImage(image = "Textures/starter.png", pos = (-1.2,0,-0.85), scale = (0.15))
		self.starter.setTransparency(TransparencyAttrib.MAlpha)
		
		self.park = OnscreenImage(image = "Textures/pbrake.png", pos = (-0.8,0,-0.85), scale = (0.1))
		self.park.setTransparency(TransparencyAttrib.MAlpha)
		
		self.rev_counter = OnscreenImage(image = "Textures/dial.png", pos = (-1.6, 0.0, -0.70), scale = (0.6,0.6,0.4))
		self.rev_counter.setTransparency(TransparencyAttrib.MAlpha)
		
		self.rev_needle = OnscreenImage(image = "Textures/needle.png", pos = (-1.6, 0.0, -0.70), scale = (0.5))
		self.rev_needle.setTransparency(TransparencyAttrib.MAlpha)
		
		self.rev_text = OnscreenText(text = " ", pos = (-1.6, -0.90, 0), scale = 0.05)
		
		self.speedometer = OnscreenImage(image = "Textures/dial.png", pos = (-1.68, 0.0, -0.10), scale = (0.7,0.7,0.5))
		self.speedometer.setTransparency(TransparencyAttrib.MAlpha)
		
		self.speedometer_needle = OnscreenImage(image = "Textures/needle.png", pos = (-1.68, 0.0, -0.10), scale = (0.5))
		self.speedometer_needle.setTransparency(TransparencyAttrib.MAlpha)
		
		self.speedometer_text = OnscreenText(text = " ", pos = (-1.68, -0.35, 0), scale = 0.05)
		
		
		#Update the HUD
		def Update_HUD():
			
			#Move gear selector
			if self.gear == -1:
				self.gear2_hud.setPos(-1,0,-0.785)
			if self.gear == 0:
				self.gear2_hud.setPos(-1,0,-0.85)
			if self.gear == 1:
				self.gear2_hud.setPos(-1,0,-0.91)
				
			#Rotate starter
			if self.start == 0:
				self.starter.setHpr(0,0,0)
			else:
				self.starter.setHpr(0,0,45)	
				
			#Update the parking brake light
			if self.Pbrake == 1:
				self.park.setImage("Textures/pbrake2.png")
				self.park.setTransparency(TransparencyAttrib.MAlpha)
			else:
				self.park.setImage("Textures/pbrake.png")
				self.park.setTransparency(TransparencyAttrib.MAlpha)	
				
			#Update the rev counter
			self.rev_needle.setR(self.RPM/22)	
			rev_string = str(self.RPM)[:4]
			self.rev_text.setText(rev_string+" RPM")
			
			#Update the speedometer
			if self.carspeed > 0.0:
				self.speedometer_needle.setR(self.carspeed*2.5)
			if self.carspeed < 0.0:
				self.speedometer_needle.setR(-self.carspeed*2.5)
			speed_string = str(self.carspeed)[:3]
			self.speedometer_text.setText(speed_string+" KPH")
					
					
						
		#Update the program
		def update(task):
			dt = globalClock.getDt() 
			processInput(dt)
			Update_HUD()
			set_time()
			set_terrain()
			set_headlights()
			update_rpm()
			scene.doPhysics(dt, 5, 1.0/180.0)
			return task.cont
			
		taskMgr.add(update, "Update")
Exemplo n.º 3
0
class Game(DirectObject):
    def __init__(self, model):
        self.model = model
        base.setBackgroundColor(0.1, 0.1, 0.8, 1)
        base.setFrameRateMeter(True)

        base.cam.setPos(0, -20, 4)
        base.cam.lookAt(0, 0, 0)

        # Light
        alight = AmbientLight('ambientLight')
        alight.setColor(Vec4(0.5, 0.5, 0.5, 1))
        alightNP = render.attachNewNode(alight)

        dlight = DirectionalLight('directionalLight')
        dlight.setDirection(Vec3(1, 1, -1))
        dlight.setColor(Vec4(0.7, 0.7, 0.7, 1))
        dlightNP = render.attachNewNode(dlight)

        render.clearLight()
        render.setLight(alightNP)
        render.setLight(dlightNP)

        # Input
        self.accept('escape', self.doExit)
        self.accept('r', self.doReset)
        self.accept('f1', self.toggleWireframe)
        self.accept('f2', self.toggleTexture)
        self.accept('f3', self.toggleDebug)
        self.accept('f5', self.doScreenshot)

        inputState.watchWithModifiers('forward', 'w')
        inputState.watchWithModifiers('left', 'a')
        inputState.watchWithModifiers('reverse', 's')
        inputState.watchWithModifiers('right', 'd')
        inputState.watchWithModifiers('turnLeft', 'q')
        inputState.watchWithModifiers('turnRight', 'e')

        # Task
        taskMgr.add(self.update, 'updateWorld')

        # Physics
        self.setup()

    # _____HANDLER_____

    def doExit(self):
        self.cleanup()
        sys.exit(1)

    def doReset(self):
        self.cleanup()
        self.setup()

    def toggleWireframe(self):
        base.toggleWireframe()

    def toggleTexture(self):
        base.toggleTexture()

    def toggleDebug(self):
        if self.debugNP.isHidden():
            self.debugNP.show()
        else:
            self.debugNP.hide()

    def doScreenshot(self):
        base.screenshot('Bullet')

    # ____TASK___

    def calculate_moves(self):
        self.y = self.model.predict(self.x)
        self.moves = self.y > 0  # 0.5

    def processInput(self, dt):
        engineForce = 0.0
        brakeForce = 0.0
        if self.moves[0]:  #inputState.isSet('forward'):
            engineForce = 1000.0
            brakeForce = 0.0

        if not self.moves[0]:  #inputState.isSet('reverse'):
            engineForce = 0.0
            brakeForce = 100.0

        if self.moves[1]:  #inputState.isSet('turnLeft'):
            self.steering += dt * self.steeringIncrement
            self.steering = min(self.steering, self.steeringClamp)

        if not self.moves[1]:  #inputState.isSet('turnRight'):
            self.steering -= dt * self.steeringIncrement
            self.steering = max(self.steering, -self.steeringClamp)
        """
    if inputState.isSet('forward'):
      engineForce = 1000.0
      brakeForce = 0.0

    if inputState.isSet('reverse'):
      engineForce = 0.0
      brakeForce = 100.0

    if inputState.isSet('turnLeft'):
      self.steering += dt * self.steeringIncrement
      self.steering = min(self.steering, self.steeringClamp)

    if inputState.isSet('turnRight'):
      self.steering -= dt * self.steeringIncrement
      self.steering = max(self.steering, -self.steeringClamp)
    """
        # Apply steering to front wheels
        self.vehicle.setSteeringValue(self.steering, 0)
        self.vehicle.setSteeringValue(self.steering, 1)

        # Apply engine and brake to rear wheels
        self.vehicle.applyEngineForce(engineForce, 2)
        self.vehicle.applyEngineForce(engineForce, 3)
        self.vehicle.setBrake(brakeForce, 2)
        self.vehicle.setBrake(brakeForce, 3)

    def raycast(self):
        """pFrom = render.getRelativePoint(self.yugoNP,Point3(0,0,0))#Point3(0,0,0)
      pFrom -= Point3(0,0,pFrom[2])
      pRel = render.getRelativePoint(base.cam,self.yugoNP.getPos())  # FIXME THIS IS IT!! get rid of z component
      pRel -= Point3(0,0,pRel[2])
      p45 = Point3(pRel[0] - pRel[1], pRel[1] + pRel[0],0)
      pn45 = Point3(pRel[0] + pRel[1], pRel[1] - pRel[0],0)
      #print(render.getRelativePoint(self.yugoNP,Point3(0,0,0)))
      #print(dir(self.yugoNP))
      pTo = [pFrom + pn45, pFrom + pRel, pFrom + p45]#[pFrom + Vec3(-10,10,0)*999,pFrom + Vec3(0,10,0)*999,pFrom + Vec3(10,10,0)*999]# FIXME should be relative to front of car, getting cloe! #self.yugoNP.getPosDelta()*99999]#[Point3(-10,10,0) * 99999,Point3(0,10,0) * 99999,Point3(10,10,0) * 99999]
      #self.ray = CollisionRay(0,0,0,100,0,0)
      result = [self.world.rayTestClosest(pFrom,pt) for pt in pTo]
      #print(dir(self.yugoNP))
      #print(result.getHitPos())
      return tuple([res.getHitPos().length() for res in result])
      """#queue = CollisionHandlerQueue()
        #traverser.addCollider(fromObject, queue)
        #traverser.traverse(render)
        #queue.sortEntries()
        #for entry in queue.getEntries():
        #print(entry)
        #print(result.getHitPos())
        #if result.getNode() != None:
        #print(self.yugoNP.getPos(result.getNode()))
        #print(self.cTrav)
        self.cTrav.traverse(render)
        entries = list(self.colHandler.getEntries())
        entries.sort(key=lambda y: y.getSurfacePoint(render).getY())
        #for entry in entries:      print(entry.getFromNodePath().getName())
        if entries:  # and len(result) > 1:
            for r in entries:
                if r.getIntoNodePath().getName(
                ) == 'Box' and r.getFromNodePath().getName() in [
                        'ray%d' % i for i in range(3)
                ]:
                    self.ray_col_vec_dict[
                        r.getFromNodePath().getName()].append(
                            numpy.linalg.norm(
                                list(r.getSurfacePoint(
                                    r.getFromNodePath()))[:-1]))
        self.ray_col_vec_dict = {
            k: (min(self.ray_col_vec_dict[k])
                if len(self.ray_col_vec_dict[k]) >= 1 else 10000)
            for k in self.ray_col_vec_dict
        }
        self.x = numpy.array(list(self.ray_col_vec_dict.values()))
        #return entries

    def update(self, task):

        dt = globalClock.getDt()

        self.raycast()
        self.calculate_moves()
        self.ray_col_vec_dict = {k: [] for k in self.ray_col_vec_dict}
        self.processInput(dt)
        self.world.doPhysics(dt, 10, 0.008)

        #print(dir(result[1]))
        #print(numpy.linalg.norm(list(result[1].getSurfacePoint(result[1].getFromNodePath()))[:-1]))
        #base.camera.setPos(0,-40,10)
        #print self.vehicle.getWheel(0).getRaycastInfo().isInContact()
        #print self.vehicle.getWheel(0).getRaycastInfo().getContactPointWs()

        #print self.vehicle.getChassis().isKinematic()

        return task.cont

    def cleanup(self):
        self.world = None
        self.worldNP.removeNode()

    def setup(self):
        self.worldNP = render.attachNewNode('World')

        # World
        self.debugNP = self.worldNP.attachNewNode(BulletDebugNode('Debug'))
        self.debugNP.show()

        self.world = BulletWorld()
        self.world.setGravity(Vec3(0, 0, -9.81))
        self.world.setDebugNode(self.debugNP.node())

        #terrain = GeoMipTerrain("mySimpleTerrain")
        #terrain.setHeightfield("./models/heightfield_2.png")
        #terrain.getRoot().reparentTo(self.worldNP)#render)
        #terrain.generate()

        # Plane
        shape = BulletPlaneShape(Vec3(0, 0, 1), 0)

        np = self.worldNP.attachNewNode(BulletRigidBodyNode('Ground'))
        np.node().addShape(shape)
        np.setPos(0, 0, -1)
        np.setCollideMask(BitMask32.allOn())

        self.world.attachRigidBody(np.node())

        np = self.worldNP.attachNewNode(BulletRigidBodyNode('Track'))
        np.node().setMass(5000.0)
        np.setPos(3, 0, 10)
        np.setCollideMask(BitMask32.allOn())  #(0x0f))
        #self.track = BulletVehicle(self.world, np.node())
        #self.track.setCoordinateSystem(ZUp)
        self.track_np = loader.loadModel('models/race_track.egg')
        self.track_np.setScale(100)
        self.track_np.reparentTo(np)

        self.track_np.setCollideMask(BitMask32.allOn())
        self.world.attachRigidBody(np.node())
        self.track_np = np
        #self.track_np.show()

        # Chassis
        shape = BulletBoxShape(Vec3(0.6, 1.4, 0.5))
        ts = TransformState.makePos(Point3(0, 0, 0.5))

        np = self.worldNP.attachNewNode(BulletRigidBodyNode('Vehicle'))
        np.node().addShape(shape, ts)
        np.setPos(0, 0, 1)
        np.node().setMass(800.0)
        np.node().setDeactivationEnabled(False)

        self.world.attachRigidBody(np.node())

        #np.node().setCcdSweptSphereRadius(1.0)
        #np.node().setCcdMotionThreshold(1e-7)
        self.cTrav = CollisionTraverser()
        # Vehicle
        self.vehicle = BulletVehicle(self.world, np.node())
        self.vehicle.setCoordinateSystem(ZUp)
        self.yugoNP = loader.loadModel('models/yugo/yugo.egg')
        self.yugoNP.reparentTo(np)
        self.colHandler = CollisionHandlerQueue()
        self.ray_col_np = {}
        self.ray_col_vec_dict = {}
        for ray_dir in range(-1, 2):  # populate collision rays
            self.ray = CollisionRay()
            self.ray.setOrigin(ray_dir, 0.5, 0.5)
            self.ray.setDirection(ray_dir, 1, 0)
            self.ray_col = CollisionNode('ray%d' % (ray_dir + 1))
            self.ray_col.addSolid(self.ray)
            self.ray_col.setFromCollideMask(
                BitMask32.allOn())  #(0x0f))#CollideMask.bit(0)
            #self.ray_col.setIntoCollideMask(CollideMask.allOff())
            self.ray_col_np['ray%d' %
                            (ray_dir + 1)] = self.yugoNP.attachNewNode(
                                self.ray_col)
            self.cTrav.addCollider(self.ray_col_np['ray%d' % (ray_dir + 1)],
                                   self.colHandler)
            self.ray_col_np['ray%d' % (ray_dir + 1)].show()
            self.ray_col_vec_dict['ray%d' % (ray_dir + 1)] = []
        self.world.attachVehicle(self.vehicle)
        self.cTrav.showCollisions(render)

        # FIXME
        base.camera.reparentTo(self.yugoNP)

        # Right front wheel
        np = loader.loadModel('models/yugo/yugotireR.egg')
        np.reparentTo(self.worldNP)
        self.addWheel(Point3(0.70, 1.05, 0.3), True, np)

        # Left front wheel
        np = loader.loadModel('models/yugo/yugotireL.egg')
        np.reparentTo(self.worldNP)
        self.addWheel(Point3(-0.70, 1.05, 0.3), True, np)

        # Right rear wheel
        np = loader.loadModel('models/yugo/yugotireR.egg')
        np.reparentTo(self.worldNP)
        self.addWheel(Point3(0.70, -1.05, 0.3), False, np)

        # Left rear wheel
        np = loader.loadModel('models/yugo/yugotireL.egg')
        np.reparentTo(self.worldNP)
        self.addWheel(Point3(-0.70, -1.05, 0.3), False, np)

        # Steering info
        self.steering = 0.0  # degree
        self.steeringClamp = 45.0  # degree
        self.steeringIncrement = 120.0  # degree per second

        # Box
        for i, j in [(0, 8), (-3, 5), (6, -5), (8, 3), (-4, -4)]:
            shape = BulletBoxShape(Vec3(0.5, 0.5, 0.5))
            # https://discourse.panda3d.org/t/wall-collision-help/23606
            np = self.worldNP.attachNewNode(BulletRigidBodyNode('Box'))
            np.node().setMass(1.0)
            np.node().addShape(shape)
            np.setPos(i, j, 2)
            np.setCollideMask(BitMask32.allOn())  #(0x0f))

            self.world.attachRigidBody(np.node())
            self.boxNP = np
            #self.colHandler2 = CollisionHandlerQueue()

            visualNP = loader.loadModel('models/box.egg')
            visualNP.reparentTo(self.boxNP)
        #self.cTrav.addCollider(self.boxNP,self.colHandler)
        """
    aNode = CollisionNode("TheRay")

    self.ray = CollisionRay()
    self.ray.setOrigin( self.yugoNP.getPos() )
    self.ray.setDirection( Vec3(0, 10, 0) )
    #self.ray.show()


    aNodePath = self.yugoNP.attachNewNode( CollisionNode("TheRay") )
    aNodePath.node().addSolid(self.ray)
    aNodePath.show()
    """
        #aNode.addSolid(self.ray)
        #self.ray = CollisionRay(0,0,0,10,0,0)
        #self.ray.reparentTo(self.yugoNP)
        #self.rayColl = CollisionNode('PlayerRay')
        #self.rayColl.addSolid(self.ray)

        #self.playerRayNode = self.yugoNP.attachNewNode( self.rayColl )
        #self.playerRayNode.show()

        #base.myTraverser.addCollider (self.playerRayNode, base.floor)
        #base.floor.addCollider( self.playerRayNode, self.yugoNP)
        """
    MyEvent=CollisionHandlerFloor()
    MyEvent.setReach(100)
    MyEvent.setOffset(15.0)

    aNode = CollisionNode("TheRay")
    ray = CollisionRay()
    ray.setOrigin( self.boxNP.getPos() )
    ray.setDirection( Vec3(10, 0, 0) )

    aNode.addSolid(ray)
    aNodePath = MyModel.attachNewNode( aNode )

    Collision = ( aNode, "TheRay" )
    Collision[0].setFromCollideMask( BitMask32.bit( 1 ) )
    """

    def addWheel(self, pos, front, np):
        wheel = self.vehicle.createWheel()

        wheel.setNode(np.node())
        wheel.setChassisConnectionPointCs(pos)
        wheel.setFrontWheel(front)

        wheel.setWheelDirectionCs(Vec3(0, 0, -1))
        wheel.setWheelAxleCs(Vec3(1, 0, 0))
        wheel.setWheelRadius(0.25)
        wheel.setMaxSuspensionTravelCm(40.0)

        wheel.setSuspensionStiffness(40.0)
        wheel.setWheelsDampingRelaxation(2.3)
        wheel.setWheelsDampingCompression(4.4)
        wheel.setFrictionSlip(100.0)
        wheel.setRollInfluence(0.1)
Exemplo n.º 4
0
class Vehicle(object):
    COUNT = 0

    def __init__(self, bulletWorld, pos, username, isMainChar=False):
        self.specs = {
            "mass": 400.0,
            "maxWheelForce": 2000.0,
            "brakeForce": 100.0,
            "steeringLock": 45.0
        }
        self.vehicleControlState = {
            "throttle": 0,
            "reverse": False,
            "brake": 0.0,
            "steering": 0.0
        }
        self.username = username
        self.isMainChar = isMainChar
        # Steering change per second, normalised to steering lock
        # Eg. 45 degrees lock and 1.0 rate means 45 degrees per second
        self.steeringRate = 0.8
        self.centreingRate = 1.2

        self.pos = pos

        self.currentPowerups = {
            "powerup1": None,
            "powerup2": None,
            "powerup3": None
        }

        self.setupVehicle(bulletWorld)
        self.startTime = time.time()
        COUNT = 1

    def move(self, steering, wheelForce, brakeForce, x, y, z, h, p, r):
        self.applyForcesAndSteering(steering, wheelForce, brakeForce)
        self.endTime = time.time()
        #print self.endTime
        elapsed = self.endTime - self.startTime
        #if elapsed > .1:
        #print "Set Pos Now"
        self.setVehiclePos(x, y, z, h, p, r)
        self.startTime = self.endTime
        #print "Do Move"

    def applyForcesAndSteering(self, steering, wheelForce, brakeForce):
        # Apply steering to front wheels
        self.vehicle.setSteeringValue(steering, 0)
        self.vehicle.setSteeringValue(steering, 1)
        # Apply engine and brake to rear wheels
        self.vehicle.applyEngineForce(wheelForce, 2)
        self.vehicle.applyEngineForce(wheelForce, 3)
        self.vehicle.setBrake(brakeForce, 2)
        self.vehicle.setBrake(brakeForce, 3)

    def processInput(self, inputState, dt):
        # print self.chassisNP.getPos()
        #print self.chassisNP.getH()
        """Use controls to update the player's car"""
        # For keyboard throttle and brake are either 0 or 1
        if inputState.isSet('forward'):
            self.vehicleControlState["throttle"] = 1.0
        else:
            self.vehicleControlState["throttle"] = 0.0

        velocity = self.chassisNode.getLinearVelocity()
        speed = math.sqrt(sum(v**2 for v in velocity))
        # Update braking and reversing
        if inputState.isSet('brake'):
            if speed < 0.5 or self.vehicleControlState["reverse"]:
                # If we're stopped, then start reversing
                # Also keep reversing if we already were
                self.vehicleControlState["reverse"] = True
                self.vehicleControlState["throttle"] = 1.0
                self.vehicleControlState["brake"] = 0.0
            else:
                self.vehicleControlState["reverse"] = False
                self.vehicleControlState["brake"] = 1.0
        else:
            self.vehicleControlState["reverse"] = False
            self.vehicleControlState["brake"] = 0.0

        # steering is normalised from -1 to 1, corresponding
        # to the steering lock right and left
        steering = self.vehicleControlState["steering"]
        if inputState.isSet('left'):
            steering += dt * self.steeringRate
            steering = min(steering, 1.0)
        elif inputState.isSet('right'):
            steering -= dt * self.steeringRate
            steering = max(steering, -1.0)
        else:
            # gradually re-center the steering
            if steering > 0.0:
                steering -= dt * self.centreingRate
                if steering < 0.0:
                    steering = 0.0
            elif steering < 0.0:
                steering += dt * self.centreingRate
                if steering > 0.0:
                    steering = 0.0
        self.vehicleControlState["steering"] = steering

        # """Updates acceleration, braking and steering
        # These are all passed in through a controlState dictionary
        # """
        # Update acceleration and braking
        wheelForce = self.vehicleControlState["throttle"] * self.specs[
            "maxWheelForce"]
        self.reversing = self.vehicleControlState["reverse"]
        if self.reversing:
            # Make reversing a bit slower than moving forward
            wheelForce *= -0.5

        brakeForce = self.vehicleControlState["brake"] * self.specs[
            "brakeForce"]

        # Update steering
        # Steering control state is from -1 to 1
        steering = self.vehicleControlState["steering"] * self.specs[
            "steeringLock"]

        self.applyForcesAndSteering(steering, wheelForce, brakeForce)

        return [steering, wheelForce, brakeForce]

    def setVehiclePos(self, x, y, z, h, p, r):
        self.chassisNP.setPosHpr(x, y, z, h, p, r)

    def setupVehicle(self, bulletWorld):
        # Chassis
        shape = BulletBoxShape(Vec3(1, 2.2, 0.5))
        ts = TransformState.makePos(Point3(0, 0, .7))
        if self.isMainChar:
            self.chassisNode = BulletRigidBodyNode(self.username)
        else:
            self.chassisNode = BulletRigidBodyNode('vehicle')
        self.chassisNode.setTag("username", str(self.username))

        self.chassisNP = render.attachNewNode(self.chassisNode)
        self.chassisNP.node().addShape(shape, ts)
        if self.isMainChar:
            self.chassisNP.node().notifyCollisions(True)
        else:
            self.chassisNP.node().notifyCollisions(False)
        self.setVehiclePos(self.pos[0], self.pos[1], self.pos[2], self.pos[3],
                           self.pos[4], self.pos[5])
        # self.chassisNP.setPos(-5.34744, 114.773, 6)
        #self.chassisNP.setPos(49.2167, 64.7968, 10)
        self.chassisNP.node().setMass(800.0)
        self.chassisNP.node().setDeactivationEnabled(False)

        bulletWorld.attachRigidBody(self.chassisNP.node())

        #np.node().setCcdSweptSphereRadius(1.0)
        #np.node().setCcdMotionThreshold(1e-7)

        # Vehicle
        self.vehicle = BulletVehicle(bulletWorld, self.chassisNP.node())
        self.vehicle.setCoordinateSystem(ZUp)
        bulletWorld.attachVehicle(self.vehicle)

        self.carNP = loader.loadModel('models/batmobile-chassis.egg')
        #self.yugoNP.setScale(.7)
        self.carNP.reparentTo(self.chassisNP)

        # Right front wheel
        np = loader.loadModel('models/batmobile-wheel-right.egg')
        np.reparentTo(render)
        self.addWheel(Point3(1, 1.1, .7), True, np)

        # Left front wheel
        np = loader.loadModel('models/batmobile-wheel-left.egg')
        np.reparentTo(render)
        self.addWheel(Point3(-1, 1.1, .7), True, np)

        # Right rear wheel
        np = loader.loadModel('models/batmobile-wheel-right.egg')
        np.reparentTo(render)
        self.addWheel(Point3(1, -2, .7), False, np)

        # Left rear wheel
        np = loader.loadModel('models/batmobile-wheel-left.egg')
        np.reparentTo(render)
        self.addWheel(Point3(-1, -2, .7), False, np)

    def addWheel(self, pos, front, np):
        wheel = self.vehicle.createWheel()

        wheel.setNode(np.node())
        wheel.setChassisConnectionPointCs(pos)
        wheel.setFrontWheel(front)

        wheel.setWheelDirectionCs(Vec3(0, 0, -1))
        wheel.setWheelAxleCs(Vec3(1, 0, 0))
        wheel.setWheelRadius(0.33)
        wheel.setMaxSuspensionTravelCm(40.0)

        wheel.setSuspensionStiffness(40.0)
        wheel.setWheelsDampingRelaxation(2.3)
        wheel.setWheelsDampingCompression(4.4)
        wheel.setFrictionSlip(100.0)
        wheel.setRollInfluence(0.1)

    def reset(self):
        self.chassisNP.setP(0)
        self.chassisNP.setR(0)

    def pickedPowerup(self, powerup):
        if not powerup.pickable:
            powerup.useAbility()
        else:
            if self.currentPowerups["powerup1"] is None:
                self.currentPowerups["powerup1"] = powerup
            elif self.currentPowerups["powerup2"] is None:
                self.currentPowerups["powerup2"] = powerup
            elif self.currentPowerups["powerup3"] is None:
                self.currentPowerups["powerup3"] = powerup

    def canPickUpPowerup(self):
        return (self.currentPowerups["powerup1"] is None
                or self.currentPowerups["powerup2"] is None
                or self.currentPowerups["powerup3"] is None)

    def usePowerup(self, powerupIndex):
        # Move usePowerupN to this function
        if powerupIndex == 0 and self.currentPowerups["powerup1"] is not None:
            self.currentPowerups["powerup1"].useAbility()
            self.currentPowerups["powerup1"] = None
        elif powerupIndex == 1 and self.currentPowerups["powerup2"] is not None:
            self.currentPowerups["powerup2"].useAbility()
            self.currentPowerups["powerup2"] = None
        elif powerupIndex == 2 and self.currentPowerups["powerup3"] is not None:
            self.currentPowerups["powerup3"].useAbility()
            self.currentPowerups["powerup3"] = None
Exemplo n.º 5
0
class CarEnv(DirectObject):
    def __init__(self, params={}):
        self._params = params
        if 'random_seed' in self._params:
            np.random.seed(self._params['random_seed'])
        self._use_vel = self._params.get('use_vel', True)
        self._run_as_task = self._params.get('run_as_task', False)
        self._do_back_up = self._params.get('do_back_up', False)
        self._use_depth = self._params.get('use_depth', False)
        self._use_back_cam = self._params.get('use_back_cam', False)
        self._collision_reward = self._params.get('collision_reward', 0.)
        if not self._params.get('visualize', False):
            loadPrcFileData('', 'window-type offscreen')

        # Defines base, render, loader

        try:
            ShowBase()
        except:
            pass

        base.setBackgroundColor(0.0, 0.0, 0.0, 1)

        # World
        self._worldNP = render.attachNewNode('World')
        self._world = BulletWorld()
        self._world.setGravity(Vec3(0, 0, -9.81))
        self._dt = params.get('dt', 0.25)
        self._step = 0.05

        # Vehicle
        shape = BulletBoxShape(Vec3(0.6, 1.0, 0.25))
        ts = TransformState.makePos(Point3(0., 0., 0.25))
        self._vehicle_node = BulletRigidBodyNode('Vehicle')
        self._vehicle_node.addShape(shape, ts)
        self._mass = self._params.get('mass', 10.)
        self._vehicle_node.setMass(self._mass)
        self._vehicle_node.setDeactivationEnabled(False)
        self._vehicle_node.setCcdSweptSphereRadius(1.0)
        self._vehicle_node.setCcdMotionThreshold(1e-7)
        self._vehicle_pointer = self._worldNP.attachNewNode(self._vehicle_node)

        self._world.attachRigidBody(self._vehicle_node)

        self._vehicle = BulletVehicle(self._world, self._vehicle_node)
        self._vehicle.setCoordinateSystem(ZUp)
        self._world.attachVehicle(self._vehicle)
        self._addWheel(Point3(0.3, 0.5, 0.07), True, 0.07)
        self._addWheel(Point3(-0.3, 0.5, 0.07), True, 0.07)
        self._addWheel(Point3(0.3, -0.5, 0.07), False, 0.07)
        self._addWheel(Point3(-0.3, -0.5, 0.07), False, 0.07)

        # Camera
        size = self._params.get('size', [160, 90])
        hfov = self._params.get('hfov', 60)
        near_far = self._params.get('near_far', [0.1, 100.])
        self._camera_sensor = Panda3dCameraSensor(base,
                                                  color=not self._use_depth,
                                                  depth=self._use_depth,
                                                  size=size,
                                                  hfov=hfov,
                                                  near_far=near_far,
                                                  title='front cam')
        self._camera_node = self._camera_sensor.cam
        self._camera_node.setPos(0.0, 0.5, 0.375)
        self._camera_node.lookAt(0.0, 6.0, 0.0)
        self._camera_node.reparentTo(self._vehicle_pointer)

        if self._use_back_cam:
            self._back_camera_sensor = Panda3dCameraSensor(
                base,
                color=not self._use_depth,
                depth=self._use_depth,
                size=size,
                hfov=hfov,
                near_far=near_far,
                title='back cam')

            self._back_camera_node = self._back_camera_sensor.cam
            self._back_camera_node.setPos(0.0, -0.5, 0.375)
            self._back_camera_node.lookAt(0.0, -6.0, 0.0)
            self._back_camera_node.reparentTo(self._vehicle_pointer)

