def _setupEyetracking(self): """ sets up eye tracking""" try: eyetrackerip = "DESKTOP-EE5KKDO" eyetrackerport = 10000 trackeyepos = False from aibs.Eyetracking.EyetrackerClient import Client self.eyetracker = Client(outgoing_ip=eyetrackerip, outgoing_port=eyetrackerport, output_filename=str(datetime.datetime.now()).replace(':','').replace('.','').replace(' ','-')) self.eyetracker.setup() # eyedatalog = [] # if trackeyepos: # eyeinitpos = None except: print("Could not initialize eyetracker:") self.eyetracker = None
class MouseTunnel(ShowBase): def __init__(self): # Initialize the ShowBase class from which we inherit, which will # create a window and set up everything we need for rendering into it. ShowBase.__init__(self) self.stimtype = 'image_sequence' #session_start self.session_start_time = datetime.datetime.now() # self.accept("escape", sys.exit, [0])#don't let the user do this, because then the data isn't saved. self.accept('q', self.close) self.accept('Q', self.close) self.AUTO_REWARD = AUTO_REWARD # disable mouse control so that we can place the camera base.disableMouse() camera.setPosHpr(0, 0, 10, 0, -90, 0) mat = Mat4(camera.getMat()) mat.invertInPlace() base.mouseInterfaceNode.setMat(mat) # base.enableMouse() props = WindowProperties() # props.setFullscreen(True) props.setOrigin(-924, 70) # props.setSize(1880,1040) props.setCursorHidden(True) props.setMouseMode(WindowProperties.M_relative) base.win.requestProperties(props) base.setBackgroundColor(0, 0, 0) # set the background color to black #set up the textures # we now get buffer thats going to hold the texture of our new scene altBuffer = self.win.makeTextureBuffer("hello", 1524, 1024) # altBuffer.getDisplayRegion(0).setDimensions(0.5,0.9,0.5,0.8) # altBuffer = base.win.makeDisplayRegion() # altBuffer.makeDisplayRegion(0,1,0,1) # now we have to setup a new scene graph to make this scene self.dr2 = base.win.makeDisplayRegion(0, 0.1, 0, 0.1) altRender = NodePath("new render") # this takes care of setting up ther camera properly self.altCam = self.makeCamera(altBuffer) self.dr2.setCamera(self.altCam) self.altCam.reparentTo(altRender) self.altCam.setPos(0, -10, 0) self.bufferViewer.setPosition("llcorner") # self.bufferViewer.position = (.1,.4,.1,.4) self.bufferViewer.setCardSize(1.0, 0.0) print(self.bufferViewer.position) self.imagesTexture = MovieTexture("image_sequence") # success = self.imagesTexture.read("models/natural_images.avi") success = self.imagesTexture.read("models/movie_5hz.mpg") self.imagesTexture.setPlayRate(1.0) self.imagesTexture.setLoopCount(10) # self.imageTexture =loader.loadTexture("models/NaturalImages/BSDs_8143.tiff") # self.imagesTexture.reparentTo(altRender) cm = CardMaker("stimwindow") cm.setFrame(-4, 4, -3, 3) # cm.setUvRange(self.imagesTexture) self.card = NodePath(cm.generate()) self.card.reparentTo(altRender) if self.stimtype == 'image_sequence': self.card.setTexture(self.imagesTexture, 1) # self.imagesTexture.play() # self.bufferViewer.setPosition("lrcorner") # self.bufferViewer.setCardSize(1.0, 0.0) self.accept("v", self.bufferViewer.toggleEnable) self.accept("V", self.bufferViewer.toggleEnable) # Load the tunnel self.initTunnel() #initialize some things # for the tunnel construction: self.boundary_to_add_next_segment = -1 * TUNNEL_SEGMENT_LENGTH self.current_number_of_segments = 8 #task flow booleans self.in_waiting_period = False self.stim_started = False self.looking_for_a_cue_zone = True self.in_reward_window = False self.show_stimulus = False #for task control self.interval = 0 self.time_waiting_in_cue_zone = 0 self.wait_time = 1.83 self.stim_duration = 4.0 # in seconds self.max_stim_duration = 6.0 # in seconds self.stim_elapsed = 0.0 # in seconds self.last_position = base.camera.getZ() self.position_on_track = base.camera.getZ() #for reward control self.reward_window = REWARD_WINDOW # in seconds self.reward_elapsed = 0.0 # self.reward_volume = 0.008 # in mL. this is for the hardcoded 0.1 seconds of reward time self.reward_volume = int(REWARD_VOLUME) # in uL, for the stepper motor self.reward_time = 0.1 # in sec, based on volume. hard coded right now but should be modified by the (1) calibration and (2) optionally by the main loop for dynamic reward scheduling # self.lick_buffer = [] #INITIALIZE NIDAQ self.nidevice = 'Dev2' self.encodervinchannel = 1 self.encodervsigchannel = 0 self.invertdo = False self.diport = 1 self.lickline = 0 self.doport = 0 self.rewardline = 0 self.rewardlines = [0] self._setupDAQ() self.do.WriteBit(1, 1) self.do.WriteBit( 3, 1 ) #set reward high, because the logic is flipped somehow. possibly by haphazard wiring of the circuit (12/24/2018 djd) self.previous_encoder_position = self.ai.data[0][ self.encodervsigchannel] self.encoder_gain = 30 #INITIALIZE LICK SENSOR self._lickSensorSetup() #INITIALIZE output data self.lickData = [] self.x = [] self.t = [] self.trialData = [] self.rewardData = [] #INITIALIZE KEY SENSOR, for backup inputs and other user controls self.keys = key.KeyStateHandler() self.accept('r', self._give_reward, [self.reward_volume]) self.accept('l', self._toggle_reward) img_list = glob.glob('models/NaturalImages/*.tiff')[:10] print(img_list) self.imageTextures = [loader.loadTexture(img) for img in img_list] self._setupEyetracking() self._startEyetracking() if AUTO_MODE: self.gameTask = taskMgr.add(self.autoLoop2, "autoLoop2") self.rewardTask = taskMgr.add(self.rewardControl, "reward") self.cue_zone = concatenate((self.cue_zone,arange(\ self.current_number_of_segments*-TUNNEL_SEGMENT_LENGTH,\ self.current_number_of_segments*-TUNNEL_SEGMENT_LENGTH-TUNNEL_SEGMENT_LENGTH-80,\ -1))) self.auto_position_on_track = 0 self.auto_restart = False self.auto_running = True self.contTunnel() else: # Now we create the task. taskMgr is the task manager that actually # calls the function each frame. The add method creates a new task. # The first argument is the function to be called, and the second # argument is the name for the task. It returns a task object which # is passed to the function each frame. self.gameTask = taskMgr.add(self.gameLoop, "gameLoop") # self.stimulusTask = taskMgr.add(self.stimulusControl, "stimulus") self.lickTask = taskMgr.add(self.lickControl, "lick") self.rewardTask = taskMgr.add(self.rewardControl, "reward") # Code to initialize the tunnel def initTunnel(self): self.tunnel = [None] * 8 for x in range(8): # Load a copy of the tunnel