Example #1
0
 def get_ground_bounces(self):
     # returns bounce prediction as [[[game_seconds],...],
     # [vec3(location.x, location.y, location.z)],...]]
     # Based on the fact that angular velocity changes on each bounce
     self.ground_bounce = [[], []]
     for p_slice in range(1, self.ball_prediction_font.num_slices):
         prev_ang_v = self.ball_prediction_font.slices[
             p_slice - 1].physics.angular_velocity
         prev_norm_ang_vel = (math.sqrt(prev_ang_v.x**2 + prev_ang_v.y**2 +
                                        prev_ang_v.z**2))
         current_slice = self.ball_prediction_font.slices[p_slice]
         current_ang_v = self.ball_prediction_font.slices[
             p_slice].physics.angular_velocity
         current_norm_ang_vel = (math.sqrt(current_ang_v.x**2 +
                                           current_ang_v.y**2 +
                                           current_ang_v.z**2))
         if prev_norm_ang_vel != current_norm_ang_vel and current_slice.physics.location.z < 125:
             self.ground_bounce[0] = self.ground_bounce[0] + [
                 current_slice.game_seconds
             ]
             self.ground_bounce[1] = self.ground_bounce[1] + [
                 la.vec3(current_slice.physics.location.x,
                         current_slice.physics.location.y,
                         current_slice.physics.location.z)
             ]
     return
Example #2
0
 def return_ball_prediction(self, draw=False):
     # returns ball prediction as [[[game_seconds],...],
     # [vec3(prediction_loc.x, prediction_loc.y, prediction_loc.z)],...]]
     self.ball_prediction_font = self.get_ball_prediction_struct()
     self.ball_prediction = [[], []]
     self.ball_prediction[0] = [None] * self.ball_prediction_font.num_slices
     self.ball_prediction[1] = [None] * self.ball_prediction_font.num_slices
     if self.ball_prediction_font is not None:
         for p_slice in range(0, self.ball_prediction_font.num_slices):
             prediction_slice = self.ball_prediction_font.slices[p_slice]
             prediction_loc = prediction_slice.physics.location
             self.ball_prediction[0][
                 p_slice] = prediction_slice.game_seconds
             self.ball_prediction[1][p_slice] = la.vec3(
                 prediction_loc.x, prediction_loc.y, prediction_loc.z)
         if draw:
             self.renderer.begin_rendering('Prediction')
             self.renderer.draw_polyline_3d(self.ball_prediction[1],
                                            self.renderer.black())
             self.renderer.end_rendering()
Example #3
0
    def update_values(self, packet):
        self.self = packet.game_cars[self.index]

        # Bot Physics
        self.loc = self.self.physics.location
        self.loc = la.vec3(self.loc.x, self.loc.y, self.loc.z)
        self.rot = self.self.physics.rotation
        self.rot = la.vec3(self.rot.pitch, self.rot.yaw, self.rot.roll)
        self.theta = la.euler_rotation(self.rot)
        self.vel = self.self.physics.velocity
        self.vel = la.vec3(self.vel.x, self.vel.y, self.vel.z)
        self.a_vel = self.self.physics.angular_velocity
        self.a_vel = la.vec3(self.a_vel.x, self.a_vel.y, self.a_vel.z)
        self.max_current_radius = 1 / sim.max_curvature(la.norm(self.vel))

        # Other bot info
        self.demoed = self.self.is_demolished
        self.wheel_contact = self.self.has_wheel_contact
        self.sonic = self.self.is_super_sonic
        self.jumped = self.self.jumped
        self.d_jumped = self.self.double_jumped
        self.team = self.self.team
        self.boost = self.self.boost

        # Ball physics
        self.ball = packet.game_ball
        self.ball_loc = self.ball.physics.location
        self.ball_loc = la.vec3(self.ball_loc.x, self.ball_loc.y,
                                self.ball_loc.z)
        self.ball_rot = self.ball.physics.rotation
        self.ball_rot = la.vec3(self.ball_rot.pitch, self.ball_rot.yaw,
                                self.ball_rot.roll)
        self.ball_vel = self.ball.physics.velocity
        self.ball_vel = la.vec3(self.ball_vel.x, self.ball_vel.y,
                                self.ball_vel.z)

        # Game info
        self.game = packet.game_info
        self.n_cars = packet.num_cars
        self.time = self.game.seconds_elapsed
        self.r_active = self.game.is_round_active
        self.in_kickoff = self.game.is_kickoff_pause
        self.ended = self.game.is_match_ended