        # Car Simulator
        self._des_vel = None
        self._setup()

        # Input
        self.accept('escape', self._doExit)
        self.accept('r', self.reset)
        self.accept('f1', self._toggleWireframe)
        self.accept('f2', self._toggleTexture)
        self.accept('f3', self._view_image)
        self.accept('f5', self._doScreenshot)
        self.accept('q', self._forward_0)
        self.accept('w', self._forward_1)
        self.accept('e', self._forward_2)
        self.accept('a', self._left)
        self.accept('s', self._stop)
        self.accept('x', self._backward)
        self.accept('d', self._right)
        self.accept('m', self._mark)

        self._steering = 0.0  # degree
        self._engineForce = 0.0
        self._brakeForce = 0.0
        self._p = self._params.get('p', 1.25)
        self._d = self._params.get('d', 0.0)
        self._last_err = 0.0
        self._curr_time = 0.0
        self._accelClamp = self._params.get('accelClamp', 2.0)
        self._engineClamp = self._accelClamp * self._mass
        self._collision = False
        if self._run_as_task:
            self._mark_d = 0.0
            taskMgr.add(self._update_task, 'updateWorld')
            base.run()

    # _____HANDLER_____

    def _doExit(self):
        sys.exit(1)

    def _toggleWireframe(self):
        base.toggleWireframe()

    def _toggleTexture(self):
        base.toggleTexture()

    def _doScreenshot(self):
        base.screenshot('Bullet')

    def _forward_0(self):
        self._des_vel = 1
        self._brakeForce = 0.0

    def _forward_1(self):
        self._des_vel = 2
        self._brakeForce = 0.0

    def _forward_2(self):
        self._des_vel = 4
        self._brakeForce = 0.0

    def _stop(self):
        self._des_vel = 0.0
        self._brakeForce = 0.0

    def _backward(self):
        self._des_vel = -4
        self._brakeForce = 0.0

    def _right(self):
        self._steering = np.min([np.max([-30, self._steering - 5]), 0.0])

    def _left(self):
        self._steering = np.max([np.min([30, self._steering + 5]), 0.0])

    def _view_image(self):
        from matplotlib import pyplot as plt
        image = self._camera_sensor.observe()[0]
        if self._use_depth:
            plt.imshow(image[:, :, 0], cmap='gray')
        else:
            import cv2

            def rgb2gray(rgb):
                return np.dot(rgb[..., :3], [0.299, 0.587, 0.114])

            image = rgb2gray(image)
            im = cv2.resize(image, (64, 36), interpolation=cv2.INTER_AREA
                            )  # TODO how does this deal with aspect ratio
            plt.imshow(im.astype(np.uint8), cmap='Greys_r')
        plt.show()

    def _mark(self):
        self._mark_d = 0.0

    # Setup
    def _setup(self):
        if hasattr(self, '_model_path'):
            # Collidable objects
            visNP = loader.loadModel(self._model_path)
            visNP.clearModelNodes()
            visNP.reparentTo(render)
            pos = (0., 0., 0.)
            visNP.setPos(pos[0], pos[1], pos[2])

            bodyNPs = BulletHelper.fromCollisionSolids(visNP, True)
            for bodyNP in bodyNPs:
                bodyNP.reparentTo(render)
                bodyNP.setPos(pos[0], pos[1], pos[2])

                if isinstance(bodyNP.node(), BulletRigidBodyNode):
                    bodyNP.node().setMass(0.0)
                    bodyNP.node().setKinematic(True)
                    bodyNP.setCollideMask(BitMask32.allOn())
                    self._world.attachRigidBody(bodyNP.node())
        else:
            ground = self._worldNP.attachNewNode(BulletRigidBodyNode('Ground'))
            shape = BulletPlaneShape(Vec3(0, 0, 1), 0)
            ground.node().addShape(shape)
            ground.setCollideMask(BitMask32.allOn())
            self._world.attachRigidBody(ground.node())
        self._place_vehicle()
        self._setup_light()
        self._setup_restart_pos()

    def _setup_restart_pos(self):
        self._restart_pos = []
        self._restart_index = 0
        if self._params.get('position_ranges', None) is not None:
            ranges = self._params['position_ranges']
            num_pos = self._params['num_pos']
            if self._params.get('range_type', 'random') == 'random':
                for _ in range(num_pos):
                    ran = ranges[np.random.randint(len(ranges))]
                    self._restart_pos.append(np.random.uniform(ran[0], ran[1]))
            elif self._params['range_type'] == 'fix_spacing':
                num_ran = len(ranges)
                num_per_ran = num_pos // num_ran
                for i in range(num_ran):
                    ran = ranges[i]
                    low = np.array(ran[0])
                    diff = np.array(ran[1]) - np.array(ran[0])
                    for j in range(num_per_ran):
                        val = diff * ((j + 0.0) / num_per_ran) + low
                        self._restart_pos.append(val)
        elif self._params.get('positions', None) is not None:
            self._restart_pos = self._params['positions']
        else:
            self._restart_pos = self._default_restart_pos()

    def _next_restart_pos_hpr(self):
        num = len(self._restart_pos)
        if num == 0:
            return None, None
        else:
            pos_hpr = self._restart_pos[self._restart_index]
            self._restart_index = (self._restart_index + 1) % num
            return pos_hpr[:3], pos_hpr[3:]

    def _next_random_restart_pos_hpr(self):
        num = len(self._restart_pos)
        if num == 0:
            return None, None
        else:
            index = np.random.randint(num)
            pos_hpr = self._restart_pos[index]
            self._restart_index = (self._restart_index + 1) % num
            return pos_hpr[:3], pos_hpr[3:]

    def _setup_light(self):
        alight = AmbientLight('ambientLight')
        alight.setColor(Vec4(0.5, 0.5, 0.5, 1))
        alightNP = render.attachNewNode(alight)
        render.clearLight()
        render.setLight(alightNP)

    # Vehicle
    def _default_pos(self):
        return (0.0, 0.0, 0.3)

    def _default_hpr(self):
        return (0.0, 0.0, 3.14)

    def _default_restart_pos():
        return [self._default_pos() + self._default_hpr()]

    def _get_speed(self):
        vel = self._vehicle.getCurrentSpeedKmHour() / 3.6
        return vel

    def _update(self, dt=1.0, coll_check=True):
        self._vehicle.setSteeringValue(self._steering, 0)
        self._vehicle.setSteeringValue(self._steering, 1)
        self._vehicle.setBrake(self._brakeForce, 0)
        self._vehicle.setBrake(self._brakeForce, 1)
        self._vehicle.setBrake(self._brakeForce, 2)
        self._vehicle.setBrake(self._brakeForce, 3)

        if dt >= self._step:
            # TODO maybe change number of timesteps
            for i in range(int(dt / self._step)):
                if self._des_vel is not None:
                    vel = self._get_speed()
                    err = self._des_vel - vel
                    d_err = (err - self._last_err) / self._step
                    self._last_err = err
                    self._engineForce = np.clip(
                        self._p * err + self._d * d_err, -self._accelClamp,
                        self._accelClamp) * self._mass
                self._vehicle.applyEngineForce(self._engineForce, 0)
                self._vehicle.applyEngineForce(self._engineForce, 1)
                self._vehicle.applyEngineForce(self._engineForce, 2)
                self._vehicle.applyEngineForce(self._engineForce, 3)
                self._world.doPhysics(self._step, 1, self._step)
            self._collision = self._is_contact()
        elif self._run_as_task:
            self._curr_time += dt
            if self._curr_time > 0.05:
                if self._des_vel is not None:
                    vel = self._get_speed()
                    self._mark_d += vel * self._curr_time
                    print(vel, self._mark_d, self._is_contact())
                    err = self._des_vel - vel
                    d_err = (err - self._last_err) / 0.05
                    self._last_err = err
                    self._engineForce = np.clip(
                        self._p * err + self._d * d_err, -self._accelClamp,
                        self._accelClamp) * self._mass
                self._curr_time = 0.0
                self._vehicle.applyEngineForce(self._engineForce, 0)
                self._vehicle.applyEngineForce(self._engineForce, 1)
                self._vehicle.applyEngineForce(self._engineForce, 2)
                self._vehicle.applyEngineForce(self._engineForce, 3)
            self._world.doPhysics(dt, 1, dt)
            self._collision = self._is_contact()
        else:
            raise ValueError(
                "dt {0} s is too small for velocity control".format(dt))

    def _stop_car(self):
        self._steering = 0.0
        self._engineForce = 0.0
        self._vehicle.setSteeringValue(0.0, 0)
        self._vehicle.setSteeringValue(0.0, 1)
        self._vehicle.applyEngineForce(0.0, 0)
        self._vehicle.applyEngineForce(0.0, 1)
        self._vehicle.applyEngineForce(0.0, 2)
        self._vehicle.applyEngineForce(0.0, 3)

        if self._des_vel is not None:
            self._des_vel = 0

        self._vehicle_node.setLinearVelocity(Vec3(0.0, 0.0, 0.0))
        self._vehicle_node.setAngularVelocity(Vec3(0.0, 0.0, 0.0))
        for i in range(self._vehicle.getNumWheels()):
            wheel = self._vehicle.getWheel(i)
            wheel.setRotation(0.0)
        self._vehicle_node.clearForces()

    def _place_vehicle(self, pos=None, hpr=None):
        if pos is None:
            pos = self._default_pos()
        if hpr is None:
            hpr = self._default_hpr()
        self._vehicle_pointer.setPos(pos[0], pos[1], pos[2])
        self._vehicle_pointer.setHpr(hpr[0], hpr[1], hpr[2])
        self._stop_car()

    def _addWheel(self, pos, front, radius=0.25):
        wheel = self._vehicle.createWheel()
        wheel.setChassisConnectionPointCs(pos)
        wheel.setFrontWheel(front)
        wheel.setWheelDirectionCs(Vec3(0, 0, -1))
        wheel.setWheelAxleCs(Vec3(1, 0, 0))
        wheel.setWheelRadius(radius)
        wheel.setMaxSuspensionTravelCm(40.0)
        wheel.setSuspensionStiffness(40.0)
        wheel.setWheelsDampingRelaxation(2.3)
        wheel.setWheelsDampingCompression(4.4)
        wheel.setFrictionSlip(1e2)
        wheel.setRollInfluence(0.1)

    # Task

    def _update_task(self, task):
        dt = globalClock.getDt()
        self._update(dt=dt)
        self._get_observation()
        return task.cont

    # Helper functions

    def _get_observation(self):
        self._obs = self._camera_sensor.observe()
        observation = []
        observation.append(self._obs[0])
        if self._use_back_cam:
            self._back_obs = self._back_camera_sensor.observe()
            observation.append(self._back_obs[0])
        observation = np.concatenate(observation, axis=2)
        return observation

    def _get_reward(self):
        reward = self._collision_reward if self._collision else self._get_speed(
        )
        return reward

    def _get_done(self):
        return self._collision

    def _get_info(self):
        info = {}
        info['pos'] = np.array(self._vehicle_pointer.getPos())
        info['hpr'] = np.array(self._vehicle_pointer.getHpr())
        info['vel'] = self._get_speed()
        info['coll'] = self._collision
        return info

    def _back_up(self):
        assert (self._use_vel)
        back_up_vel = self._params['back_up'].get('vel', -2.0)
        self._des_vel = back_up_vel
        back_up_steer = self._params['back_up'].get('steer', (-5.0, 5.0))
        # TODO
        self._steering = np.random.uniform(*back_up_steer)
        self._brakeForce = 0.
        duration = self._params['back_up'].get('duration', 1.0)
        self._update(dt=duration)
        self._des_vel = 0.0
        self._steering = 0.0
        self._update(dt=duration)
        self._brakeForce = 0.

    def _is_contact(self):
        result = self._world.contactTest(self._vehicle_node)
        num_contacts = result.getNumContacts()
        return result.getNumContacts() > 0

    # Environment functions

    def reset(self, pos=None, hpr=None, hard_reset=False, random_reset=False):
        if self._do_back_up and not hard_reset and \
                pos is None and hpr is None:
            if self._collision:
                self._back_up()
        else:
            if pos is None and hpr is None:
                if random_reset:
                    pos, hpr = self._next_random_restart_pos_hpr()
                else:
                    pos, hpr = self._next_restart_pos_hpr()
            self._place_vehicle(pos=pos, hpr=hpr)
        self._collision = False
        return self._get_observation()

    def step(self, action):
        self._steering = action[0]
        if action[1] == 0.0:
            self._brakeForce = 1000.
        else:
            self._brakeForce = 0.
        if self._use_vel:
            # Convert from m/s to km/h
            self._des_vel = action[1]
        else:
            self._engineForce = self._engineClamp * \
                ((action[1] - 49.5) / 49.5)

        self._update(dt=self._dt)
        observation = self._get_observation()
        reward = self._get_reward()
        done = self._get_done()
        info = self._get_info()
        return observation, reward, done, info
Exemplo n.º 6
0
class Vehicle(object):
    def __init__(self, positionHpr, render, world, base):
        self.base = base
        loader = base.loader
        position, hpr = positionHpr

        vehicleType = "yugo"
        self.vehicleDir = "data/vehicles/" + vehicleType + "/"
        # Load vehicle description and specs
        with open(self.vehicleDir + "vehicle.json") as vehicleData:
            data = json.load(vehicleData)
            self.specs = data["specs"]

        # Chassis for collisions and mass uses a simple box shape
        halfExtents = (0.5 * dim for dim in self.specs["dimensions"])
        shape = BulletBoxShape(Vec3(*halfExtents))
        ts = TransformState.makePos(Point3(0, 0, 0.5))

        self.rigidNode = BulletRigidBodyNode("vehicle")
        self.rigidNode.addShape(shape, ts)
        self.rigidNode.setMass(self.specs["mass"])
        self.rigidNode.setDeactivationEnabled(False)

        self.np = render.attachNewNode(self.rigidNode)
        self.np.setPos(position)
        self.np.setHpr(hpr)
        world.attachRigidBody(self.rigidNode)

        # Vehicle physics model
        self.vehicle = BulletVehicle(world, self.rigidNode)
        self.vehicle.setCoordinateSystem(ZUp)
        world.attachVehicle(self.vehicle)

        # Vehicle graphical model
        self.vehicleNP = loader.loadModel(self.vehicleDir + "car.egg")
        self.vehicleNP.reparentTo(self.np)

        # Create wheels
        wheelPos = self.specs["wheelPositions"]
        for fb, y in (("F", wheelPos[1]), ("B", -wheelPos[1])):
            for side, x in (("R", wheelPos[0]), ("L", -wheelPos[0])):
                np = loader.loadModel(self.vehicleDir + "tire%s.egg" % side)
                np.reparentTo(render)
                isFront = fb == "F"
                self.addWheel(Point3(x, y, wheelPos[2]), isFront, np)

    def addWheel(self, position, isFront, np):
        wheel = self.vehicle.createWheel()
        wheelSpecs = self.specs["wheels"]

        wheel.setNode(np.node())
        wheel.setChassisConnectionPointCs(position)
        wheel.setFrontWheel(isFront)

        wheel.setWheelDirectionCs(Vec3(0, 0, -1))
        wheel.setWheelAxleCs(Vec3(1, 0, 0))
        wheel.setWheelRadius(wheelSpecs["radius"])
        wheel.setMaxSuspensionTravelCm(wheelSpecs["suspensionTravel"] * 100.0)
        wheel.setSuspensionStiffness(wheelSpecs["suspensionStiffness"])
        wheel.setWheelsDampingRelaxation(wheelSpecs["dampingRelaxation"])
        wheel.setWheelsDampingCompression(wheelSpecs["dampingCompression"])
        wheel.setFrictionSlip(wheelSpecs["frictionSlip"])
        wheel.setRollInfluence(wheelSpecs["rollInfluence"])

    def initialiseSound(self, audioManager):
        """Start the engine sound and set collision sounds"""

        # Set sounds to play for collisions
        self.collisionSound = CollisionSound(
            nodePath=self.np, sounds=["data/sounds/09.wav"], thresholdForce=600.0, maxForce=800000.0
        )

        self.engineSound = audioManager.loadSfx(self.vehicleDir + "engine.wav")
        audioManager.attachSoundToObject(self.engineSound, self.np)
        self.engineSound.setLoop(True)
        self.engineSound.setPlayRate(0.6)
        self.engineSound.play()

        self.gearSpacing = self.specs["sound"]["maxExpectedRotationRate"] / self.specs["sound"]["numberOfGears"]
        self.reversing = False

    def updateSound(self, dt):
        """Use vehicle speed to update sound pitch"""

        soundSpecs = self.specs["sound"]
        # Use rear wheel rotation speed as some measure of engine revs
        wheels = (self.vehicle.getWheel(idx) for idx in (2, 3))
        # wheelRate is in degrees per second
        wheelRate = 0.5 * abs(sum(w.getDeltaRotation() / dt for w in wheels))

        # Calculate which gear we're in, and what the normalised revs are
        if self.reversing:
            numberOfGears = 1
        else:
            numberOfGears = self.specs["sound"]["numberOfGears"]
        gear = min(int(wheelRate / self.gearSpacing), numberOfGears - 1)
        posInGear = (wheelRate - gear * self.gearSpacing) / self.gearSpacing

        targetPlayRate = 0.6 + posInGear * (1.5 - 0.6)
        currentRate = self.engineSound.getPlayRate()
        self.engineSound.setPlayRate(0.8 * currentRate + 0.2 * targetPlayRate)

    def updateControl(self, controlState, dt):
        """Updates acceleration, braking and steering

        These are all passed in through a controlState dictionary
        """

        # Update acceleration and braking
        wheelForce = controlState["throttle"] * self.specs["maxWheelForce"]
        self.reversing = controlState["reverse"]
        if self.reversing:
            # Make reversing a bit slower than moving forward
            wheelForce *= -0.5

        brakeForce = controlState["brake"] * self.specs["brakeForce"]

        # Update steering
        # Steering control state is from -1 to 1
        steering = controlState["steering"] * self.specs["steeringLock"]

        # Apply steering to front wheels
        self.vehicle.setSteeringValue(steering, 0)
        self.vehicle.setSteeringValue(steering, 1)
        # Apply engine and brake to rear wheels
        self.vehicle.applyEngineForce(wheelForce, 2)
        self.vehicle.applyEngineForce(wheelForce, 3)
        self.vehicle.setBrake(brakeForce, 2)
        self.vehicle.setBrake(brakeForce, 3)
class Vehicle(object):
    COUNT = 0

    def __init__(self, main, username, pos = LVecBase3(-5, -5, 1), isCurrentPlayer = False, carId=3):
        self.username = username
        self.main = main
        self.isCurrentPlayer = isCurrentPlayer
        self.boostCount = 0
        self.boostActive = False
        self.boostStep = 2
        self.boostDuration = 0
        self.moveStartTime = self.startTime = self.boostStartTime = time.time()
        self.pos = pos
        self.boostFactor = 1.2
        self.specs = {"mass": 800.0,
                    "maxWheelForce": 2000.0,
                    "brakeForce": 100.0,
                    "steeringLock": 45.0,
                    "maxSpeed": 33.0,
                    "maxReverseSpeed": 10.0}
        self.vehicleControlState = {"throttle": 0, "reverse": False, "brake": 0.0, "steering": 0.0, "health": 1}

        # Steering change per second, normalised to steering lock
        # Eg. 45 degrees lock and 1.0 rate means 45 degrees per second
        self.steeringRate = 0.8
        self.centreingRate = 1.2
        self.speed = 0

        self.setupVehicle(main)

        self.props = VehicleProps(carId)

        self.currentPowerups = {"powerup1": None, "powerup2": None, "powerup3": None}
        if isCurrentPlayer:
            #This command is required for Panda to render particles
            base.enableParticles()
            self.p = ParticleEffect()
        #     self.loadParticleConfig('steam.ptf')

    def setPropHealth(self, health):
        self.props.setHealth(health)
        if not self.isCurrentPlayer:
            self.main.updateStatusBars(self.username, self.props.health)

    def loadParticleConfig(self, file):
        #Start of the code from steam.ptf
        self.p.cleanup()
        self.p = ParticleEffect()
        self.p.loadConfig(Filename(file))
        # print type(main.worldNp)
        self.p.softStart()
        self.p.start(self.yugoNP)
        # self.p.setPos(0.000, -0.700, 0.250)
        self.p.setPos(0.000, -0.700, 0)

        #self.setupVehicle(bulletWorld)
        self.startTime = time.time()
        #COUNT = 1

    def move(self, steering, wheelForce, brakeForce, x, y, z, h, p, r):
        self.applyForcesAndSteering(steering, wheelForce, brakeForce)
        self.endTime = time.time()
        #print self.endTime
        elapsed = self.endTime - self.moveStartTime
        #self.startTime = self.endTime
        #if elapsed > 1:
        self.moveStartTime = self.endTime
        if not self.isCurrentPlayer:
            self.setVehiclePos(x, y, z, h, p, r)

        #print "Do Move"

    def applyForcesAndSteering(self, steering, wheelForce, brakeForce):
        # Apply steering to front wheels
        self.vehicle.setSteeringValue(steering, 0);
        self.vehicle.setSteeringValue(steering, 1);
        # Apply engine and brake to rear wheels
        self.vehicle.applyEngineForce(wheelForce, 2);
        self.vehicle.applyEngineForce(wheelForce, 3);
        self.vehicle.setBrake(brakeForce, 2);
        self.vehicle.setBrake(brakeForce, 3);
    def addBoost(self):
        if self.boostCount > 0:
            self.boostCount -= 1
            if not self.boostActive:
                self.boostStartTime = time.time()
                self.boostActive = True
            self.boostDuration += self.boostStep
    def checkDisableBoost(self):
        if time.time() - self.boostStartTime > self.boostDuration:
            self.boostActive = False

    def reset(self):
        self.chassisNP.setP(0)
        self.chassisNP.setR(0)

    def processInput(self, inputState, dt):
        # print self.chassisNP.getPos()
        #print self.chassisNP.getH()
        """Use controls to update the player's car"""
        # For keyboard throttle and brake are either 0 or 1
        self.checkDisableBoost()
        if inputState.isSet('forward'):
            self.vehicleControlState["throttle"] = 1.0
        else:
            self.vehicleControlState["throttle"] = 0.0

        velocity = self.chassisNode.getLinearVelocity()
        speed = math.sqrt(sum(v ** 2 for v in velocity))
        self.speed = speed
        # Update braking and reversing
        if inputState.isSet('brake'):
            if speed < 0.5 or self.vehicleControlState["reverse"]:
                # If we're stopped, then start reversing
                # Also keep reversing if we already were
                self.vehicleControlState["reverse"] = True
                self.vehicleControlState["throttle"] = 1.0
                self.vehicleControlState["brake"] = 0.0
            else:
                self.vehicleControlState["reverse"] = False
                self.vehicleControlState["brake"] = 1.0
        else:
            self.vehicleControlState["reverse"] = False
            self.vehicleControlState["brake"] = 0.0

        # steering is normalised from -1 to 1, corresponding
        # to the steering lock right and left
        steering = self.vehicleControlState["steering"]
        if inputState.isSet('left'):
            steering += dt * self.steeringRate
            steering = min(steering, 1.0)
        elif inputState.isSet('right'):
            steering -= dt * self.steeringRate
            steering = max(steering, -1.0)
        else:
            # gradually re-center the steering
            if steering > 0.0:
                steering -= dt * self.centreingRate
                if steering < 0.0:
                    steering = 0.0
            elif steering < 0.0:
                steering += dt * self.centreingRate
                if steering > 0.0:
                    steering = 0.0
        self.vehicleControlState["steering"] = steering

        # """Updates acceleration, braking and steering
        # These are all passed in through a controlState dictionary
        # """
        # Update acceleration and braking
        self.reversing = self.vehicleControlState["reverse"]
        brakeForce = self.vehicleControlState["brake"] * self.specs["brakeForce"]

        if self.reversing and self.speed > self.specs["maxReverseSpeed"]:
            self.applyForcesAndSteering(steering, 0, brakeForce)
            return
        if not self.reversing and self.speed > self.specs["maxSpeed"]:
            self.applyForcesAndSteering(steering, 0, brakeForce)
            return

        wheelForce = self.vehicleControlState["throttle"] * self.specs["maxWheelForce"]

        if self.reversing:
            # Make reversing a bit slower than moving forward
            wheelForce *= -0.5

        # Update steering
        # Steering control state is from -1 to 1
        steering = self.vehicleControlState["steering"] * self.specs["steeringLock"]
        if self.boostActive:
            wheelForce *= self.boostFactor
        self.applyForcesAndSteering(steering, wheelForce, brakeForce)
        return [steering, wheelForce, brakeForce]

    def getSpeed(self):
        velocity = self.chassisNode.getLinearVelocity()
        speed = math.sqrt(sum(v ** 2 for v in velocity))
        return speed, speed/self.specs["maxSpeed"]

    def getBoost(self):
        maxBoost = 3.0
        currentScaledBoost = self.boostCount / maxBoost
        return currentScaledBoost

    def updateHealth(self, damage):
        self.vehicleControlState["health"] -= 0.25
        if self.vehicleControlState["health"] <= 0.0:
            self.killVehicle("Lost health")

    def killVehicle(self, reason = ""):
        print "Sent request to server for killing this player because: ", reason

    def updateMovement(self, move, dt):
        """Use controls to update the player's car"""
        # For keyboard throttle and brake are either 0 or 1
        if move == 'f':
            self.vehicleControlState["throttle"] = 1.0
        else:
            self.vehicleControlState["throttle"] = 0.0

        velocity = self.chassisNode.getLinearVelocity()
        speed = math.sqrt(sum(v ** 2 for v in velocity))
        # Update braking and reversing
        if move == 'b':
            if speed < 0.5 or self.vehicleControlState["reverse"]:
                # If we're stopped, then start reversing
                # Also keep reversing if we already were
                self.vehicleControlState["reverse"] = True
                self.vehicleControlState["throttle"] = 1.0
                self.vehicleControlState["brake"] = 0.0
            else:
                self.vehicleControlState["reverse"] = False
                self.vehicleControlState["brake"] = 1.0
        else:
            self.vehicleControlState["reverse"] = False
            self.vehicleControlState["brake"] = 0.0

        # steering is normalised from -1 to 1, corresponding
        # to the steering lock right and left
        steering = self.vehicleControlState["steering"]
        if move == 'l':
            steering += dt * self.steeringRate
            steering = min(steering, 1.0)
        elif move == 'r':
            steering -= dt * self.steeringRate
            steering = max(steering, -1.0)
        else:
            # gradually re-center the steering
            if steering > 0.0:
                steering -= dt * self.centreingRate
                if steering < 0.0:
                    steering = 0.0
            elif steering < 0.0:
                steering += dt * self.centreingRate
                if steering > 0.0:
                    steering = 0.0
        self.vehicleControlState["steering"] = steering

        # """Updates acceleration, braking and steering
        # These are all passed in through a controlState dictionary
        # """
        # Update acceleration and braking
        wheelForce = self.vehicleControlState["throttle"] * self.specs["maxWheelForce"]
        self.reversing = self.vehicleControlState["reverse"]
        if self.reversing:
            # Make reversing a bit slower than moving forward
            wheelForce *= -0.5

        brakeForce = self.vehicleControlState["brake"] * self.specs["brakeForce"]

        # Update steering
        # Steering control state is from -1 to 1
        steering = self.vehicleControlState["steering"] * self.specs["steeringLock"]

        self.applyForcesAndSteering(steering, wheelForce, brakeForce)

        return [steering, wheelForce, brakeForce]

    def setVehiclePos(self, x,y, z, h, p, r):
        #self.chassisNP.setX(x)
        #self.chassisNP.setY(y)
        #self.chassisNP.setP(p)
        #self.chassisNP.setR(r)
        self.chassisNP.setPosHpr(x, y, z, h, p, r)
        return

    def setupVehicle(self, main):
        scale = 0.5
        # Chassis
        shape = BulletBoxShape(Vec3(0.6, 1.4, 0.5))
        ts = TransformState.makePos(Point3(0, 0, 0.5 * scale))

        name = self.username
        self.chassisNode = BulletRigidBodyNode(name)
        self.chassisNode.setTag('username', str(name))
        self.chassisNP = main.worldNP.attachNewNode(self.chassisNode)
        self.chassisNP.setName(str(name))
        self.chassisNP.node().addShape(shape, ts)
        self.chassisNP.setScale(scale)

        self.chassisNP.setPos(self.pos)
        if self.isCurrentPlayer:
            self.chassisNP.node().notifyCollisions(True)
            self.chassisNP.node().setMass(800.0)
        else:
            self.chassisNP.node().notifyCollisions(True)
            self.chassisNP.node().setMass(400.0)
        self.chassisNP.node().setDeactivationEnabled(False)

        main.world.attachRigidBody(self.chassisNP.node())

        #np.node().setCcdSweptSphereRadius(1.0)
        #np.node().setCcdMotionThreshold(1e-7)

        # Vehicle
        self.vehicle = BulletVehicle(main.world, self.chassisNP.node())
        self.vehicle.setCoordinateSystem(ZUp)
        main.world.attachVehicle(self.vehicle)

        self.yugoNP = loader.loadModel('models/yugo/yugo.egg')
        self.yugoNP.reparentTo(self.chassisNP)

        #self.carNP = loader.loadModel('models/batmobile-chassis.egg')
        #self.yugoNP.setScale(.7)
        #self.carNP.reparentTo(self.chassisNP)

        # Right front wheel
        np = loader.loadModel('models/yugo/yugotireR.egg')
        np.reparentTo(main.worldNP)
        self.addWheel(Point3( 0.70 * scale,  1.05 * scale, 0.3), True, np)

        # Left front wheel
        np = loader.loadModel('models/yugo/yugotireL.egg')
        np.reparentTo(main.worldNP)
        self.addWheel(Point3(-0.70 * scale,  1.05 * scale, 0.3), True, np)

        # Right rear wheel
        np = loader.loadModel('models/yugo/yugotireR.egg')
        np.reparentTo(main.worldNP)
        self.addWheel(Point3( 0.70 * scale, -1.05 * scale, 0.3), False, np)

