def __init__(self, *args, **kwargs): Camera.__init__(self, *args, **kwargs) self.phi_tracker = ValueTracker(self.phi) self.theta_tracker = ValueTracker(self.theta) self.distance_tracker = ValueTracker(self.distance) self.gamma_tracker = ValueTracker(self.gamma) self.light_source = Point(self.light_source_start_point) self.frame_center = Point(self.frame_center) self.reset_rotation_matrix()
class ThreeDCamera(Camera): CONFIG = { "sun_vect": 5 * UP + LEFT, "shading_factor": 0.2, "distance": 20.0, "default_distance": 5.0, "phi": 0, # Angle off z axis "theta": -90 * DEGREES, # Rotation about z axis "gamma": 0, # Rotation about normal vector to camera "light_source_start_point": 9 * DOWN + 7 * LEFT + 10 * OUT, "frame_center": ORIGIN, "should_apply_shading": True, } def __init__(self, *args, **kwargs): Camera.__init__(self, *args, **kwargs) self.phi_tracker = ValueTracker(self.phi) self.theta_tracker = ValueTracker(self.theta) self.distance_tracker = ValueTracker(self.distance) self.gamma_tracker = ValueTracker(self.gamma) self.light_source = Point(self.light_source_start_point) self.frame_center = Point(self.frame_center) self.fixed_orientation_mobjects = set() self.fixed_in_frame_mobjects = set() self.reset_rotation_matrix() def capture_mobjects(self, mobjects, **kwargs): self.reset_rotation_matrix() Camera.capture_mobjects(self, mobjects, **kwargs) def get_value_trackers(self): return [ self.phi_tracker, self.theta_tracker, self.distance_tracker, self.gamma_tracker, ] def modified_rgbas(self, vmobject, rgbas): if not self.should_apply_shading: return rgbas if vmobject.shade_in_3d and (vmobject.get_num_points() > 0): light_source_point = self.light_source.points[0] if len(rgbas) < 2: shaded_rgbas = rgbas.repeat(2, axis=0) else: shaded_rgbas = np.array(rgbas[:2]) shaded_rgbas[0, :3] = get_shaded_rgb( shaded_rgbas[0, :3], get_3d_vmob_start_corner(vmobject), get_3d_vmob_start_corner_unit_normal(vmobject), light_source_point, ) shaded_rgbas[1, :3] = get_shaded_rgb( shaded_rgbas[1, :3], get_3d_vmob_end_corner(vmobject), get_3d_vmob_end_corner_unit_normal(vmobject), light_source_point, ) return shaded_rgbas return rgbas def get_stroke_rgbas(self, vmobject, background=False): return self.modified_rgbas(vmobject, vmobject.get_stroke_rgbas(background)) def get_fill_rgbas(self, vmobject): return self.modified_rgbas(vmobject, vmobject.get_fill_rgbas()) def display_multiple_vectorized_mobjects(self, vmobjects, pixel_array): rot_matrix = self.get_rotation_matrix() def z_key(vmob): # Assign a number to a three dimensional mobjects # based on how close it is to the camera if vmob.shade_in_3d: return np.dot(vmob.get_center(), rot_matrix.T)[2] else: return np.inf Camera.display_multiple_vectorized_mobjects( self, sorted(vmobjects, key=z_key), pixel_array) def get_phi(self): return self.phi_tracker.get_value() def get_theta(self): return self.theta_tracker.get_value() def get_distance(self): return self.distance_tracker.get_value() def get_gamma(self): return self.gamma_tracker.get_value() def get_frame_center(self): return self.frame_center.points[0] def set_phi(self, value): self.phi_tracker.set_value(value) def set_theta(self, value): self.theta_tracker.set_value(value) def set_distance(self, value): self.distance_tracker.set_value(value) def set_gamma(self, value): self.gamma_tracker.set_value(value) def set_frame_center(self, point): self.frame_center.move_to(point) def reset_rotation_matrix(self): self.rotation_matrix = self.generate_rotation_matrix() def get_rotation_matrix(self): return self.rotation_matrix def generate_rotation_matrix(self): phi = self.get_phi() theta = self.get_theta() gamma = self.get_gamma() matrices = [ rotation_about_z(-theta - 90 * DEGREES), rotation_matrix(-phi, RIGHT), rotation_about_z(gamma), ] result = np.identity(3) for matrix in matrices: result = np.dot(matrix, result) return result def project_points(self, points): frame_center = self.get_frame_center() distance = self.get_distance() rot_matrix = self.get_rotation_matrix() points -= frame_center points = np.dot(points, rot_matrix.T) zs = points[:, 2] zs[zs >= distance] = distance - 0.001 for i in 0, 1: points[:, i] *= distance / (distance - zs) points += frame_center return points def project_point(self, point): return self.project_points(point.reshape((1, 3)))[0, :] def transform_points_pre_display(self, mobject, points): fixed_orientation = mobject in self.fixed_orientation_mobjects fixed_in_frame = mobject in self.fixed_in_frame_mobjects if fixed_in_frame: return points if fixed_orientation: center = center_of_mass(points) new_center = self.project_point(center) return points + (new_center - center) else: return self.project_points(points) def add_fixed_orientation_mobjects(self, *mobjects): for mobject in self.extract_mobject_family_members(mobjects): self.fixed_orientation_mobjects.add(mobject) def add_fixed_in_frame_mobjects(self, *mobjects): for mobject in self.extract_mobject_family_members(mobjects): self.fixed_in_frame_mobjects.add(mobject) def remove_fixed_orientation_mobjects(self, *mobjects): for mobject in self.extract_mobject_family_members(mobjects): if mobject in self.fixed_orientation_mobjects: self.fixed_orientation_mobjects.remove(mobject) def remove_fixed_in_frame_mobjects(self, *mobjects): for mobject in self.extract_mobject_family_members(mobjects): if mobject in self.fixed_in_frame_mobjects: self.fixed_in_frame_mobjects.remove(mobject)
class ThreeDCamera(Camera): CONFIG = { "sun_vect": 5 * UP + LEFT, "shading_factor": 0.2, "distance": 20.0, "default_distance": 5.0, "phi": 0, # Angle off z axis "theta": -90 * DEGREES, # Rotation about z axis "gamma": 0, # Rotation about normal vector to camera "light_source_start_point": 9 * DOWN + 7 * LEFT + 10 * OUT, "frame_center": ORIGIN, "should_apply_shading": True, "exponential_projection": False, } def __init__(self, *args, **kwargs): Camera.__init__(self, *args, **kwargs) self.phi_tracker = ValueTracker(self.phi) self.theta_tracker = ValueTracker(self.theta) self.distance_tracker = ValueTracker(self.distance) self.gamma_tracker = ValueTracker(self.gamma) self.light_source = Point(self.light_source_start_point) self.frame_center = Point(self.frame_center) self.fixed_orientation_mobjects = dict() self.fixed_in_frame_mobjects = set() self.reset_rotation_matrix() def capture_mobjects(self, mobjects, **kwargs): self.reset_rotation_matrix() Camera.capture_mobjects(self, mobjects, **kwargs) def get_value_trackers(self): return [ self.phi_tracker, self.theta_tracker, self.distance_tracker, self.gamma_tracker, ] def modified_rgbas(self, vmobject, rgbas): if not self.should_apply_shading: return rgbas if vmobject.shade_in_3d and (vmobject.get_num_points() > 0): light_source_point = self.light_source.points[0] if len(rgbas) < 2: shaded_rgbas = rgbas.repeat(2, axis=0) else: shaded_rgbas = np.array(rgbas[:2]) shaded_rgbas[0, :3] = get_shaded_rgb( shaded_rgbas[0, :3], get_3d_vmob_start_corner(vmobject), get_3d_vmob_start_corner_unit_normal(vmobject), light_source_point, ) shaded_rgbas[1, :3] = get_shaded_rgb( shaded_rgbas[1, :3], get_3d_vmob_end_corner(vmobject), get_3d_vmob_end_corner_unit_normal(vmobject), light_source_point, ) return shaded_rgbas return rgbas def get_stroke_rgbas(self, vmobject, background=False): return self.modified_rgbas(vmobject, vmobject.get_stroke_rgbas(background)) def get_fill_rgbas(self, vmobject): return self.modified_rgbas(vmobject, vmobject.get_fill_rgbas()) def get_mobjects_to_display(self, *args, **kwargs): mobjects = Camera.get_mobjects_to_display(self, *args, **kwargs) rot_matrix = self.get_rotation_matrix() def z_key(mob): if not (hasattr(mob, "shade_in_3d") and mob.shade_in_3d): return np.inf # Assign a number to a three dimensional mobjects # based on how close it is to the camera return np.dot(mob.get_center(), rot_matrix.T)[2] return sorted(mobjects, key=z_key) def get_phi(self): return self.phi_tracker.get_value() def get_theta(self): return self.theta_tracker.get_value() def get_distance(self): return self.distance_tracker.get_value() def get_gamma(self): return self.gamma_tracker.get_value() def get_frame_center(self): return self.frame_center.points[0] def set_phi(self, value): self.phi_tracker.set_value(value) def set_theta(self, value): self.theta_tracker.set_value(value) def set_distance(self, value): self.distance_tracker.set_value(value) def set_gamma(self, value): self.gamma_tracker.set_value(value) def set_frame_center(self, point): self.frame_center.move_to(point) def reset_rotation_matrix(self): self.rotation_matrix = self.generate_rotation_matrix() def get_rotation_matrix(self): return self.rotation_matrix def generate_rotation_matrix(self): phi = self.get_phi() theta = self.get_theta() gamma = self.get_gamma() matrices = [ rotation_about_z(-theta - 90 * DEGREES), rotation_matrix(-phi, RIGHT), rotation_about_z(gamma), ] result = np.identity(3) for matrix in matrices: result = np.dot(matrix, result) return result def project_points(self, points): frame_center = self.get_frame_center() distance = self.get_distance() rot_matrix = self.get_rotation_matrix() points -= frame_center points = np.dot(points, rot_matrix.T) zs = points[:, 2] for i in 0, 1: if self.exponential_projection: # Proper projedtion would involve multiplying # x and y by d / (d-z). But for points with high # z value that causes weird artifacts, and applying # the exponential helps smooth it out. factor = np.exp(zs / distance) lt0 = zs < 0 factor[lt0] = (distance / (distance - zs[lt0])) else: factor = (distance / (distance - zs)) factor[(distance - zs) < 0] = 10**6 # clip_in_place(factor, 0, 10**6) points[:, i] *= factor points += frame_center return points def project_point(self, point): return self.project_points(point.reshape((1, 3)))[0, :] def transform_points_pre_display(self, mobject, points): fixed_orientation = mobject in self.fixed_orientation_mobjects fixed_in_frame = mobject in self.fixed_in_frame_mobjects if fixed_in_frame: return points if fixed_orientation: # center = center_of_mass(points) center_func = self.fixed_orientation_mobjects[mobject] center = center_func() new_center = self.project_point(center) return points + (new_center - center) else: return self.project_points(points) def add_fixed_orientation_mobjects(self, *mobjects, use_static_center_func=False, center_func=None): # This prevents the computation of mobject.get_center # every single time a projetion happens def get_static_center_func(mobject): point = mobject.get_center() return (lambda: point) for mobject in mobjects: if center_func: func = center_func elif use_static_center_func: func = get_static_center_func(mobject) else: func = mobject.get_center for submob in mobject.get_family(): self.fixed_orientation_mobjects[submob] = func def add_fixed_in_frame_mobjects(self, *mobjects): for mobject in self.extract_mobject_family_members(mobjects): self.fixed_in_frame_mobjects.add(mobject) def remove_fixed_orientation_mobjects(self, *mobjects): for mobject in self.extract_mobject_family_members(mobjects): if mobject in self.fixed_orientation_mobjects: self.fixed_orientation_mobjects.remove(mobject) def remove_fixed_in_frame_mobjects(self, *mobjects): for mobject in self.extract_mobject_family_members(mobjects): if mobject in self.fixed_in_frame_mobjects: self.fixed_in_frame_mobjects.remove(mobject)