        # Field info
        self.field = self.get_field_info()
        for goal in range(self.field.num_goals):
            if self.field.goals[goal].team_num == self.team:
                self.own_goal = self.field.goals[goal]
                self.own_goal_loc = la.vec3(self.own_goal.location.x,
                                            self.own_goal.location.y,
                                            self.own_goal.location.z)
            else:
                self.enemy_goal = self.field.goals[goal]
                self.enemy_goal_loc = la.vec3(self.enemy_goal.location.x,
                                              self.enemy_goal.location.y,
                                              self.enemy_goal.location.z)
        self.n_boost_pads = self.field.num_boosts
        # Normalize boost pads
        self.boost_pads = []  # [(is_active, location, is_full_boost, timer)]
        for pad in range(self.n_boost_pads):
            self.boost_pads = self.boost_pads + [
                (packet.game_boosts[pad].is_active,
                 self.field.boost_pads[pad].location,
                 self.field.boost_pads[pad].is_full_boost,
                 packet.game_boosts[pad].timer)
            ]
Example #4
0
 def grounded(self, vector):
     vector2 = la.vec3(0, 0, 0)
     vector2[0] = vector[0]
     vector2[1] = vector[1]
     vector2[2] = 0
     return vector2
Example #5
0
    def render(self):
        self.renderer.begin_rendering('stuff')
        # AXIS
        # X - CYAN
        self.renderer.draw_line_3d(
            (self.to_world(la.vec3(100, 0, 0)) + self.loc), self.loc,
            self.renderer.cyan())
        # Y - RED
        self.renderer.draw_line_3d(
            (self.to_world(la.vec3(0, 100, 0)) + self.loc), self.loc,
            self.renderer.red())
        # X - GREEN
        self.renderer.draw_line_3d(
            (self.to_world(la.vec3(0, 0, 100)) + self.loc), self.loc,
            self.renderer.green())

        # car to ball
        # self.renderer.draw_line_3d(self.ball_loc, self.loc, self.renderer.team_color())

        # car to goal corners
        self.renderer.draw_line_3d(
            self.enemy_goal_loc + la.vec3(892.755, 0, 642.775 / 2), self.loc,
            self.renderer.team_color(1 - self.team))
        self.renderer.draw_line_3d(
            self.enemy_goal_loc + la.vec3(892.755, 0, -642.775 / 2), self.loc,
            self.renderer.team_color(1 - self.team))
        self.renderer.draw_line_3d(
            self.enemy_goal_loc + la.vec3(-892.755, 0, 642.775 / 2), self.loc,
            self.renderer.team_color(1 - self.team))
        self.renderer.draw_line_3d(
            self.enemy_goal_loc + la.vec3(-892.755, 0, -642.775 / 2), self.loc,
            self.renderer.team_color(1 - self.team))

        # curvature radius
        points = 25
        curve = [None] * (points + 1)
        both_sides = [-1, 1]
        for side in both_sides:
            for divn in range(points + 1):
                x = math.cos(
                    ((2 * math.pi) / points) * divn) * self.max_current_radius
                y = math.sin(
                    ((2 * math.pi) / points) * divn) * self.max_current_radius
                curve[divn] = self.to_world(
                    la.vec3(x, y, 0) +
                    la.vec3(0, self.max_current_radius * side, 0)) + self.loc
            self.renderer.draw_polyline_3d(curve, self.renderer.team_color())
        points = 100
        curve = [None] * (points + 1)
        for divn in range(points + 1):
            x = math.cos(
                ((2 * math.pi) / points) *
                divn) * self.max_current_radius * (1 / self.controller.steer)
            y = math.sin(
                ((2 * math.pi) / points) *
                divn) * self.max_current_radius * (1 / self.controller.steer)
            curve[divn] = self.to_world(
                la.vec3(x, y, 0) +
                la.vec3(0, self.max_current_radius *
                        (1 / self.controller.steer), 0)) + self.loc
        self.renderer.draw_polyline_3d(curve, self.renderer.black())