        # Left rear wheel
        np = loader.loadModel('models/yugo/yugotireL.egg')
        np.reparentTo(main.worldNP)
        self.addWheel(Point3(-0.70 * scale, -1.05 * scale, 0.3), False, np)

    def addWheel(self, pos, front, np):
        wheel = self.vehicle.createWheel()

        wheel.setNode(np.node())
        wheel.setChassisConnectionPointCs(pos)
        wheel.setFrontWheel(front)

        wheel.setWheelDirectionCs(Vec3(0, 0, -1))
        wheel.setWheelAxleCs(Vec3(1, 0, 0))
        wheel.setWheelRadius(0.25)
        wheel.setMaxSuspensionTravelCm(40.0)

        wheel.setSuspensionStiffness(40.0)
        wheel.setWheelsDampingRelaxation(2.3)
        wheel.setWheelsDampingCompression(4.4)
        wheel.setFrictionSlip(100.0);
        wheel.setRollInfluence(0.1)


    def reset(self):
        #self.chassisNP.setP(0)
        #self.chassisNP.setR(0)
        #print "kegwe", self.chassisNP.getX(),self.chassisNP.getY(),self.chassisNP.getZ(),self.chassisNP.getH(),0,0
        self.chassisNP.setPosHpr(self.chassisNP.getX(),self.chassisNP.getY(),self.chassisNP.getZ(),self.chassisNP.getH(),0,0)


    def pickedPowerup(self, powerup):
        if not powerup.pickable:
            powerup.useAbility()
        else:
            if self.currentPowerups["powerup1"] is None:
                self.currentPowerups["powerup1"] = powerup
            elif self.currentPowerups["powerup2"] is None:
                self.currentPowerups["powerup2"] = powerup
            elif self.currentPowerups["powerup3"] is None:
                self.currentPowerups["powerup3"] = powerup


    def canPickUpPowerup(self):
        return (self.currentPowerups["powerup1"] is None or
                self.currentPowerups["powerup2"] is None or
                self.currentPowerups["powerup3"] is None)


    def usePowerup(self, powerupIndex):
        # Move usePowerupN to this function
        if powerupIndex == 0 and self.currentPowerups["powerup1"] is not None:
            self.currentPowerups["powerup1"].useAbility()
            self.currentPowerups["powerup1"] = None
        elif powerupIndex == 1 and self.currentPowerups["powerup2"] is not None:
            self.currentPowerups["powerup2"].useAbility()
            self.currentPowerups["powerup2"] = None
        elif powerupIndex == 2 and self.currentPowerups["powerup3"] is not None:
            self.currentPowerups["powerup3"].useAbility()
            self.currentPowerups["powerup3"] = None
Exemplo n.º 8
0
class Game(DirectObject):
    def __init__(self):
        base.setBackgroundColor(0.1, 0.1, 0.8, 1)
        base.setFrameRateMeter(True)

        base.cam.setPos(0, -20, 4)
        base.cam.lookAt(0, 0, 0)

        # Light
        alight = AmbientLight('ambientLight')
        alight.setColor(Vec4(0.5, 0.5, 0.5, 1))
        alightNP = render.attachNewNode(alight)

        dlight = DirectionalLight('directionalLight')
        dlight.setDirection(Vec3(1, 1, -1))
        dlight.setColor(Vec4(0.7, 0.7, 0.7, 1))
        dlightNP = render.attachNewNode(dlight)

        render.clearLight()
        render.setLight(alightNP)
        render.setLight(dlightNP)

        # Input
        self.accept('escape', self.doExit)
        self.accept('r', self.doReset)
        self.accept('f1', self.toggleWireframe)
        self.accept('f2', self.toggleTexture)
        self.accept('f3', self.toggleDebug)
        self.accept('f5', self.doScreenshot)

        inputState.watchWithModifiers('forward', 'w')
        inputState.watchWithModifiers('left', 'a')
        inputState.watchWithModifiers('reverse', 's')
        inputState.watchWithModifiers('right', 'd')
        inputState.watchWithModifiers('turnLeft', 'q')
        inputState.watchWithModifiers('turnRight', 'e')

        # Task
        taskMgr.add(self.update, 'updateWorld')

        # Physics
        self.setup()

    # _____HANDLER_____

    def doExit(self):
        self.cleanup()
        sys.exit(1)

    def doReset(self):
        self.cleanup()
        self.setup()

    def toggleWireframe(self):
        base.toggleWireframe()

    def toggleTexture(self):
        base.toggleTexture()

    def toggleDebug(self):
        if self.debugNP.isHidden():
            self.debugNP.show()
        else:
            self.debugNP.hide()

    def doScreenshot(self):
        base.screenshot('Bullet')

    # ____TASK___

    def processInput(self, dt):
        engineForce = 0.0
        brakeForce = 0.0

        if inputState.isSet('forward'):
            engineForce = 1000.0
            brakeForce = 0.0

        if inputState.isSet('reverse'):
            engineForce = 0.0
            brakeForce = 100.0

        if inputState.isSet('turnLeft'):
            self.steering += dt * self.steeringIncrement
            self.steering = min(self.steering, self.steeringClamp)

        if inputState.isSet('turnRight'):
            self.steering -= dt * self.steeringIncrement
            self.steering = max(self.steering, -self.steeringClamp)

        # Apply steering to front wheels
        self.vehicle.setSteeringValue(self.steering, 0)
        self.vehicle.setSteeringValue(self.steering, 1)

        # Apply engine and brake to rear wheels
        self.vehicle.applyEngineForce(engineForce, 2)
        self.vehicle.applyEngineForce(engineForce, 3)
        self.vehicle.setBrake(brakeForce, 2)
        self.vehicle.setBrake(brakeForce, 3)

    def update(self, task):
        dt = globalClock.getDt()

        self.processInput(dt)
        self.world.doPhysics(dt, 10, 0.008)

        #print self.vehicle.getWheel(0).getRaycastInfo().isInContact()
        #print self.vehicle.getWheel(0).getRaycastInfo().getContactPointWs()

        #print self.vehicle.getChassis().isKinematic()

        return task.cont

    def cleanup(self):
        self.world = None
        self.worldNP.removeNode()

    def setup(self):
        self.worldNP = render.attachNewNode('World')

        # World
        self.debugNP = self.worldNP.attachNewNode(BulletDebugNode('Debug'))
        self.debugNP.show()

        self.world = BulletWorld()
        self.world.setGravity(Vec3(0, 0, -9.81))
        self.world.setDebugNode(self.debugNP.node())

        # Plane
        shape = BulletPlaneShape(Vec3(0, 0, 1), 0)

        np = self.worldNP.attachNewNode(BulletRigidBodyNode('Ground'))
        np.node().addShape(shape)
        np.setPos(0, 0, -1)
        np.setCollideMask(BitMask32.allOn())

        self.world.attachRigidBody(np.node())

        # Chassis
        shape = BulletBoxShape(Vec3(0.6, 1.4, 0.5))
        ts = TransformState.makePos(Point3(0, 0, 0.5))

        np = self.worldNP.attachNewNode(BulletRigidBodyNode('Vehicle'))
        np.node().addShape(shape, ts)
        np.setPos(0, 0, 1)
        np.node().setMass(800.0)
        np.node().setDeactivationEnabled(False)

        self.world.attachRigidBody(np.node())

        #np.node().setCcdSweptSphereRadius(1.0)
        #np.node().setCcdMotionThreshold(1e-7)

        # Vehicle
        self.vehicle = BulletVehicle(self.world, np.node())
        self.vehicle.setCoordinateSystem(ZUp)
        self.world.attachVehicle(self.vehicle)

        self.yugoNP = loader.loadModel('car/yugo.egg')
        self.yugoNP.reparentTo(np)

        # Right front wheel
        np = loader.loadModel('car/yugotireR.egg')
        np.reparentTo(self.worldNP)
        self.addWheel(Point3(0.70, 1.05, 0.3), True, np)

        # Left front wheel
        np = loader.loadModel('car/yugotireL.egg')
        np.reparentTo(self.worldNP)
        self.addWheel(Point3(-0.70, 1.05, 0.3), True, np)

        # Right rear wheel
        np = loader.loadModel('car/yugotireR.egg')
        np.reparentTo(self.worldNP)
        self.addWheel(Point3(0.70, -1.05, 0.3), False, np)

        # Left rear wheel
        np = loader.loadModel('car/yugotireL.egg')
        np.reparentTo(self.worldNP)
        self.addWheel(Point3(-0.70, -1.05, 0.3), False, np)

        # Steering info
        self.steering = 0.0  # degree
        self.steeringClamp = 45.0  # degree
        self.steeringIncrement = 120.0  # degree per second

    def addWheel(self, pos, front, np):
        wheel = self.vehicle.createWheel()

        wheel.setNode(np.node())
        wheel.setChassisConnectionPointCs(pos)
        wheel.setFrontWheel(front)

        wheel.setWheelDirectionCs(Vec3(0, 0, -1))
        wheel.setWheelAxleCs(Vec3(1, 0, 0))
        wheel.setWheelRadius(0.25)
        wheel.setMaxSuspensionTravelCm(40.0)

        wheel.setSuspensionStiffness(40.0)
        wheel.setWheelsDampingRelaxation(2.3)
        wheel.setWheelsDampingCompression(4.4)
        wheel.setFrictionSlip(100.0)
        wheel.setRollInfluence(0.1)
Exemplo n.º 9
0
class Game(DirectObject):

  def __init__(self):
    base.setBackgroundColor(0.1, 0.1, 0.8, 1)
    base.setFrameRateMeter(True)

    base.cam.setPos(0, -20, 4)
    base.cam.lookAt(0, 0, 0)

    # Light
    alight = AmbientLight('ambientLight')
    alight.setColor(Vec4(0.5, 0.5, 0.5, 1))
    alightNP = render.attachNewNode(alight)

    dlight = DirectionalLight('directionalLight')
    dlight.setDirection(Vec3(1, 1, -1))
    dlight.setColor(Vec4(0.7, 0.7, 0.7, 1))
    dlightNP = render.attachNewNode(dlight)

    render.clearLight()
    render.setLight(alightNP)
    render.setLight(dlightNP)

    # Input
    self.accept('escape', self.doExit)
    self.accept('r', self.doReset)
    self.accept('f1', self.toggleWireframe)
    self.accept('f2', self.toggleTexture)
    self.accept('f3', self.toggleDebug)
    self.accept('f5', self.doScreenshot)

    inputState.watchWithModifiers('forward', 'w')
    inputState.watchWithModifiers('left', 'a')
    inputState.watchWithModifiers('reverse', 's')
    inputState.watchWithModifiers('right', 'd')
    inputState.watchWithModifiers('turnLeft', 'q')
    inputState.watchWithModifiers('turnRight', 'e')

    # Task
    taskMgr.add(self.update, 'updateWorld')

    # Physics
    self.setup()

  # _____HANDLER_____

  def doExit(self):
    self.cleanup()
    sys.exit(1)

  def doReset(self):
    self.cleanup()
    self.setup()

  def toggleWireframe(self):
    base.toggleWireframe()

  def toggleTexture(self):
    base.toggleTexture()

  def toggleDebug(self):
    if self.debugNP.isHidden():
      self.debugNP.show()
    else:
      self.debugNP.hide()

  def doScreenshot(self):
    base.screenshot('Bullet')

  # ____TASK___

  def processInput(self, dt):
    engineForce = 0.0
    brakeForce = 0.0

    if inputState.isSet('forward'):
      engineForce = 1000.0
      brakeForce = 0.0

    if inputState.isSet('reverse'):
      engineForce = 0.0
      brakeForce = 100.0

    if inputState.isSet('turnLeft'):
      self.steering += dt * self.steeringIncrement
      self.steering = min(self.steering, self.steeringClamp)

    if inputState.isSet('turnRight'):
      self.steering -= dt * self.steeringIncrement
      self.steering = max(self.steering, -self.steeringClamp)

    # Apply steering to front wheels
    self.vehicle.setSteeringValue(self.steering, 0);
    self.vehicle.setSteeringValue(self.steering, 1);

    # Apply engine and brake to rear wheels
    self.vehicle.applyEngineForce(engineForce, 2);
    self.vehicle.applyEngineForce(engineForce, 3);
    self.vehicle.setBrake(brakeForce, 2);
    self.vehicle.setBrake(brakeForce, 3);

  def update(self, task):
    dt = globalClock.getDt()

    self.processInput(dt)
    self.world.doPhysics(dt, 10, 0.008)

    #print self.vehicle.getWheel(0).getRaycastInfo().isInContact()
    #print self.vehicle.getWheel(0).getRaycastInfo().getContactPointWs()

    #print self.vehicle.getChassis().isKinematic()

    return task.cont

  def cleanup(self):
    self.world = None
    self.worldNP.removeNode()

  def setup(self):
    self.worldNP = render.attachNewNode('World')

    # World
    self.debugNP = self.worldNP.attachNewNode(BulletDebugNode('Debug'))
    self.debugNP.show()

    self.world = BulletWorld()
    self.world.setGravity(Vec3(0, 0, -9.81))
    self.world.setDebugNode(self.debugNP.node())

    # Plane
    shape = BulletPlaneShape(Vec3(0, 0, 1), 0)

    np = self.worldNP.attachNewNode(BulletRigidBodyNode('Ground'))
    np.node().addShape(shape)
    np.setPos(0, 0, -1)
    np.setCollideMask(BitMask32.allOn())

    self.world.attachRigidBody(np.node())

    # Chassis
    shape = BulletBoxShape(Vec3(0.6, 1.4, 0.5))
    ts = TransformState.makePos(Point3(0, 0, 0.5))

    np = self.worldNP.attachNewNode(BulletRigidBodyNode('Vehicle'))
    np.node().addShape(shape, ts)
    np.setPos(0, 0, 1)
    np.node().setMass(800.0)
    np.node().setDeactivationEnabled(False)

    self.world.attachRigidBody(np.node())

    #np.node().setCcdSweptSphereRadius(1.0)
    #np.node().setCcdMotionThreshold(1e-7) 

    # Vehicle
    self.vehicle = BulletVehicle(self.world, np.node())
    self.vehicle.setCoordinateSystem(ZUp)
    self.world.attachVehicle(self.vehicle)

    self.yugoNP = loader.loadModel('models/yugo/yugo.egg')
    self.yugoNP.reparentTo(np)

    # Right front wheel
    np = loader.loadModel('models/yugo/yugotireR.egg')
    np.reparentTo(self.worldNP)
    self.addWheel(Point3( 0.70,  1.05, 0.3), True, np)

    # Left front wheel
    np = loader.loadModel('models/yugo/yugotireL.egg')
    np.reparentTo(self.worldNP)
    self.addWheel(Point3(-0.70,  1.05, 0.3), True, np)

    # Right rear wheel
    np = loader.loadModel('models/yugo/yugotireR.egg')
    np.reparentTo(self.worldNP)
    self.addWheel(Point3( 0.70, -1.05, 0.3), False, np)

    # Left rear wheel
    np = loader.loadModel('models/yugo/yugotireL.egg')
    np.reparentTo(self.worldNP)
    self.addWheel(Point3(-0.70, -1.05, 0.3), False, np)

    # Steering info
    self.steering = 0.0            # degree
    self.steeringClamp = 45.0      # degree
    self.steeringIncrement = 120.0 # degree per second

  def addWheel(self, pos, front, np):
    wheel = self.vehicle.createWheel()

    wheel.setNode(np.node())
    wheel.setChassisConnectionPointCs(pos)
    wheel.setFrontWheel(front)

    wheel.setWheelDirectionCs(Vec3(0, 0, -1))
    wheel.setWheelAxleCs(Vec3(1, 0, 0))
    wheel.setWheelRadius(0.25)
    wheel.setMaxSuspensionTravelCm(40.0)

    wheel.setSuspensionStiffness(40.0)
    wheel.setWheelsDampingRelaxation(2.3)
    wheel.setWheelsDampingCompression(4.4)
    wheel.setFrictionSlip(100.0);
    wheel.setRollInfluence(0.1)
Exemplo n.º 10
0
class CarPhys(Phys):
    def __init__(self, mdt, carphys_props):
        Phys.__init__(self, mdt)
        self.pnode = None
        self.vehicle = None
        self.curr_speed_factor = 1.0
        self.__prev_speed = 0
        self.__finds = {}  # cache for find's results
        self.props = carphys_props
        self._load_phys()
        self.__set_collision_mesh()
        self.__set_phys_node()
        self.__set_vehicle()
        self.__set_wheels()
        eng.attach_obs(self.on_end_frame)

    def _load_phys(self):
        fpath = self.props.phys_file % self.mdt.name
        with open(fpath) as phys_file:  # pass phys props as a class
            self.cfg = load(phys_file)
        self.cfg['max_speed'] = self.get_speed()
        self.cfg['friction_slip'] = self.get_friction()
        self.cfg['roll_influence'] = self.get_roll_influence()
        s_a = (self.mdt.name, round(self.cfg['max_speed'],
                                    2), self.props.driver_engine)
        LogMgr().log('speed %s: %s (%s)' % s_a)
        fr_slip = round(self.cfg['friction_slip'], 2)
        f_a = (self.mdt.name, fr_slip, self.props.driver_tires)
        LogMgr().log('friction %s: %s (%s)' % f_a)
        r_a = (self.mdt.name, round(self.cfg['roll_influence'],
                                    2), self.props.driver_suspensions)
        LogMgr().log('roll %s: %s (%s)' % r_a)
        s_a = lambda field: setattr(self, field, self.cfg[field])
        map(s_a, self.cfg.keys())

    def __set_collision_mesh(self):
        fpath = self.props.coll_path % self.mdt.name
        self.coll_mesh = loader.loadModel(fpath)
        chassis_shape = BulletConvexHullShape()
        for geom in PhysMgr().find_geoms(self.coll_mesh, self.props.coll_name):
            chassis_shape.addGeom(geom.node().getGeom(0), geom.getTransform())
        self.mdt.gfx.nodepath.node().addShape(chassis_shape)
        self.mdt.gfx.nodepath.setCollideMask(
            BitMask32.bit(1)
            | BitMask32.bit(2 + self.props.cars.index(self.mdt.name)))
        #nodepath = self.mdt.gfx.nodepath.attachNewNode(BulletGhostNode('car ghost'))
        #nodepath.node().addShape(BulletCapsuleShape(4, 5, ZUp))
        #eng.attach_ghost(nodepath.node())
        #nodepath.node().notifyCollisions(False)

    def __set_phys_node(self):
        self.pnode = self.mdt.gfx.nodepath.node()
        self.pnode.setMass(self.mass)
        self.pnode.setDeactivationEnabled(False)
        PhysMgr().attach_rigid_body(self.pnode)
        PhysMgr().add_collision_obj(self.pnode)

    def __set_vehicle(self):
        self.vehicle = BulletVehicle(PhysMgr().root, self.pnode)
        self.vehicle.setCoordinateSystem(ZUp)
        self.vehicle.setPitchControl(self.pitch_control)
        tuning = self.vehicle.getTuning()
        tuning.setSuspensionCompression(self.suspension_compression)
        tuning.setSuspensionDamping(self.suspension_damping)
        PhysMgr().attach_vehicle(self.vehicle)

    def __set_wheels(self):
        fwheel_bounds = self.mdt.gfx.wheels['fr'].get_tight_bounds()
        f_radius = (fwheel_bounds[1][2] - fwheel_bounds[0][2]) / 2.0 + .01
        rwheel_bounds = self.mdt.gfx.wheels['rr'].get_tight_bounds()
        r_radius = (rwheel_bounds[1][2] - rwheel_bounds[0][2]) / 2.0 + .01
        ffr = self.coll_mesh.find('**/' + self.props.wheel_names[0][0])
        ffl = self.coll_mesh.find('**/' + self.props.wheel_names[0][1])
        rrr = self.coll_mesh.find('**/' + self.props.wheel_names[0][2])
        rrl = self.coll_mesh.find('**/' + self.props.wheel_names[0][3])
        meth = self.coll_mesh.find
        fr_node = ffr if ffr else meth('**/' + self.props.wheel_names[1][0])
        fl_node = ffl if ffl else meth('**/' + self.props.wheel_names[1][1])
        rr_node = rrr if rrr else meth('**/' + self.props.wheel_names[1][2])
        rl_node = rrl if rrl else meth('**/' + self.props.wheel_names[1][3])
        wheel_fr_pos = fr_node.get_pos() + (0, 0, f_radius)
        wheel_fl_pos = fl_node.get_pos() + (0, 0, f_radius)
        wheel_rr_pos = rr_node.get_pos() + (0, 0, r_radius)
        wheel_rl_pos = rl_node.get_pos() + (0, 0, r_radius)
        frw = self.mdt.gfx.wheels['fr']
        flw = self.mdt.gfx.wheels['fl']
        rrw = self.mdt.gfx.wheels['rr']
        rlw = self.mdt.gfx.wheels['rl']
        wheels_info = [(wheel_fr_pos, True, frw, f_radius),
                       (wheel_fl_pos, True, flw, f_radius),
                       (wheel_rr_pos, False, rrw, r_radius),
                       (wheel_rl_pos, False, rlw, r_radius)]
        for (pos, front, nodepath, radius) in wheels_info:
            self.__add_wheel(pos, front, nodepath.node(), radius)

    def __add_wheel(self, pos, front, node, radius):
        whl = self.vehicle.createWheel()
        whl.setNode(node)
        whl.setChassisConnectionPointCs(LPoint3f(*pos))
        whl.setFrontWheel(front)
        whl.setWheelDirectionCs((0, 0, -1))
        whl.setWheelAxleCs((1, 0, 0))
        whl.setWheelRadius(radius)
        whl.setSuspensionStiffness(self.suspension_stiffness)
        whl.setWheelsDampingRelaxation(self.wheels_damping_relaxation)
        whl.setWheelsDampingCompression(self.wheels_damping_compression)
        whl.setFrictionSlip(self.friction_slip)  # high -> more adherence
        whl.setRollInfluence(self.roll_influence)  # low ->  more stability
        whl.setMaxSuspensionForce(self.max_suspension_force)
        whl.setMaxSuspensionTravelCm(self.max_suspension_travel_cm)
        whl.setSkidInfo(self.skid_info)

    @property
    def lateral_force(self):
        vel = self.vehicle.get_chassis().get_linear_velocity()
        vel.normalize()
        dir = self.mdt.logic.car_vec
        lat = dir.dot(vel)
        lat_force = 0
        if lat > .5:
            lat_force = min(1, (lat - 1.0) / -.2)
        return lat_force

    @property
    def is_flying(self):  # no need to be cached
        rays = [whl.getRaycastInfo() for whl in self.vehicle.get_wheels()]
        return not any(ray.isInContact() for ray in rays)

    @property
    def prev_speed(self):
        return self.__prev_speed

    @property
    def prev_speed_ratio(self):
        return max(0, min(1.0, self.prev_speed / self.max_speed))

    def on_end_frame(self):
        self.__prev_speed = self.speed

    @property
    def speed(self):
        if self.mdt.fsm.getCurrentOrNextState() == 'Countdown':
            return 0  # getCurrentSpeedKmHour returns odd values otherwise
        return self.vehicle.getCurrentSpeedKmHour()

    @property
    def speed_ratio(self):
        return max(0, min(1.0, self.speed / self.max_speed))

    def set_forces(self, eng_frc, brake_frc, steering):
        self.vehicle.setSteeringValue(steering, 0)
        self.vehicle.setSteeringValue(steering, 1)
        self.vehicle.applyEngineForce(eng_frc, 2)
        self.vehicle.applyEngineForce(eng_frc, 3)
        self.vehicle.setBrake(brake_frc, 2)
        self.vehicle.setBrake(brake_frc, 3)

    def update_car_props(self):
        speeds = []
        for whl in self.vehicle.get_wheels():
            contact_pt = whl.get_raycast_info().getContactPointWs()
            gnd_name = self.gnd_name(contact_pt)
            if not gnd_name:
                continue
            if gnd_name not in self.__finds:
                gnd = self.props.track_phys.find('**/' + gnd_name)
                self.__finds[gnd_name] = gnd
            gfx_node = self.__finds[gnd_name]
            if gfx_node.has_tag('speed'):
                speeds += [float(gfx_node.get_tag('speed'))]
            if gfx_node.has_tag('friction'):
                fric = float(gfx_node.get_tag('friction'))
                whl.setFrictionSlip(self.friction_slip * fric)
        self.curr_speed_factor = (sum(speeds) / len(speeds)) if speeds else 1.0

    @property
    def gnd_names(self):  # no need to be cached
        whls = self.vehicle.get_wheels()
        pos = map(lambda whl: whl.get_raycast_info().getContactPointWs(), whls)
        return map(self.gnd_name, pos)

    @staticmethod
    def gnd_name(pos):
        top = pos + (0, 0, 20)
        bottom = pos + (0, 0, -20)
        result = PhysMgr().ray_test_closest(bottom, top)
        ground = result.get_node()
        return ground.get_name() if ground else ''

    def apply_damage(self, reset=False):
        if reset:
            self.max_speed = self.get_speed()
            self.friction_slip = self.get_friction()
            self.roll_influence = self.get_roll_influence()
        else:
            self.max_speed *= .95
            self.friction_slip *= .95
            self.roll_influence *= 1.05
        fric = lambda whl: whl.setFrictionSlip(self.friction_slip)
        map(fric, self.vehicle.get_wheels())
        roll = lambda whl: whl.setRollInfluence(self.roll_influence)
        map(roll, self.vehicle.get_wheels())
        s_a = (str(round(self.max_speed, 2)), self.props.driver_engine)
        LogMgr().log('speed: %s (%s)' % s_a)
        f_a = (str(round(self.friction_slip, 2)), self.props.driver_tires)
        LogMgr().log('friction: %s (%s)' % f_a)
        r_a = (str(round(self.roll_influence,
                         2)), self.props.driver_suspensions)
        LogMgr().log('roll: %s (%s)' % r_a)

    def get_speed(self):
        return self.cfg['max_speed'] * (1 + .01 * self.props.driver_engine)

    def get_friction(self):
        return self.cfg['friction_slip'] * (1 + .01 * self.props.driver_tires)

    def get_roll_influence(self):
        return self.cfg['roll_influence'] * (
            1 + .01 * self.props.driver_suspensions)

    def destroy(self):
        eng.detach_obs(self.on_end_frame)
        eng.remove_vehicle(self.vehicle)
        self.pnode = self.vehicle = self.__finds = self.__track_phys = \
            self.coll_mesh = None
        Phys.destroy(self)
Exemplo n.º 11
0
class Game(DirectObject):
    def __init__(self, model):
        self.model = model

        base.setBackgroundColor(0.1, 0.1, 0.8, 1)
        base.setFrameRateMeter(True)

        base.cam.setPos(0, -20, 4)
        base.cam.lookAt(0, 0, 0)

        w = WindowProperties()
        w.setFullscreen(False)
        w.setOrigin(5, 20)
        w.setSize(865, 800)
        base.win.requestProperties(w)

        # Light
        alight = AmbientLight('ambientLight')
        alight.setColor(Vec4(0.5, 0.5, 0.5, 1))
        alightNP = render.attachNewNode(alight)

        dlight = DirectionalLight('directionalLight')
        dlight.setDirection(Vec3(1, 1, -1))
        dlight.setColor(Vec4(0.7, 0.7, 0.7, 1))
        dlightNP = render.attachNewNode(dlight)

        render.clearLight()
        render.setLight(alightNP)
        render.setLight(dlightNP)

        # Input
        self.accept('escape', self.doExit)
        self.accept('r', self.doReset)
        self.accept('f1', self.toggleWireframe)
        self.accept('f2', self.toggleTexture)
        self.accept('f3', self.toggleDebug)
        self.accept('f5', self.doScreenshot)

        inputState.watchWithModifiers('forward', 'w')
        inputState.watchWithModifiers('left', 'a')
        inputState.watchWithModifiers('reverse', 's')
        inputState.watchWithModifiers('right', 'd')
        inputState.watchWithModifiers('turnLeft', 'q')
        inputState.watchWithModifiers('turnRight', 'e')

        # Task
        taskMgr.add(self.update, 'updateWorld')

        # Physics
        self.setup()

    # _____HANDLER_____

    def doExit(self):
        self.cleanup()
        sys.exit(1)

    def endLoop(self):
        self.penalized_distance = self.distance * (numpy.exp(
            -self.time_max_steering / self.total_time))
        pickle.dump(self.penalized_distance, open('distance.p', 'wb'))
        sys.exit()
        #quit()
        #print("Distance was: ",self.distance)
        #os.execv(sys.executable,['python']+[__file__])
        #taskMgr.running = False

    def doReset(self):
        self.cleanup()
        self.setup()

    def toggleWireframe(self):
        base.toggleWireframe()

    def toggleTexture(self):
        base.toggleTexture()

    def toggleDebug(self):
        if self.debugNP.isHidden():
            self.debugNP.show()
        else:
            self.debugNP.hide()

    def doScreenshot(self):
        base.screenshot('Bullet')

    # ____TASK___

    def calculate_moves(self):
        self.y = self.model.predict(self.x)
        #print(self.y)
        self.moves = self.y > 0  #+ self.model_offset # 0.5
        #self.moves[0] = True # FIXME test

    def processInput(self, dt):
        engineForce = 0.0
        brakeForce = 0.0
        if self.moves[
                0]:  #inputState.isSet('forward'): FIXME maybe engine and brake can be linked to self.y, rectified, continuous
            engineForce = 2000.0  # 1000.
            brakeForce = 0.0

        if not self.moves[0]:  #inputState.isSet('reverse'):
            engineForce = 200.0  #0.0
            brakeForce = 100.0

        self.steering = self.y[1]
        if self.moves[1]:
            self.steering = min(self.steering, self.steeringClamp)
        if not self.moves[1]:
            self.steering = max(self.steering, -self.steeringClamp)
        """ # FIXME option may be better if self.steering is fed into self.y[3] for 4th element
    if not self.moves[2]: # enabled steering lock

        if self.moves[1]:#inputState.isSet('turnLeft'):
          self.steering += dt * self.steeringIncrement
          self.steering = min(self.steering, self.steeringClamp)

        if not self.moves[1]:#inputState.isSet('turnRight'):
          self.steering -= dt * self.steeringIncrement
          self.steering = max(self.steering, -self.steeringClamp)
    """ """
    if inputState.isSet('forward'):
      engineForce = 1000.0
      brakeForce = 0.0

    if inputState.isSet('reverse'):
      engineForce = 0.0
      brakeForce = 100.0

    if inputState.isSet('turnLeft'):
      self.steering += dt * self.steeringIncrement
      self.steering = min(self.steering, self.steeringClamp)

    if inputState.isSet('turnRight'):
      self.steering -= dt * self.steeringIncrement
      self.steering = max(self.steering, -self.steeringClamp)
    """
        # Apply steering to front wheels
        self.vehicle.setSteeringValue(self.steering, 0)
        self.vehicle.setSteeringValue(self.steering, 1)

