class ShapeImageGenerator(object): def __init__(self): self.model_path = '' self.vis = Vis() self.Hand = HandVis(self.vis) self.Hand.loadHand() self.Hand.localTranslation(np.array([0,0,-0.075])) #offset so palm is at 0,0,0 self.Obj = ObjectGenericVis(self.vis) self.groundPlane = AddGroundPlane(self.vis) self.loadSTLFileList() def loadSTLFileList(self): # get all STL files in directory self.STLFileList = list() directory = curdir + '/../ShapeGenerator/Shapes' for root, dirs, filenames in os.walk(directory): if filenames != []: for fname in filenames: if os.path.splitext(fname)[1] == '.stl': #only want stl files self.STLFileList.append(root + '/' + fname) def valuesFromFileName(self, fn_abs): # gets features of object from file name fn = fn_abs.split('/')[-1] fn_parts = fn.strip('.stl').split('_') shape = fn_parts[0] h = int(fn_parts[1].strip('h')) w = int(fn_parts[2].strip('w')) e = int(fn_parts[3].strip('e')) a = None if len(fn_parts) == 5: # extra feature when there is alpha a = int(fn_parts[4].strip('a')) return shape, h, w, e, a def loadObject(self, objtype, h, w, e, a = None): # loads stl object into scene # only centroid that hasn't been dealt with is the handle. # all centroids shoudl be in the center of the object self.Obj.features['type'] = objtype self.Obj.features['h'] = h self.Obj.features['w'] = w self.Obj.features['e'] = e self.Obj.features['a'] = a result = self.Obj.loadObject(objtype, h, w, e, a) return result def setObjTransparent(self, alpha = 0.5): # change transparency of object self.Obj.changeColor(alpha = alpha) # this can be changed to changeColor def readParameterFile(self, fn): # reads in parameters for creating images from a CSV file params_list = list() with open(fn, 'rb') as file: csvreader = csv.reader(file, delimiter = ',') headers = csvreader.next() for row in csvreader: D = dict() for header,val in zip(headers,row): D[header] = val params_list.append(D) for ip in range(len(params_list)): for k in params_list[ip].keys(): if 'Joint Angles' == k: try: params_list[ip][k] = np.array(params_list[ip][k].split(',')).astype('float')#convert to numpy array except Exception: # for when that entry is blank like when no hand in image # params_list[ip][k] = np.zeros(10) # set to some position so error is not thrown pass elif 'Hand Matrix' == k: # extract array try: params_list[ip][k] = self.stringToArray(params_list[ip][k]) except Exception: # for when that entry is blank like when no hand in image # params_list[ip][k] = np.eye(4) # set to some position so error is not thrown pass elif 'Image Save Name' == k: params_list[ip][k] += '.png' # add extension elif 'Model' == k: params_list[ip][k] += '.stl' # add extension elif 'Model Matrix' == k: # extract array mat_str = params_list[ip][k] mat_num = self.stringToArray(mat_str) params_list[ip][k] = mat_num elif 'Camera Transform' == k: params_list[ip][k] = np.array(params_list[ip][k].split(',')).astype('float')#convert to numpy array elif 'Image Size' == k: i = 1 # should do soemthing here else: print('Unexpected Key: %s' %(k)) self.params_list = params_list return self.params_list def stringToArray(self, mat_str): # Description: convert string to array # had to do this because it is really easy to just copy and paste a matrix into spreadsheet (or save through DictWriter) # The matrix is also much easier to read in the csv file in this form # downside is that when you read it out, the brackets are part of the string. # this can be done in fewer, more efficient steps with regex, but i couldn't figure it out mat_re = re.findall(r'\[.*?