self.tunnel[x] = loader.loadModel('models/tunnel') # The front segment needs to be attached to render if x == 0: self.tunnel[x].reparentTo(render) # The rest of the segments parent to the previous one, so that by moving # the front segement, the entire tunnel is moved else: self.tunnel[x].reparentTo(self.tunnel[x - 1]) # We have to offset each segment by its length so that they stack onto # each other. Otherwise, they would all occupy the same space. self.tunnel[x].setPos(0, 0, -TUNNEL_SEGMENT_LENGTH) # Now we have a tunnel consisting of 4 repeating segments with a # hierarchy like this: # render<-tunnel[0]<-tunnel[1]<-tunnel[2]<-tunnel[3] self.tunnel[0] = loader.loadModel('models/grating') self.tunnel[0].reparentTo(render) self.cue_zone = arange(0, TUNNEL_SEGMENT_LENGTH, -1) # This function is called to snap the front of the tunnel to the back # to simulate traveling through it def contTunnel(self): self.auto_position_on_track -= 50 position_on_track = self.auto_position_on_track print(str(int(position_on_track)) + ' ' + str(self.cue_zone)) if int(position_on_track) in np.array( self.cue_zone): #check for cue zone if not self.auto_restart: print('STOP!') self.tunnelMove.pause() self.auto_presentation = True # self.current_number_of_segments +=1 else: self.auto_restart = True self.tunnelMove.resume() else: self.in_waiting_period = False self.auto_presentation = False # base.setBackgroundColor([1,0 , 0]) if self.looking_for_a_cue_zone == False: self.looking_for_a_cue_zone = True if self.stim_started == True: self.stop_a_presentation() # This line uses slices to take the front of the list and put it on the # back. For more information on slices check the Python manual self.tunnel = self.tunnel[1:] + self.tunnel[0:1] # Set the front segment (which was at TUNNEL_SEGMENT_LENGTH) to 0, which # is where the previous segment started self.tunnel[0].setZ(0) # Reparent the front to render to preserve the hierarchy outlined above self.tunnel[0].reparentTo(render) # Set the scale to be apropriate (since attributes like scale are # inherited, the rest of the segments have a scale of 1) self.tunnel[0].setScale(.155, .155, .305) # Set the new back to the values that the rest of the segments have self.tunnel[3].reparentTo(self.tunnel[2]) self.tunnel[3].setZ(-TUNNEL_SEGMENT_LENGTH) self.tunnel[3].setScale(1) # Set up the tunnel to move one segment and then call contTunnel again # to make the tunnel move infinitely self.tunnelMove = Sequence( LerpFunc(self.tunnel[0].setZ, duration=TUNNEL_TIME, fromData=0, toData=TUNNEL_SEGMENT_LENGTH * .305), Func(self.contTunnel)) self.tunnelMove.start() def start_a_presentation(self): print("start") self.do.WriteBit(2, 1) # self.bufferViewer.toggleEnable() self.lick_buffer = [] if self.stimtype == 'random image': for i in range(randint(len(self.imageTextures))): self.card.setTexture(self.imageTextures[i], 1) if self.stimtype == 'image_sequence': self.imagesTexture.setTime(0.) self.dr2.setDimensions(0.4, 0.8, 0.4, 0.70) #floats (left, right, bottom, top) self.imagesTexture.play() def stop_a_presentation(self): if self.stim_started == True: self.dr2.setDimensions(0, 0.1, 0, 0.1) # self.bufferViewer.toggleEnable() self.stim_started = False self.stim_elapsed = 0. self.stim_duration = 0. while self.stim_duration < 1. or self.stim_duration > self.max_stim_duration * 2.: # set some limits on the random duration so is not too short or too long self.stim_duration = exponential(self.max_stim_duration) self.stim_off_time = globalClock.getFrameTime() self.do.WriteBit(2, 0) def _lickSensorSetup(self): """ Attempts to set up lick sensor NI task. """ ##TODO: Make lick sensor object if necessary. Let user select port and line. if self.di: self.lickSensor = self.di # just use DI for now licktest = [] for i in range(30): licktest.append(self.di.Read()[self.lickline]) time.sleep(0.01) licktest = np.array(licktest, dtype=np.uint8) if len(licktest[np.where(licktest > 0)]) > 25: self.lickSensor = None self.lickData = [np.zeros(len(self.rewardlines))] print("Lick sensor failed startup test.") else: print('lick sensor setup succeeded.') self.keycontrol = True else: print( "Could not initialize lick sensor. Ensure that NIDAQ is connected properly." ) self.keycontrol = True self.lickSensor = None self.lickData = [np.zeros(len(self.rewardlines))] self.keys = key.KeyStateHandler() # self.window.winHandle.push_handlers(self.keys) # def _read_licks(self): # not yet implemented; should be replaces with check to beam break def _give_reward(self, volume): print("reward!") self.rewardData.extend([globalClock.getFrameTime()]) self.do.WriteBit(3, 0) time.sleep(self.reward_time) self.do.WriteBit( 3, 1) # put a TTL on a line to indicate that a reward was given s.dispense(volume) #pass # not yet implemented def _toggle_reward(self): if self.AUTO_REWARD: self.AUTO_REWARD = False print('switched to lick sensing for reward.') else: self.AUTO_REWARD = True print('switched to automatic rewards after stimuli.') def autoLoop2(self, task): dt = globalClock.getDt() current_time = globalClock.getFrameTime() self.x.extend([self.auto_position_on_track]) self.t.extend([globalClock.getFrameTime()]) if self.auto_presentation: self.auto_running = False if self.in_waiting_period: self.time_waited += dt else: self.time_waited = 0 self.in_waiting_period = True if self.time_waited > self.wait_time: #if in cue zone,see if we have been ther for long enough #start a trial self.start_position = self.auto_position_on_track self.start_time = current_time if not self.stim_started: self.start_a_presentation() # print(self.stim_duration) self.stim_started = True self.show_stimulus = True else: self.stim_elapsed += dt if self.stim_elapsed > self.stim_duration: self.show_stimulus = False self.in_reward_window = True self.stop_a_presentation() self.auto_restart = False # print(self.current_number_of_segments) self.current_number_of_segments += 9 #redefine the cue zone as the next one self.cue_zone = arange( self.current_number_of_segments * -TUNNEL_SEGMENT_LENGTH, self.current_number_of_segments * -TUNNEL_SEGMENT_LENGTH - TUNNEL_SEGMENT_LENGTH - 80, -1) #extend cue zone, keeping old ones # self.cue_zone = concatenate((self.cue_zone,arange(self.current_number_of_segments*-TUNNEL_SEGMENT_LENGTH-40, # self.current_number_of_segments*-TUNNEL_SEGMENT_LENGTH-TUNNEL_SEGMENT_LENGTH-40, # -1))) self.contTunnel() self.time_waited = 0 self.looking_for_a_cue_zone = False # base.setBackgroundColor([0, 