        # Apply engine and brake to rear wheels
        self.vehicle.applyEngineForce(engineForce, 2)
        self.vehicle.applyEngineForce(engineForce, 3)
        self.vehicle.setBrake(brakeForce, 2)
        self.vehicle.setBrake(brakeForce, 3)

    def check_collisions(self):
        """pFrom = render.getRelativePoint(self.yugoNP,Point3(0,0,0))#Point3(0,0,0)
      pFrom -= Point3(0,0,pFrom[2])
      pRel = render.getRelativePoint(base.cam,self.yugoNP.getPos())  # FIXME THIS IS IT!! get rid of z component
      pRel -= Point3(0,0,pRel[2])
      p45 = Point3(pRel[0] - pRel[1], pRel[1] + pRel[0],0)
      pn45 = Point3(pRel[0] + pRel[1], pRel[1] - pRel[0],0)
      #print(render.getRelativePoint(self.yugoNP,Point3(0,0,0)))
      #print(dir(self.yugoNP))
      pTo = [pFrom + pn45, pFrom + pRel, pFrom + p45]#[pFrom + Vec3(-10,10,0)*999,pFrom + Vec3(0,10,0)*999,pFrom + Vec3(10,10,0)*999]# FIXME should be relative to front of car, getting cloe! #self.yugoNP.getPosDelta()*99999]#[Point3(-10,10,0) * 99999,Point3(0,10,0) * 99999,Point3(10,10,0) * 99999]
      #self.ray = CollisionRay(0,0,0,100,0,0)
      result = [self.world.rayTestClosest(pFrom,pt) for pt in pTo]
      #print(dir(self.yugoNP))
      #print(result.getHitPos())
      return tuple([res.getHitPos().length() for res in result])
      """#queue = CollisionHandlerQueue()
        #traverser.addCollider(fromObject, queue)
        #traverser.traverse(render)
        #queue.sortEntries()
        #for entry in queue.getEntries():
        #print(entry)
        #print(result.getHitPos())
        #if result.getNode() != None:
        #print(self.yugoNP.getPos(result.getNode()))
        #print(self.cTrav)
        self.cTrav.traverse(render)
        entries = list(self.colHandler.getEntries())
        #print(entries)
        entries.sort(key=lambda y: y.getSurfacePoint(render).getY())
        #for entry in entries:      print(entry.getFromNodePath().getName())
        if entries:  # and len(result) > 1:
            #print(entries)
            for r in entries:

                #print(r.getIntoNodePath().getName())
                if r.getIntoNodePath().getName(
                ) == 'Plane' and r.getFromNodePath().getName() == 'yugo_box':
                    self.endLoop()
                if r.getIntoNodePath().getName(
                ) == 'Plane' and r.getFromNodePath().getName() in [
                        'ray%d' % i for i in range(self.n_rays)
                ]:  #Box
                    self.ray_col_vec_dict[
                        r.getFromNodePath().getName()].append(
                            numpy.linalg.norm(
                                list(r.getSurfacePoint(
                                    r.getFromNodePath()))[:-1]))
        self.ray_col_vec_dict = {
            k: (min(self.ray_col_vec_dict[k])
                if len(self.ray_col_vec_dict[k]) >= 1 else 10000)
            for k in self.ray_col_vec_dict
        }
        self.x = numpy.array(list(self.ray_col_vec_dict.values()))
        #print(self.x)
        result = self.world.contactTest(self.yugoNP.node())
        #print(result.getNumContacts())
        #print(dir(self.yugoNP))
        #return entries

    def check_prevPos(self):
        if len(self.prevPos) > 80:
            #print(self.prevPos)
            #print(numpy.linalg.norm(self.prevPos[-1] - self.prevPos[0]))
            if numpy.linalg.norm(self.prevPos[-1] - self.prevPos[0]) < 4.5:
                #print("ERROR")
                self.endLoop()

            del self.prevPos[0:len(self.prevPos) - 80]

    def update(self, task):

        self.prevPos.append(self.yugoNP.getPos(render))
        dx = numpy.linalg.norm(self.prevPos[-1] - self.prevPos[-2])
        self.distance += dx
        self.distance_text.setText('Distance=%.3f' % (self.distance))
        #print(len(self.prevPos))

        dt = globalClock.getDt()
        self.total_time += dt
        if abs(self.steering) == abs(self.steeringClamp):
            self.time_max_steering += dt
        self.time_text.setText('TotalTime=%.3f' % (self.total_time))
        #self.time_maxsteer_text.setText('TotalTimeMaxSteer=%f'%(self.time_max_steering))
        #self.penalized_distance = self.distance*(1.-numpy.exp(-self.time_max_steering/self.total_time))
        if self.distance > 10000:
            self.endLoop()
        self.check_prevPos()
        self.speed = dx / dt
        self.speed_text.setText('Speed=%.3f' % (self.speed))

        self.check_collisions()
        self.calculate_moves()
        self.model.plot_NN()
        #self.nn_image.setImage('neural_net_vis.png')
        self.ray_col_vec_dict = {k: [] for k in self.ray_col_vec_dict}
        self.processInput(dt)
        self.world.doPhysics(dt, 10, 0.008)
        # FIXME KEEP TRACK OF TOTAL DEGREES TURNED AND PENALIZE
        #self.doReset()

        #print(dir(result[1]))
        #print(numpy.linalg.norm(list(result[1].getSurfacePoint(result[1].getFromNodePath()))[:-1]))
        #base.camera.setPos(0,-40,10)
        #print self.vehicle.getWheel(0).getRaycastInfo().isInContact()
        #print self.vehicle.getWheel(0).getRaycastInfo().getContactPointWs()

        #print self.vehicle.getChassis().isKinematic()

        return task.cont

    def cleanup(self):
        self.world = None
        self.worldNP.removeNode()

    def setup(self):
        self.worldNP = render.attachNewNode('World')
        self.distance_text = OnscreenText(
            text='Distance=0', pos=(0.75, 0.85), scale=0.08,
            mayChange=1)  #Directxxxxxx(distance='Distance=%d'%(0))
        self.speed_text = OnscreenText(
            text='Speed=0', pos=(0.75, 0.78), scale=0.08,
            mayChange=1)  #Directxxxxxx(distance='Distance=%d'%(0))
        self.time_text = OnscreenText(
            text='TotalTime=0', pos=(0.75, 0.71), scale=0.08,
            mayChange=1)  #Directxxxxxx(distance='Distance=%d'%(0))
        #self.time_maxsteer_text = OnscreenText(text='TotalTimeMaxSteer=0', pos = (0.85,0.70), scale = 0.05, mayChange=1)#Directxxxxxx(distance='Distance=%d'%(0))
        #self.nn_image = OnscreenImage(image='blank.png', pos= (0.85,0,0.15), scale=0.45) # http://dev-wiki.gestureworks.com/index.php/GestureWorksCore:Python_%26_Panda3D:_Getting_Started_II_(Hello_Multitouch)#8._Create_a_method_to_draw_touchpoint_data
        self.total_time = 0.
        self.time_max_steering = 0.
        # World
        self.debugNP = self.worldNP.attachNewNode(BulletDebugNode('Debug'))
        self.debugNP.show()

        self.world = BulletWorld()
        self.world.setGravity(Vec3(0, 0, -9.81))
        self.world.setDebugNode(self.debugNP.node())

        #terrain = GeoMipTerrain("mySimpleTerrain")
        #terrain.setHeightfield("./models/heightfield_2.png")
        #terrain.getRoot().reparentTo(self.worldNP)#render)
        #terrain.generate()

        # Plane
        shape = BulletPlaneShape(Vec3(0, 0, 1), 0)

        np = self.worldNP.attachNewNode(BulletRigidBodyNode('Ground'))
        np.node().addShape(shape)
        np.setPos(0, 0, -1)
        np.setCollideMask(BitMask32.allOn())

        self.world.attachRigidBody(np.node())

        #np = self.worldNP.attachNewNode(BulletRigidBodyNode('Track'))
        #np.node().setMass(5000.0)
        #np.setPos(3, 0, 10)
        #np.setCollideMask(BitMask32.allOn())#(0x0f))
        #self.track = BulletVehicle(self.world, np.node())
        #self.track.setCoordinateSystem(ZUp)
        self.track_np = loader.loadModel(
            'models/race_track_2.egg'
        )  # https://discourse.panda3d.org/t/panda3d-and-bullet-physics/15724/10
        self.track_np.setPos(-72, -7, -3.5)
        self.track_np.setScale(10)
        self.track_np.reparentTo(render)

        self.track_np.setCollideMask(BitMask32.allOn())  #(0))#.allOn())
        self.world.attachRigidBody(np.node())
        self.track_np = np
        #self.track_np.show()

        # Chassis
        shape = BulletBoxShape(Vec3(0.6, 1.4, 0.5))
        ts = TransformState.makePos(Point3(0, 0, 0.5))

        np = self.worldNP.attachNewNode(BulletRigidBodyNode('Vehicle'))
        np.node().addShape(shape, ts)
        np.setPos(0, 0, 0.05)
        np.node().setMass(800.0)
        np.node().setDeactivationEnabled(False)

        self.world.attachRigidBody(np.node())

        #np.node().setCcdSweptSphereRadius(1.0)
        #np.node().setCcdMotionThreshold(1e-7)
        self.cTrav = CollisionTraverser()
        # Vehicle
        self.vehicle = BulletVehicle(self.world, np.node())
        self.vehicle.setCoordinateSystem(ZUp)
        self.yugoNP = loader.loadModel('models/yugo/yugo.egg')
        self.yugoNP.setCollideMask(BitMask32(0))  #.allOn())
        self.yugoNP.reparentTo(np)
        self.colHandler = CollisionHandlerQueue()

        # travel distance
        self.distance = 0.
        """self.sphere = CollisionSphere(0,0,0,2)
    self.sphere_col = CollisionNode('yugo')
    self.sphere_col.addSolid(self.sphere)
    self.sphere_col.setFromCollideMask(BitMask32.allOn())
    self.sphere_col_np = self.yugoNP.attachNewNode(self.sphere_col)
    self.cTrav.addCollider(self.sphere_col_np,self.colHandler)
    self.sphere_col_np.show()"""

        self.yugo_col = CollisionNode('yugo_box')
        self.yugo_col.addSolid(CollisionBox(Point3(0, 0, 0.7), 0.9, 1.6, 0.05))
        self.yugo_col.setFromCollideMask(BitMask32(1))
        self.box_col_np = self.yugoNP.attachNewNode(self.yugo_col)
        self.cTrav.addCollider(self.box_col_np, self.colHandler)
        self.box_col_np.show()

        self.ray_col_np = {}
        self.ray_col_vec_dict = {}
        self.n_rays = self.model.shape[0]
        for i, ray_dir in enumerate(
                numpy.linspace(-numpy.pi / 4, numpy.pi / 4,
                               self.n_rays)):  # populate collision rays
            #print(ray_dir)
            self.ray = CollisionRay()
            y_dir, x_dir = numpy.cos(ray_dir), numpy.sin(ray_dir)
            self.ray.setOrigin(1.3 * x_dir, 1.3 * y_dir, 0.5)
            self.ray.setDirection(x_dir, y_dir, 0)
            self.ray_col = CollisionNode('ray%d' % (i))
            self.ray_col.addSolid(self.ray)
            self.ray_col.setFromCollideMask(
                BitMask32.allOn())  #(0x0f))#CollideMask.bit(0)
            #self.ray_col.setIntoCollideMask(CollideMask.allOff())
            self.ray_col_np['ray%d' % (i)] = self.yugoNP.attachNewNode(
                self.ray_col)
            self.cTrav.addCollider(self.ray_col_np['ray%d' % (i)],
                                   self.colHandler)
            self.ray_col_np['ray%d' % (i)].show()
            self.ray_col_vec_dict['ray%d' % (i)] = []
        self.world.attachVehicle(self.vehicle)
        self.cTrav.showCollisions(render)

        # FIXME
        base.camera.reparentTo(self.yugoNP)

        # Right front wheel
        np = loader.loadModel('models/yugo/yugotireR.egg')
        np.reparentTo(self.worldNP)
        self.addWheel(Point3(0.70, 1.05, 0.3), True, np)

        # Left front wheel
        np = loader.loadModel('models/yugo/yugotireL.egg')
        np.reparentTo(self.worldNP)
        self.addWheel(Point3(-0.70, 1.05, 0.3), True, np)

        # Right rear wheel
        np = loader.loadModel('models/yugo/yugotireR.egg')
        np.reparentTo(self.worldNP)
        self.addWheel(Point3(0.70, -1.05, 0.3), False, np)

        # Left rear wheel
        np = loader.loadModel('models/yugo/yugotireL.egg')
        np.reparentTo(self.worldNP)
        self.addWheel(Point3(-0.70, -1.05, 0.3), False, np)

        # Steering info
        self.steering = 0.0  # degree
        self.steeringClamp = 38.0  #45.0      # degree
        self.steeringIncrement = 105.0  #120.0 # degree per second

        # add previous positions
        self.prevPos = []
        self.prevPos.append(self.yugoNP.getPos(render))

        self.model_offset = 0.5 if self.model.activation == 'relu' else 0.
        # Box
        """
    for i,j in [(0,8),(-3,5),(6,-5),(8,3),(-4,-4),(0,0)]:
        shape = BulletBoxShape(Vec3(0.5, 0.5, 0.5))
        # https://discourse.panda3d.org/t/wall-collision-help/23606
        np = self.worldNP.attachNewNode(BulletRigidBodyNode('Box'))
        np.node().setMass(1.0)
        np.node().addShape(shape)
        np.setPos(i, j, 2)
        np.setCollideMask(BitMask32.allOn())#(0x0f))

        self.world.attachRigidBody(np.node())
        self.boxNP = np
        #self.colHandler2 = CollisionHandlerQueue()


        visualNP = loader.loadModel('models/box.egg')
        visualNP.reparentTo(self.boxNP)
    #self.cTrav.addCollider(self.boxNP,self.colHandler)
    """
        """
    aNode = CollisionNode("TheRay")

    self.ray = CollisionRay()
    self.ray.setOrigin( self.yugoNP.getPos() )
    self.ray.setDirection( Vec3(0, 10, 0) )
    #self.ray.show()


    aNodePath = self.yugoNP.attachNewNode( CollisionNode("TheRay") )
    aNodePath.node().addSolid(self.ray)
    aNodePath.show()
    """
        #aNode.addSolid(self.ray)
        #self.ray = CollisionRay(0,0,0,10,0,0)
        #self.ray.reparentTo(self.yugoNP)
        #self.rayColl = CollisionNode('PlayerRay')
        #self.rayColl.addSolid(self.ray)

        #self.playerRayNode = self.yugoNP.attachNewNode( self.rayColl )
        #self.playerRayNode.show()

        #base.myTraverser.addCollider (self.playerRayNode, base.floor)
        #base.floor.addCollider( self.playerRayNode, self.yugoNP)
        """
    MyEvent=CollisionHandlerFloor()
    MyEvent.setReach(100)
    MyEvent.setOffset(15.0)

    aNode = CollisionNode("TheRay")
    ray = CollisionRay()
    ray.setOrigin( self.boxNP.getPos() )
    ray.setDirection( Vec3(10, 0, 0) )

    aNode.addSolid(ray)
    aNodePath = MyModel.attachNewNode( aNode )

    Collision = ( aNode, "TheRay" )
    Collision[0].setFromCollideMask( BitMask32.bit( 1 ) )
    """

    def addWheel(self, pos, front, np):
        wheel = self.vehicle.createWheel()

        wheel.setNode(np.node())
        wheel.setChassisConnectionPointCs(pos)
        wheel.setFrontWheel(front)

        wheel.setWheelDirectionCs(Vec3(0, 0, -1))
        wheel.setWheelAxleCs(Vec3(1, 0, 0))
        wheel.setWheelRadius(0.25)
        wheel.setMaxSuspensionTravelCm(40.0)

        wheel.setSuspensionStiffness(40.0)
        wheel.setWheelsDampingRelaxation(2.3)
        wheel.setWheelsDampingCompression(4.4)
        wheel.setFrictionSlip(100.0)
        wheel.setRollInfluence(0.1)
Exemplo n.º 12
0
class CarEnv(DirectObject):
    def __init__(self, params={}):
        self._params = params
        if 'random_seed' in self._params:
            np.random.seed(self._params['random_seed'])
        self._use_vel = self._params.get('use_vel', True)
        self._run_as_task = self._params.get('run_as_task', False)
        self._do_back_up = self._params.get('do_back_up', False)
        self._use_depth = self._params.get('use_depth', False)
        self._use_back_cam = self._params.get('use_back_cam', False)

        self._collision_reward_only = self._params.get('collision_reward_only',
                                                       False)
        self._collision_reward = self._params.get('collision_reward', -10.0)
        self._obs_shape = self._params.get('obs_shape', (64, 36))
        self._steer_limits = params.get('steer_limits', (-30., 30.))
        self._speed_limits = params.get('speed_limits', (-4.0, 4.0))
        self._motor_limits = params.get('motor_limits', (-0.5, 0.5))
        self._fixed_speed = (self._speed_limits[0] == self._speed_limits[1]
                             and self._use_vel)
        if not self._params.get('visualize', False):
            loadPrcFileData('', 'window-type offscreen')

        # Defines base, render, loader

        try:
            ShowBase()
        except:
            pass

        base.setBackgroundColor(0.0, 0.0, 0.0, 1)

        # World
        self._worldNP = render.attachNewNode('World')
        self._world = BulletWorld()
        self._world.setGravity(Vec3(0, 0, -9.81))
        self._dt = params.get('dt', 0.25)
        self._step = 0.05

        # Vehicle
        shape = BulletBoxShape(Vec3(0.6, 1.0, 0.25))
        ts = TransformState.makePos(Point3(0., 0., 0.25))
        self._vehicle_node = BulletRigidBodyNode('Vehicle')
        self._vehicle_node.addShape(shape, ts)
        self._mass = self._params.get('mass', 10.)
        self._vehicle_node.setMass(self._mass)
        self._vehicle_node.setDeactivationEnabled(False)
        self._vehicle_node.setCcdSweptSphereRadius(1.0)
        self._vehicle_node.setCcdMotionThreshold(1e-7)
        self._vehicle_pointer = self._worldNP.attachNewNode(self._vehicle_node)

        self._world.attachRigidBody(self._vehicle_node)

        self._vehicle = BulletVehicle(self._world, self._vehicle_node)
        self._vehicle.setCoordinateSystem(ZUp)
        self._world.attachVehicle(self._vehicle)
        self._addWheel(Point3(0.3, 0.5, 0.07), True, 0.07)
        self._addWheel(Point3(-0.3, 0.5, 0.07), True, 0.07)
        self._addWheel(Point3(0.3, -0.5, 0.07), False, 0.07)
        self._addWheel(Point3(-0.3, -0.5, 0.07), False, 0.07)

        # Camera
        size = self._params.get('size', [160, 90])
        hfov = self._params.get('hfov', 120)
        near_far = self._params.get('near_far', [0.1, 100.])
        self._camera_sensor = Panda3dCameraSensor(base,
                                                  color=not self._use_depth,
                                                  depth=self._use_depth,
                                                  size=size,
                                                  hfov=hfov,
                                                  near_far=near_far,
                                                  title='front cam')
        self._camera_node = self._camera_sensor.cam
        self._camera_node.setPos(0.0, 0.5, 0.375)
        self._camera_node.lookAt(0.0, 6.0, 0.0)
        self._camera_node.reparentTo(self._vehicle_pointer)

        if self._use_back_cam:
            self._back_camera_sensor = Panda3dCameraSensor(
                base,
                color=not self._use_depth,
                depth=self._use_depth,
                size=size,
                hfov=hfov,
                near_far=near_far,
                title='back cam')

            self._back_camera_node = self._back_camera_sensor.cam
            self._back_camera_node.setPos(0.0, -0.5, 0.375)
            self._back_camera_node.lookAt(0.0, -6.0, 0.0)
            self._back_camera_node.reparentTo(self._vehicle_pointer)

        # Car Simulator
        self._des_vel = None
        self._setup()

        # Input
        self.accept('escape', self._doExit)
        self.accept('r', self.reset)
        self.accept('f1', self._toggleWireframe)
        self.accept('f2', self._toggleTexture)
        self.accept('f3', self._view_image)
        self.accept('f5', self._doScreenshot)
        self.accept('q', self._forward_0)
        self.accept('w', self._forward_1)
        self.accept('e', self._forward_2)
        self.accept('a', self._left)
        self.accept('s', self._stop)
        self.accept('x', self._backward)
        self.accept('d', self._right)
        self.accept('m', self._mark)

        self._steering = 0.0  # degree
        self._engineForce = 0.0
        self._brakeForce = 0.0
        self._env_time_step = 0
        self._p = self._params.get('p', 1.25)
        self._d = self._params.get('d', 0.0)
        self._last_err = 0.0
        self._curr_time = 0.0
        self._accelClamp = self._params.get('accelClamp', 0.5)
        self._engineClamp = self._accelClamp * self._mass
        self._collision = False

        self._setup_spec()

        self.spec = EnvSpec(observation_im_space=self.observation_im_space,
                            action_space=self.action_space,
                            action_selection_space=self.action_selection_space,
                            observation_vec_spec=self.observation_vec_spec,
                            action_spec=self.action_spec,
                            action_selection_spec=self.action_selection_spec,
                            goal_spec=self.goal_spec)

        if self._run_as_task:
            self._mark_d = 0.0
            taskMgr.add(self._update_task, 'updateWorld')
            base.run()

    def _setup_spec(self):
        self.action_spec = OrderedDict()
        self.action_selection_spec = OrderedDict()
        self.observation_vec_spec = OrderedDict()
        self.goal_spec = OrderedDict()

        self.action_spec['steer'] = Box(low=-45., high=45.)
        self.action_selection_spec['steer'] = Box(low=self._steer_limits[0],
                                                  high=self._steer_limits[1])

        if self._use_vel:
            self.action_spec['speed'] = Box(low=-4., high=4.)
            self.action_space = Box(low=np.array([
                self.action_spec['steer'].low[0],
                self.action_spec['speed'].low[0]
            ]),
                                    high=np.array([
                                        self.action_spec['steer'].high[0],
                                        self.action_spec['speed'].high[0]
                                    ]))

            self.action_selection_spec['speed'] = Box(
                low=self._speed_limits[0], high=self._speed_limits[1])
            self.action_selection_space = Box(
                low=np.array([
                    self.action_selection_spec['steer'].low[0],
                    self.action_selection_spec['speed'].low[0]
                ]),
                high=np.array([
                    self.action_selection_spec['steer'].high[0],
                    self.action_selection_spec['speed'].high[0]
                ]))
        else:
            self.action_spec['motor'] = Box(low=-self._accelClamp,
                                            high=self._accelClamp)
            self.action_space = Box(low=np.array([
                self.action_spec['steer'].low[0],
                self.action_spec['motor'].low[0]
            ]),
                                    high=np.array([
                                        self.action_spec['steer'].high[0],
                                        self.action_spec['motor'].high[0]
                                    ]))

            self.action_selection_spec['motor'] = Box(
                low=self._motor_limits[0], high=self._motor_limits[1])
            self.action_selection_space = Box(
                low=np.array([
                    self.action_selection_spec['steer'].low[0],
                    self.action_selection_spec['motor'].low[0]
                ]),
                high=np.array([
                    self.action_selection_spec['steer'].high[0],
                    self.action_selection_spec['motor'].high[0]
                ]))

        assert (np.logical_and(
            self.action_selection_space.low >= self.action_space.low - 1e-4,
            self.action_selection_space.high <=
            self.action_space.high + 1e-4).all())

        self.observation_im_space = Box(low=0,
                                        high=255,
                                        shape=tuple(
                                            self._get_observation()[0].shape))
        self.observation_vec_spec['coll'] = Discrete(1)
        self.observation_vec_spec['heading'] = Box(low=0, high=2 * 3.14)
        self.observation_vec_spec['speed'] = Box(low=-4.0, high=4.0)

    @property
    def _base_dir(self):
        return os.path.join(os.path.dirname(os.path.abspath(__file__)),
                            'models')

    @property
    def horizon(self):
        return np.inf

    @property
    def max_reward(self):
        return np.inf

    # _____HANDLER_____

    def _doExit(self):
        sys.exit(1)

    def _toggleWireframe(self):
        base.toggleWireframe()

    def _toggleTexture(self):
        base.toggleTexture()

    def _doScreenshot(self):
        base.screenshot('Bullet')

    def _forward_0(self):
        self._des_vel = 1
        self._brakeForce = 0.0

    def _forward_1(self):
        self._des_vel = 2
        self._brakeForce = 0.0

    def _forward_2(self):
        self._des_vel = 4
        self._brakeForce = 0.0

    def _stop(self):
        self._des_vel = 0.0
        self._brakeForce = 0.0

    def _backward(self):
        self._des_vel = -4
        self._brakeForce = 0.0

    def _right(self):
        self._steering = np.min([np.max([-30, self._steering - 5]), 0.0])

    def _left(self):
        self._steering = np.max([np.min([30, self._steering + 5]), 0.0])

    def _view_image(self):
        from matplotlib import pyplot as plt
        image = self._camera_sensor.observe()[0]
        if self._use_depth:
            plt.imshow(image[:, :, 0], cmap='gray')
        else:

            def rgb2gray(rgb):
                return np.dot(rgb[..., :3], [0.299, 0.587, 0.114])

            image = rgb2gray(image)
            im = cv2.resize(image, (64, 36), interpolation=cv2.INTER_AREA
                            )  # TODO how does this deal with aspect ratio
            plt.imshow(im.astype(np.uint8), cmap='Greys_r')
        plt.show()

    def _mark(self):
        self._mark_d = 0.0

    # Setup

    def _setup(self):
        self._setup_map()
        self._place_vehicle()
        self._setup_light()
        self._setup_restart_pos()

    def _setup_map(self):
        if hasattr(self, '_model_path'):
            # Collidable objects
            self._setup_collision_object(self._model_path)
        else:
            ground = self._worldNP.attachNewNode(BulletRigidBodyNode('Ground'))
            shape = BulletPlaneShape(Vec3(0, 0, 1), 0)
            ground.node().addShape(shape)
            ground.setCollideMask(BitMask32.allOn())
            self._world.attachRigidBody(ground.node())

    def _setup_collision_object(self,
                                path,
                                pos=(0.0, 0.0, 0.0),
                                hpr=(0.0, 0.0, 0.0),
                                scale=1):
        visNP = loader.loadModel(path)
        visNP.clearModelNodes()
        visNP.reparentTo(render)
        visNP.setPos(pos[0], pos[1], pos[2])
        visNP.setHpr(hpr[0], hpr[1], hpr[2])
        visNP.set_scale(scale, scale, scale)
        bodyNPs = BulletHelper.fromCollisionSolids(visNP, True)
        for bodyNP in bodyNPs:
            bodyNP.reparentTo(render)
            bodyNP.setPos(pos[0], pos[1], pos[2])
            bodyNP.setHpr(hpr[0], hpr[1], hpr[2])
            bodyNP.set_scale(scale, scale, scale)
            if isinstance(bodyNP.node(), BulletRigidBodyNode):
                bodyNP.node().setMass(0.0)
                bodyNP.node().setKinematic(True)
                bodyNP.setCollideMask(BitMask32.allOn())
                self._world.attachRigidBody(bodyNP.node())
            else:
                print("Issue")

    def _setup_restart_pos(self):
        self._restart_index = 0
        self._restart_pos = self._default_restart_pos()

    def _next_restart_pos_hpr(self):
        num = len(self._restart_pos)
        if num == 0:
            return None, None
        else:
            pos_hpr = self._restart_pos[self._restart_index]
            self._restart_index = (self._restart_index + 1) % num
            return pos_hpr[:3], pos_hpr[3:]

    def _setup_light(self):
        #        alight = AmbientLight('ambientLight')
        #        alight.setColor(Vec4(0.5, 0.5, 0.5, 1))
        #        alightNP = render.attachNewNode(alight)
        #        render.clearLight()
        #        render.setLight(alightNP)
        pass