\]', mat_str) mat_strip = [t.strip('[]') for t in mat_re] mat_num = np.array([t.split() for t in mat_strip]).astype('float') return mat_num def createImagesFromParametersList(self, shapes = None): # creates images from a list of parameters print("Total: %s" %(len(self.params_list))) counter = 0 for params in self.params_list: counter += 1 if ((shapes == None) or (params['Model'].split('_')[0] in shapes)): # allows only a single set of shapes to be made from list. Mostly during development imageSuccess = self.createImageFromParameters(params) # if not imageSuccess: # pdb.set_trace() print("Current: %s" %counter) def createImageFromParameters(self, params): # creates image from a single set of parameters objLoadSuccess = self.loadObjectFromParameters(params) if objLoadSuccess: self.groundPlane.createGroundPlane(y_height = self.Obj.h/2.0/100) # self.vis.changeBackgroundColor(self.groundPlane.groundPlane.GetLinks()[0].GetGeometries()[0].GetAmbientColor()) self.Obj.changeColor('purpleI') self.Hand.changeColor('yellowI') cam_params = params['Camera Transform'] self.vis.setCamera(cam_params[0], cam_params[1], cam_params[2]) if params['Joint Angles'] is not '' and params['Hand Matrix'] is not '': self.Hand.show() self.Hand.setJointAngles(params['Joint Angles']) self.Hand.obj.SetTransform(params['Hand Matrix']) else: #for images where no hand is shown self.Hand.hide() self.Obj.obj.SetTransform(params['Model Matrix']) if np.sum(self.Obj.obj.GetTransform() - matrixFromAxisAngle([0,0,np.pi/2])) < 1e-4: #if object is rotated 90, use different dimension self.groundPlane.createGroundPlane(y_height = self.Obj.w/2.0/100) else: #offset by height if no rotation -- this is not a great solution when object starts to rotate! self.groundPlane.createGroundPlane(y_height = self.Obj.h/2.0/100) # this should definitely be taken care of when making the spreadsheet pts = self.Hand.getContactPoints() while len(pts) > 0: self.Hand.moveY(-0.001) pts = self.Hand.getContactPoints() # pdb.set_trace() self.vis.takeImage(params['Image Save Name'], delay = True) print("Image Recorded: %s" %params['Image Save Name']) return True else: print("Model Not Found: %s" %params['Model']) return False def loadObjectFromParameters(self, params): # loads objects from a single set of parameters objLoadSuccess = self.Obj.loadObjectFN(self.Obj.stl_path + params['Model']) return objLoadSuccess def loadHandFromParameters(self, params): # sets hand features from a single set of parameters self.Hand.show() self.Hand.setJointAngles(params['Joint Angles']) self.Hand.obj.SetTransform(params['Hand Matrix']) def loadSceneFromParameters(self, params): self.loadObjectFromParameters(params) self.loadHandFromParameters(params) def getParameterFromList(self, list_indx): return self.params_list[list_indx] #get parameters from a location in the list
class HandView(object): def __init__(self, handColor, objColor, grasps): self.setDefaults(handColor, objColor) self.setView() self.grasps = grasps def setDefaults(self, handColor, objColor): #handColor and objColor are colors from Colors.py #sets any start hardcoded values self.fingerOpeningDict = {1: False, 2: False, 3: False} self.handMovingForward = {"X": False, "Y": False, "Z": False} self.ignoreContact = {"1": True, "2": True, "3": True, "Palm": True} self.distJointAngles = {"min": 0, "max": .837} self.medJointAngles = {"min": 0, "max": 2.44} self.handColor = handColor self.objColor = objColor def addGroundPlane(self): #adds a ground plane to the scene self.ground = AddGroundPlane(self.vis) self.ground.createGroundPlane(.175) def setView(self): #creates a scene with a ground plane self.vis = Vis() self.vis.setCamera(60, 7 * np.pi / 8, 0) self.addGroundPlane() def addHand(self, grasp): #grasp