0, 1]) else: pass # base.setBackgroundColor([0, 1, 0]) else: self.auto_running = True return Task.cont # Since every return is Task.cont, the task will def gameLoop(self, task): # get the time elapsed since the next frame. dt = globalClock.getDt() current_time = globalClock.getFrameTime() # get the camera position. position_on_track = base.camera.getZ() #get the encoder position from NIDAQ Analog Inputs channel 2 encoder_position = self.ai.data[0][ self. encodervsigchannel] #zeroth sample in buffer [0], from ai2 [2] #convert to track coordinates encoder_position_diff = (encoder_position - self.previous_encoder_position) if abs( encoder_position_diff ) > 0.025: #manually set threshold to remove encoder noise jittering the positionq if encoder_position_diff > 4.5: encoder_position_diff -= 5. if encoder_position_diff < -4.5: encoder_position_diff += 5. encoder_position_diff *= self.encoder_gain self.previous_encoder_position = encoder_position position_on_track = base.camera.getZ() + encoder_position_diff #reset the camera position self.camera.setPos(base.camera.getX(), base.camera.getY(), position_on_track) self.x.extend([position_on_track]) self.t.extend([globalClock.getFrameTime()]) #first check if the mouse moved on the last frame. if abs( self.last_position - position_on_track ) < 1.5: #the mouse didn't move more than 0.5 units on the track self.moved = False if int(position_on_track) in self.cue_zone: #check for cue zone if self.looking_for_a_cue_zone: #make sure we transitioning from the tunnel to a cue zone #increment how long we've been waiting in the cue zone. if self.in_waiting_period: self.time_waited += dt else: self.time_waited = 0 self.in_waiting_period = True if self.time_waited > self.wait_time: #if in cue zone,see if we have been ther for long enough #start a trial self.start_position = position_on_track self.start_time = current_time if not self.stim_started: self.start_a_presentation() print(self.stim_duration) self.stim_started = True self.show_stimulus = True else: self.stim_elapsed += dt if self.stim_elapsed > self.stim_duration: self.show_stimulus = False self.in_reward_window = True self.stop_a_presentation() self.time_waited = 0 self.looking_for_a_cue_zone = False # base.setBackgroundColor([0, 0, 1]) else: pass # base.setBackgroundColor([0, 1, 0]) else: self.in_waiting_period = False # base.setBackgroundColor([1,0 , 0]) if self.looking_for_a_cue_zone == False: self.looking_for_a_cue_zone = True if self.stim_started == True: self.stop_a_presentation() else: #the mouse did move self.moved = True if self.stim_started == True: #check if it moved during a presenation self.stop_a_presentation() self.time_waited = 0 self.looking_for_a_cue_zone = False self.show_stimulus = False #if we need to add another segment, do so if position_on_track < self.boundary_to_add_next_segment: self.tunnel.extend([None]) x = self.current_number_of_segments if x % 8 == 0: self.tunnel[x] = loader.loadModel('models/grating') self.cue_zone = concatenate((self.cue_zone,arange(\ self.current_number_of_segments*-TUNNEL_SEGMENT_LENGTH,\ self.current_number_of_segments*-TUNNEL_SEGMENT_LENGTH-TUNNEL_SEGMENT_LENGTH-80,\ -1))) else: self.tunnel[x] = loader.loadModel('models/tunnel') self.tunnel[x].setPos(0, 0, -TUNNEL_SEGMENT_LENGTH) self.tunnel[x].reparentTo(self.tunnel[x - 1]) #increment self.boundary_to_add_next_segment -= TUNNEL_SEGMENT_LENGTH self.current_number_of_segments += 1 else: pass #print('current:'+str(position_on_track) +' next boundary:' + str(self.boundary_to_add_next_segment)) self.last_position = position_on_track # lick_times = self. # self._read_licks() return Task.cont # Since every return is Task.cont, the task will # continue indefinitely, under control of the mouse (animal) def stimulusControl(self, task): if self.show_stimulus and not self.bufferViewer.isEnabled(): # self.bufferViewer.toggleEnable() self.dr2.setDimensions(0.5, 0.9, 0.5, 0.8) if not self.show_stimulus and self.bufferViewer.isEnabled(): # self.bufferViewer.toggleEnable() self.dr2.setDimensions(0, 0.1, 0, 0.1) return Task.cont def lickControl(self, task): """ Checks to see if a lick is occurring. """ ##TODO: Let user select line for lick sensing. if self.lickSensor: if self.lickSensor.Read()[self.lickline]: self.lickData.extend([globalClock.getFrameTime()]) print('lick happened at: ' + str(self.lickData[-1])) elif self.keycontrol == True: #NO NI BOARD. KEY INPUT? if self.keys[key.SPACE]: data = [globalClock.getFrameTime()] elif self.keys[key.NUM_1]: # print(self.lickData) # elif self.keys[key.NUM_3]: # data = [0,1] # else: # data = [0,0] self.lickData.extend(data) return Task.cont def rewardControl(self, task): if self.in_reward_window: self.reward_elapsed += globalClock.getDt() if not self.AUTO_REWARD: if self.reward_elapsed < self.reward_window: if len( np.where( np.array(self.lickData) > self.stim_off_time) [0] ) > 1: # this checks if there has been more than zero licks since the stimulus turned off self._give_reward(self.reward_volume) self.in_reward_window = False self.reward_elapsed = 0. #reset else: self.in_reward_window = False self.reward_elapsed = 0. #reset else: self._give_reward(self.reward_volume) self.in_reward_window = False self.reward_elapsed = 0. #reset # self.reward_elapsed=0. # base.setBackgroundColor([1, 1, 0]) # if self.keys[key.NUM_1]: # print('reward!') if self.reward_elapsed > self.reward_window: self.in_reward_window = False self.reward_elapsed = 0. return Task.cont def _setupEyetracking(self): """ sets up eye tracking""" try: eyetrackerip = "DESKTOP-EE5KKDO" eyetrackerport = 10000 trackeyepos = False from aibs.Eyetracking.EyetrackerClient import Client self.eyetracker = Client( outgoing_ip=eyetrackerip, outgoing_port=eyetrackerport, output_filename=str(datetime.datetime.now()).replace( ':', '').replace('.', '').replace(' ', '-')) self.eyetracker.setup() # eyedatalog = [] # if trackeyepos: # eyeinitpos = None except: print("Could not initialize eyetracker:") self.eyetracker = None def _startEyetracking(self): if self.eyetracker: self.eyetracker.recordStart() def _setupDAQ(self): """ Sets up some digital IO for sync and tiggering. """ print('SETTING UP DAQ') try: if self.invertdo: istate = 'low' else: istate = 'high' self.do = DigitalOutput(self.nidevice, self.doport, initial_state='low') self.do.StartTask() except: # Exception, e: print("Error starting DigitalOutput task:") self.do = None try: self.di = DigitalInput(self.nidevice, self.diport) self.di.StartTask() except: # Exception, e: print("Error starting DigitalInput task:") self.di = None # try: #set up 8 channels, only use 2 though for now self.ai = AnalogInput(self.nidevice, range(8), buffer_size=25, terminal_config='RSE', clock_speed=6000.0, voltage_range=[-5.0, 5.0]) self.ai.StartTask() print(type(self.ai)) # except:# Exception, e: # print("Error starting AnalogInput task:") # self.ai = None # try: # self.ao = AnalogOutput(self.nidevice, channels=[0, 1],terminal_config = 'RSE', # voltage_range=[0.0, 5.0]) # self.ao.StartTask() # except:# Exception, e: # print("Error starting AnalogOutput task:") # self.ao = None def close(self): if self.eyetracker: self.eyetracker.recordStop() print('stop eyetracking') save_path = os.path.join(os.getcwd(),'data',str(MOUSE_ID)+'_'+\ str(self.session_start_time.year)+'_'+\ str(self.session_start_time.month)+'_'+\ str(self.session_start_time.day)+'-'+\ str(self.session_start_time.hour)+'_'+\ str(self.session_start_time.minute)+'_'+\ str(self.session_start_time.second)) if ~os.path.isdir(save_path): os.mkdir(save_path) print("saving data to " + save_path) np.save(os.path.join(save_path, 'licks.npy'), self.lickData) np.save(os.path.join(save_path, 'x.npy'), self.x) np.save(os.path.join(save_path, 't.npy'), self.t) np.save(os.path.join(save_path, 'trialData.npy'), self.trialData) np.save(os.path.join(save_path, 'rewardData.npy'), self.rewardData) print('rewardData:') print(np.shape(self.rewardData)) sys.exit(0)
class MouseTunnel(ShowBase): def __init__(self): # Initialize the ShowBase class from which we inherit, which will # create a window and set up everything we need for rendering into it. ShowBase.__init__(self) self.stimtype = 'random image' # session_start self.session_start_time = datetime.datetime.now() # self.accept("escape", sys.exit, [0])#don't let the user do this, because then the data isn't saved. self.accept('q', self.close) self.accept('Q', self.close) self.upArrowIsPressed = base.mouseWatcherNode.isButtonDown(KeyboardButton.up()) self.downArrowIsPressed = base.mouseWatcherNode.isButtonDown(KeyboardButton.down()) self.rightArrowIsPressed = base.mouseWatcherNode.isButtonDown(KeyboardButton.right()) self.leftArrowIsPressed = base.mouseWatcherNode.isButtonDown(KeyboardButton.left()) self.AUTO_REWARD = AUTO_REWARD # disable mouse control so that we can place the camera base.disableMouse() camera.setPosHpr(0, 0, 10, 0, -90, 0) mat = Mat4(camera.getMat()) mat.invertInPlace() base.mouseInterfaceNode.setMat(mat) # base.enableMouse() props = WindowProperties() # props.setOrigin(0, 0) props.setFullscreen(True) props.setCursorHidden(True) props.setMouseMode(WindowProperties.M_relative) base.win.requestProperties(props) base.setBackgroundColor(0, 0, 0) # set the background color to black print('FULSCREEN:') print(props.getFullscreen()) print('=============') # set up the textures # we now get buffer thats going to hold the texture of our new scene altBuffer = self.win.makeTextureBuffer("hello", 1524, 1024) # altBuffer.getDisplayRegion(0).setDimensions(0.5,0.9,0.5,0.8) # altBuffer = base.win.makeDisplayRegion() # altBuffer.makeDisplayRegion(0,1,0,1) # now we have to setup a new scene graph to make this scene self.dr2 = base.win.makeDisplayRegion(0, 0.001, 0, 0.001)#make this really,really small so it's not seeable by the subject altRender = NodePath("new render") # this takes care of setting up ther camera properly self.altCam = self.makeCamera(altBuffer) self.dr2.setCamera(self.altCam) self.altCam.reparentTo(altRender) self.altCam.setPos(0, -10, 0) self.bufferViewer.setPosition("lrcorner") # self.bufferViewer.position = (-.1,-.4,-.1,-.4) self.bufferViewer.setCardSize(1.0, 0.0) print(self.bufferViewer.position) self.imagesTexture = MovieTexture("image_sequence") # success = self.imagesTexture.read("models/natural_images.avi") # success = self.imagesTexture.read("models/movie_5hz.mpg") self.imagesTexture.setPlayRate(1.0) self.imagesTexture.setLoopCount(10) # self.imageTexture =loader.loadTexture("models/NaturalImages/BSDs_8143.tiff") # self.imagesTexture.reparentTo(altRender) self.fixationPoint = OnscreenImage(image='models/fixationpoint.jpg', pos=(0, 0,0),scale=0.01) cm = CardMaker("stimwindow") cm.setFrame(-4, 4, -3, 3) # cm.setUvRange(self.imagesTexture) self.card = NodePath(cm.generate()) self.card.reparentTo(altRender) if self.stimtype == 'image_sequence': self.card.setTexture(self.imagesTexture, 1) # add the score display self.scoreLabel = OnscreenText(text='Current Score:', pos=(-1, 0.9), scale=0.1, fg=(0.8, 0.8, 0.8, 1)) self.scoreText = OnscreenText(text=str(0), pos=(-1, 0.76), scale=0.18, fg=(0, 1, 0, 1), shadow=(0.1, 1, 0.1, 0.5)) self.feebackScoreText = OnscreenText(text='+ ' + str(0), pos=(-0.5, 0.5), scale=0.3, fg=(0, 1, 0, 1), shadow=(0.1, 1, 0.1, 0.5)) self.feebackScoreText.setX(3.) # self.imagesTexture.play() # self.bufferViewer.setPosition("lrcorner") # self.bufferViewer.setCardSize(1.0, 0.0) self.accept("v", self.bufferViewer.toggleEnable) self.accept("V", self.bufferViewer.toggleEnable) # Load the tunnel self.initTunnel() # initialize some things # for the tunnel construction: self.boundary_to_add_next_segment = -1 * TUNNEL_SEGMENT_LENGTH self.current_number_of_segments = 8 # task flow booleans self.in_waiting_period = False self.stim_started = False self.looking_for_a_cue_zone = True self.in_reward_window = False self.show_stimulus = False # for task control self.interval = 0 self.time_waiting_in_cue_zone = 0 self.wait_time = 1.83 self.stim_duration = 0 # in seconds # self.distribution_type = np.random.uniform# # self.distribution_type_inputs = [0.016,0.4] #change the min & max stim duration times #New lines EAS: set weights higher for faster image durations self.durWeights = list() a = np.linspace(0.016,0.4,10) for i,j in enumerate(a): if j<0.1: p1 = 0.25 self.durWeights.append(p1) elif j > 0.1 and j < 0.21: p1 = 0.1 self.durWeights.append(p1) elif j> 0.21: p1 = 0.04 self.durWeights.append(p1) self.rng = np.random.default_rng() a = np.asarray(a) self.distribution_type_inputs = a #subset_size = len(p) #End new lines # self.distribution_type_inputs = [0.05,1.5] #can be anytong should match # self.distribution_type_inputs = [0.016,0.4] #change the min & max stim duration times # self.distribution_type_inputs = [0.016,0.4, 10] #change the min & max stim duration times self.max_stim_duration = 1.0 # in seconds self.stim_elapsed = 0.0 # in seconds self.last_position = base.camera.getZ() self.position_on_track = base.camera.getZ() # for reward control self.reward_window = REWARD_WINDOW # in seconds self.reward_elapsed = 0.0 # self.new_dt = list() # self.reward_volume = 0.008 # in mL. this is for the hardcoded 0.1 seconds of reward time self.reward_volume = int(REWARD_VOLUME) # in uL, for the stepper motor self.reward_time = 0.1 # in sec, based on volume. hard coded right now but should be modified by the (1) calibration and (2) optionally by the main loop for dynamic reward scheduling # self.lick_buffer = [] self.current_score = 0 self.score = 0 self.feedback_score_startime = -2 # INITIALIZE NIDAQ self.nidevice = 'Dev2' self.encodervinchannel = 1 self.encodervsigchannel = 0 self.invertdo = False self.diport = 1 self.lickline = 1 self.doport = 0 self.rewardline = 0 self.rewardlines = [0] self.encoder_position_diff = 0 if have_nidaq: self._setupDAQ() self.do.WriteBit(1, 1) self.do.WriteBit(3, 1) # set reward high, because the logic is flipped somehow. possibly by haphazard wiring of the circuit (12/24/2018 djd) self.previous_encoder_position = self.ai.data[0][self.encodervsigchannel] else: self.previous_encoder_position = 0 self.encoder_gain = 3 # INITIALIZE LICK SENSOR self._lickSensorSetup() # INITIALIZE output data self.lickData = [] self.x = [] self.t = [] self.trialData = [] self.reactionTimeData = [] self.rewardData = [] self.rightKeyData = [] self.leftKeyData = [] self.imageData = [] self.imageTimeData = [] self.scoreData = [] self.trialDurationData = [] self.new_dt = [] # INITIALIZE KEY SENSOR, for backup inputs and other user controls self.keys = key.KeyStateHandler() self.accept('r', self._give_reward, [self.reward_volume]) self.accept('l', self._toggle_reward) # initialize the image list and populate what images you want included # self.img_list = glob.glob('models/2AFC_IMAGES_HUMAN/*.tif') # self.img_list = glob.glob('models/2AFC_IMAGES_HUMAN2/*.tif') # self.img_list = glob.glob('/Users/elizabethstubblefield/Desktop/cheetah_or_elephant/composite_images/masks/all_same_num_ea/*.tif') #Newest images self.img_list = glob.glob('models/all_same_ea/*.tif') #Newest images #No longer hard-coded: self.original_indices = [0,0] #this was manually counted... first number must was the index of the first easy img; was [43, -18] for ndx, name in enumerate(self.img_list): if 'Cheetah255' in name: self.original_indices[0] = ndx elif 'Elephant0' in name: self.original_indices[1] = ndx # print(self.img_list) # self.original_indices = [43,-18] #manually counted, grump #Problematic w/out at least 43 images in the folder self.imageTextures =[loader.loadTexture(img) for img in self.img_list] self.img_id = None #this variable is used so we know which stimulus is being presented self.img_mask = None #this tells us what the image mask being presented is # self._setupEyetracking() # self._startEyetracking() if AUTO_MODE: self.gameTask = taskMgr.add(self.autoLoop2, "autoLoop2") self.rewardTask = taskMgr.add(self.rewardControl, "reward") self.cue_zone = concatenate((self.cue_zone, arange( \ self.current_number_of_segments * -TUNNEL_SEGMENT_LENGTH-50, \ self.current_number_of_segments * -TUNNEL_SEGMENT_LENGTH - TUNNEL_SEGMENT_LENGTH - 100, \ -1))) self.auto_position_on_track = 0 self.auto_restart = False self.auto_running = True self.contTunnel() else: # Now we create the task. taskMgr is the task manager that actually # calls the function each frame. The add method creates a new task. # The first argument is the function to be called, and the second # argument is the name for the task. It returns a task object which # is passed to the function each frame. self.gameTask = taskMgr.add(self.gameLoop, "gameLoop") # self.stimulusTask = taskMgr.add(self.stimulusControl, "stimulus") self.lickTask = taskMgr.add(self.lickControl, "lick") self.rewardTask = taskMgr.add(self.rewardControl, "reward") self.keyTask = taskMgr.add(self.keyControl, "Key press") # Code to initialize the tunnel def initTunnel(self): self.tunnel = [None] * 8 for x in range(8): # Load a copy of the tunnel self.tunnel[x] = loader.loadModel('models/tunnel') # The front segment needs to be attached to render if x == 0: self.tunnel[x].reparentTo(render) # The rest of the segments parent to the previous one, so that by moving # the front segement, the entire tunnel is moved else: self.tunnel[x].reparentTo(self.tunnel[x - 1]) # We have to offset each segment by its length so that they stack onto # each other. Otherwise, they would all occupy the same space. self.tunnel[x].setPos(0, 0, -TUNNEL_SEGMENT_LENGTH) # Now we have a tunnel consisting of 4 repeating segments with a # hierarchy like this: # render<-tunnel[0]<-tunnel[1]<-tunnel[2]<-tunnel[3] self.tunnel[0] = loader.loadModel('models/grating') self.tunnel[0].reparentTo(render) self.cue_zone = arange(0, TUNNEL_SEGMENT_LENGTH, -1)-280 # This function is called to snap the front of the tunnel to the back # to simulate traveling through it def contTunnel(self): self.auto_position_on_track -= 50 position_on_track = self.auto_position_on_track print(str(int(position_on_track)) + ' ' + str(self.cue_zone)) if int(position_on_track) in np.array(self.cue_zone): # check for cue zone if not self.auto_restart: print('STOP!') self.tunnelMove.pause() self.auto_presentation = True # self.current_number_of_segments +=1 else: self.auto_restart = True self.tunnelMove.resume() else: self.in_waiting_period = False self.auto_presentation = False # base.setBackgroundColor([1,0 , 0]) if self.looking_for_a_cue_zone == False: self.looking_for_a_cue_zone = True if self.stim_started == True: self.stop_a_presentation() # This line uses slices to take the front of the list and put it on the # back. For more information on slices check the Python manual self.tunnel = self.tunnel[1:] + self.tunnel[0:1] # Set the front segment (which was at TUNNEL_SEGMENT_LENGTH) to 0, which # is where the previous segment started self.tunnel[0].setZ(0) # Reparent the front to render to preserve the hierarchy outlined above self.tunnel[0].reparentTo(render) # Set the scale to be apropriate (since attributes like scale are # inherited, the rest of the segments have a scale of 1) self.tunnel[0].setScale(.155, .155, .305) # Set the new back to the values that the rest of the segments have self.tunnel[3].reparentTo(self.tunnel[2]) self.tunnel[3].setZ(-TUNNEL_SEGMENT_LENGTH) self.tunnel[3].setScale(1) # Set