    # Vehicle
    def _default_pos(self):
        return (0.0, 0.0, 0.3)

    def _default_hpr(self):
        return (0.0, 0.0, 0.0)

    def _default_restart_pos(self):
        return [self._default_pos() + self._default_hpr()]

    def _get_speed(self):
        vel = self._vehicle.getCurrentSpeedKmHour() / 3.6
        return vel

    def _get_heading(self):
        h = np.array(self._vehicle_pointer.getHpr())[0]
        ori = h * (pi / 180.)
        while (ori > 2 * pi):
            ori -= 2 * pi
        while (ori < 0):
            ori += 2 * pi
        return ori

    def _update(self, dt=1.0, coll_check=True):
        self._vehicle.setSteeringValue(self._steering, 0)
        self._vehicle.setSteeringValue(self._steering, 1)
        self._vehicle.setBrake(self._brakeForce, 0)
        self._vehicle.setBrake(self._brakeForce, 1)
        self._vehicle.setBrake(self._brakeForce, 2)
        self._vehicle.setBrake(self._brakeForce, 3)
        if dt >= self._step:
            # TODO maybe change number of timesteps
            #            for i in range(int(dt/self._step)):
            if self._des_vel is not None:
                vel = self._get_speed()
                err = self._des_vel - vel
                d_err = (err - self._last_err) / self._step
                self._last_err = err
                self._engineForce = np.clip(self._p * err + self._d * d_err,
                                            -self._accelClamp,
                                            self._accelClamp) * self._mass
            self._vehicle.applyEngineForce(self._engineForce, 0)
            self._vehicle.applyEngineForce(self._engineForce, 1)
            self._vehicle.applyEngineForce(self._engineForce, 2)
            self._vehicle.applyEngineForce(self._engineForce, 3)
            for _ in range(int(dt / self._step)):
                self._world.doPhysics(self._step, 1, self._step)
            self._collision = self._is_contact()
        elif self._run_as_task:
            self._curr_time += dt
            if self._curr_time > 0.05:
                if self._des_vel is not None:
                    vel = self._get_speed()
                    self._mark_d += vel * self._curr_time
                    print(vel, self._mark_d, self._is_contact())
                    err = self._des_vel - vel
                    d_err = (err - self._last_err) / 0.05
                    self._last_err = err
                    self._engineForce = np.clip(
                        self._p * err + self._d * d_err, -self._accelClamp,
                        self._accelClamp) * self._mass
                self._curr_time = 0.0
                self._vehicle.applyEngineForce(self._engineForce, 0)
                self._vehicle.applyEngineForce(self._engineForce, 1)
                self._vehicle.applyEngineForce(self._engineForce, 2)
                self._vehicle.applyEngineForce(self._engineForce, 3)
            self._world.doPhysics(dt, 1, dt)
            self._collision = self._is_contact()
        else:
            raise ValueError(
                "dt {0} s is too small for velocity control".format(dt))

    def _stop_car(self):
        self._steering = 0.0
        self._engineForce = 0.0
        self._vehicle.setSteeringValue(0.0, 0)
        self._vehicle.setSteeringValue(0.0, 1)
        self._vehicle.applyEngineForce(0.0, 0)
        self._vehicle.applyEngineForce(0.0, 1)
        self._vehicle.applyEngineForce(0.0, 2)
        self._vehicle.applyEngineForce(0.0, 3)

        if self._des_vel is not None:
            self._des_vel = 0

        self._vehicle_node.setLinearVelocity(Vec3(0.0, 0.0, 0.0))
        self._vehicle_node.setAngularVelocity(Vec3(0.0, 0.0, 0.0))
        for i in range(self._vehicle.getNumWheels()):
            wheel = self._vehicle.getWheel(i)
            wheel.setRotation(0.0)
        self._vehicle_node.clearForces()

    def _place_vehicle(self, pos=None, hpr=None):
        if pos is None:
            pos = self._default_pos()
        if hpr is None:
            hpr = self._default_hpr()
        self._vehicle_pointer.setPos(pos[0], pos[1], pos[2])
        self._vehicle_pointer.setHpr(hpr[0], hpr[1], hpr[2])
        self._stop_car()

    def _addWheel(self, pos, front, radius=0.25):
        wheel = self._vehicle.createWheel()
        wheel.setChassisConnectionPointCs(pos)
        wheel.setFrontWheel(front)
        wheel.setWheelDirectionCs(Vec3(0, 0, -1))
        wheel.setWheelAxleCs(Vec3(1, 0, 0))
        wheel.setWheelRadius(radius)
        wheel.setMaxSuspensionTravelCm(40.0)
        wheel.setSuspensionStiffness(40.0)
        wheel.setWheelsDampingRelaxation(2.3)
        wheel.setWheelsDampingCompression(4.4)
        wheel.setFrictionSlip(1e2)
        wheel.setRollInfluence(0.1)

    # Task

    def _update_task(self, task):
        dt = globalClock.getDt()
        self._update(dt=dt)
        self._get_observation()
        return task.cont

    # Helper functions

    def _get_observation(self):
        self._obs = self._camera_sensor.observe()
        observation = []
        observation.append(self.process(self._obs[0], self._obs_shape))
        if self._use_back_cam:
            self._back_obs = self._back_camera_sensor.observe()
            observation.append(self.process(self._back_obs[0],
                                            self._obs_shape))
        observation_im = np.concatenate(observation, axis=2)
        coll = self._collision
        heading = self._get_heading()
        speed = self._get_speed()
        observation_vec = np.array([coll, heading, speed])
        return observation_im, observation_vec

    def _get_goal(self):
        return np.array([])

    def process(self, image, obs_shape):
        if self._use_depth:
            im = np.reshape(image, (image.shape[0], image.shape[1]))
            if im.shape != obs_shape:
                im = cv2.resize(im, obs_shape, interpolation=cv2.INTER_AREA)
            return im.astype(np.uint8)
        else:
            image = np.dot(image[..., :3], [0.299, 0.587, 0.114])
            im = cv2.resize(image, obs_shape, interpolation=cv2.INTER_AREA
                            )  #TODO how does this deal with aspect ratio
            # TODO might not be necessary
            im = np.expand_dims(im, 2)
            return im.astype(np.uint8)

    def _get_reward(self):
        if self._collision_reward_only:
            if self._collision:
                reward = self._collision_reward
            else:
                reward = 0.0
        else:
            if self._collision:
                reward = self._collision_reward
            else:
                reward = self._get_speed()
        assert (reward <= self.max_reward)
        return reward

    def _get_done(self):
        return self._collision

    def _get_info(self):
        info = {}
        info['pos'] = np.array(self._vehicle_pointer.getPos())
        info['hpr'] = np.array(self._vehicle_pointer.getHpr())
        info['vel'] = self._get_speed()
        info['coll'] = self._collision
        info['env_time_step'] = self._env_time_step
        return info

    def _back_up(self):
        assert (self._use_vel)
        #        logger.debug('Backing up!')
        self._params['back_up'] = self._params.get('back_up', {})
        back_up_vel = self._params['back_up'].get('vel', -1.0)
        self._des_vel = back_up_vel
        back_up_steer = self._params['back_up'].get('steer', (-5.0, 5.0))
        self._steering = np.random.uniform(*back_up_steer)
        self._brakeForce = 0.
        duration = self._params['back_up'].get('duration', 3.0)
        self._update(dt=duration)
        self._des_vel = 0.
        self._steering = 0.
        self._update(dt=duration)
        self._brakeForce = 0.

    def _is_contact(self):
        result = self._world.contactTest(self._vehicle_node)
        return result.getNumContacts() > 0

    # Environment functions

    def reset(self, pos=None, hpr=None, hard_reset=False):
        if self._do_back_up and not hard_reset and \
                pos is None and hpr is None:
            if self._collision:
                self._back_up()
        else:
            if hard_reset:
                logger.debug('Hard resetting!')
            if pos is None and hpr is None:
                pos, hpr = self._next_restart_pos_hpr()
            self._place_vehicle(pos=pos, hpr=hpr)
        self._collision = False
        self._env_time_step = 0
        return self._get_observation(), self._get_goal()

    def step(self, action):
        self._steering = action[0]
        if action[1] == 0.0:
            self._brakeForce = 1000.
        else:
            self._brakeForce = 0.
        if self._use_vel:
            # Convert from m/s to km/h
            self._des_vel = action[1]
        else:
            self._engineForce = self._mass * action[1]

        self._update(dt=self._dt)
        observation = self._get_observation()
        goal = self._get_goal()
        reward = self._get_reward()
        done = self._get_done()
        info = self._get_info()
        self._env_time_step += 1
        return observation, goal, reward, done, info
Exemplo n.º 13
0
class Character:
    playerId = 1
    type = 0

    def __init__(self, tempworld, bulletWorld, type, playerId):
        self.world = tempworld
        self.speed = 0
        self.acceleration = 1.5
        self.brakes = .7
        self.min_speed = 0
        self.max_speed = 150
        self.reverse_speed = 20
        self.reverse_limit = -40
        self.armor = 100
        self.health = 100
        self.a_timer_start = time.time()
        self.a_timer_end = time.time()
        self.power_ups = [0, 0, 0]
        self.playerId = playerId

        if type == 0:
            self.actor = Actor("models/batmobile-chassis")
            self.actor.setScale(0.7)
            carRadius = 3
        elif type == 1:
            self.actor = Actor("models/policecarpainted", {})
            self.actor.setScale(0.30)
            self.actor.setH(180)  # elif type == 2:
        # self.actor = loader.loadModel("knucklehead.egg")
        #     self.tex = loader.loadTexture("knucklehead.jpg")
        #     self.actor.setTexture(self.car_tex, 1)


        shape = BulletBoxShape(Vec3(1.0, 1.5, 0.4))
        ts = TransformState.makePos(Point3(0, 0, 0.6))

        self.chassisNP = render.attachNewNode(BulletRigidBodyNode('Vehicle'))
        self.chassisNP.node().addShape(shape, ts)
        self.chassisNP.setPos(50 * random.random(), 50 * random.random(), 1)
        self.chassisNP.setH(180)
        self.chassisNP.node().setMass(800.0)
        self.chassisNP.node().setDeactivationEnabled(False)

        bulletWorld.attachRigidBody(self.chassisNP.node())

        self.actor.reparentTo(self.chassisNP)
        self.actor.setH(180)

        # Vehicle
        self.vehicle = BulletVehicle(bulletWorld, self.chassisNP.node())
        self.vehicle.setCoordinateSystem(ZUp)
        bulletWorld.attachVehicle(self.vehicle)

        for fb, y in (("F", 1.1), ("B", -1.1)):
            for side, x in (("R", 0.75), ("L", -0.75)):
                np = loader.loadModel("models/tire%s.egg" % side)
                np.reparentTo(render)
                isFront = fb == "F"
                self.addWheel(Point3(x, y, 0.55), isFront, np)

    def addWheel(self, position, isFront, np):
        wheel = self.vehicle.createWheel()

        wheel.setNode(np.node())
        wheel.setChassisConnectionPointCs(position)
        wheel.setFrontWheel(isFront)

        wheel.setWheelDirectionCs(Vec3(0, 0, -1))
        wheel.setWheelAxleCs(Vec3(1, 0, 0))
        wheel.setWheelRadius(0.2)
        wheel.setMaxSuspensionTravelCm(0.4 * 100.0)
        wheel.setSuspensionStiffness(40.0)
        wheel.setWheelsDampingRelaxation(2.3)
        wheel.setWheelsDampingCompression(4.4)
        wheel.setFrictionSlip(100)
        wheel.setRollInfluence(0.1)

    def getActor(self):
        return self.actor

    def get_speed(self):
        return self.speed

    def accelerate(self):
        # check how long you were accelerating
        time_elapsed = time.time() - self.a_timer_end
        if time_elapsed > 1:  # in seconds last accelerated
            self.a_timer_start = time.time()

        if self.speed < self.max_speed:
            self.speed += self.acceleration * (time.time() - self.a_timer_start)
            # print(time_elapsed)
        else:
            self.speed = self.max_speed
        # reset timer
        self.a_timer_end = time.time()

    def friction(self, friction):
        if self.speed > 0:
            self.speed -= friction
        else:
            self.speed = 0

    def brake(self):
        if self.speed > self.min_speed:
            self.speed -= self.brakes
            # reset acceleration timer
            self.a_timer_start = time.time()

    def reverse(self):
        if self.speed > self.reverse_limit:
            self.speed -= self.reverse_speed

    def walk(self):
        self.actor.stop()
        self.actor.pose("walk", 5)
        self.isMoving = False

    def run(self):
        self.actor.loop("run")
        self.isMoving = True
Exemplo n.º 14
0
class Tank(DynamicWorldObject):

    '''Child of WorldObject, with all of the things that makes a Tank a tank.

    Includes a Weapon
    '''

    def __init__(self, world, attach, name = '', position = Vec3(0,0,0), orientation = Vec3(0,0,0), 
            turretPitch = 0): 

        #Constant Relevant Instatiation Parameters
        self._tankSize = Vec3(1, 1.5, .5) # Actually a half-size
        self._tankSideLength = max(self._tankSize)
        friction = .3
        tankMass = 800.0

        # Rewrite constructor to include these?
        self._maxVel = 4
        self._maxRotVel = 1
        self._maxThrusterAccel = 5000
        self._breakForce = 1000
        turretRelPos = (0, 0, 0) #Relative to tank
       
        self._shape = BulletBoxShape(Vec3(1,1.5,.5)) #chassis
        self._transformState = TransformState.makePos(Point3(0, 0, 0)) #offset 
        DynamicWorldObject.__init__(self, world, attach, name, position, self._shape, orientation, Vec3(0,0,0), mass = tankMass)   #Initial velocity must be 0
        self.__createVehicle(self._tankWorld.getPhysics())

        self._collisionCounter = 0
        self._taskTimer = 0
        self._nodePath.node().setFriction(friction)		
        self._nodePath.setPos(position)
        # Set up turret nodepath
        # (Nodepaths are how objects are managed in Panda3d)
 
        self.onTask = 0

        # Make collide mask (What collides with what)
        self._nodePath.setCollideMask(0xFFFF0000)
        #self._nodePath.setCollideMask(BitMask32.allOff())

        self.movementPoint = Point3(10,10,0)

        #print "Tank.__init__: " + name
        
        # Set up the 
    def __createVehicle(self,bulletWorld):
        '''
            Creates a vehicle, sets up wheels and does all the things
        '''
        
        self._nodePath.node().setMass(800.0)
         
        # Chassis geometry
        np  = loader.loadModel('media/tankBody.x')
        np.setHpr(90,0,0)
        np.reparentTo(self._nodePath)
        #np.setScale(self._tankSize*2)
        np.setPos(-self._tankSize+Vec3(1, 0, .5))
       
        # Vehicle
        self.vehicle = BulletVehicle(bulletWorld, self._nodePath.node())
        self.vehicle.setCoordinateSystem(2)
        bulletWorld.attachVehicle(self.vehicle)
        
    
        wheelNP = loader.loadModel('box')
        wheelNP.setScale(.01,.01,.01) 

        wheelPos = [Point3(1, 1, 0),Point3(-1, 1, 0),
                    Point3(1, -1, 0),Point3(-1, -1, 0)]

        for i in range(4):
            wheel = self.vehicle.createWheel()
            wheel.setWheelAxleCs(Vec3(-2*(i%2)+1, 0, 0))
            wheel.setChassisConnectionPointCs(wheelPos[i])            
            self.__createWheel(wheel)
            self.vehicle.setSteeringValue(0,i)
            wheel.setRollInfluence((-2*(i%2)+1)*0.2)
    def __createWheel(self,wheel):
        '''
            sets up properties for wheel.
        '''
        wheel.setWheelDirectionCs(Vec3(0, 0, -1))
        wheel.setFrontWheel(False)
        wheel.setWheelRadius(0.15)
        wheel.setMaxSuspensionTravelCm(40.0)
        wheel.setSuspensionStiffness(40.0)
        wheel.setWheelsDampingRelaxation(2.3)
        wheel.setWheelsDampingCompression(4.4)
        wheel.setFrictionSlip(100.0)
        

    def getWheels(self):
        '''
            returns a list of wheelPos
        '''
        return self.vehicle.getWheels()

    def setWeaponHp(self, heading, pitch):
        '''
        float heading
        float pitch
        '''

        self._weapon.setHp(heading,pitch)

    def moveWeapon(self, heading = 0, pitch = 0):
        rot = self.getHpr()

        self.setWeaponHp(rot[0] + heading, rot[1] + pitch)

    def distanceScan(self):
        '''
        This scan projects rays from the objects in the field toward the tank 
        in question. This scan does not perform as well as scan when the 
        objects are bunched together. When small objects are spread out 
        reasonably (more than 5 at a viewing range of 50), this scan performs 
        better.

        Using this scan, large objects can hide behind small objects

        This scan has the feature that it will pick up a lone object 
        guaranteed at any distance.
        '''
        self.wait(.1)
        potentialNPs = self._tankWorld.render.getChildren()

        found = []

        for np in potentialNPs:
            if type(np.node()) == BulletRigidBodyNode and np != self and not np.isHidden():
                
                pFrom = np.getPos(render) 
                #Fix for cubeObjects (z = 0). They collide with the floor
                if pFrom[2] < 1:
                    pFrom[2] = 1.1

                pTo = self.getPos() + self.getPos() - pFrom 
                #pTo is a Vec3, turned to a point for rayTest
                
                result = self._tankWorld.getPhysics().rayTestClosest(
                        pFrom, Point3(pTo[0], pTo[1], pTo[2]))

                if result.hasHit() and result.getNode() == self._nodePath.node():

                    #found.append((np.node().getPrevTransform().getPos(),
                    #    np.node().getName()))

                    found.append((np.getPos(render),
                        np.node().getName()))
                elif result.hasHit():
                    #print "Tank.distanceScan: ",
                    #print np, result.getNode(), pFrom, pTo
                    #print "Neigh"
                    x = 1                    

        return found


    def __bulletRays(self, numPoints, relAngleRange, height):
        '''Helper function for scans and pings. Runs through the 
        relAngleRange (two ints, in degrees) at the given numPoints and height.
        Runs a Bullet rayTestClosest to find the nearest hit.

        Returns a list of BulletClosestHitRayResult objects
        '''

        distanceOfMap = 100000
        results = []
        #scanResolution = numPoints / 360.0
        angleSweep = relAngleRange[1] - relAngleRange[0] + 0.0
        pos = self._nodePath.getPos()
        heading = self._nodePath.getH()
        
        for i in range(numPoints):

            if angleSweep == 0:
                angle = (heading + relAngleRange[0]) * (math.pi / 180)
            else:
                angle = (i / angleSweep + heading + relAngleRange[0]) * (math.pi / 180)

            pFrom = Point3(math.sin(angle) * self._tankSideLength + pos[0], 
                    math.cos(angle) *  self._tankSideLength + pos[1], height)
            pTo = Point3(math.sin(angle) * distanceOfMap + pos[0], 
                    math.cos(angle) * distanceOfMap + pos[1], height)
            result = self._tankWorld.getPhysics().rayTestClosest(pFrom, pTo)

            results.append((result, angle * 180 / math.pi - heading))

        return results

    
    def scan(self, numPoints = 360, relAngleRange = (-180, 180), height = 1):
        '''
        This function scans the map to find the other objects on it. The scan 
        works iteratively, based on the angle range (given relative to the 
        tank's current heading) and the number of points given. This is a more
        realistic scan, but does not work as well with smaller objects and 
        larger distances
        '''
        found = []
        numFound = 0
        results = self.__bulletRays(numPoints, relAngleRange, height)
        prevNodes = dict()

        for item in results:
            result = item[0]
            if result.hasHit():
                newNode = result.getNode()
                if newNode not in prevNodes:
                    found.append((newNode.getPrevTransform().getPos(), 
                        newNode.getName()))
                    prevNodes[newNode] = 0
                    numFound = numFound + 1     
        return found

    def pingPointsAbs(self, numPoints = 360, relAngleRange = (-180, 180), height = 1):
        '''Returns a list of absolute coordinate points on each of the 

        '''
        
        found = []     
        results = self.__bulletRays(numPoints, relAngleRange, height)

        for item in results:
            result = item[0]
            if result.hasHit():
                newNode = result.getNode()
                found.append((result.getHitPos(), item[1], newNode.getName()))
            
        return found

    def pingPoints(self, numPoints = 360, relAngleRange = (-180, 180), height = 1):
        found = self.pingPointsAbs(numPoints, relAngleRange, height)
        pos = self.getPos()

        for i in range(len(found)):
            hitPos = found[i][0]
            relPos = Point3(hitPos[0] - pos[0], hitPos[1] - pos[1], hitPos[2] - pos[2])
            found[i] = (relPos, found[i][1], found[i][2])
        return found

    def pingDistance(self, numPoints = 360, relAngleRange = (-180, 180), height = 1):
        found = self.pingPoints(numPoints, relAngleRange, height)

        for i in range(len(found)):
            relPos = found[i][0]
            distance = math.sqrt(relPos[0]**2 + relPos[1]**2)
            found[i] = (distance, found[i][1], found[i][2])

        return found


    def applyThrusters(self, right = 1, left = 1):    #set acceleration
        '''change acceleration to a percent of the maximum acceleration'''
        
        #if right > 1 or amt < 0:
        #   raise ValueError("amt must be between 0 and 1")
        
        # tankNode = self._nodePath.node()
        # angle = self.nodePath.getH() #Apply force in current direction
        # magnitude = amt * (self._maxThrusterAccel) + (tankNode.getFriction() * 
        #     self._nodePath.node().getMass())
        # force = Vec3(magnitude * math.cos(angle), 
        #     magnitude * math.sin(angle), 0)
        # self.nodePath.node().applyForce(force)
        self.vehicle.reset_suspension()
        self.applyBrakes(0)
        vel = self.vehicle.getChassis().getLinearVelocity()

        for i in range(4):
            self.vehicle.applyEngineForce(0,i)  
            self.vehicle.setBrake(0,i)

        if vel.length() < self._maxVel:
            self.vehicle.applyEngineForce(-left*self._maxThrusterAccel,0)
            self.vehicle.applyEngineForce(right*self._maxThrusterAccel,1)
            self.vehicle.applyEngineForce(-left*self._maxThrusterAccel,2)
            self.vehicle.applyEngineForce(right*self._maxThrusterAccel,3)
            #for i in range(0,1):
            #    self.vehicle.applyEngineForce((left*(i)%2+right*(i+1)%2)*self._maxThrusterAccel,i)

            #for i in range(2):
            #   self.vehicle.applyEngineForce((left*(i)%2+right*(i+1)%2)*self._maxThrusterAccel,i+2)
                #self.vehicle.applyEngineForce((2*i%2-1)*engineForce,i)
                ## for 1 and 3useleft 
                ## for 0 and 2 use right

                

        else:
            for i in range(4):
                #self.vehicle.applyEngineForce((2*i%2-1)*engineForce,i)
                self.vehicle.applyEngineForce(0,i)
            
    def applyBrakes(self, amt=1):
        
        for i in range(4):
            #self.vehicle.applyEngineForce((2*i%2-1)*engineForce,i)
            self.vehicle.applyEngineForce(0,i)
            self.vehicle.setBrake(amt*self._breakForce,i)
        

    def setVel(self, goal	):
        pass 

    def move(self, dist):   
        '''Moves using a distance. Adds an updateMoveLoc task to the taskMgr.
        '''        

        heading = self._nodePath.getH() * math.pi/180
        pos = self.getPos()
        self._stop = False
        
        #Of the form (goalLoc, startLoc, distance)
        self._moveLoc = (Point3(pos[0] + math.sin(heading) * dist, pos[1] - math.cos(heading) * dist, pos[2]), pos, dist)

        self._tankWorld.taskMgr.add(self.updateMoveLoc,'userTank '+self.getName(),uponDeath=self.nextTask)


    def rotate(self, angle):
        '''Rotate function. All angles given between 0 and 360
        Angle changes are between -180 and 180
        '''

        angle = angle % 360
        if angle > 180:
            angle -= 360

        
        heading = self.fixAngle(self._nodePath.getH())
        newH = self.fixAngle(heading + angle)

        self._moveLoc = (newH, heading, angle)
        self._stop = False

        self._tankWorld.taskMgr.add(self.updateRotateLoc, 'userTank '+self.getName(), uponDeath=self.nextTask)


    def moveTime(self, moveTime):
        self._taskTimer = moveTime
        self._tankWorld.taskMgr.add(self.updateMove,'userTank '+self.getName(),uponDeath=self.nextTask)
    
    def rotateTime(self, rotateTime):
        self._taskTimer = rotateTime
        self._tankWorld.taskMgr.add(self.updateRotate,'userTank '+self.getName(),uponDeath=self.nextTask)


    def wait(self, waitTime):
        self._taskTimer = waitTime
        self._tankWorld.taskMgr.add(self.updateWait,'userTank '+self.getName(),uponDeath=self.nextTask)

    def updateWait(self, task):
        '''
        Tasks called to wait
        '''
        try:
            if self._tankWorld.isRealTime():
                dt = globalClock.getDt()
            else:
                dt = 1.0/60.0
            #print "Tank.updateWait: ", dt
            self._taskTimer -= dt

            if self._taskTimer < 0: 
                return task.done

            return task.cont
        except:
            print "error, tank.wait"

    def updateRotateLoc(self, task):
        heading = self.fixAngle(self._nodePath.getH())
        toHeading = self._moveLoc[0]
        w = self._nodePath.node().getAngularVelocity()[2]

        #Right wheel direction for rotating in the direction of goal
        rFor = self._moveLoc[2]/abs(self._moveLoc[2]) 

        slowTheta = 1.5 * rFor
        brakePercent = w**2 / (2 * slowTheta * self._maxThrusterAccel)
        theta = self.fixAngle(toHeading - heading)
        if theta > 180:
            theta -= 360
        thetaFromStart = heading - self._moveLoc[1]
        thetaFromStart = thetaFromStart % 360
        if thetaFromStart > 180:
            thetaFromStart -= 360

        if self._stop:
            if abs(w) < .1:
                self._nodePath.node().setAngularVelocity(Vec3(0,0,0))
                self._nodePath.setH(self._moveLoc[0])
                return task.done
            self.applyBrakes()
            return task.cont
        
        if abs(theta) < slowTheta - .25:
            self.applyThrusters(-rFor * brakePercent, rFor * brakePercent)
        elif abs(theta) > slowTheta - .25:
            if w < self._maxRotVel:
                self.applyThrusters(rFor, -1 * rFor)
            else:
                self.applyThrusters(0,0)
        else:
            self.applyBrakes(brakePercent)
        
        if abs(theta) < .1:
            self._stop = True
        if abs(thetaFromStart + .1) > abs(self._moveLoc[2]):
            self._stop = True
        
        #emergency stop based on a long time.
        if task.time > 3:
            #print "Tank.updateRotateLoc", "your rotate could not be completed, sorry"
            return task.done
            
        return task.cont

    def updateMoveLoc(self, task):
        '''Bases how much to slow down on a = v^2/2x. 
        x is slowDist, chosen to play nice. 

        Generally accurate to 5cm, rarely 20cm or worse 

        Stops at an arbitrary low velocity because it will never exit
        at a lower minimum
        '''

        pos = self.getPos()
        toLoc = self._moveLoc[0]
        distance = math.sqrt((pos[0] - toLoc[0])**2 + (pos[1] - toLoc[1])**2)
        v = self._nodePath.node().getLinearVelocity().length()
        slowAccel = 2
        slowDist = v**2 / (2 * slowAccel * self._breakForce)
        brakePercent = slowAccel * self._nodePath.node().getMass() / self._breakForce

        deltaPos = (self.getPos() - self._moveLoc[1])
        distFromStart = deltaPos.length()

        if self._stop:
            if v < .4:
                #self._nodePath.node().setLinearVelocity(Vec3(0,0,0))
                #self._nodePath.setPos(self._moveLoc[0])
                return task.done
            self.applyBrakes()
            return task.cont
        
        if distance < slowDist:
            self.applyBrakes(brakePercent * 1.1)
        elif distance > slowDist:
            if self._moveLoc[2] > 0:
                self.applyThrusters(1,1)
            else:
                self.applyThrusters(-1, -1)
        else:
            self.applyBrakes(brakePercent)
        
        if distance < .01: 
            self._stop = True
        if abs(distFromStart) > abs(self._moveLoc[2]):
            self._stop = True
        
        return task.cont

    
    def nextTask(self,task):
        self._nodePath.node().setActive(True)
        self.onTask += 1
        if(self._tankWorld.isDead or self._tankWorld.isOver):
            return
        #if self.onTask >= len(self.taskList):
        #   return
       
        def getNumUserTask():
            
            taskAmount = 0
            for t in self._tankWorld.taskMgr.getTasks():

                if t.getName() == 'userTank '+self.getName():
                    taskAmount +=1
            return taskAmount

        pre = getNumUserTask()
        try:
            self.taskList.next()
            if(getNumUserTask() == pre):
                self.nextTask(task)

        except StopIteration:
            #print 'Tank.nextTask error'
            pass
        #self.taskList[self.onTask][0](self.taskList[self.onTask][1])
    
    def runTasks(self):
        self.onTask = 0
        self.nextTask(None)
    
    def setGenerator(self, gen):
        self.taskList = gen
        self.runTasks()

    def updateMove(self, task):
        '''
        Task Called to do movement. This is called once perframe
        '''
        try:
            #small hack to prevent the first frame from doing all the tasks.
            dt = globalClock.getDt()    
            if dt > .1:
                return task.cont
            self._taskTimer -= dt

            if self._taskTimer < 0:
                self.applyBrakes(1)
            else:
                self.applyThrusters(1,1)

            if self._taskTimer < -1: #one second to stop
                return task.done
        except:
            print "ERROR in tank.updateMove"

        return task.cont

    def updateRotate(self, task):

        ''' called to do rotation. This is called once per frame
        '''
        try:
            dt = globalClock.getDt()
            #small hack to prevent the first frame from doing all the tasks.
            if dt > .1:
                return task.cont
            self._taskTimer -= dt


            if self._taskTimer < 0:
                self.applyBrakes(1)
            else:
                self.applyThrusters(1,-1)
            

            if self._taskTimer < -1: #one second to stop
                return task.done

        except:
            print "ERROR in tank.updateRotate"
        return task.cont

    def update(self, task):
        pass
        
    def aimAt(self, point, amt = 1, aimLow = True):
        return self._weapon.aimAt(point, aimLow)

    def setWeapon(self, weopwn):
        self._weapon = weopwn


    def fire(self, amt = 1):

        x = self._weapon.fire(amt)        
        self.wait(.1)
        return x

    def deleteAfter(self, task = None):
        if not self._nodePath.is_empty():
            x = self._nodePath.node()
            self._tankWorld.removeRigidBody(x)
            self.hide()                 
            self._tankWorld.lose()                               
            #self._nodePath.detachNode()

    def handleCollision(self, collide, taskName):
        self._collisionCounter += 1

        forReal = True

        hitBy = collide.getNode0()
        if hitBy.getName() == self._nodePath.node().getName():
            hitBy = collide.getNode1()

        allowedNames = ['floor', 'wall', 'State']

        for name in allowedNames:
            if name in hitBy.getName():
                forReal = False

        if not self._nodePath.is_empty():        
            
            if forReal:
                print "Tank.handleCollision:(pos) ", self.getPos(), 'obj 1', collide.getNode0().getName(), 'obj 2', collide.getNode1().getName()
            
                self._tankWorld.taskMgr.remove(taskName)
                self._tankWorld.doMethodLater(.01, self.deleteAfter, 'deleteAfter')

        else:
            print "Tank.handleCollision Failed to have _nodepath"
            self._tankWorld.taskMgr.remove(taskName)
Exemplo n.º 15
0
class RonnieRacer(DirectObject):
  
  gameState = 'INIT'
  gameLevel = 1
  distanceTravelled = 0
  speed = 0
  score = 0
  triesLeft = 3
  count = 0
  rot = 0
  time = 0
  pause = False
  
  def __init__(self):
    self.imageObject = OnscreenImage(image = 'media/images/splashscreen.png', pos=(0,0,0), scale=(1.4,1,1))
    self.loseScreen = OnscreenImage(image = 'media/images/gameover.png', pos=(0,0,0), scale=(1,1,0.8))
    self.loseScreen.hide()
    self.retryScreen = OnscreenImage(image = 'media/images/retry.png', pos=(0,0,0), scale=(1,1,0.8))
    self.retryScreen.hide()
    self.congratScreen = OnscreenImage(image = 'media/images/congratulations.png', pos=(0,0,0), scale = (1,1,0.8))
    self.congratScreen.hide()
    self.winScreen = OnscreenImage(image = 'media/images/victory.png', pos=(0,0,0), scale = (1,1,0.8))
    self.winScreen.hide()
    self.pauseScreen = OnscreenImage(image = 'media/images/pause.png', pos=(0,0,0), scale = (1,1,0.8))
    self.pauseScreen.hide()
    self.instructionScreen = OnscreenImage(image = 'media/images/instructions.png', pos=(0,0,0), scale = (1,1,0.8))
    self.instructionScreen.hide()
    preloader = Preloader()
    base.setBackgroundColor(0, 0, 0, 1)
    base.setFrameRateMeter(True)
    