is either "The Two-fer", "The Claw", "The Pinch", "The Cup" #adds the hand to the scene and sets the grasp and wrist rotation self.Hand = HandVis(self.vis) self.Hand.loadHand() self.Hand.changeColor(self.handColor) self.setGrasp(grasp) self.setWristRotation('Z', 0) def addObject(self, objParameters): #objParameters = {"shape":,"h":,"w":,"e":,"a":} #adds an object to the scene based on the object parameters #shifts the hand accordingly self.Obj = ObjectGenericVis(self.vis) self.setHandTranslation( 'Z', -.075 - (float(objParameters["e"]) / 100) - .02) self.setObject(objParameters) self.Obj.changeColor(self.objColor) def setIgnoreAllContact(self, value): #value is either True or False #sets all fingers and palm to ignore or not ignore contact with the object for link in self.ignoreContact: self.ignoreContact[link] = value def setIgnoreFingerContact(self, value): #value is either True or False #sets all fingers to ignore or not ignore contact with the object for link in self.ignoreContact: if link != "Palm": self.ignoreContact[link] = value def totalNumberofTranslationIncrements(self, newOffset, increment): #newOffset is a float and increment is a float #returns the total number of iterations of the increment to reach the newOffset return int(math.ceil((newOffset + increment) / increment)) def translateHand(self, dimension, amount): #direction should be either 'X', 'Y', or 'Z' ;;; amount is a float #shifts the hand in relation to the object in the direction of the dimension by the amount if dimension == 'X': self.Hand.localTranslation(np.array([amount, 0, 0])) elif dimension == 'Y': self.Hand.localTranslation(np.array([0, amount, 0])) elif dimension == 'Z': self.Hand.localTranslation(np.array([0, 0, amount])) def tryTranslateHandByOneIncrement(self, dimension, increment): #direction should be either 'X', 'Y', or 'Z' ;;; increment is a float #shifts the hand in the direction of dimension by the increment #if hand comes into contact with the object and contact is not ignored, #hand backs up to where it started and returns False, otherwise returns True #if contact is ignored, but the palm is not in contact, it no longer ignores contact self.translateHand(dimension, increment) pC = self.palmContact() if self.ignoreContact["Palm"]: self.ignoreContact["Palm"] = pC return True else: if pC: self.setHandTranslation(dimension, -increment) return False else: return True def setHandTranslation(self, dimension, newOffset): #shifts the hand in the direction of dimension by the newOffset #if shifting the hand causes a collision between the palm and object, #hand is shifted in the opposite direction by one increment so it is no longer touching #returns the amount by which the hand was shifted direction = newOffset / abs(newOffset) increment = .005 * direction for i in range( 1, self.totalNumberofTranslationIncrements(newOffset, increment)): if not self.tryTranslateHandByOneIncrement(dimension, increment): return (i - 1) * increment return newOffset def setWristRotation(self, direction, rotation): #direction should be either 'X', 'Y', or 'Z' ;;; rotation is a float #rotates the hand's wrist in the direction specified #sets ignore contact for every finger/palm if direction == 'X': rot = matrixFromAxisAngle([rotation, 0, 0]) elif direction == 'Y': rot = matrixFromAxisAngle([0, rotation, 0]) elif direction == 'Z': rot = matrixFromAxisAngle([0, 0, rotation]) self.Hand.localRotation(rot) self.setIgnoreAllContact(True) def setObjRotation(self, direction, rotation): #direction should be either 'X', 'Y', or 'Z' ;;; rotation is a float #rotates the object in the direction specified #sets ignore