        self.renderer.end_rendering()
        return
Example #6
0
 def choose_bounce_new_way(self):
     ball_goal_vector = la.vec2(self.enemy_goal_loc[0], self.enemy_goal_loc[1]) - \
                        la.vec2(self.ball_loc[0], self.ball_loc[1])
     radius_multiplier = 1 / 1  # 0.8
     num_bounce = len(self.ground_bounce[1])
     # num_bounce = 3
     path = [None] * num_bounce
     end_radius = self.max_current_radius
     self.renderer.begin_rendering('bounce time')
     for bounce_n in range(num_bounce):
         bounce = self.ground_bounce[1][bounce_n]
         if bounce_n < 5:
             self.renderer.draw_string_3d(
                 bounce, 1, 1,
                 str(self.ground_bounce[0][bounce_n] - self.time),
                 self.renderer.black())
         bounce = self.grounded(bounce)
         radius_1_sgn = la.sgn(self.ball_loc_loc[1])
         radius_2_sgn = -la.sgn(
             self.ball_loc_loc[1] * self.enemy_goal_loc_loc[0])
         path[bounce_n] = sim.ArcLineArc(
             self.g_vec2(self.loc),  # first point
             self.g_vec2(la.normalize(self.vel)),  # first tangent
             self.max_current_radius * radius_1_sgn *
             radius_multiplier,  #first radius
             self.g_vec2(bounce) + la.normalize(ball_goal_vector) * -500,
             la.normalize(ball_goal_vector),
             end_radius * radius_2_sgn * radius_multiplier)
         # path.is_valid
         # path.length
         # path.p1  # point 1
         # path.p2  # point 2
         # path.q1  # circle to line 1
         # path.q2  # line to circle 2
         # path.o1  # circle 1 center
         # path.o2  # circle 2 center
         # print(path.q1)
     self.renderer.end_rendering()
     self.renderer.begin_rendering('path')
     for line in range(len(path)):
         if not path[line].is_valid:
             continue
         speed_needed = abs((path[line].length + 1000) /
                            ((self.ground_bounce[0][line]) - self.time))
         if 0 > speed_needed or speed_needed > self.max_speed[1]:
             continue
         else:
             print(line)
             print(path[line].is_valid)
             bounce = self.ground_bounce[1][line]
             self.renderer.draw_line_3d(self.g_vec3(path[line].q1),
                                        self.g_vec3(path[line].q2),
                                        self.renderer.pink())
             points = 25
             curve1 = [None] * (points + 1)
             curve2 = [None] * (points + 1)
             for divn in range(points + 1):
                 x = math.cos(
                     ((2 * math.pi) / points) *
                     divn) * -self.max_current_radius * radius_multiplier
                 y = math.sin(
                     ((2 * math.pi) / points) *
                     divn) * -self.max_current_radius * radius_multiplier
                 x2 = math.cos(((2 * math.pi) / points) *
                               divn) * -end_radius * radius_multiplier
                 y2 = math.sin(((2 * math.pi) / points) *
                               divn) * -end_radius * radius_multiplier
                 curve1[divn] = self.to_world(la.vec3(
                     x, y, 0)) + self.g_vec3(path[line].o1)
                 curve2[divn] = self.to_world(la.vec3(
                     x2, y2, 0)) + self.g_vec3(path[line].o2)
             self.renderer.draw_polyline_3d(curve1, self.renderer.pink())
             self.renderer.draw_polyline_3d(curve2, self.renderer.pink())
             self.renderer.draw_line_3d(self.g_vec3(path[line].p2),
                                        self.g_vec3(self.enemy_goal_loc),
                                        self.renderer.pink())
             self.renderer.draw_line_3d((self.g_vec3(
                 self.g_vec2(bounce) +
                 la.normalize(ball_goal_vector) * -500)), ((self.c_vec3(
                     self.g_vec2(bounce) +
                     la.normalize(ball_goal_vector) * -500))),
                                        self.renderer.black())
             self.renderer.draw_line_3d((self.g_vec3(self.g_vec2(bounce))),
                                        (self.c_vec3(self.g_vec2(bounce))),
                                        self.renderer.red())
             self.renderer.end_rendering()
             print(self.g_vec3(path[line].q2))
             return [self.g_vec3(path[line].q2), speed_needed]
     self.renderer.end_rendering()
     print('old way')  # Todo: if none found use current or last position
     return self.choose_bounce_old_way()
Example #7
0
 def c_vec3(self, vec2):
     # unflattens the vector2 into a vector3 on the ground
     vec3 = la.vec3(vec2[0], vec2[1], 1000)
     return vec3