    # Audio
    self.loseSound = base.loader.loadSfx("media/audio/sfxboo.wav")
    self.winSound = base.loader.loadSfx("media/audio/cheer2.aif")
    self.menuMusic = base.loader.loadSfx("media/audio/Scattershot.mp3")
    self.gameMusic = base.loader.loadSfx("media/audio/Ghostpocalypse - 7 Master.mp3")
    
    self.menuMusic.setLoop(True)
    self.menuMusic.setLoopCount(0)
    
    self.gameMusic.setLoop(True)
    self.gameMusic.setLoopCount(0)

    #setup buttons
    self.retryBtn = DirectButton(text="Retry", scale = 0.1, pos = (0,0,0), command = self.doRetry)
    self.retryBtn.hide()
    self.menuBtn = DirectButton(text="Main Menu", scale = 0.1, pos = (0,0,0), command = self.doMenu)
    self.menuBtn.hide()
    self.nextBtn = DirectButton(text='Next', scale = 0.1, pos = (0,0,0), command = self.doNext)
    self.nextBtn.hide()
    self.backBtn = DirectButton(text='back', scale = 0.1, pos = (-0.7,0,-0.7), command = self.doBack)
    self.backBtn.hide()
    
    #setup font
    self.font = loader.loadFont('media/SHOWG.TTF')
    self.font.setPixelsPerUnit(60)
    
    #setup text
    self.text = OnscreenText(text = '', pos = (0, 0), scale = 0.07, font = self.font)
    
    self.rpmText = OnscreenText(text = '', 
                            pos = (-0.9, -0.9), scale = 0.07, font = self.font)
                            
    self.speedText = OnscreenText(text = '', 
                            pos = (0, -0.9), scale = 0.07, font = self.font)
                            
    self.distanceText = OnscreenText(text = '', 
                            pos = (0.9, -0.9), scale = 0.07, font = self.font)
    
    self.triesLeftText = OnscreenText(text = '', 
                            pos = (1.0, 0.9), scale = 0.07, font = self.font)
    
    self.gameLevelText = OnscreenText(text = '', 
                            pos = (-1.0, 0.9), scale = 0.07, font = self.font)
    
    self.timeText = OnscreenText(text = '', 
                            pos = (0, 0.9), scale = 0.07, font = self.font)
    
    self.scoreText = OnscreenText(text = '', 
                            pos = (1.0, 0.8), scale = 0.07, font = self.font)
    
    self.finalScoreText = OnscreenText(text = '', 
                            pos = (0, 0.2), scale = 0.07, font = self.font)
    # Light
    alight = AmbientLight('ambientLight')
    alight.setColor(Vec4(0.5, 0.5, 0.5, 1))
    alightNP = render.attachNewNode(alight)

    dlight = DirectionalLight('directionalLight')
    dlight.setDirection(Vec3(1, 1, -1))
    dlight.setColor(Vec4(0.7, 0.7, 0.7, 1))
    dlightNP = render.attachNewNode(dlight)

    render.clearLight()
    render.setLight(alightNP)
    render.setLight(dlightNP)

    # Input
    self.accept('escape', self.doExit)
    self.accept('r', self.doReset)
    self.accept('f1', self.toggleWireframe)
    self.accept('f2', self.toggleTexture)
    self.accept('f3', self.toggleDebug)
    self.accept('f5', self.doScreenshot)

    inputState.watchWithModifiers('forward', 'w')
    inputState.watchWithModifiers('left', 'a')
    inputState.watchWithModifiers('reverse', 's')
    inputState.watchWithModifiers('right', 'd')
    inputState.watchWithModifiers('turnLeft', 'a')
    inputState.watchWithModifiers('turnRight', 'd')

    # Task
    taskMgr.add(self.update, 'updateWorld')

  # _____HANDLER_____
  def doExit(self):
    sys.exit(1)

  def doReset(self):
    self.cleanup()
    self.terrain.getRoot().removeNode()
    self.setup()

  def doBack(self):
    self.backBtn.hide()
    self.instructionScreen.hide()
    
    self.imageObject.show()
    self.helpBtn.show()
    self.startBtn.show()
    self.exitBtn.show()

  def toggleWireframe(self):
    base.toggleWireframe()

  def toggleTexture(self):
    base.toggleTexture()

  def toggleDebug(self):
    if self.debugNP.isHidden():
      self.debugNP.show()
    else:
      self.debugNP.hide()

  def doScreenshot(self):
    base.screenshot('Bullet')

  # ____TASK___

  def processInput(self, dt):
    # Process input
    engineForce = 0.0
    brakeForce = 0.0
    
    self.accept('p', self.doPause)
  
    if inputState.isSet('forward'):
       engineForce = 15.0
       brakeForce = 0.0
   
    if inputState.isSet('reverse'):
       engineForce = -25.0
       brakeForce = 25.0
   
    if inputState.isSet('turnLeft'):
       self.steering += dt * self.steeringIncrement
       self.steering = min(self.steering, self.steeringClamp)
   
    if inputState.isSet('turnRight'):
       self.steering -= dt * self.steeringIncrement
       self.steering = max(self.steering, -self.steeringClamp)
   
    # Apply steering to front wheels
    self.vehicle.setSteeringValue(self.steering, 0)
    self.vehicle.setSteeringValue(self.steering, 1)
   
    # Apply engine and brake to rear wheels
    self.vehicle.applyEngineForce(engineForce, 2)
    self.vehicle.applyEngineForce(engineForce, 3)
    self.vehicle.setBrake(brakeForce, 2)
    self.vehicle.setBrake(brakeForce, 3)
    
  def processContacts(self, dt):
    result = self.world.contactTestPair(self.vehicleNP.node(), self.flagNP.node())
    if(result.getNumContacts() > 0):
      self.gameState = 'WIN'
      self.doContinue()
      
  def doContinue(self):
    if(self.gameState == 'INIT'):
      self.gameState = 'MENU'
      self.menuMusic.play()
      self.text.hide()
      self.startBtn = DirectButton(text=("Play"), scale = 0.1, pos = (0.5,0,0),command=self.playGame)
      self.helpBtn = DirectButton(text=("Help"), scale = 0.1, pos = (0.5,0,-0.2),command=self.help)
      self.exitBtn = DirectButton(text=("Exit"), scale = 0.1,  pos = (0.5,0,-0.4), command = self.doExit)
      return
      
    if(self.gameState == 'RETRY'):
      self.retryScreen.show()
      self.retryBtn.show()
      
      self.loseSound.play()
      return
    
    if(self.gameState == 'LOSE'):
      self.loseScreen.show()
      self.menuBtn.show()
      return
    
    if(self.gameState == 'WIN'):
      if(self.gameLevel < 3):
        self.congratScreen.show()
        self.nextBtn.show()
      elif(self.gameLevel >= 3):
        self.winScreen.show()
        self.menuBtn.show()
      self.finalScoreText.setText('Your Score: '+str(int(self.score)))
      self.finalScoreText.show()
        
      self.winSound.play()
      
  def help(self):
    self.gameState = 'HELP'
    self.startBtn.hide()
    self.exitBtn.hide()
    self.helpBtn.hide()
    self.imageObject.hide()
    self.instructionScreen.show()
    self.backBtn.show()
    
  def doNext(self):
    self.nextBtn.hide()
    self.finalScoreText.hide()
    self.congratScreen.hide()
    self.gameLevel += 1
    if(self.gameLevel == 2):
      self.score += 2000
    elif(self.gameLevel == 3):
      self.score += 3000
    self.doReset()
    self.triesLeft = 3
    self.gameState = 'PLAY'
    
  def doRetry(self):
    self.doReset()
    self.gameState = 'PLAY'
    self.retryScreen.hide()
    self.retryBtn.hide()
    self.triesLeft -= 1
  
  def doMenu(self):
    self.cleanup()
    self.terrain.getRoot().removeNode()
    self.gameState = 'MENU'
    
    self.score = 0
    
    self.imageObject.show()
    self.startBtn.show()
    self.exitBtn.show()
    self.helpBtn.show()
    
    self.loseScreen.hide()
    self.menuBtn.hide()
    self.winScreen.hide()
    self.finalScoreText.hide()
    
    self.speedText.hide()
    self.distanceText.hide()
    self.rpmText.hide()
    self.scoreText.hide()
    self.gameLevelText.hide()
    self.timeText.hide()
    self.triesLeftText.hide()
    
    self.gameMusic.stop()
    self.menuMusic.play()
      
  def doPause(self):
    self.pause  = not self.pause
    if(self.pause):
      self.pauseScreen.show()
    else:
      self.pauseScreen.hide()
      
  def playGame(self):
    self.gameState = 'PLAY'
    
    self.triesLeft = 3
    self.gameLevel = 1
    
    self.imageObject.hide()
    self.startBtn.hide()
    self.exitBtn.hide()
    self.helpBtn.hide()
    
    self.menuMusic.stop()
    self.gameMusic.play()
    
    self.speedText.show()
    self.distanceText.show()
    self.rpmText.show()
    self.scoreText.show()
    self.gameLevelText.show()
    self.triesLeftText.show()
    self.timeText.show()
    
    # Physics
    self.setup()

  def update(self, task):
    dt = globalClock.getDt()
    if(not self.pause):
      if(self.gameState == 'RETRY'):
        return task.cont
      
      if (self.gameState == 'INIT'):
        self.accept('space', self.doContinue)
        self.text.setText('Press Space to Continue')
        
      if(self.gameState == 'PLAY'):
        if (self.steering > 0):
            self.steering -= dt * 50
        if (self.steering < 0):
            self.steering += dt * 50
            
        playerOldSpeed = self.vehicle.getCurrentSpeedKmHour()
        
        self.processInput(dt)
        self.processContacts(dt)
        self.world.doPhysics(dt, 10, 0.008)
  
        #calculate speed,rpm,distance and display text
        self.speed = self.vehicle.getCurrentSpeedKmHour()
        if(self.speed<0):
            self.speed = -self.speed
        self.speedText.setText('Speed: ' + str(int(self.speed)) + 'Km/h')
        self.distanceTravelled += self.speed*(dt/3600)
        self.distanceText.setText('Distance: '+str(float(int(self.distanceTravelled * 1000))/1000) + 'Km')
  
        playerNewSpeed = self.vehicle.getCurrentSpeedKmHour()
  
        playerAcceleration = (playerNewSpeed - playerOldSpeed) / (dt/60)
        #playerPosText = self.vehicleNP.getPos()
        #self.text.setText('Player position: %s'%playerPosText)
        self.rpmText.setText('Engine RPM: ' + str(int(((self.vehicle.getCurrentSpeedKmHour() / 60) * 1000) / (2 * 0.4 * 3.14159265))) + ' Rpm')
        
        self.triesLeftText.setText('Tries Left: ' + str(self.triesLeft))
  
        self.gameLevelText.setText('Level: '+ str(self.gameLevel))
        
        #update camera
        #position
        d = self.vehicleNP.getPos() - base.cam.getPos()
        if(d.length() > 8):
          base.cam.setX(base.cam.getX() + d.getX()*dt)
          base.cam.setY(base.cam.getY() + d.getY()*dt)
        base.cam.setZ(self.vehicleNP.getZ() + 4)
        #lookat
        base.cam.lookAt(self.vehicleNP.getPos()+Vec3(0,0,1))
        
        if(self.gameLevel == 1):
          if(self.vehicleNP.getZ() < -17):
            if(self.triesLeft > 0):
              self.gameState = 'RETRY'
            else:
              self.gameState = 'LOSE'
            self.doContinue()
        elif(self.gameLevel == 2):
          if(self.vehicleNP.getZ() < -20):
            if(self.triesLeft > 0):
              self.gameState = 'RETRY'
            else:
              self.gameState = 'LOSE'
            self.doContinue()
        elif(self.gameLevel == 3):
          if(self.vehicleNP.getZ() < -17):
            if(self.triesLeft > 0):
              self.gameState = 'RETRY'
            else:
              self.gameState = 'LOSE'
            self.doContinue()
            
        if(self.speed < 5):
          self.steeringIncrement = 120
        elif(self.speed >= 5 and self.speed < 10):
          self.steeringIncrement = 100
        elif(self.speed >= 10 and self.speed < 15):
          self.steeringIncrement = 80
        elif(self.speed >=15 and self.speed < 30):
          self.steeringIncrement = 60
          
        #spin the flag
        self.rot += 1
        self.flagNP.setHpr(self.rot,0,0)
        
        #time
        self.time += dt
        self.timeText.setText('Time: ' + str(int(self.time)))
        if(self.score > 0):
          self.score -= dt
        self.scoreText.setText('Score: '+str(int(self.score)))

    return task.cont

  def cleanup(self):
    self.world = None
    self.worldNP.removeNode()

  def setup(self):
    # Steering info
    self.steering = 0.0            # degree
    self.steeringClamp = 30.0      # degree
    self.steeringIncrement = 80.0 # degree per second
    
    self.worldNP = render.attachNewNode('World')

    # World
    self.debugNP = self.worldNP.attachNewNode(BulletDebugNode('Debug'))
    #self.debugNP.show()

    self.world = BulletWorld()
    self.world.setGravity(Vec3(0, 0, -9.81))
    self.world.setDebugNode(self.debugNP.node())
    
    if(self.gameLevel == 1):
      #set score
      print('GameLevel')
      self.score = 1000
      self.distanceTravelled = 0
      self.time = 0
      # Plane
      img = PNMImage(Filename('media/terrain/SIMP_Assignment_2_Terrain_1.png'))
      shape = BulletHeightfieldShape(img, 50.0, ZUp)

      np = self.worldNP.attachNewNode(BulletRigidBodyNode('Ground'))
      np.node().addShape(shape)
      np.setPos(0, 0, 0)
      np.setCollideMask(BitMask32.allOn())

      self.world.attachRigidBody(np.node())
    
      #skybox
      skybox = loader.loadModel('media/models/skybox/skybox_01.X')
      skybox.reparentTo(render)

    # Chassis
      shape = BulletBoxShape(Vec3(0.6, 1.4, 0.5))
      ts = TransformState.makePos(Point3(0, 0, 1.0))

      self.vehicleNP = self.worldNP.attachNewNode(BulletRigidBodyNode('Vehicle'))
      self.vehicleNP.node().addShape(shape, ts)
      self.vehicleNP.setPos(-93, -88, -7)#-93, -88, -7) #(-82,65.8,-8) #(55,8.38,-6)#(45, -19, -8)#(-93, -88, -7)
      self.vehicleNP.setHpr(-90,0,0)
      self.vehicleNP.node().setMass(5.0)
      self.vehicleNP.node().setDeactivationEnabled(False)
      
      base.cam.setPos(self.vehicleNP.getPos().getX()+2,self.vehicleNP.getPos().getY()+2,self.vehicleNP.getPos().getZ()+2)

      self.world.attachRigidBody(self.vehicleNP.node())

      # Vehicle
      self.vehicle = BulletVehicle(self.world, self.vehicleNP.node())
      self.vehicle.setCoordinateSystem(ZUp)
      self.world.attachVehicle(self.vehicle)

      self.hummerNP = loader.loadModel('media/models/vehicle/body.X')
      self.hummerNP.reparentTo(self.vehicleNP)
  
      # Right front wheel
      np = loader.loadModel('media/models/vehicle/front_right.X')
      np.reparentTo(self.worldNP)
      self.addWheel(Point3( 0.8,  0.9, 0.8), True, np)
  
      # Left front wheel
      np = loader.loadModel('media/models/vehicle/front_left.X')
      np.reparentTo(self.worldNP)
      self.addWheel(Point3(-0.8,  0.9, 0.8), True, np)
  
      # Right rear wheel
      np = loader.loadModel('media/models/vehicle/back_right.X')
      np.reparentTo(self.worldNP)
      self.addWheel(Point3( 0.8, -0.7, 0.8), False, np)
  
      # Left rear wheel
      np = loader.loadModel('media/models/vehicle/back_left.X')
      np.reparentTo(self.worldNP)
      self.addWheel(Point3(-0.8, -0.7, 0.8), False, np)
      
      #Obstacles
      self.setupObstacleOne(Vec3(50, -5, -4), 1.8, Vec3(60, 0, 0))
      self.setupObstacleFour(Vec3(63.3, 59.2, -10), 1.5, Vec3(0,0,0))
      self.setupObstacleFour(Vec3(41, 57, -10), 1.5, Vec3(0,0,0))
      self.setupObstacleFour(Vec3(7.5, 53.8, -10), 1.5, Vec3(0,0,0))
      self.setupObstacleFour(Vec3(-28, 81.4, -10), 1.5, Vec3(0,0,0))
      self.setupObstacleSix(Vec3(-91, 81 , -6), 1, Vec3(60,0,0))
      
      #Goal
      self.setupGoal(Vec3(-101,90.6,-6.5))
      
      #self.vehicleNP.setPos(Vec3(6,52,-6))
      self.setupTerrain()
    elif(self.gameLevel == 2):
      self.distanceTravelled = 0
      self.time  = 0 
      # Plane
      img = PNMImage(Filename('media/terrain/SIMP_Assignment_2_Terrain_2.png'))
      shape = BulletHeightfieldShape(img, 50.0, ZUp)

      np = self.worldNP.attachNewNode(BulletRigidBodyNode('Ground'))
      np.node().addShape(shape)
      np.setPos(0, 0, 0)
      np.setCollideMask(BitMask32.allOn())

      self.world.attachRigidBody(np.node())
      
      #skybox
      skybox = loader.loadModel('media/models/skybox/skybox_01.X')
      skybox.reparentTo(render)

      # Chassis
      shape = BulletBoxShape(Vec3(0.6, 1.4, 0.5))
      ts = TransformState.makePos(Point3(0, 0, 1.0))

      self.vehicleNP = self.worldNP.attachNewNode(BulletRigidBodyNode('Vehicle'))
      self.vehicleNP.node().addShape(shape, ts)
      self.vehicleNP.setPos(-99.6,105,-11.8)#(88, 21, -11)#(34.3,8.4,-11.8)#(-99.6,105,-11.8)#(86.4,41.2,-12)
      self.vehicleNP.setHpr(-130,0,0)
      self.vehicleNP.node().setMass(5.0)
      self.vehicleNP.node().setDeactivationEnabled(False)
      
      base.cam.setPos(self.vehicleNP.getPos().getX()+2,self.vehicleNP.getPos().getY()+2,self.vehicleNP.getPos().getZ()+2)

      self.world.attachRigidBody(self.vehicleNP.node())

      # Vehicle
      self.vehicle = BulletVehicle(self.world, self.vehicleNP.node())
      self.vehicle.setCoordinateSystem(ZUp)
      self.world.attachVehicle(self.vehicle)

      self.hummerNP = loader.loadModel('media/models/vehicle/body.X')
      self.hummerNP.reparentTo(self.vehicleNP)
  
      # Right front wheel
      np = loader.loadModel('media/models/vehicle/front_right.X')
      np.reparentTo(self.worldNP)
      self.addWheel(Point3( 0.8,  0.9, 0.8), True, np)
  
      # Left front wheel
      np = loader.loadModel('media/models/vehicle/front_left.X')
      np.reparentTo(self.worldNP)
      self.addWheel(Point3(-0.8,  0.9, 0.8), True, np)
  
      # Right rear wheel
      np = loader.loadModel('media/models/vehicle/back_right.X')
      np.reparentTo(self.worldNP)
      self.addWheel(Point3( 0.8, -0.7, 0.8), False, np)
  
      # Left rear wheel
      np = loader.loadModel('media/models/vehicle/back_left.X')
      np.reparentTo(self.worldNP)
      self.addWheel(Point3(-0.8, -0.7, 0.8), False, np)
      
      self.setupObstacleFive(Vec3(91, 3, -9),1,Vec3(90,0,0))
      self.setupObstacleFive(Vec3(94,-19, -10),0.9,Vec3(90,0,0))
      self.setupObstacleFive(Vec3(85,-40, -10),1,Vec3(90,0,0))
      self.setupObstacleFour(Vec3(-33.5, 23.4,-14.5),1,Vec3(0,0,0))
      self.setupObstacleFour(Vec3(-43.3, 24.2,-14.5),1,Vec3(0,0,0))
      self.setupObstacleTwo(Vec3(34.7,20.9,-8.5),1,Vec3(90,0,0))
      self.setupObstacleTwo(Vec3(26.8,20.3,-8.5),1,Vec3(90,0,0))
      self.setupObstacleTwo(Vec3(42.1,22.5,-8.5),1,Vec3(90,0,0))
      #self.setupObstacleFive(Vec3(91,0.2, -8),2.1,Vec3(90,0,0))
            
      #Goal
      self.setupGoal(Vec3(94,-89.7,-10))
      self.setupTerrain()
    elif(self.gameLevel == 3):
      self.distanceTravelled = 0
      self.time  = 0 
      # Plane
      img = PNMImage(Filename('media/terrain/SIMP_Assignment_2_Terrain_3.png'))
      shape = BulletHeightfieldShape(img, 50.0, ZUp)

      np = self.worldNP.attachNewNode(BulletRigidBodyNode('Ground'))
      np.node().addShape(shape)
      np.setPos(0, 0, 0)
      np.setCollideMask(BitMask32.allOn())

      self.world.attachRigidBody(np.node())
      
      #skybox
      skybox = loader.loadModel('media/models/skybox/skybox_01.X')
      skybox.reparentTo(render)

      # Chassis
      shape = BulletBoxShape(Vec3(0.6, 1.4, 0.5))
      ts = TransformState.makePos(Point3(0, 0, 1.0))

      self.vehicleNP = self.worldNP.attachNewNode(BulletRigidBodyNode('Vehicle'))
      self.vehicleNP.node().addShape(shape, ts)
      self.vehicleNP.setPos(-110, -110, 0)
      self.vehicleNP.setHpr(-40,0,0)
      self.vehicleNP.node().setMass(5.0)
      self.vehicleNP.node().setDeactivationEnabled(False)
      
      base.cam.setPos(self.vehicleNP.getPos().getX()+2,self.vehicleNP.getPos().getY()+2,self.vehicleNP.getPos().getZ()+2)

      self.world.attachRigidBody(self.vehicleNP.node())

      # Vehicle
      self.vehicle = BulletVehicle(self.world, self.vehicleNP.node())
      self.vehicle.setCoordinateSystem(ZUp)
      self.world.attachVehicle(self.vehicle)

      self.hummerNP = loader.loadModel('media/models/vehicle/body.X')
      self.hummerNP.reparentTo(self.vehicleNP)
  
      # Right front wheel
      np = loader.loadModel('media/models/vehicle/front_right.X')
      np.reparentTo(self.worldNP)
      self.addWheel(Point3( 0.8,  0.9, 0.8), True, np)
  
      # Left front wheel
      np = loader.loadModel('media/models/vehicle/front_left.X')
      np.reparentTo(self.worldNP)
      self.addWheel(Point3(-0.8,  0.9, 0.8), True, np)
  
      # Right rear wheel
      np = loader.loadModel('media/models/vehicle/back_right.X')
      np.reparentTo(self.worldNP)
      self.addWheel(Point3( 0.8, -0.7, 0.8), False, np)
  
      # Left rear wheel
      np = loader.loadModel('media/models/vehicle/back_left.X')
      np.reparentTo(self.worldNP)
      self.addWheel(Point3(-0.8, -0.7, 0.8), False, np)

      self.setupTerrain()
      
      #Goal
      self.setupGoal(Vec3(114,100,-13))
      
      #Obstacles
      self.setupObstacleFour(Vec3(-60, -73, -9), 1, Vec3(0, 0, 0))
      self.setupObstacleFour(Vec3(-63, -77, -9), 1, Vec3(0, 0, 0))
      self.setupObstacleTwo(Vec3(-15, -40, -3), 1, Vec3(0, 0, 0))
      self.setupObstacleFour(Vec3(-60, 12, -11), 1, Vec3(0, 0, 0))
      self.setupObstacleSix(Vec3(-15, 90, -6), 1.5, Vec3(-30, 0, 0))
      self.setupObstacleFour(Vec3(28, 87, -11), 1, Vec3(0, 0, 0))
      self.setupObstacleFour(Vec3(32, 90, -11), 1, Vec3(0, 0, 0))



  def addWheel(self, pos, front, np):
    wheel = self.vehicle.createWheel()

    wheel.setNode(np.node())
    wheel.setChassisConnectionPointCs(pos)
    wheel.setFrontWheel(front)

    wheel.setWheelDirectionCs(Vec3(0, 0, -1))
    wheel.setWheelAxleCs(Vec3(1, 0, 0))
    wheel.setWheelRadius(0.4)
    wheel.setMaxSuspensionTravelCm(40.0)

    wheel.setSuspensionStiffness(40.0)
    wheel.setWheelsDampingRelaxation(2.3)
    wheel.setWheelsDampingCompression(4.4)
    wheel.setFrictionSlip(100.0);
    wheel.setRollInfluence(0.1)

  def setupTerrain(self):
    if(self.gameLevel == 1):
      #terrain setting
      img = PNMImage(Filename('media/terrain/SIMP_Assignment_2_Terrain_1.png'))
      self.terrain = GeoMipTerrain("myTerrain") 
      self.terrain.setHeightfield(img) 
      self.terrain.getRoot().setSz(50) 
      self.terrain.setBlockSize(4) 
      #self.terrain.setFactor(10) 
      #self.terrain.setMinLevel(0)
      self.terrain.setNear(50)
      self.terrain.setFar(1000)
      self.terrain.setFocalPoint(base.camera)
      self.terrain.getRoot().reparentTo(render)
      offset = img.getXSize() / 2.0 - 0.5
      self.terrain.getRoot().setPos(-offset, -offset, -50 / 2.0) 
      self.terrain.generate() 
    
      #load textures 
      tex0 = loader.loadTexture("media/terrain/SIMP_Assignment_2_Terrain_1_d.png") 
      tex0.setMinfilter(Texture.FTLinearMipmapLinear) 
      tex1 = loader.loadTexture("media/terrain/longGrass.png") 
      tex1.setMinfilter(Texture.FTLinearMipmapLinear) 
      tex2 = loader.loadTexture("media/terrain/bigRockFace.png") 
      tex2.setMinfilter(Texture.FTLinearMipmapLinear) 
      tex3 = loader.loadTexture("media/terrain/greenrough.png") 
      tex3.setMinfilter(Texture.FTLinearMipmapLinear) 
      tex4 = loader.loadTexture("media/terrain/grayRock.png") 
      tex4.setMinfilter(Texture.FTLinearMipmapLinear) 
      tex5 = loader.loadTexture("media/terrain/SIMP_Assignment_2_Terrain_1_c.png") 
      tex5.setMinfilter(Texture.FTLinearMipmapLinear) 
      tex6 = loader.loadTexture("media/terrain/SIMP_Assignment_2_Terrain_1_l.png") 
      tex6.setMinfilter(Texture.FTLinearMipmapLinear) 
      #set mutiltextures 
      self.terrain.getRoot().setTexture( TextureStage('tex0'),tex0 ) 
      self.terrain.getRoot().setTexture( TextureStage('tex1'),tex1 ) 
      self.terrain.getRoot().setTexture( TextureStage('tex2'),tex2 ) 
      self.terrain.getRoot().setTexture( TextureStage('tex3'),tex3 ) 
      self.terrain.getRoot().setTexture( TextureStage('tex4'),tex4 ) 
      self.terrain.getRoot().setTexture( TextureStage('tex5'),tex5 ) 
      self.terrain.getRoot().setTexture( TextureStage('tex6'),tex6 ) 
      #load shader 
      self.terrain.getRoot().setShader(loader.loadShader('terraintexture.sha'))
    elif(self.gameLevel == 2):
      #terrain setting
      img = PNMImage(Filename('media/terrain/SIMP_Assignment_2_Terrain_2.png'))
      self.terrain = GeoMipTerrain("myTerrain") 
      self.terrain.setHeightfield(img) 
      self.terrain.getRoot().setSz(50) 
      self.terrain.setBlockSize(4) 
      #self.terrain.setFactor(10) 
      #self.terrain.setMinLevel(0)
      self.terrain.setNear(50)
      self.terrain.setFar(100)
      self.terrain.setFocalPoint(base.camera)
      self.terrain.getRoot().reparentTo(render)
      offset = img.getXSize() / 2.0 - 0.5
      self.terrain.getRoot().setPos(-offset, -offset, -50 / 2.0) 
      self.terrain.generate() 
    