contact for every finger/palm if direction == 'X': rot = matrixFromAxisAngle([rotation, 0, 0]) elif direction == 'Y': rot = matrixFromAxisAngle([0, rotation, 0]) elif direction == 'Z': rot = matrixFromAxisAngle([0, 0, rotation]) self.Obj.localRotation(rot) self.setIgnoreAllContact(True) def setObject(self, newObj): #newObj is a dict {"shape":, "h":, "w":, "e":, "a":} #assumes an object has already been added with addObject #sets ignore contact for every finger/palm if newObj["shape"] == 'cone': self.Obj.loadObject(newObj["shape"], int(newObj["h"]), int(newObj["w"]), int(newObj["e"]), int(newObj["a"])) else: self.Obj.loadObject(newObj["shape"], int(newObj["h"]), int(newObj["w"]), int(newObj["e"]), None) self.Obj.changeColor(self.objColor) self.setIgnoreAllContact(True) def setGrasp(self, newGrasp): #newGrasp is one of the keys in self.grasps #sets the grasp so that it goes to a certain pregrasp #sets ignore contact for every finger/palm #returns the new grasp array so the finger sliders can be reset self.grasp = self.grasps[newGrasp] self.showGrasp() self.setIgnoreFingerContact(True) return self.grasp def getMedJointAngle(self, percentClosed): #percentClosed is a float 0<>100 #returns the grasp array value for a med joint given the percent it is closed return ((self.medJointAngles["max"] - self.medJointAngles["min"]) * percentClosed) + self.medJointAngles["min"] def getDistJointAngle(self, percentClosed): #percentClosed is a float 0<>100 #returns the grasp array value for a the dist joint given the percent it is closed return ((self.distJointAngles["max"] - self.distJointAngles["min"]) * percentClosed) + self.distJointAngles["min"] def fingerOpening(self, finger, percentClosed): #finger is either 1, 2, or 3 #percentClosed is a float 0<>100 #returns a bool if finger == 1: return self.getMedJointAngle(percentClosed) < self.grasp[3] elif finger == 2: return self.getMedJointAngle(percentClosed) < self.grasp[6] elif finger == 3: return self.getMedJointAngle(percentClosed) < self.grasp[8] def anyFingerContact(self): #returns whether any finger is in contact with the object for contact in self.Hand.getContact(self.Obj.boj).keys(): if contact.find("finger_") != -1 and contact[-9:] != "prox_link": return True return False def fingerContact(self, finger): #finger should be either 1, 2, or 3 #returns whether the provided finger is in contact with the object for contact in self.Hand.getContact(self.Obj.obj).keys(): if contact.find("finger_" + str(finger)) != -1 and contact[-9:] != "prox_link": return True return False def fullFingerContact(self, finger): #finger is either 1, 2, or 3 #if the tip finger link is in contact, returns 't' (finger is fully in contact) #if only the lower finger link is in contact, returns 's' (only lower link in contact) #if there is no contact return 'f' (nothing is in contact) someContact = False for contact in self.Hand.getContact(self.Obj.obj).keys(): if contact.find("finger_" + str(finger)) != -1 and contact[-9:] == "dist_link": return 't' elif contact.find("finger_" + str(finger) ) != -1 and contact[-8:] == "med_link": someContact = True if someContact: return 's' else: return 'f' def palmContact(self): #returns whether or not the palm is in contact with the object for contact in self.Hand.getContact(self.Obj.obj).keys(): if contact[-9:] == "palm_link": return True return False def fingerChangingDirection(self, finger, percentClosed): #finger is either 1, 2, or 3 #percentClosed is a float 0<>100 #determines if the finger's motion has changed (was closing, now opening or was opening, now closing) return self.fingerOpening( finger, percentClosed) != self.fingerOpeningDict[finger] def