up the tunnel to move one segment and then call contTunnel again # to make the tunnel move infinitely self.tunnelMove = Sequence( LerpFunc(self.tunnel[0].setZ, duration=TUNNEL_TIME, fromData=0, toData=TUNNEL_SEGMENT_LENGTH * .305), Func(self.contTunnel) ) self.tunnelMove.start() def get_trial_duration(self): #EAS updated 10.5.20 self.stim_duration = self.rng.choice(self.distribution_type_inputs, 1, p=self.durWeights) #pull out one value in array a, w/ probability based on weights return self.stim_duration[0] # return self.distribution_type(*self.distribution_type_inputs) def start_a_presentation(self): self.save_data() self.stim_duration = self.get_trial_duration() self.fixationPoint.destroy() # import pickle # with open('objs.pkl', 'wb') as f: # Python 3: open(..., 'wb') # pickle.dump([self.stim_duration,self.distribution_type_inputs], f) # print('variables saved!!!') self.in_reward_window = True print("start") if have_nidaq: self.do.WriteBit(2, 1) # self.bufferViewer.toggleEnable() self.lick_buffer = [] self.trialData.extend([globalClock.getFrameTime()]) self.reactionTimeData.extend([-1]) if self.stimtype == 'random image': if len(self.trialData) < 4: i=self.original_indices[int(np.round(np.random.random()))] #commented out due to <43 images [see l. 290ish] self.stim_duration = 2.0 else: #commented out due to <43 images i = randint(len(self.imageTextures)) self.card.setTexture(self.imageTextures[i],0) self.dr2.setDimensions(0.25, 0.75, 0.25, 0.75) # floats (left, right, bottom, top) self.img_id = self.img_list[i] #this assigns the current presented image to self.image_id print(self.img_id) self.imageData.extend(self.img_id) if self.stimtype == 'image_sequence': self.imagesTexture.setTime(0.) self.dr2.setDimensions(0.4, 0.8, 0.4, 0.70) # floats (left, right, bottom, top) self.imagesTexture.play() self.imageTimeData.extend([globalClock.getFrameTime()]) self.imageData.extend(self.img_id) def check_arrows(self): # this function will report which arrow was pressed. right = 1, left = 2, no press = 0 if self.rightArrowIsPressed: #print('check arrows RIGHT') return 1 # time.sleep(2) elif self.leftArrowIsPressed: #print('check arrows LEFT') return 2 # time.sleep(2) else: return 0 def stop_a_presentation(self): if self.stim_started == True: if self.stim_elapsed > self.stim_duration: self.trialDurationData.append(self.stim_duration) else: self.trialDurationData.append(self.stim_duration) self.dr2.setDimensions(0, 0.001, 0, 0.001)#make this really,really small so it's not seeable by the subject # self.bufferViewer.toggleEnable() self.stim_started = False self.stim_elapsed = 0. self.stim_duration = 0. self.stim_off_time = globalClock.getFrameTime() if have_nidaq: self.do.WriteBit(2, 0) # if globalClock.getFrameTime() > self.feedback_score_startime + 1.5: # arbitrary wait to make sure this isn't after a correct trial # self.feebackScoreText.setText('+' + str(0)) # self.feebackScoreText.setFg((1, 0, 0, 1)) # self.feebackScoreText.setX(.5) # self.feedback_score_startime = globalClock.getFrameTime() self.scoreData.append(self.current_score) self.fixationPoint = OnscreenImage(image='models/fixationpoint.jpg', pos=(0, 0,0),scale=0.01) # def keySensorSetup(self): def show_the_score(self): self.feebackScoreText.setText('+' + str(self.score)) if self.score == 0: self.feebackScoreText.setFg((1, 0, 0, 1)) else: self.feebackScoreText.setFg((0, 1, 0, 1)) self.feebackScoreText.setX(.5) self.feedback_score_startime = globalClock.getFrameTime() # sets up the task to listen for user input from the keys def _lickSensorSetup(self): """ Attempts to set up lick sensor NI task. """ ##TODO: Make lick sensor object if necessary. Let user select port and line. if have_nidaq: if self.di: self.lickSensor = self.di # just use DI for now licktest = [] for i in range(30): licktest.append(self.rightArrowIsPressed.Read()[self.lickline]) time.sleep(0.01) licktest = np.array(licktest, dtype=np.uint8) if len(licktest[np.where(licktest > 0)]) > 25: self.lickSensor = None self.lickData = [np.zeros(len(self.rewardlines))] print("Lick sensor failed startup test.") else: print('lick sensor setup succeeded.') self.keycontrol = True else: print("Could not initialize lick sensor. Ensure that NIDAQ is connected properly.") self.keycontrol = True self.lickSensor = None self.lickData = [np.zeros(len(self.rewardlines))] self.keys = key.KeyStateHandler() # self.window.winHandle.push_handlers(self.keys) else: print("Could not initialize lick sensor. Ensure that NIDAQ is connected properly.") self.keycontrol = True self.lickSensor = None self.lickData = [np.zeros(len(self.rewardlines))] self.keys = key.KeyStateHandler() def reactiontime_to_score(self): rt = globalClock.getFrameTime() - self.trialData[-1] self.reactionTimeData[-1] = rt score = 100. / rt # scale the reaction time, with faster producing more points return int(score / 20.) # def _read_licks(self): # not yet implemented; should be replaces with check to beam break def _give_reward(self, volume): print("reward!") self.rewardData.extend([globalClock.getFrameTime()]) # for humans self.score = self.reactiontime_to_score() self.current_score += self.score self.show_the_score() self.scoreText.setText(str(self.current_score)) # for mice if have_nidaq: self.do.WriteBit(3, 0) time.sleep(self.reward_time) self.do.WriteBit(3, 1) # put a TTL on a line to indicate that a reward was given s.dispense(volume) # pass # not yet implemented def _toggle_reward(self): if self.AUTO_REWARD: self.AUTO_REWARD = False print('switched to lick sensing for reward.') else: self.AUTO_REWARD = True print('switched to automatic rewards after stimuli.') def autoLoop2(self, task): dt = globalClock.getDt() current_time = globalClock.getFrameTime() self.x.extend([self.auto_position_on_track]) self.t.extend([globalClock.getFrameTime()]) if self.auto_presentation: self.auto_running = False if self.in_waiting_period: self.time_waited += dt else: self.time_waited = 0 self.in_waiting_period = True if self.time_waited > self.wait_time: # if in cue zone,see if we have been ther for long enough # start a trial self.start_position = self.auto_position_on_track self.start_time = current_time if not self.stim_started: self.start_a_presentation() # print(self.stim_duration) self.stim_started = True self.show_stimulus = True else: self.stim_elapsed += dt if self.stim_elapsed > self.stim_duration: self.show_stimulus = False self.in_reward_window = True self.stop_a_presentation() self.auto_restart = False # print(self.current_number_of_segments) self.current_number_of_segments += 9 # redefine the cue zone as the next one self.cue_zone = arange(self.current_number_of_segments * -TUNNEL_SEGMENT_LENGTH, self.current_number_of_segments * -TUNNEL_SEGMENT_LENGTH - TUNNEL_SEGMENT_LENGTH - 280, -1) # extend cue zone, keeping old ones # self.cue_zone = concatenate((self.cue_zone,arange(self.current_number_of_segments*-TUNNEL_SEGMENT_LENGTH-40, # self.current_number_of_segments*-TUNNEL_SEGMENT_LENGTH-TUNNEL_SEGMENT_LENGTH-40, # -1))) self.contTunnel() self.time_waited = 0 self.looking_for_a_cue_zone = False # base.setBackgroundColor([0, 0, 1]) else: pass # base.setBackgroundColor([0, 1, 0]) else: self.auto_running = True return Task.cont # Since every return is Task.cont, the task will def gameLoop(self, task): # get the time elapsed since the next frame. dt = globalClock.getDt() self.new_dt.append(dt) #Store the append here for dt current_time = globalClock.getFrameTime() #This is for the key press if current_time > self.feedback_score_startime + 1.5: self.feebackScoreText.setX(3.) # get the camera position. position_on_track = base.camera.getZ() # get the encoder position from NIDAQ Analog Inputs channel 2 if have_nidaq: encoder_position = self.ai.data[0][self.encodervsigchannel] # zeroth sample in buffer [0], from ai2 [2] # convert to track coordinates encoder_position_diff = (encoder_position - self.previous_encoder_position) if encoder_position_diff > 4.5: encoder_position_diff -= 5. if encoder_position_diff < -4.5: encoder_position_diff += 5. self.encoder_position_diff = encoder_position_diff * self.encoder_gain self.previous_encoder_position = encoder_position else: self.read_keys() if self.upArrowIsPressed: self.encoder_position_diff = -1 * self.encoder_gain if self.downArrowIsPressed: self.encoder_position_diff = 1 * self.encoder_gain if not self.downArrowIsPressed: if not self.upArrowIsPressed: self.encoder_position_diff = 0 position_on_track = base.camera.getZ() + self.encoder_position_diff # reset the camera position self.camera.setPos(base.camera.getX(), base.camera.getY(), position_on_track) self.x.extend([position_on_track]) self.t.extend([globalClock.getFrameTime()]) # first check if the mouse moved on the last frame. if abs(self.last_position - position_on_track) < 1.5: # the mouse didn't move more than 0.5 units on the track self.moved = False if int(position_on_track) in self.cue_zone: # check for cue zone if self.looking_for_a_cue_zone: # make sure we transitioning from the tunnel to a cue zone # increment how long we've been waiting in the cue zone. if self.in_waiting_period: self.time_waited += dt else: self.time_waited = 0 self.in_waiting_period = True if self.time_waited > self.wait_time: # if in cue zone,see if we have been ther for long enough # start a trial self.start_position = position_on_track self.start_time = current_time if not self.stim_started: self.start_a_presentation() print(self.stim_duration) self.stim_started = True self.show_stimulus = True else: self.stim_elapsed += dt if self.stim_elapsed > self.stim_duration: self.show_stimulus = False self.stop_a_presentation() self.time_waited = 0 self.looking_for_a_cue_zone = False # base.setBackgroundColor([0, 0, 1]) else: pass # base.setBackgroundColor([0, 1, 0]) else: self.in_waiting_period = False # base.setBackgroundColor([1,0 , 0]) if self.looking_for_a_cue_zone == False: self.looking_for_a_cue_zone = True if self.stim_started == True: self.stop_a_presentation() else: # the mouse did move self.moved = True if self.stim_started == True: # check if it moved during a presenation self.stop_a_presentation() self.time_waited = 0 self.looking_for_a_cue_zone = False self.show_stimulus = False # if we need to add another segment, do so if position_on_track < self.boundary_to_add_next_segment: self.tunnel.extend([None]) x = self.current_number_of_segments if x % 8 == 0: self.tunnel[x] = loader.loadModel('models/grating') self.cue_zone = concatenate((self.cue_zone, arange( \ self.current_number_of_segments * -TUNNEL_SEGMENT_LENGTH - 50, \ self.current_number_of_segments * -TUNNEL_SEGMENT_LENGTH - TUNNEL_SEGMENT_LENGTH - 100, \ -1))) else: self.tunnel[x] = loader.loadModel('models/tunnel') self.tunnel[x].setPos(0, 0, -TUNNEL_SEGMENT_LENGTH) self.tunnel[x].reparentTo(self.tunnel[x - 1]) # increment self.boundary_to_add_next_segment -= TUNNEL_SEGMENT_LENGTH self.current_number_of_segments += 1 else: pass # print('current:'+str(position_on_track) +' next boundary:' + str(self.boundary_to_add_next_segment)) self.last_position = position_on_track # lick_times = self. # self._read_licks() return Task.cont # Since every return is Task.cont, the task will # continue indefinitely, under control of the mouse (animal) def stimulusControl(self, task): if self.show_stimulus and not self.bufferViewer.isEnabled(): # self.bufferViewer.toggleEnable() self.dr2.setDimensions(0.5, 0.9, 0.5, 0.8) if not self.show_stimulus and self.bufferViewer.isEnabled(): # self.bufferViewer.toggleEnable() self.dr2.setDimensions(0, 0.1, 0, 0.1) return Task.cont def lickControl(self, task): """ Checks to see if a lick is occurring. """ ##TODO: Let user select line for lick sensing. if self.lickSensor: if self.lickSensor.Read()[self.lickline]: self.lickData.extend([globalClock.getFrameTime()]) print('lick happened at: ' + str(self.lickData[-1])) elif self.keycontrol == True: # NO NI BOARD. KEY INPUT? if self.keys[key.SPACE]: data = [globalClock.getFrameTime()] elif self.keys[key.NUM_1]: # print(self.lickData) # elif self.keys[key.NUM_3]: # data = [0,1] # else: # data = [0,0] self.lickData.extend(data) return Task.cont def keyControl(self, task): # listen to and record when the arrows are pressed self.read_keys() if self.rightArrowIsPressed: self.rightKeyData.extend([globalClock.getFrameTime()]) print('right arrow at: ' + str(self.rightKeyData[-1])) # time.sleep(.2) #EAS changed this only allows for one keystroke to be recorded every 0.5s elif self.leftArrowIsPressed: self.leftKeyData.extend([globalClock.getFrameTime()]) print('left arrow at: ' + str(self.leftKeyData[-1])) # time.sleep(.2) #EAS changed this only allows for one keystroke to be recorded every 0.5s return Task.cont def rewardControl(self, task): # print(self.in_reward_window) if self.in_reward_window == True: if