      #load textures 
      tex0 = loader.loadTexture("media/terrain/SIMP_Assignment_2_Terrain_2_d.png") 
      tex0.setMinfilter(Texture.FTLinearMipmapLinear) 
      tex1 = loader.loadTexture("media/terrain/sandripple.png") 
      tex1.setMinfilter(Texture.FTLinearMipmapLinear) 
      tex2 = loader.loadTexture("media/terrain/orangesand.png") 
      tex2.setMinfilter(Texture.FTLinearMipmapLinear) 
      tex3 = loader.loadTexture("media/terrain/grayRock.png") 
      tex3.setMinfilter(Texture.FTLinearMipmapLinear) 
      tex4 = loader.loadTexture("media/terrain/bigRockFace.png") 
      tex4.setMinfilter(Texture.FTLinearMipmapLinear) 
      tex5 = loader.loadTexture("media/terrain/SIMP_Assignment_2_Terrain_2_c.png") 
      tex5.setMinfilter(Texture.FTLinearMipmapLinear) 
      tex6 = loader.loadTexture("media/terrain/SIMP_Assignment_2_Terrain_2_l.png") 
      tex6.setMinfilter(Texture.FTLinearMipmapLinear) 
      #set mutiltextures 
      self.terrain.getRoot().setTexture( TextureStage('tex0'),tex0 ) 
      self.terrain.getRoot().setTexture( TextureStage('tex1'),tex1 ) 
      self.terrain.getRoot().setTexture( TextureStage('tex2'),tex2 ) 
      self.terrain.getRoot().setTexture( TextureStage('tex3'),tex3 ) 
      self.terrain.getRoot().setTexture( TextureStage('tex4'),tex4 ) 
      self.terrain.getRoot().setTexture( TextureStage('tex5'),tex5 ) 
      self.terrain.getRoot().setTexture( TextureStage('tex6'),tex6 ) 
      #load shader 
      self.terrain.getRoot().setShader(loader.loadShader('terraintexture.sha'))
    elif(self.gameLevel == 3):
      #terrain setting
      img = PNMImage(Filename('media/terrain/SIMP_Assignment_2_Terrain_3.png'))
      self.terrain = GeoMipTerrain("myTerrain") 
      self.terrain.setHeightfield(img) 
      self.terrain.getRoot().setSz(50) 
      self.terrain.setBlockSize(4) 
      #self.terrain.setFactor(10) 
      #self.terrain.setMinLevel(0)
      self.terrain.setNear(50)
      self.terrain.setFar(100)
      self.terrain.setFocalPoint(base.camera)
      self.terrain.getRoot().reparentTo(render)
      offset = img.getXSize() / 2.0 - 0.5
      self.terrain.getRoot().setPos(-offset, -offset, -50 / 2.0) 
      self.terrain.generate() 
    
      #load textures 
      tex0 = loader.loadTexture("media/terrain/SIMP_Assignment_2_Terrain_3_d.png") 
      tex0.setMinfilter(Texture.FTLinearMipmapLinear) 
      tex1 = loader.loadTexture("media/terrain/hardDirt.png") 
      tex1.setMinfilter(Texture.FTLinearMipmapLinear) 
      tex2 = loader.loadTexture("media/terrain/littlerocks.png") 
      tex2.setMinfilter(Texture.FTLinearMipmapLinear) 
      tex3 = loader.loadTexture("media/terrain/greenrough.png") 
      tex3.setMinfilter(Texture.FTLinearMipmapLinear) 
      tex4 = loader.loadTexture("media/terrain/bigRockFace.png") 
      tex4.setMinfilter(Texture.FTLinearMipmapLinear) 
      tex5 = loader.loadTexture("media/terrain/SIMP_Assignment_2_Terrain_3_c.png") 
      tex5.setMinfilter(Texture.FTLinearMipmapLinear) 
      tex6 = loader.loadTexture("media/terrain/SIMP_Assignment_2_Terrain_3_l.png") 
      tex6.setMinfilter(Texture.FTLinearMipmapLinear) 
      #set mutiltextures 
      self.terrain.getRoot().setTexture( TextureStage('tex0'),tex0 ) 
      self.terrain.getRoot().setTexture( TextureStage('tex1'),tex1 ) 
      self.terrain.getRoot().setTexture( TextureStage('tex2'),tex2 ) 
      self.terrain.getRoot().setTexture( TextureStage('tex3'),tex3 ) 
      self.terrain.getRoot().setTexture( TextureStage('tex4'),tex4 ) 
      self.terrain.getRoot().setTexture( TextureStage('tex5'),tex5 ) 
      self.terrain.getRoot().setTexture( TextureStage('tex6'),tex6 ) 
      #load shader 
      self.terrain.getRoot().setShader(loader.loadShader('terraintexture.sha'))

  def setupObstacleOne(self, pos, scale, turn):
    
    #box A
    shape = BulletBoxShape(Vec3(3, 0.1, 0.1) * scale)
    
    bodyA = BulletRigidBodyNode('Box A')
    bodyNP= self.worldNP.attachNewNode(bodyA)
    bodyNP.node().addShape(shape)
    bodyNP.setCollideMask(BitMask32.allOn())
    bodyNP.setPos(pos)
    bodyNP.setHpr(turn)
    
    visNP = loader.loadModel('media/models/box.egg')
    visNP.setScale(Vec3(3, 0.1, 0.1)*2 * scale)
    visNP.clearModelNodes()
    visNP.reparentTo(bodyNP)
    
    self.world.attachRigidBody(bodyA)
    
    # Box C
    shape = BulletBoxShape(Vec3(0.1, 0.1, 0.9)*scale)
    
    bodyC = BulletRigidBodyNode('Box C')
    bodyNP = self.worldNP.attachNewNode(bodyC)
    bodyNP.node().addShape(shape)
    bodyNP.node().setMass(1.0)
    bodyNP.node().setLinearDamping(0.5)
    bodyNP.node().setDeactivationEnabled(False)
    bodyNP.setCollideMask(BitMask32.allOn())
    bodyNP.setPos(pos)
    bodyNP.setHpr(turn)
    
    visNP = loader.loadModel('media/models/box.egg')
    visNP.setScale(Vec3(0.1, 0.1, 0.9)*2*scale)
    visNP.clearModelNodes()
    visNP.reparentTo(bodyNP)
    
    self.world.attachRigidBody(bodyC)
    
    pivotA = Point3(0, 0, -0.1 * scale)
    pivotB = Point3(0, 0, 1 * scale)
    axisA = Vec3(1, 0, 0)
    axisB = Vec3(1, 0, 0)
    
    hinge = BulletHingeConstraint(bodyA, bodyC, pivotA, pivotB, axisA, axisB, True)
    hinge.setDebugDrawSize(2.0)
    hinge.setLimit(-90,90, softness=1.0, bias=0.3, relaxation=1.0)
    self.world.attachConstraint(hinge)
    
    # Box B
    shape = BulletBoxShape(Vec3(3, 2, 0.1)*scale)
    
    bodyB = BulletRigidBodyNode('Box B')
    bodyNP = self.worldNP.attachNewNode(bodyB)
    bodyNP.node().addShape(shape)
    bodyNP.node().setMass(1.0)
    bodyNP.node().setLinearDamping(0.5)
    bodyNP.node().setDeactivationEnabled(False)
    bodyNP.setCollideMask(BitMask32.allOn())
    bodyNP.setPos(pos)
    bodyNP.setHpr(turn);
    
    visNP = loader.loadModel('media/models/box.egg')
    visNP.setScale(Vec3(3, 2, 0.1)*2*scale)
    visNP.clearModelNodes()
    visNP.reparentTo(bodyNP)
    
    self.world.attachRigidBody(bodyB)
    
    # Hinge
    pivotA = Point3(0, 0, 0)
    pivotB = Point3(0, 0, -1 * scale)
    
    hinge = BulletHingeConstraint(bodyB, bodyC, pivotA, pivotB, axisA, axisB, True)
    hinge.setLimit(0,360, softness=1.0, bias=0.3, relaxation=1.0)
    self.world.attachConstraint(hinge)
  
  def setupObstacleTwo(self,pos,scale,turn):
    
    #box A
    shape = BulletBoxShape(Vec3(3, 0.1, 0.1)*scale)
    
    bodyA = BulletRigidBodyNode('Box A')
    bodyNP= self.worldNP.attachNewNode(bodyA)
    bodyNP.node().addShape(shape)
    bodyNP.setCollideMask(BitMask32.allOn())
    bodyNP.setPos(pos)
    bodyNP.setHpr(turn)
    
    visNP = loader.loadModel('media/models/box.egg')
    visNP.setScale(Vec3(3, 0.1, 0.1)*2*scale)
    visNP.clearModelNodes()
    visNP.reparentTo(bodyNP)
    
    self.world.attachRigidBody(bodyA)
    
    # Box B
    shape = BulletBoxShape(Vec3(0.1, 1, 1)*scale)
    
    bodyB = BulletRigidBodyNode('Box B')
    bodyNP = self.worldNP.attachNewNode(bodyB)
    bodyNP.node().addShape(shape)
    bodyNP.node().setMass(100.0)
    bodyNP.node().setDeactivationEnabled(False)
    bodyNP.setCollideMask(BitMask32.allOn())
    bodyNP.setPos(pos)
    bodyNP.setHpr(turn)
    
    
    visNP = loader.loadModel('media/models/box.egg')
    visNP.setScale(Vec3(0.1, 1, 1)*2*scale)
    visNP.clearModelNodes()
    visNP.reparentTo(bodyNP)
    
    self.world.attachRigidBody(bodyB)
    
    # Hinge
    pivotA = Point3(2, 0, 0)
    pivotB = Point3(0, 0, 2)
    axisA = Vec3(1, 0, 0)
    axisB = Vec3(1, 0, 0)
    
    hinge = BulletHingeConstraint(bodyA, bodyB, pivotA, pivotB, axisA, axisB, True)
    hinge.setDebugDrawSize(2.0)
    hinge.setLimit(-90,90, softness=1.0, bias=0.3, relaxation=1.0)
    self.world.attachConstraint(hinge)
    
    # Box C
    shape = BulletBoxShape(Vec3(0.1, 1, 1)*scale)
    
    bodyC = BulletRigidBodyNode('Box C')
    bodyNP = self.worldNP.attachNewNode(bodyC)
    bodyNP.node().addShape(shape)
    bodyNP.node().setMass(100.0)
    bodyNP.node().setDeactivationEnabled(False)
    bodyNP.setCollideMask(BitMask32.allOn())
    bodyNP.setPos(pos)
    bodyNP.setHpr(turn)
    
    visNP = loader.loadModel('media/models/box.egg')
    visNP.setScale(Vec3(0.1, 1, 1)*2*scale)
    visNP.clearModelNodes()
    visNP.reparentTo(bodyNP)
    
    self.world.attachRigidBody(bodyC)
    
    pivotA = Point3(-2, 0, 0)
    pivotB = Point3(0, 0, 2)
    
    hinge = BulletHingeConstraint(bodyA, bodyC, pivotA, pivotB, axisA, axisB, True)
    self.world.attachConstraint(hinge)
  
  def setupObstacleThree(self, pos, scale, turn):
    # Box A
    shape = BulletBoxShape(Vec3(0.1, 0.1, 0.1))
    
    bodyA = BulletRigidBodyNode('Box A')
    bodyA.setRestitution(1.0)
    bodyNP = self.worldNP.attachNewNode(bodyA)
    bodyNP.node().addShape(shape)
    bodyNP.setCollideMask(BitMask32.allOn())
    bodyNP.setPos(pos)
    bodyNP.setHpr(turn)
    
    visNP = loader.loadModel('media/models/box.egg')
    visNP.setScale(Vec3(0.1, 0.1, 0.1)*2*scale)
    visNP.clearModelNodes()
    visNP.reparentTo(bodyNP)
    
    self.world.attachRigidBody(bodyA)
    
    #Box B
    shape = BulletBoxShape(Vec3(0.1,0.1,0.1))
    
    bodyB = BulletRigidBodyNode('Box B')
    bodyB.setRestitution(1.0)
    bodyNP = self.worldNP.attachNewNode(bodyB)
    bodyNP.node().addShape(shape)
    bodyNP.setCollideMask(BitMask32.allOn())
    bodyNP.setPos(pos)
    bodyNP.setHpr(turn)
    
    visNP = loader.loadModel('media/models/box.egg')
    visNP.setScale(Vec3(0.1,0.1,0.1)*2*scale)
    visNP.clearModelNodes()
    visNP.reparentTo(bodyNP)
    
    self.world.attachRigidBody(bodyB)
    
    # Slider
    frameA = TransformState.makePosHpr(Point3(0, 0, 0), Vec3(0, 0, 0))
    frameB = TransformState.makePosHpr(Point3(0, 0, 0), Vec3(0, 0, 0))
    
    slider = BulletSliderConstraint(bodyA, bodyB, frameA, frameB, True)
    slider.setDebugDrawSize(2.0)
    slider.setLowerLinearLimit(0)
    slider.setUpperLinearLimit(12)
    slider.setLowerAngularLimit(-90)
    slider.setUpperAngularLimit(-85)
    self.world.attachConstraint(slider)
    
    # Box C
    shape = BulletBoxShape(Vec3(1, 3, 0.1))
    
    bodyC = BulletRigidBodyNode('Box C')
    bodyC.setRestitution(1.0)
    bodyNP = self.worldNP.attachNewNode(bodyC)
    bodyNP.node().addShape(shape)
    bodyNP.node().setMass(0.1)
    bodyNP.node().setDeactivationEnabled(False)
    bodyNP.setCollideMask(BitMask32.allOn())  
    bodyNP.setPos(Vec3(pos.getX() + 3, pos.getY() - 4, pos.getZ()))
    bodyNP.setHpr(turn)
    
    visNP = loader.loadModel('media/models/box.egg')
    visNP.setScale(Vec3(1, 3, 0.1)*2*scale)
    visNP.clearModelNodes()
    visNP.reparentTo(bodyNP)
    
    self.world.attachRigidBody(bodyC)
    
    bodyNP.node().setLinearVelocity(-100)
    
    # Slider
    frameA = TransformState.makePosHpr(Point3(0, 0, 0), Vec3(0, 0, 0))
    frameB = TransformState.makePosHpr(Point3(0, 0, 0), Vec3(0, 0, 0))
    
    slider = BulletSliderConstraint(bodyA, bodyC, frameA, frameB, True)
    slider.setDebugDrawSize(2.0)
    slider.setLowerLinearLimit(2)
    slider.setUpperLinearLimit(6)
    slider.setLowerAngularLimit(-90)
    slider.setUpperAngularLimit(-85)
    self.world.attachConstraint(slider)
  
  def setupObstacleFour(self, pos, scale, turn):
    #Start Here
    # Box A
    shape = BulletBoxShape(Vec3(0.01, 0.01, 0.01) * scale)
    bodyA = BulletRigidBodyNode('Box A')
    bodyNP = self.worldNP.attachNewNode(bodyA)
    bodyNP.node().addShape(shape)
    bodyNP.setCollideMask(BitMask32.allOn())
    bodyNP.setPos(pos.getX(), pos.getY(), pos.getZ() + 4) #(0, 0, 4)

    visNP = loader.loadModel('media/models/box.egg')
    visNP.setScale(Vec3(0.01, 0.01, 0.01)*2*scale)
    visNP.clearModelNodes()
    visNP.reparentTo(bodyNP)

    self.world.attachRigidBody(bodyA)

    # Box B
    shape = BulletSphereShape(0.5*scale)

    bodyB = BulletRigidBodyNode('Sphere B')
    bodyNP = self.worldNP.attachNewNode(bodyB)
    bodyNP.node().addShape(shape)
    bodyNP.node().setMass(10.0)
    bodyNP.node().setDeactivationEnabled(False)
    bodyNP.setCollideMask(BitMask32.allOn())
    bodyNP.setPos(pos.getX(), pos.getY(), pos.getZ() + 5) #(0, 0, 0.001)

    visNP = loader.loadModel('media/models/ball.egg')
    visNP.clearModelNodes()
    visNP.setScale(1.25*scale)
    visNP.reparentTo(bodyNP)
    
    bodyNP.node().setLinearVelocity(100)

    self.world.attachRigidBody(bodyB)

    # Cone
    frameA = TransformState.makePosHpr(Point3(0, 0, 0), Vec3(0, 0, 90))
    frameB = TransformState.makePosHpr(Point3(2, 0, 0)*scale, Vec3(0, 0, 0))

    cone = BulletConeTwistConstraint(bodyA, bodyB, frameA, frameB)
    cone.setDebugDrawSize(2.0)
    cone.setLimit(30, 90, 270, softness=1.0, bias=0.3, relaxation=10.0)
    self.world.attachConstraint(cone)
    
    # Box C
    shape = BulletBoxShape(Vec3(0.1, 0.1, 1)*scale)

    bodyC = BulletRigidBodyNode('Box C')
    bodyNP = self.worldNP.attachNewNode(bodyC)
    bodyNP.node().addShape(shape)
    bodyNP.node().setDeactivationEnabled(False)
    bodyNP.setCollideMask(BitMask32.allOn())
    bodyNP.setPos(pos.getX(), pos.getY(), pos.getZ() + 3)
    
    self.world.attachRigidBody(bodyC)

    visNP = loader.loadModel('media/models/box.egg')
    visNP.setScale(Vec3(0.1, 0.1, 1)*2*scale)
    visNP.clearModelNodes()
    visNP.reparentTo(bodyNP)
    
  def setupObstacleSix(self, pos, scale, turn):
    #box A
    shape = BulletBoxShape(Vec3(0.1, 0.1, 0.1)*scale)
    
    bodyA = BulletRigidBodyNode('Box A')
    bodyNP= self.worldNP.attachNewNode(bodyA)
    bodyNP.node().addShape(shape)
    bodyNP.setCollideMask(BitMask32.allOff())
    bodyNP.setPos(pos.getX()-2,pos.getY(),pos.getZ()+2.5)#-2,0,2.5)
    bodyNP.setHpr(turn)
    
    # Box B
    shape = BulletBoxShape(Vec3(2, 0.1, 3)*scale)
    
    bodyB = BulletRigidBodyNode('Box B')
    bodyNP = self.worldNP.attachNewNode(bodyB)
    bodyNP.node().addShape(shape)
    bodyNP.node().setMass(1.0)
    bodyNP.node().setLinearDamping(0.5)
    bodyNP.node().setDeactivationEnabled(False)
    bodyNP.setCollideMask(BitMask32.allOn())
    bodyNP.setPos(pos.getX()-3,pos.getY(), pos.getZ())#, 0, 0)
    bodyNP.setHpr(turn)
    
    
    visNP = loader.loadModel('media/models/box.egg')
    visNP.setScale(Vec3(2, 0.1, 3)*2*scale)
    visNP.clearModelNodes()
    visNP.reparentTo(bodyNP)
    
    self.world.attachRigidBody(bodyB)
    
    
    # Hinge
    pivotA = Point3(-2, 0, -3)
    pivotB = Point3(-2, 0, -3)
    axisA = Vec3(0, 0, 1)
    axisB = Vec3(0, 0, 1)
    
    hinge = BulletHingeConstraint(bodyA, bodyB, pivotA, pivotB, axisA, axisB, True)
    hinge.setDebugDrawSize(2.0)
    hinge.setLimit(0,90, softness=1.0, bias=0.3, relaxation=1.0)
    self.world.attachConstraint(hinge)
    
    #box A
    shape = BulletBoxShape(Vec3(0.1, 0.1, 0.1)*scale)
    
    bodyA = BulletRigidBodyNode('Box A')
    bodyNP= self.worldNP.attachNewNode(bodyA)
    bodyNP.node().addShape(shape)
    bodyNP.setCollideMask(BitMask32.allOff())
    bodyNP.setPos(pos.getX()+2,pos.getY(),pos.getZ()+2.5)#2,0,2.5)
    bodyNP.setHpr(turn)
    
    # Box B
    shape = BulletBoxShape(Vec3(2, 0.1, 3)*scale)
    
    bodyB = BulletRigidBodyNode('Box B')
    bodyNP = self.worldNP.attachNewNode(bodyB)
    bodyNP.node().addShape(shape)
    bodyNP.node().setMass(1.0)
    bodyNP.node().setLinearDamping(0.5)
    bodyNP.node().setDeactivationEnabled(False)
    bodyNP.setCollideMask(BitMask32.allOn())
    bodyNP.setPos(pos.getX()+4, pos.getY(), pos.getZ())# 0, 0)
    bodyNP.setHpr(turn)
    
    
    visNP = loader.loadModel('media/models/box.egg')
    visNP.setScale(Vec3(2, 0.1, 3)*2*scale)
    visNP.clearModelNodes()
    visNP.reparentTo(bodyNP)
    
    self.world.attachRigidBody(bodyB)
    
    pivotA = Point3(2, 0, -3)
    pivotB = Point3(2, 0, -3)
    
    hinge = BulletHingeConstraint(bodyA, bodyB, pivotA, pivotB, axisA, axisB, True)
    hinge.setLimit(-90,0, softness=1.0, bias=0.3, relaxation=1.0)
    self.world.attachConstraint(hinge)
    
  def setupObstacleFive(self, pos, scale, turn):
    #box A
    shape = BulletBoxShape(Vec3(3, 0.1, 0.1)*scale)
    
    bodyA = BulletRigidBodyNode('Box A')
    bodyNP= self.worldNP.attachNewNode(bodyA)
    bodyNP.node().addShape(shape)
    bodyNP.setCollideMask(BitMask32.allOn())
    bodyNP.setPos(pos)
    bodyNP.setHpr(turn)
    
    visNP = loader.loadModel('media/models/box.egg')
    visNP.setScale(Vec3(3, 0.1, 0.1)*2*scale)
    visNP.clearModelNodes()
    visNP.reparentTo(bodyNP)
    
    self.world.attachRigidBody(bodyA)
    
    # Box B
    shape = BulletBoxShape(Vec3(3, 2, 0.1)*scale)
    
    bodyB = BulletRigidBodyNode('Box B')
    bodyNP = self.worldNP.attachNewNode(bodyB)
    bodyNP.node().addShape(shape)
    bodyNP.node().setMass(1.0)
    bodyNP.node().setDeactivationEnabled(False)
    bodyNP.setCollideMask(BitMask32.allOn())
    bodyNP.setPos(pos)
    bodyNP.setHpr(turn)
    
    visNP = loader.loadModel('media/models/box.egg')
    visNP.setScale(Vec3(3, 2, 0.1)*2*scale)
    visNP.clearModelNodes()
    visNP.reparentTo(bodyNP)
    
    self.world.attachRigidBody(bodyB)
    
    # Hinge
    pivotA = Point3(0, 0, 0)
    pivotB = Point3(0, 0, 5)
    axisA = Vec3(1, 0, 0)
    axisB = Vec3(1, 0, 0)
    
    hinge = BulletHingeConstraint(bodyA, bodyB, pivotA, pivotB, axisA, axisB, True)
    hinge.setDebugDrawSize(2.0)
    hinge.setLimit(-50,50, softness=0.5, bias=0.3, relaxation=0.6)
    self.world.attachConstraint(hinge)
    
    # Box C
    shape = BulletBoxShape(Vec3(0.1, 0.1, 0.9)*scale)
    
    bodyC = BulletRigidBodyNode('Box C')
    bodyNP = self.worldNP.attachNewNode(bodyC)
    bodyNP.node().addShape(shape)
    bodyNP.node().setMass(1.0)
    bodyNP.node().setDeactivationEnabled(False)
    bodyNP.setCollideMask(BitMask32.allOn())
    bodyNP.setPos(pos)
    bodyNP.setHpr(turn)
    
    visNP = loader.loadModel('media/models/box.egg')
    visNP.setScale(Vec3(0.1, 0.1, 0.9)*2*scale)
    visNP.clearModelNodes()
    visNP.reparentTo(bodyNP)
    
    self.world.attachRigidBody(bodyC)
    
    pivotA = Point3(0, 0, -1.1)
    pivotB = Point3(0, 0, 1)
    
    hinge = BulletHingeConstraint(bodyA, bodyC, pivotA, pivotB, axisA, axisB, True)
    hinge.setLimit(-90,90, softness=1.0, bias=0.3, relaxation=1.0)
    self.world.attachConstraint(hinge)
    
  def setupGoal(self, pos):
      # Goal
      shape = BulletBoxShape(Vec3(1, 1, 1))

      body = BulletRigidBodyNode('Flag')

      self.flagNP = self.worldNP.attachNewNode(body)
      self.flagNP.node().addShape(shape)
      self.flagNP.setCollideMask(BitMask32.allOn())
      self.flagNP.setPos(pos)
      
      visNP = loader.loadModel('media/models/Flag.X')
      visNP.clearModelNodes()
      visNP.reparentTo(self.flagNP)
    
      self.world.attachRigidBody(body)
Exemplo n.º 16
0
class Game(DirectObject):
    def __init__(self):
        base.setBackgroundColor(0.1, 0.1, 0.8, 1)
        base.setFrameRateMeter(True)

        # Light
        alight = AmbientLight('ambientLight')
        alight.setColor(Vec4(0.5, 0.5, 0.5, 1))
        alightNP = render.attachNewNode(alight)

        dlight = DirectionalLight('directionalLight')
        dlight.setDirection(Vec3(1, 1, -1))
        dlight.setColor(Vec4(0.7, 0.7, 0.7, 1))
        dlightNP = render.attachNewNode(dlight)

        render.clearLight()
        render.setLight(alightNP)
        render.setLight(dlightNP)

        # Input
        self.accept('escape', self.doExit)
        self.accept('r', self.doReset)
        self.accept('f1', self.toggleWireframe)
        self.accept('f2', self.toggleTexture)
        self.accept('f3', self.toggleDebug)
        self.accept('f5', self.doScreenshot)

        # ROS
        self.crash_pub = rospy.Publisher('crash',
                                         std_msgs.msg.Empty,
                                         queue_size=100)
        ### subscribers (info sent to Arduino)
        self.cmd_steer_sub = rospy.Subscriber(
            'cmd/steer',
            std_msgs.msg.Float32,
            callback=self._cmd_steer_callback)
        self.cmd_motor_sub = rospy.Subscriber(
            'cmd/motor',
            std_msgs.msg.Float32,
            callback=self._cmd_motor_callback)
        self.cmd_vel_sub = rospy.Subscriber('cmd/vel',
                                            std_msgs.msg.Float32,
                                            callback=self._cmd_vel_callback)
        self.reset_sub = rospy.Subscriber('reset',
                                          std_msgs.msg.Empty,
                                          callback=self._reset_callback)
        self.cmd_steer_queue = Queue.Queue(maxsize=1)
        self.cmd_motor_queue = Queue.Queue(maxsize=1)
        # Task
        taskMgr.add(self.update, 'updateWorld')
        # Physics
        self.setup()
        print('Starting ROS thread')
        threading.Thread(target=self._ros_servos_thread).start()
        threading.Thread(target=self._ros_crash_thread).start()
        threading.Thread(target=self._ros_image_thread).start()

    # Callbacks

    def _cmd_steer_callback(self, msg):
        if msg.data >= 0 and msg.data <= 99.0:
            self.cmd_steer_queue.put(msg.data)

    def _cmd_motor_callback(self, msg):
        if msg.data >= 0 and msg.data <= 99.0:
            self.cmd_motor_queue.put(msg.data)

    def _cmd_vel_callback(self, msg):
        data = numpy.clip(msg.data * 3 + 49.5, 0, 99.0)
        self.cmd_motor_queue.put(data)

    def _reset_callback(self, msg):
        self.doReset()

    # ROS thread

    def _ros_servos_thread(self):
        """
        Publishes/subscribes to Ros.
        """
        self.steering = 0.0  # degree
        self.steeringClamp = rospy.get_param('~steeringClamp')
        self.engineForce = 0.0
        self.engineClamp = rospy.get_param('~engineClamp')
        r = rospy.Rate(60)
        while not rospy.is_shutdown():
            r.sleep()
            for var, queue in (('steer', self.cmd_steer_queue),
                               ('motor', self.cmd_motor_queue)):
                if not queue.empty():
                    try:
                        if var == 'steer':
                            self.steering = self.steeringClamp * (
                                (queue.get() - 49.5) / 49.5)
                            self.vehicle.setSteeringValue(self.steering, 0)
                            self.vehicle.setSteeringValue(self.steering, 1)
                        elif var == 'motor':
                            self.vehicle.setBrake(100.0, 2)
                            self.vehicle.setBrake(100.0, 3)
                            self.engineForce = self.engineClamp * (
                                (queue.get() - 49.5) / 49.5)
                            self.vehicle.applyEngineForce(self.engineForce, 2)
                            self.vehicle.applyEngineForce(self.engineForce, 3)
                    except Exception as e:
                        print(e)

    def _ros_crash_thread(self):
        crash = 0
        r = rospy.Rate(30)
        while not rospy.is_shutdown():
            r.sleep()
            try:
                result = self.world.contactTest(self.vehicle_node)
                if result.getNumContacts() > 0:
                    self.crash_pub.publish(std_msgs.msg.Empty())
            except Exception as e:
                print(e)

    def _ros_image_thread(self):
        camera_pub = ImageROSPublisher("image")
        depth_pub = ImageROSPublisher("depth")
        r = rospy.Rate(30)
        i = 0
        while not rospy.is_shutdown():
            r.sleep()
            # sometimes fails to observe
            try:
                obs = self.camera_sensor.observe()
                camera_pub.publish_image(obs[0])
                depth_pub.publish_image(obs[1], image_format="passthrough")
            except:
                pass

    # _____HANDLER_____

    def doExit(self):
        self.cleanup()
        sys.exit(1)

    def doReset(self):
        self.cleanup()
        self.setup()

    def toggleWireframe(self):
        base.toggleWireframe()

    def toggleTexture(self):
        base.toggleTexture()

    def toggleDebug(self):
        if self.debugNP.isHidden():
            self.debugNP.show()
        else:
            self.debugNP.hide()

    def doScreenshot(self):
        base.screenshot('Bullet')

    # ____TASK___

    def update(self, task):
        dt = globalClock.getDt()

        self.world.doPhysics(dt, 10, 0.008)

        #print self.vehicle.getWheel(0).getRaycastInfo().isInContact()
        #print self.vehicle.getWheel(0).getRaycastInfo().getContactPointWs()

        #print self.vehicle.getChassis().isKinematic()

        return task.cont

    def cleanup(self):
        self.world = None
        self.worldNP.removeNode()

    def setup(self):
        self.worldNP = render.attachNewNode('World')