fingerCanBeMovedThisWay(self, finger, percentClosed, contact): #finger is either 1, 2, or 3 #percentClosed is a float 0<>100 #contact is either 't', 'f', or 's' return self.ignoreContact[str(finger)] or self.fingerChangingDirection( finger, percentClosed) or contact != 't' def setFingerPosition(self, finger, percentClosed, contact): #finger is either 1, 2, or 3 #percentClosed is a float 0<>100 #contact is either 't'(rue), 'f'(alse), or 's'(some) #sets the new grasp values for the finger joints depending on which fingers have contact if finger == 1: if contact == 'f': self.grasp[3] = self.getMedJointAngle(percentClosed) self.grasp[4] = self.getDistJointAngle(percentClosed) elif finger == 2: if contact == 'f': self.grasp[6] = self.getMedJointAngle(percentClosed) self.grasp[7] = self.getDistJointAngle(percentClosed) elif finger == 3: if contact == 'f': self.grasp[8] = self.getMedJointAngle(percentClosed) self.grasp[9] = self.getDistJointAngle(percentClosed) self.showGrasp() print self.grasp def changeFingerPosition(self, finger, percentClosed): #finger is either 1, 2, or 3 #percentClosed is a float 0<>100 #changes the finger position to the new percentage if possible #checks the ignoreContact safeguard can be removed #returns whether or not the finger could be moved as suggested contact = self.fullFingerContact(finger) if self.fingerCanBeMovedThisWay(finger, percentClosed, contact): self.fingerOpeningDict[finger] = self.fingerOpening( finger, percentClosed) self.setFingerPosition(finger, percentClosed, contact) if self.ignoreContact[str(finger)]: self.ignoreContact[str(finger)] = self.fingerContact(finger) return True return False def getFingerPositionPercent(self, finger): #finger is either 1, 2, or 3 #returns the percent of the finger closed if finger == 1: return (self.grasp[3] - self.medJointAngles["min"]) / ( self.medJointAngles["max"] - self.medJointAngles["min"]) elif finger == 2: return (self.grasp[6] - self.medJointAngles["min"]) / ( self.medJointAngles["max"] - self.medJointAngles["min"]) elif finger == 3: return (self.grasp[8] - self.medJointAngles["min"]) / ( self.medJointAngles["max"] - self.medJointAngles["min"]) def showGrasp(self): #sets the Hand to the new grasp self.Hand.setJointAngles(self.grasp)
def Test11(self): # Description: Generating Images for Interpolated Grasps # Oriignal is grey # 180 + noise grasp is pink # interpolated is violet # do STLs with noise after this. V = Vis() Hand1 = HandVis(V) Hand1.loadHand() Hand2 = HandVis(V) Hand2.loadHand() Obj1 = ObjectVis(V) Obj1.loadObject(4) Obj1.changeColor('green') Data = ParseGraspData() Data.parseOutputData() Data.parseAllTransforms() # obj4_cluster13_sub5_grasp2_optimal0_prime.jpg obj4_cluster13_sub5_grasp3_extreme1_target.jpg -- don't have the data. Tried without class but extreme grasp was too far! # grasp1 = Data.findGrasp(objnum = 4, subnum = 5, graspnum = 2, grasptype = 'optimal0', list2check = Data.all_transforms) # grasp2 = Data.findGrasp(objnum = 4, subnum = 5, graspnum = 3, grasptype = 'extreme1', list2check = Data.all_transforms) # obj4_cluster8_sub4_grasp14_extreme1_prime.jpg obj4_cluster8_sub4_grasp14_optimal0_target.jpg -- don't have the data # grasp1 = Data.findGrasp(objnum = 4, subnum = 4, graspnum = 14, grasptype = 'extreme1', list2check = Data.all_transforms) # grasp2 = Data.findGrasp(objnum = 4, subnum = 4, graspnum = 14, grasptype = 'optimal0', list2check = Data.all_transforms) # obj4_cluster8_sub4_grasp14_extreme1_prime.jpg obj4_cluster8_sub4_grasp9_optimal0_target.jpg -- don't have the data case = 4 #ones that I think look good if case == 1: grasp1 = Data.findGrasp(objnum=4, subnum=4, graspnum=11, grasptype='optimal0', list2check=Data.all_transforms) grasp2 = Data.findGrasp(objnum=4, subnum=4, graspnum=11, grasptype='optimal0', list2check=Data.all_transforms) filename_base = "obj%s_sub%s_graspnum%s_%s_%s" % ( 4, 4, 11, 'optimal0', 'optimal0') elif case == 2: grasp1 = Data.findGrasp(objnum=4, subnum=5, graspnum=2, grasptype='optimal0', list2check=Data.all_transforms) grasp2 = Data.findGrasp(objnum=4, subnum=5, graspnum=3, grasptype='extreme1', list2check=Data.all_transforms) filename_base = "obj%s_sub%s_graspnum%s_%s_%s" % ( 4, 5, '2&3', 'optimal0', 'extreme1') elif case == 3: grasp1 = Data.findGrasp(objnum=4, subnum=4, graspnum=14, grasptype='extreme1', list2check=Data.all_transforms) grasp2 = Data.findGrasp(objnum=4, subnum=4, graspnum=14, grasptype='optimal0', list2check=Data.all_transforms) filename_base = "obj%s_sub%s_graspnum%s_%s_%s" % ( 4, 4, 14, 'extreme1', 'optimal0') elif case == 4: grasp1 = Data.findGrasp(objnum=4, subnum=4, graspnum=14, grasptype='extreme1', list2check=Data.all_transforms) grasp2 = Data.findGrasp(objnum=4, subnum=4, graspnum=9, grasptype='optimal0', list2check=Data.all_transforms) filename_base = "obj%s_sub%s_graspnum%s_%s_%s" % ( 4, 4, '14&9', 'extreme1', 'optimal0') HandT1, ObjT1, Arm_JA1, Hand_JA1 = Data.matricesFromGrasp(grasp1[0]) HandT2, ObjT2, Arm_JA2, Hand_JA2 = Data.matricesFromGrasp(grasp2[0]) Hand1.orientHandtoObj(HandT1, ObjT1, Obj1) Hand1.setJointAngles(Hand_JA1) Hand1.changeColor('greyI') Hand2.orientHandtoObj(HandT2, ObjT2, Obj1) Hand2.setJointAngles(Hand_JA2) Hand2.changeColor('pinkI') Hand1.getPalmPoint() contact_points1, contact_links1 = Hand1.retractFingers(Obj1) contact_points2, contact_links2 = Hand2.retractFingers(Obj1) start_axis_angle = np.array([0, 0, 0]) end_axis_angle = np.array([0, np.pi, 0]) Hand2.ZSLERP(start_axis_angle, end_axis_angle, 1, T_zero=Hand2.obj.GetTransform()) Hand3 = HandVis(V) Hand3.loadHand() Hand3.makeEqual(Hand1) Hand3.changeColor('blueI') alpha = np.linspace(0, 1, 6)[1:-1] if case == 1: V.setCamera(60, 0, 5 / 4 * np.pi - 0.75) elif case == 2: V.setCamera(60, np.pi / 4 - 1.5, -np.pi - 1) elif case == 3: V.setCamera(40, np.pi / 3 + 0.2, -np.pi - 0.5) elif case == 4: V.setCamera(40, np.pi / 3 - np.pi, -np.pi - 0.75) # pdb.set_trace() # function to get out dist, az, el of camera from current view for a in alpha: filename = filename_base + "_alpha%s.png" % (int(10 * a)) Hand3.ZSLERP(start_axis_angle, end_axis_angle, a, T_zero=Hand1.obj.GetTransform()) V.clearPoints() V.takeImage(filename) time.sleep(1)
class TrainingVideo(object): def __init__(self): self.vis = Vis() self.Hand = HandVis(self.vis) self.Hand.loadHand() self.Obj = ObjectGenericVis(self.vis) self.GP = AddGroundPlane(self.vis) self.demoObj = list() self.frameCount = 0 self.start_offset = 0 def recordFrame(self): fn = 'Image%04d.png' %self.frameCount self.vis.takeImage(fn, delay = False) self.frameCount += 1 # Kadon Engle - last edited 07/14/17 def fingerRecord(self, oldJA, newJA): # Records a frame for multiple join angles between the starting array (OldJA) amd the ending array (newJA) try: frame_rate = 20 # An arbitrary base line for the frames in each hand movement frames = int(max(abs(newJA - oldJA)) * frame_rate) Angles = [] self.Hand.setJointAngles(oldJA) if len(self.Hand.getContactPoints()) > 0: self.Hand.setJointAngles(iP[-1]) for i in range(frames): Angles.append(list()) for i in range(len(oldJA)): current = np.linspace(oldJA[i], newJA[i], frames) for k in range(frames): Angles[k].append(current[k]) for n, i in enumerate(Angles): #More work is necessary on detecting finger collision to stop the