self.reward_elapsed < self.reward_window: self.reward_elapsed += globalClock.getDt() # self.new_reward_elapsed.append(self.reward_elapsed) # import pickle # with open('objs.pkl', 'wb') as f: # Python 3: open(..., 'wb') # pickle.dump([self.stim_duration,self.distribution_type_inputs, self.new_rew_control], f) # print('variables saved!!!') self.check_arrows() if not self.AUTO_REWARD: if self.check_arrows() == 1: # if check arrows returns a 1 the right arrow was pressed during stimulus presentation # note reaction time if self.img_id.find("Elephant") != -1: #if the current image file contains the string in () the value is not -1 self._give_reward(self.reward_volume) print('correct: image was mostly elephant') self.in_reward_window = False; self.reward_elapsed = 0. # reset elif 'Same' in self.img_id: #updated 8.24.20: reward 50/50 images 1/2 the time if round(np.random.random(1)[0]): self._give_reward(self.reward_volume) print('correct: image was same') self.in_reward_window = False; self.reward_elapsed = 0. # reset else: print(self.img_mask) print('incorrect: image was same') self.in_reward_window = False self.reward_elapsed = 0. # reset self.score=0 self.show_the_score() else: print(self.img_mask) print('image was not mostly elephant!') self.in_reward_window = False self.reward_elapsed = 0. # reset self.score=0 self.show_the_score() if self.check_arrows() == 2: #if check arrows returns a 2 the left arrow was pressed during stimulus presentation if self.img_id.find("Cheetah") != -1: #if the current image file contains the string in () the value is not -1 self._give_reward(self.reward_volume) print('correct: image was mostly cheetah') self.in_reward_window = False; self.reward_elapsed = 0. # reset elif 'Same' in self.img_id: #updated 8.24.20: reward 50/50 images 1/2 the time if round(np.random.random(1)[0]): self._give_reward(self.reward_volume) print('correct: image was same') self.in_reward_window = False; self.reward_elapsed = 0. # reset else: print(self.img_mask) print('incorrect: image was same') self.in_reward_window = False self.reward_elapsed = 0. # reset self.score=0 self.show_the_score() else: print(self.img_mask) print('image was not mostly cheetah!') self.in_reward_window = False self.reward_elapsed = 0. # reset self.score=0 self.show_the_score() else: self._give_reward(self.reward_volume) self.in_reward_window = False; self.reward_elapsed = 0. # reset # base.setBackgroundColor([1, 1, 0]) # # if self.keys[key.NUM_1]: # # print('reward!') else: self.score=0 self.show_the_score() self.in_reward_window = False self.reward_elapsed = 0. else: pass#print('not listening for reward'+str(globalClock.getFrameTime())) return Task.cont def _setupEyetracking(self): """ sets up eye tracking""" try: eyetrackerip = "DESKTOP-EE5KKDO" eyetrackerport = 10000 trackeyepos = False from aibs.Eyetracking.EyetrackerClient import Client self.eyetracker = Client(outgoing_ip=eyetrackerip, outgoing_port=eyetrackerport, output_filename=str(datetime.datetime.now()).replace(':', '').replace('.', '').replace( ' ', '-')) self.eyetracker.setup() # eyedatalog = [] # if trackeyepos: # eyeinitpos = None except: print("Could not initialize eyetracker:") self.eyetracker = None def _startEyetracking(self): if self.eyetracker: self.eyetracker.recordStart() def _setupDAQ(self): """ Sets up some digital IO for sync and tiggering. """ print('SETTING UP DAQ') try: if self.invertdo: istate = 'low' else: istate = 'high' self.do = DigitalOutput(self.nidevice, self.doport, initial_state='low') self.do.StartTask() except: # Exception, e: print("Error starting DigitalOutput task:") self.do = None try: self.di = DigitalInput(self.nidevice, self.diport) self.di.StartTask() except: # Exception, e: print("Error starting DigitalInput task:") self.di = None # try: # set up 8 channels, only use 2 though for now self.ai = AnalogInput(self.nidevice, range(8), buffer_size=25, terminal_config='RSE', clock_speed=6000.0, voltage_range=[-5.0, 5.0]) self.ai.StartTask() # except:# Exception, e: # print("Error starting AnalogInput task:") # self.ai = None try: self.ao = AnalogOutput(self.nidevice, channels=[0, 1], terminal_config='RSE', voltage_range=[0.0, 5.0]) self.ao.StartTask() except: # Exception, e: print("Error starting AnalogOutput task:") self.ao = None def read_keys(self): self.upArrowIsPressed = base.mouseWatcherNode.isButtonDown(KeyboardButton.up()) self.downArrowIsPressed = base.mouseWatcherNode.isButtonDown(KeyboardButton.down()) self.rightArrowIsPressed = base.mouseWatcherNode.isButtonDown(KeyboardButton.right()) self.leftArrowIsPressed = base.mouseWatcherNode.isButtonDown(KeyboardButton.left()) def save_data(self): if not os.path.isdir(os.path.join(os.getcwd(), 'data')): os.mkdir(os.path.join(os.getcwd(), 'data')) save_path = os.path.join(os.getcwd(), 'data', str(MOUSE_ID) + '_' + \ str(self.session_start_time.year) + '_' + \ str(self.session_start_time.month) + '_' + \ str(self.session_start_time.day) + '-' + \ str(self.session_start_time.hour) + '_' + \ str(self.session_start_time.minute) + '_' + \ str(self.session_start_time.second)) if not os.path.isdir(save_path): os.mkdir(save_path) print("saving data to " + save_path) np.save(os.path.join(save_path, 'licks.npy'), self.lickData) np.save(os.path.join(save_path, 'x.npy'), self.x) np.save(os.path.join(save_path, 't.npy'), self.t) np.save(os.path.join(save_path, 'trialData.npy'), self.trialData) np.save(os.path.join(save_path, 'rewardData.npy'), self.rewardData) np.save(os.path.join(save_path, 'rtData.npy'), self.reactionTimeData) np.save(os.path.join(save_path, 'rightKeyData.npy'), self.rightKeyData) np.save(os.path.join(save_path, 'leftKeyData.npy'), self.leftKeyData) np.save(os.path.join(save_path, 'imageData.npy'), self.imageData) np.save(os.path.join(save_path, 'imageTimeData.npy'), self.imageTimeData) np.save(os.path.join(save_path, 'scoreData.npy'), self.scoreData) np.save(os.path.join(save_path, 'trialDurationData.npy'), self.trialDurationData) np.save(os.path.join(save_path, 'dT.npy'), self.new_dt) def close(self): self.save_data() print('rewardData:') print(np.shape(self.rewardData)) try: #push anonymized data to Denman Lab Open Science Framework project for human psychophysics subprocess.call('osf -p 7xruh -u [email protected] upload -r '+save_path+' data/'+os.path.basename(save_path),shell=True) #commented these lines out to test if saving to osf is the hangup; it's not except:pass sys.exit(0)