class ThreeDCamera(Camera): CONFIG = { "sun_vect": 5 * UP + LEFT, "shading_factor": 0.2, "distance": 20.0, "default_distance": 5.0, "phi": 0, # Angle off z axis "theta": -90 * DEGREES, # Rotation about z axis "gamma": 0, # Rotation about normal vector to camera "light_source_start_point": 9 * DOWN + 7 * LEFT + 10 * OUT, "frame_center": ORIGIN, } def __init__(self, *args, **kwargs): Camera.__init__(self, *args, **kwargs) self.phi_tracker = ValueTracker(self.phi) self.theta_tracker = ValueTracker(self.theta) self.distance_tracker = ValueTracker(self.distance) self.gamma_tracker = ValueTracker(self.gamma) self.light_source = Point(self.light_source_start_point) self.frame_center = Point(self.frame_center) self.reset_rotation_matrix() def capture_mobjects(self, mobjects, **kwargs): self.reset_rotation_matrix() Camera.capture_mobjects(self, mobjects, **kwargs) def get_value_trackers(self): return [ self.phi_tracker, self.theta_tracker, self.distance_tracker, self.gamma_tracker, ] def modified_rgbas(self, vmobject, rgbas): is_3d = isinstance(vmobject, ThreeDVMobject) has_points = (vmobject.get_num_points() > 0) if is_3d and has_points: light_source_point = self.light_source.points[0] if len(rgbas) < 2: shaded_rgbas = rgbas.repeat(2, axis=0) else: shaded_rgbas = np.array(rgbas[:2]) shaded_rgbas[0, :3] = get_shaded_rgb( shaded_rgbas[0, :3], vmobject.get_start_corner(), vmobject.get_start_corner_unit_normal(), light_source_point, ) shaded_rgbas[1, :3] = get_shaded_rgb( shaded_rgbas[1, :3], vmobject.get_end_corner(), vmobject.get_end_corner_unit_normal(), light_source_point, ) return shaded_rgbas return rgbas def get_stroke_rgbas(self, vmobject, background=False): return self.modified_rgbas( vmobject, vmobject.get_stroke_rgbas(background) ) def get_fill_rgbas(self, vmobject): return self.modified_rgbas( vmobject, vmobject.get_fill_rgbas() ) def display_multiple_vectorized_mobjects(self, vmobjects, pixel_array): rot_matrix = self.get_rotation_matrix() def z_key(vmob): # Assign a number to a three dimensional mobjects # based on how close it is to the camera if isinstance(vmob, ThreeDVMobject): return np.dot( vmob.get_center(), rot_matrix.T )[2] else: return np.inf Camera.display_multiple_vectorized_mobjects( self, sorted(vmobjects, key=z_key), pixel_array ) def get_phi(self): return self.phi_tracker.get_value() def get_theta(self): return self.theta_tracker.get_value() def get_distance(self): return self.distance_tracker.get_value() def get_gamma(self): return self.gamma_tracker.get_value() def get_frame_center(self): return self.frame_center.points[0] def set_phi(self, value): self.phi_tracker.set_value(value) def set_theta(self, value): self.theta_tracker.set_value(value) def set_distance(self, value): self.distance_tracker.set_value(value) def set_gamma(self, value): self.gamma_tracker.set_value(value) def set_frame_center(self, point): self.frame_center.move_to(point) def reset_rotation_matrix(self): self.rotation_matrix = self.generate_rotation_matrix() def get_rotation_matrix(self): return self.rotation_matrix def generate_rotation_matrix(self): phi = self.get_phi() theta = self.get_theta() gamma = self.get_gamma() matrices = [ rotation_about_z(-theta - 90 * DEGREES), rotation_matrix(-phi, RIGHT), rotation_about_z(gamma), ] result = np.identity(3) for matrix in matrices: result = np.dot(matrix, result) return result def transform_points_pre_display(self, points): fc = self.get_frame_center() distance = self.get_distance() points -= fc rot_matrix = self.get_rotation_matrix() points = np.dot(points, rot_matrix.T) zs = points[:, 2] points[:, 0] *= (distance + zs) / distance points[:, 1] *= (distance + zs) / distance points += fc return points