fingers self.Hand.setJointAngles(np.array(i)) if len(self.Hand.getContactPoints()) > 0: self.Hand.setJointAngles(Angles[n-1]) return Angles[n-1] self.recordFrame() return Angles[n-1] except: print "Invalid Joint Angle" # Kadon Engle - last edited 07/14/17 def handRecord(self, x, y, z): # Records frames as hand moves in x, y, and/or z direction self.T_current = self.Hand.obj.GetTransform() T = copy.deepcopy(self.T_current) xyz = [x, y, z] frames = 20 # Arbitrary value, needs to be changed so that when x, y, or z moves shorter distances, it records less frames. Should be changed so that it records less frames for shorter movements and more frames for longer movements. for idx, i in enumerate(xyz): if abs(i - self.T_current[idx,3]) > 0.1e-5: V = np.linspace(self.T_current[idx,3], i, frames) for n in V: T[idx,3] = n self.Hand.obj.SetTransform(T) self.recordFrame() def stationaryRecord(self, frames): for i in range(int(frames)): self.recordFrame() def createVideo(self, fn): # creates a video from images recorded in previous section # there is a built in openrave function which would be much better, but doesn't work on all hardware # uses PIL and cv2. opencv is a pain to setup, so may not be worth the hassle try: if os.path.splitext(fn)[1] != '.avi': print("Did not save Video: Invalid File Name") return initImage = Image.open('Image0001.png') height, width, layers = np.array(initImage).shape fourcc = cv2.VideoWriter_fourcc(*'XVID') video = cv2.VideoWriter(fn, fourcc, 24, (width, height)) Files = os.listdir(curdir) for file in np.sort(Files): if os.path.splitext(file)[1] == '.png': image = Image.open(file) video.write(cv2.cvtColor(numpy.array(image), cv2.COLOR_RGB2BGR)) video.release() except: print 'Something went wrong. Maybe you didn\'t record any images' # native linux method -- most likely to work # subprocess.call(["avconv", "-f", "image2", "-i", "Image%04d.png", "-r", "5", "-s", "800x600", fn+".avi"]) def removeImages(self): # remove image files that were created Files = os.listdir(curdir) for file in Files: if os.path.splitext(file)[1] == '.png': os.remove(file) def VLCPlay(self, fn): subprocess.call(["vlc", fn]) def Video1(self): # setup self.Obj.loadObject('cube',36,18,3,None) # TODO: Object with larger extent! self.Obj.changeColor('purpleI') self.Hand.changeColor('mustard') self.GP.createGroundPlane(0.175) extent_offset = -3.0/100 # offset by thickness of object palm_offset = -0.075 #offset so palm is at 0,0,0 clearance_offset = -1.0/100 # offset to have clearance between palm and object self.start_offset = extent_offset + palm_offset + clearance_offset self.Hand.localTranslation(np.array([0, 0, self.start_offset])) rot = matrixFromAxisAngle([0,0, np.pi/2]) self.Hand.localRotation(rot) # rotate hand to put stationary finger on one side of object self.T_start = self.Hand.obj.GetTransform() # get starting transform so everything can be done relative to this oHand = np.array([0, 0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0]) # position fingers such that hand can move in x, y, and z without hitting object cHand = np.array([0, 0, 0.0, 1.3, 0.4, 0.0, 1.3, 0.4, 1.3, 0.4]) # position fingers such that the hand will be closed around the object without hititng it self.Hand.setJointAngles(oHand) dist_range_min = -0.1 dist_range_max = 0.1 frame_rate = 20/0.1 # frames/cm # Different arbitrary camera angles for needed viewpoints # self.vis.setCamera(60,3*np.pi/4,-np.pi/4-0.1) # self.vis.setCamera(60, np.pi, -np.pi/2) # top view # self.vis.setCamera(60, -2.25, -np.pi/2.10) self.vis.setCamera(60, -2.25, -0.75) # Numbers are completely arbitrary, gives a good view of object and hand.