        # World
        self.debugNP = self.worldNP.attachNewNode(BulletDebugNode('Debug'))

        self.world = BulletWorld()
        self.world.setGravity(Vec3(0, 0, -9.81))
        self.world.setDebugNode(self.debugNP.node())

        # Plane
        shape = BulletPlaneShape(Vec3(0, 0, 1), 0)

        np = self.ground = self.worldNP.attachNewNode(
            BulletRigidBodyNode('Ground'))
        np.node().addShape(shape)
        np.setPos(0, 0, -1)
        np.setCollideMask(BitMask32.allOn())

        self.world.attachRigidBody(np.node())

        # collision
        self.maze = []
        for pos in [(0.0, 72.0, 0.0), (-11.0, 60.0, 0.0), (11.0, 60.0, 0.0),
                    (-11.0, 48.0, 0.0), (11.0, 48.0, 0.0), (-11.0, 36.0, 0.0),
                    (11.0, 36.0, 0.0), (-11.0, 24.0, 0.0), (11.0, 24.0, 0.0),
                    (-11.0, 12.0, 0.0), (11.0, 12.0, 0.0), (-11.0, 0.0, 0.0),
                    (11.0, 0.0, 0.0), (0.0, -12.0, 0.0), (0.5, 12.0, 1.0),
                    (-0.5, 12.0, 1.0)]:
            translate = False
            if (abs(pos[0]) == 0.5):
                translate = True
                visNP = loader.loadModel('../models/ball.egg')
            else:
                visNP = loader.loadModel('../models/maze.egg')
            visNP.clearModelNodes()
            visNP.reparentTo(self.ground)
            visNP.setPos(pos[0], pos[1], pos[2])

            bodyNPs = BulletHelper.fromCollisionSolids(visNP, True)
            for bodyNP in bodyNPs:
                bodyNP.reparentTo(render)
                if translate:
                    bodyNP.setPos(pos[0], pos[1], pos[2] - 1)
                else:
                    bodyNP.setPos(pos[0], pos[1], pos[2])

                if isinstance(bodyNP.node(), BulletRigidBodyNode):
                    bodyNP.node().setMass(0.0)
                    bodyNP.node().setKinematic(True)
                    self.maze.append(bodyNP)

        for bodyNP in self.maze:
            self.world.attachRigidBody(bodyNP.node())
        # Chassis
        mass = rospy.get_param('~mass')
        #chassis_shape = rospy.get_param('~chassis_shape')
        shape = BulletBoxShape(Vec3(0.6, 1.4, 0.5))
        ts = TransformState.makePos(Point3(0, 0, 0.5))

        np = self.worldNP.attachNewNode(BulletRigidBodyNode('Vehicle'))
        np.node().addShape(shape, ts)
        rand_vals = numpy.random.random(2) * 8 - 4.0
        np.setPos(rand_vals[0], 0.0, -0.6)
        np.node().setMass(mass)
        np.node().setDeactivationEnabled(False)

        first_person = rospy.get_param('~first_person')
        self.camera_sensor = Panda3dCameraSensor(base,
                                                 color=True,
                                                 depth=True,
                                                 size=(160, 90))

        self.camera_node = self.camera_sensor.cam
        if first_person:
            self.camera_node.reparentTo(np)
            self.camera_node.setPos(0.0, 1.0, 1.0)
            self.camera_node.lookAt(0.0, 6.0, 0.0)
        else:
            self.camera_node.reparentTo(np)
            self.camera_node.setPos(0.0, -10.0, 5.0)
            self.camera_node.lookAt(0.0, 5.0, 0.0)
        base.cam.reparentTo(np)
        base.cam.setPos(0.0, -10.0, 5.0)
        base.cam.lookAt(0.0, 5.0, 0.0)
        self.world.attachRigidBody(np.node())

        np.node().setCcdSweptSphereRadius(1.0)
        np.node().setCcdMotionThreshold(1e-7)

        # Vehicle
        self.vehicle_node = np.node()
        self.vehicle = BulletVehicle(self.world, np.node())
        self.vehicle.setCoordinateSystem(ZUp)
        self.world.attachVehicle(self.vehicle)

        self.yugoNP = loader.loadModel('../models/yugo/yugo.egg')
        self.yugoNP.reparentTo(np)

        # Right front wheel
        np = loader.loadModel('../models/yugo/yugotireR.egg')
        np.reparentTo(self.worldNP)
        self.addWheel(Point3(0.70, 1.05, 0.3), True, np)

        # Left front wheel
        np = loader.loadModel('../models/yugo/yugotireL.egg')
        np.reparentTo(self.worldNP)
        self.addWheel(Point3(-0.70, 1.05, 0.3), True, np)

        # Right rear wheel
        np = loader.loadModel('../models/yugo/yugotireR.egg')
        np.reparentTo(self.worldNP)
        self.addWheel(Point3(0.70, -1.05, 0.3), False, np)

        # Left rear wheel
        np = loader.loadModel('../models/yugo/yugotireL.egg')
        np.reparentTo(self.worldNP)
        self.addWheel(Point3(-0.70, -1.05, 0.3), False, np)

        # Collision handle
        #base.cTrav = CollisionTraverser()
        #self.notifier = CollisionHandlerEvent()
        #self.notifier.addInPattern("%fn")
        #self.accept("Vehicle", self.onCollision)

    def onCollision(self):
        print("crash")

    def addWheel(self, pos, front, np):
        wheel = self.vehicle.createWheel()

        wheel.setNode(np.node())
        wheel.setChassisConnectionPointCs(pos)
        wheel.setFrontWheel(front)

        wheel.setWheelDirectionCs(Vec3(0, 0, -1))
        wheel.setWheelAxleCs(Vec3(1, 0, 0))
        wheel.setWheelRadius(0.25)
        wheel.setMaxSuspensionTravelCm(40.0)

        wheel.setSuspensionStiffness(40.0)
        wheel.setWheelsDampingRelaxation(2.3)
        wheel.setWheelsDampingCompression(4.4)
        wheel.setFrictionSlip(1e3)
        wheel.setRollInfluence(0.0)
Exemplo n.º 17
0
class CarSrv(DirectObject):
    def __init__(self):
        base.setBackgroundColor(0.1, 0.1, 0.8, 1)
        assert ("offscreen" == base.config.GetString("window-type",
                                                     "offscreen"))

        # Light
        alight = AmbientLight('ambientLight')
        alight.setColor(Vec4(0.5, 0.5, 0.5, 1))
        alightNP = render.attachNewNode(alight)

        dlight = DirectionalLight('directionalLight')
        dlight.setDirection(Vec3(1, 1, -1))
        dlight.setColor(Vec4(0.7, 0.7, 0.7, 1))
        dlightNP = render.attachNewNode(dlight)

        render.clearLight()
        render.setLight(alightNP)
        render.setLight(dlightNP)

        # Input
        self.accept('escape', self.doExit)
        self.accept('r', self.doReset)
        self.accept('f1', self.toggleWireframe)
        self.accept('f2', self.toggleTexture)
        self.accept('f3', self.toggleDebug)
        self.accept('f5', self.doScreenshot)

        self.params = rospy.get_param('~sim')
        # Car Simulator
        self.dt = rospy.get_param('~dt')
        self.setup()
        self.load_vehicle()

        # ROS
        self.crash_pub = rospy.Publisher('crash',
                                         std_msgs.msg.Empty,
                                         queue_size=1)
        self.bridge = cv_bridge.CvBridge()
        #        taskMgr.add(self.update, 'updateWorld')
        self.start_update_server()

    # _____HANDLER_____

    def doExit(self):
        self.cleanup()
        sys.exit(1)

    def doReset(self, pos=None, quat=None):
        self.cleanup()
        self.setup()
        if pos is None or quat is None:
            self.load_vehicle()
        else:
            self.load_vehicle(pos=pos, quat=quat)

    def toggleWireframe(self):
        base.toggleWireframe()

    def toggleTexture(self):
        base.toggleTexture()

    def toggleDebug(self):
        if self.debugNP.isHidden():
            self.debugNP.show()
        else:
            self.debugNP.hide()

    def doScreenshot(self):
        base.screenshot('Bullet')

    def get_ros_image(self, cv_image, image_format="rgb8"):
        return self.bridge.cv2_to_imgmsg(cv_image, image_format)

    def get_handler(self):
        def sim_env_handler(req):
            start_time = time.time()
            cmd_steer = req.steer
            motor = req.motor
            vel = req.vel
            reset = req.reset
            pose = req.pose
            # If motor is default then use velocity
            if motor == 0.0:
                cmd_motor = numpy.clip(vel * 3 + 49.5, 0., 99.)
            else:
                cmd_motor = numpy.clip(motor, 0., 99.)

            self.steering = self.steeringClamp * \
                ((cmd_steer - 49.5) / 49.5)
            self.engineForce = self.engineClamp * \
                ((cmd_motor - 49.5) / 49.5)

            if reset:
                self.steering = 0.0  # degree
                self.engineForce = 0.0
                pos = pose.position.x, pose.position.y, pose.position.z
                quat = pose.orientation.x, pose.orientation.y, pose.orientation.z, pose.orientation.w
                if numpy.all(numpy.array(pos) == 0.):
                    self.doReset()
                else:
                    self.doReset(pos=pos, quat=quat)

            self.vehicle.setSteeringValue(self.steering, 0)
            self.vehicle.setSteeringValue(self.steering, 1)
            self.vehicle.setBrake(100.0, 2)
            self.vehicle.setBrake(100.0, 3)
            self.vehicle.applyEngineForce(self.engineForce, 2)
            self.vehicle.applyEngineForce(self.engineForce, 3)

            pos = numpy.array(self.vehicle_pointer.getPos())
            np_quat = self.vehicle_pointer.getQuat()
            quat = numpy.array(np_quat)
            self.previous_pos = pos
            self.previous_quat = np_quat

            # TODO maybe change number of timesteps
            self.world.doPhysics(self.dt, 10, 0.05)
            # Collision detection
            result = self.world.contactTest(self.vehicle_node)
            collision = result.getNumContacts() > 0

            if collision:
                # TODO figure out why this causes problems
                #                self.crash_pub.publish(std_msgs.msg.Empty())
                self.doReset(pos=self.previous_pos, quat=self.previous_quat)

            state = geometry_msgs.msg.Pose()
            pos = numpy.array(self.vehicle_pointer.getPos())
            np_quat = self.vehicle_pointer.getQuat()
            quat = numpy.array(np_quat)
            self.previous_pos = pos
            self.previous_quat = np_quat
            state.position.x, state.position.y, state.position.z = pos
            state.orientation.x, state.orientation.y, \
                    state.orientation.z, state.orientation.w = quat

            # Get observation
            obs = self.camera_sensor.observe()
            back_obs = self.back_camera_sensor.observe()
            cam_image = self.get_ros_image(obs[0])
            cam_depth = self.get_ros_image(obs[1], image_format="passthrough")
            self.camera_pub.publish_image(obs[0])
            self.depth_pub.publish_image(obs[1], image_format="passthrough")
            back_cam_image = self.get_ros_image(back_obs[0])
            back_cam_depth = self.get_ros_image(back_obs[1],
                                                image_format="passthrough")
            self.back_camera_pub.publish_image(back_obs[0])
            self.back_depth_pub.publish_image(back_obs[1],
                                              image_format="passthrough")
            return [
                collision, cam_image, cam_depth, back_cam_image,
                back_cam_depth, state
            ]

        return sim_env_handler

    def load_vehicle(self, pos=(0.0, -20.0, -0.6), quat=None):
        # Chassis
        self._mass = self.params['mass']
        #chassis_shape = self.params['chassis_shape']
        shape = BulletBoxShape(Vec3(0.6, 1.4, 0.5))
        ts = TransformState.makePos(Point3(0, 0, 0.5))

        self.vehicle_pointer = self.worldNP.attachNewNode(
            BulletRigidBodyNode('Vehicle'))
        self.vehicle_node = self.vehicle_pointer.node()
        self.vehicle_node.addShape(shape, ts)
        self.previous_pos = pos
        self.vehicle_pointer.setPos(pos[0], pos[1], pos[2])
        if quat is not None:
            self.vehicle_pointer.setQuat(quat)
        self.previous_quat = self.vehicle_pointer.getQuat()
        self.vehicle_node.setMass(self._mass)
        self.vehicle_node.setDeactivationEnabled(False)

        #        first_person = self.params['first_person']
        self.camera_sensor = Panda3dCameraSensor(base,
                                                 color=True,
                                                 depth=True,
                                                 size=(160, 90))

        self.camera_node = self.camera_sensor.cam
        #        if first_person:
        #            self.camera_node.setPos(0.0, 1.0, 1.0)
        #            self.camera_node.lookAt(0.0, 6.0, 0.0)
        #        else:
        #            self.camera_node.setPos(0.0, -10.0, 5.0)
        #            self.camera_node.lookAt(0.0, 5.0, 0.0)

        self.camera_node.reparentTo(self.vehicle_pointer)
        self.camera_node.setPos(0.0, 1.0, 1.0)
        self.camera_node.lookAt(0.0, 6.0, 0.0)

        self.back_camera_sensor = Panda3dCameraSensor(base,
                                                      color=True,
                                                      depth=True,
                                                      size=(160, 90))

        self.back_camera_node = self.back_camera_sensor.cam
        #        if first_person:
        #            self.camera_node.setPos(0.0, 1.0, 1.0)
        #            self.camera_node.lookAt(0.0, 6.0, 0.0)
        #        else:
        #            self.camera_node.setPos(0.0, -10.0, 5.0)
        #            self.camera_node.lookAt(0.0, 5.0, 0.0)

        self.back_camera_node.reparentTo(self.vehicle_pointer)
        self.back_camera_node.setPos(0.0, -1.0, 1.0)
        self.back_camera_node.lookAt(0.0, -6.0, 0.0)

        self.world.attachRigidBody(self.vehicle_node)

        self.vehicle_node.setCcdSweptSphereRadius(1.0)
        self.vehicle_node.setCcdMotionThreshold(1e-7)

        # Vehicle
        self.vehicle = BulletVehicle(self.world, self.vehicle_node)
        self.vehicle.setCoordinateSystem(ZUp)
        self.world.attachVehicle(self.vehicle)

        self.yugoNP = loader.loadModel('../models/yugo/yugo.egg')
        self.yugoNP.reparentTo(self.vehicle_pointer)

        self._wheels = []
        # Right front wheel
        np = loader.loadModel('../models/yugo/yugotireR.egg')
        np.reparentTo(self.worldNP)
        self.addWheel(Point3(0.70, 1.05, 0.3), True, np)
        # Left front wheel
        np = loader.loadModel('../models/yugo/yugotireL.egg')
        np.reparentTo(self.worldNP)
        self.addWheel(Point3(-0.70, 1.05, 0.3), True, np)
        # Right rear wheel
        np = loader.loadModel('../models/yugo/yugotireR.egg')
        np.reparentTo(self.worldNP)
        self.addWheel(Point3(0.70, -1.05, 0.3), False, np)
        # Left rear wheel
        np = loader.loadModel('../models/yugo/yugotireL.egg')
        np.reparentTo(self.worldNP)
        self.addWheel(Point3(-0.70, -1.05, 0.3), False, np)

    def addWheel(self, pos, front, np):
        wheel = self.vehicle.createWheel()

        wheel.setNode(np.node())
        wheel.setChassisConnectionPointCs(pos)
        wheel.setFrontWheel(front)

        wheel.setWheelDirectionCs(Vec3(0, 0, -1))
        wheel.setWheelAxleCs(Vec3(1, 0, 0))
        wheel.setWheelRadius(0.25)
        wheel.setMaxSuspensionTravelCm(40.0)

        wheel.setSuspensionStiffness(40.0)
        wheel.setWheelsDampingRelaxation(2.3)
        wheel.setWheelsDampingCompression(4.4)
        wheel.setFrictionSlip(1e3)
        wheel.setRollInfluence(0.0)
        self._wheels.append(np.node())

    def start_update_server(self):
        self.steering = 0.0  # degree
        self.steeringClamp = self.params['steeringClamp']
        self.engineForce = 0.0
        self.engineClamp = self.params['engineClamp']
        self.camera_pub = ImageROSPublisher("image")
        self.depth_pub = ImageROSPublisher("depth")
        self.back_camera_pub = ImageROSPublisher("back_image")
        self.back_depth_pub = ImageROSPublisher("back_depth")
        s = rospy.Service('sim_env', bair_car.srv.sim_env, self.get_handler())
        rospy.spin()

    def update(self, task):
        dt = globalClock.getDt()

        self.world.doPhysics(dt, 10, 0.008)
        obs = self.camera_sensor.observe()
        obs = self.back_camera_sensor.observe()
        return task.cont

    def cleanup(self):
        self.world = None
        self.worldNP.removeNode()

    @abc.abstractmethod
    def setup(self):
        pass
Exemplo n.º 18
0
class Vehicle(object):
    COUNT = 0

    def __init__(self, bulletWorld, pos, username):
        self.world = bulletWorld
        self.acceleration = 1.5
        self.brakeForce = 100.0
        self.mass = 800
        self.max_speed = 150
        self.reverse_limit = -40
        self.mass = 800.0  # kg
        self.max_speed = 150  # km
        self.armor = 100
        self.health = 100
        self.friction = 0.2 #slows the car when not accelerating (based on the brakes)
        self.maxWheelForce = 2000.0
        self.maxWheelForce = 2000.0  # acceleration
        self.power_ups = [0, 0, 0]

        self.specs = {"mass": self.mass, "maxWheelForce": self.maxWheelForce, "brakeForce": self.brakeForce,
                      "steeringLock": 20.0}
        self.vehicleControlState = {"throttle": 0, "reverse": False, "brake": 0.0, "steering": 0.0}
        self.username = username
        # Steering change per second, normalised to steering lock
        # Eg. 45 degrees lock and 1.0 rate means 45 degrees per second
        self.steeringRate = 0.7
        self.centreingRate = 5.0

        self.pos = pos

        self.currentPowerups = {"powerup1": None, "powerup2": None, "powerup3": None}

        self.setupVehicle(bulletWorld)

        COUNT = 1

    def processInput(self, inputState, dt):
        # print self.chassisNP.getPos()
        # print self.chassisNP.getH()
        """Use controls to update the player's car"""
        # For keyboard throttle and brake are either 0 or 1
        if inputState.isSet('forward') and self.vehicle.getCurrentSpeedKmHour() <= self.max_speed:
            self.vehicleControlState["throttle"] = 1.0
        else:
            self.vehicleControlState["throttle"] = 0.0

        velocity = self.chassisNode.getLinearVelocity()
        speed = math.sqrt(sum(v ** 2 for v in velocity))
        # Update braking and reversing
        if inputState.isSet('brake'):
            if speed < 0.5 or self.vehicleControlState["reverse"]:
                # If we're stopped, then start reversing
                # Also keep reversing if we already were
                self.vehicleControlState["reverse"] = True
                self.vehicleControlState["throttle"] = 1.0
                self.vehicleControlState["brake"] = 0.0
            else:
                self.vehicleControlState["reverse"] = False
                self.vehicleControlState["brake"] = 1.0
        else:
            self.vehicleControlState["reverse"] = False
            self.vehicleControlState["brake"] = 0.0

        # steering is normalised from -1 to 1, corresponding
        # to the steering lock right and left
        steering = self.vehicleControlState["steering"]
        if inputState.isSet('left'):
            steering += dt * self.steeringRate
            steering = min(steering, 1.0)
        elif inputState.isSet('right'):
            steering -= dt * self.steeringRate
            steering = max(steering, -1.0)
        else:
            # gradually re-center the steering
            if steering > 0.0:
                steering -= dt * self.centreingRate
                if steering < 0.0:
                    steering = 0.0
            elif steering < 0.0:
                steering += dt * self.centreingRate
                if steering > 0.0:
                    steering = 0.0
        self.vehicleControlState["steering"] = steering

        # """Updates acceleration, braking and steering
        # These are all passed in through a controlState dictionary
        # """
        # Update acceleration and braking
        wheelForce = self.vehicleControlState["throttle"] * self.specs["maxWheelForce"]
        self.reversing = self.vehicleControlState["reverse"]
        if self.reversing:
            # Make reversing a bit slower than moving forward
            wheelForce *= -0.5

        brakeForce = self.vehicleControlState["brake"] * self.specs["brakeForce"]

        #slows down vehicle when no key pressed
        if self.vehicleControlState["throttle"] != 1.0 and  self.vehicleControlState["reverse"] != 1.0 and self.vehicleControlState["brake"] != 1.0:
            brakeForce = self.friction * self.specs["brakeForce"]

        # Update steering
        # Steering control state is from -1 to 1
        steering = self.vehicleControlState["steering"] * self.specs["steeringLock"]

        # Apply steering to front wheels
        self.vehicle.setSteeringValue(steering, 0);
        self.vehicle.setSteeringValue(steering, 1);
        # Apply engine and brake to rear wheels
        self.vehicle.applyEngineForce(wheelForce, 2);
        self.vehicle.applyEngineForce(wheelForce, 3);
        self.vehicle.setBrake(brakeForce, 2);
        self.vehicle.setBrake(brakeForce, 3);

    def setupVehicle(self, bulletWorld):
        # Chassis
        shape = BulletBoxShape(Vec3(1, 2.2, 0.5))
        ts = TransformState.makePos(Point3(0, 0, .7))
        self.chassisNode = BulletRigidBodyNode('Vehicle')
        self.chassisNP = render.attachNewNode(self.chassisNode)
        self.chassisNP.node().addShape(shape, ts)
        self.chassisNP.node().notifyCollisions(True)
        self.chassisNP.setPosHpr(self.pos[0], self.pos[1], self.pos[2], self.pos[3], self.pos[4], self.pos[5])
        # self.chassisNP.setPos(-5.34744, 114.773, 6)
        # self.chassisNP.setPos(49.2167, 64.7968, 10)
        self.chassisNP.node().setMass(800.0)
        self.chassisNP.node().setDeactivationEnabled(False)

        bulletWorld.attachRigidBody(self.chassisNP.node())

        # np.node().setCcdSweptSphereRadius(1.0)
        # np.node().setCcdMotionThreshold(1e-7)

        # Vehicle
        self.vehicle = BulletVehicle(bulletWorld, self.chassisNP.node())
        self.vehicle.setCoordinateSystem(ZUp)
        bulletWorld.attachVehicle(self.vehicle)

        self.carNP = loader.loadModel('models/batmobile-chassis.egg')
        # self.yugoNP.setScale(.7)
        self.carNP.reparentTo(self.chassisNP)

        # Right front wheel
        np = loader.loadModel('models/batmobile-wheel-right.egg')
        np.reparentTo(render)
        self.addWheel(Point3(1, 1.1, .7), True, np)

        # Left front wheel
        np = loader.loadModel('models/batmobile-wheel-left.egg')
        np.reparentTo(render)
        self.addWheel(Point3(-1, 1.1, .7), True, np)

        # Right rear wheel
        np = loader.loadModel('models/batmobile-wheel-right.egg')
        np.reparentTo(render)
        self.addWheel(Point3(1, -2, .7), False, np)

        # Left rear wheel
        np = loader.loadModel('models/batmobile-wheel-left.egg')
        np.reparentTo(render)
        self.addWheel(Point3(-1, -2, .7), False, np)

    def addWheel(self, pos, front, np):
        wheel = self.vehicle.createWheel()

        wheel.setNode(np.node())
        wheel.setChassisConnectionPointCs(pos)
        wheel.setFrontWheel(front)

        wheel.setWheelDirectionCs(Vec3(0, 0, -1))
        wheel.setWheelAxleCs(Vec3(1, 0, 0))
        wheel.setWheelRadius(0.33)
        wheel.setMaxSuspensionTravelCm(40.0)

        wheel.setSuspensionStiffness(40.0)
        wheel.setWheelsDampingRelaxation(2.3)
        wheel.setWheelsDampingCompression(4.4)
        wheel.setFrictionSlip(100.0);
        wheel.setRollInfluence(0.1)

    def reset(self):
        self.chassisNP.setP(0)
        self.chassisNP.setR(0)

    def pickedPowerup(self, powerup):
        if not powerup.pickable:
            powerup.useAbility()
        else:
            if self.currentPowerups["powerup1"] is None:
                self.currentPowerups["powerup1"] = powerup
            elif self.currentPowerups["powerup2"] is None:
                self.currentPowerups["powerup2"] = powerup
            elif self.currentPowerups["powerup3"] is None:
                self.currentPowerups["powerup3"] = powerup

    def canPickUpPowerup(self):
        return (self.currentPowerups["powerup1"] is None or
                self.currentPowerups["powerup2"] is None or
                self.currentPowerups["powerup3"] is None)

    def usePowerup(self, powerupIndex):
        # Move usePowerupN to this function
        if powerupIndex == 0 and self.currentPowerups["powerup1"] is not None:
            self.currentPowerups["powerup1"].useAbility()
            self.currentPowerups["powerup1"] = None
        elif powerupIndex == 1 and self.currentPowerups["powerup2"] is not None:
            self.currentPowerups["powerup2"].useAbility()
            self.currentPowerups["powerup2"] = None
        elif powerupIndex == 2 and self.currentPowerups["powerup3"] is not None:
            self.currentPowerups["powerup3"].useAbility()
            self.currentPowerups["powerup3"] = None
Exemplo n.º 19
0
class RoadRally(ShowBase):
    def __init__(self):
        ShowBase.__init__(self)

        scene = BulletWorld()
        scene.setGravity(Vec3(0, 0, -9.81))
        base.setBackgroundColor(0.6, 0.9, 0.9)

        #Variables
        self.steering = 0

        #Controls
        inputState.watchWithModifiers("F", "arrow_up")
        inputState.watchWithModifiers("B", "arrow_down")
        inputState.watchWithModifiers("L", "arrow_left")
        inputState.watchWithModifiers("R", "arrow_right")

        #The ground
        self.ground = BulletPlaneShape(Vec3(
            0,
            0,
            1,
        ), 1)
        self.ground_node = BulletRigidBodyNode("The ground")
        self.ground_node.addShape(self.ground)
        self.ground_np = render.attachNewNode(self.ground_node)
        self.ground_np.setPos(0, 0, -2)
        scene.attachRigidBody(self.ground_node)

        self.track_model = loader.loadModel("Models/Track.egg")
        self.track_model.reparentTo(self.render)
        self.track_model.setPos(0, 0, -7)
        self.track_tex = loader.loadTexture("Textures/Road.jpg")
        self.track_model.setTexture(self.track_tex, 1)

        #The car
        Car_shape = BulletBoxShape(Vec3(1, 2.0, 1.0))
        Car_node = BulletRigidBodyNode("The Car")
        Car_node.setMass(1200.0)
        Car_node.addShape(Car_shape)
        Car_np = render.attachNewNode(Car_node)
        Car_np.setPos(0, 0, 0)
        Car_np.setHpr(0, 0, 0)
        Car_np.node().setDeactivationEnabled(False)
        scene.attachRigidBody(Car_node)

        #Load and transform the Car Actor
        self.car_model = loader.loadModel("Models/Car.egg")
        self.car_model.setPos(0, 20, -3)
        self.car_model.setHpr(180, 0, 0)
        self.car_model.reparentTo(Car_np)

        self.Car_sim = BulletVehicle(scene, Car_np.node())
        self.Car_sim.setCoordinateSystem(ZUp)
        scene.attachVehicle(self.Car_sim)

        #Camera
        #base.disableMouse()
        camera.reparentTo(Car_np)
        camera.setPos(0, 0, 0)
        camera.setHpr(0, 0, 0)

        def Wheel(pos, r, f):
            w = self.Car_sim.createWheel()
            w.setChassisConnectionPointCs(pos)
            w.setFrontWheel(f)
            w.setWheelDirectionCs(Vec3(0, 0, -1))
            w.setWheelAxleCs(Vec3(1, 0, 0))
            w.setWheelRadius(r)
            w.setMaxSuspensionTravelCm(40)
            w.setSuspensionStiffness(120)
            w.setWheelsDampingRelaxation(2.3)
            w.setWheelsDampingCompression(4.4)
            w.setFrictionSlip(50)
            w.setRollInfluence(0.1)

        #Wheels
        Wheel(Point3(-1, 1, -0.6), 0.4, False)
        Wheel(Point3(-1.1, -1.2, -0.6), 0.4, True)
        Wheel(Point3(1.1, -1, -0.6), 0.4, True)
        Wheel(Point3(1, 1, -0.6), 0.4, False)

        def ProcessInput(dt):

            engineForce = 0.0
            self.steeringClamp = 35.0
            self.steeringIncrement = 70

            #Get the vehicle's current speed
            self.carspeed = self.Car_sim.getCurrentSpeedKmHour()

            #Reset the steering
            if not inputState.isSet("L") and not inputState.isSet("R"):

                if self.steering < 0.00:
                    self.steering = self.steering + 0.6
                    if self.steering > 0.00:
                        self.steering = self.steering - 0.6

                    if self.steering < 1.0 and self.steering > -1.0:
                        self.steering = 0

            if inputState.isSet("F"):
                engineForce = 35

            if inputState.isSet("B"):
                engineForce = -35

            #Left
            if inputState.isSet("L"):
                if self.steering < 0.0:
                    #This makes the steering reset at the correct speed when turning from right to left
                    self.steering += dt * self.steeringIncrement + 0.6
                    self.steering = min(self.steering, self.steeringClamp)
                else:
                    #Normal steering
                    self.steering += dt * self.steeringIncrement
                    self.steering = min(self.steering, self.steeringClamp)

#Right
            if inputState.isSet("R"):
                if self.steering > 0.0:
                    #This makes the steering reset at the correct speed when turning from left to right
                    self.steering -= dt * self.steeringIncrement + 0.6
                    self.steering = max(self.steering, -self.steeringClamp)
                else:
                    #Normal steering
                    self.steering -= dt * self.steeringIncrement
                    self.steering = max(self.steering, -self.steeringClamp)

            #Apply forces to wheels
            self.Car_sim.applyEngineForce(engineForce, 0)
            self.Car_sim.applyEngineForce(engineForce, 3)

        def Update(task):
            dt = globalClock.getDt()
            ProcessInput(dt)
            scene.doPhysics(dt, 5, 1.0 / 180.0)
            return task.cont

        taskMgr.add(Update, "Update")