Exemplos de Planetaria Bearing.attractor em C# (CSharp)

Exemplo n.º 1

        private static bool platform_collision(Arc arc, PlanetariaCollider collider, PlanetariaTransform transformation, PlanetariaRigidbody rigidbody, optional <Vector3> intersection_point)
        {
            Vector3 velocity = Bearing.attractor(rigidbody.get_previous_position(), rigidbody.get_position());

            if (intersection_point.exists)
            {
                float   arc_angle            = arc.position_to_angle(intersection_point.data);
                Vector3 normal               = arc.normal(arc_angle);
                bool    upward_facing_normal = Vector3.Dot(normal, rigidbody.get_acceleration()) <= 0;
                bool    moving_toward        = Vector3.Dot(normal, velocity) <= 0;

                if (upward_facing_normal && moving_toward)
                {
                    return(true);
                }
            }
            return(false);
        }

Exemplo n.º 2

        /// <summary>
        /// Inspector (Cache Mutator) - Updates the cache so that spherical rectangle calculations avoid recomputing old values.
        /// </summary>
        /// <param name="canvas">A Rect (measuring radians) representing the start and stop angles relative to Quaternion.identity. X/Y Range: (-2PI, +2PI).</param>
        public static void cache_spherical_rectangle(Rect canvas)
        {
            if (cached_canvas != canvas)
            {
                Vector3 lower_left   = intersection(canvas.xMin, canvas.yMin);
                Vector3 lower_center = intersection(canvas.center.x, canvas.yMin);
                Vector3 lower_right  = intersection(canvas.xMax, canvas.yMin);

                Vector3 middle_left   = intersection(canvas.xMin, canvas.center.y);
                Vector3 middle_center = intersection(canvas.center.x, canvas.center.y);
                Vector3 middle_right  = intersection(canvas.xMax, canvas.center.y);

                Vector3 upper_left   = intersection(canvas.xMin, canvas.yMax);
                Vector3 upper_center = intersection(canvas.center.x, canvas.yMax);
                Vector3 upper_right  = intersection(canvas.xMax, canvas.yMax);

                Arc biangle_segment1 = ArcFactory.curve(upper_center, upper_right, -upper_center);
                Arc biangle_segment2 = ArcFactory.curve(lower_center, lower_right, -lower_center);
                cached_left_biangle_focus      = PlanetariaIntersection.arc_arc_intersection(biangle_segment1, biangle_segment2, 0).data;
                cached_left_positive_partition = Bearing.attractor(cached_left_biangle_focus, middle_left); // used for a dot product to determine if the angle applied for UV is +/-
                if (Vector3.Dot(cached_left_positive_partition, middle_center) >= 0)
                {
                    cached_left_start_angle = Vector3.Angle(cached_left_biangle_focus, middle_center) * Mathf.Deg2Rad;
                    cached_left_end_angle   = Vector3.Angle(cached_left_biangle_focus, middle_left) * Mathf.Deg2Rad;
                }
                else
                {
                    cached_left_start_angle = Vector3.Angle(-cached_left_biangle_focus, middle_center) * Mathf.Deg2Rad + Mathf.PI;
                    cached_left_end_angle   = Vector3.Angle(-cached_left_biangle_focus, middle_left) * Mathf.Deg2Rad + Mathf.PI;
                }

                biangle_segment1                = ArcFactory.curve(upper_center, upper_left, -upper_center);
                biangle_segment2                = ArcFactory.curve(lower_center, lower_left, -lower_center);
                cached_right_biangle_focus      = PlanetariaIntersection.arc_arc_intersection(biangle_segment1, biangle_segment2, 0).data;
                cached_right_positive_partition = Bearing.attractor(cached_right_biangle_focus, middle_right); // used for a dot product to determine if the angle applied for UV is +/-
                if (Vector3.Dot(cached_right_positive_partition, middle_center) >= 0)
                {
                    cached_right_start_angle = Vector3.Angle(cached_right_biangle_focus, middle_center) * Mathf.Deg2Rad;
                    cached_right_end_angle   = Vector3.Angle(cached_right_biangle_focus, middle_right) * Mathf.Deg2Rad;
                }
                else
                {
                    cached_right_start_angle = Vector3.Angle(-cached_right_biangle_focus, middle_center) * Mathf.Deg2Rad + Mathf.PI;
                    cached_right_end_angle   = Vector3.Angle(-cached_right_biangle_focus, middle_right) * Mathf.Deg2Rad + Mathf.PI;
                }

                biangle_segment1                = ArcFactory.curve(middle_left, upper_left, -middle_left);
                biangle_segment2                = ArcFactory.curve(middle_right, upper_right, -middle_right);
                cached_lower_biangle_focus      = PlanetariaIntersection.arc_arc_intersection(biangle_segment1, biangle_segment2, 0).data;
                cached_lower_positive_partition = Bearing.attractor(cached_lower_biangle_focus, lower_center); // used for a dot product to determine if the angle applied for UV is +/-
                if (Vector3.Dot(cached_lower_positive_partition, middle_center) >= 0)
                {
                    cached_lower_start_angle = Vector3.Angle(cached_lower_biangle_focus, middle_center) * Mathf.Deg2Rad;
                    cached_lower_end_angle   = Vector3.Angle(cached_lower_biangle_focus, lower_center) * Mathf.Deg2Rad;
                }
                else
                {
                    cached_lower_start_angle = Vector3.Angle(-cached_lower_biangle_focus, middle_center) * Mathf.Deg2Rad + Mathf.PI;
                    cached_lower_end_angle   = Vector3.Angle(-cached_lower_biangle_focus, lower_center) * Mathf.Deg2Rad + Mathf.PI;
                }

                biangle_segment1                = ArcFactory.curve(middle_left, lower_left, -middle_left);
                biangle_segment2                = ArcFactory.curve(middle_right, lower_right, -middle_right);
                cached_upper_biangle_focus      = PlanetariaIntersection.arc_arc_intersection(biangle_segment1, biangle_segment2, 0).data;
                cached_upper_positive_partition = Bearing.attractor(cached_upper_biangle_focus, upper_center); // used for a dot product to determine if the angle applied for UV is +/-
                if (Vector3.Dot(cached_upper_positive_partition, middle_center) >= 0)
                {
                    cached_upper_start_angle = Vector3.Angle(cached_upper_biangle_focus, middle_center) * Mathf.Deg2Rad;
                    cached_upper_end_angle   = Vector3.Angle(cached_upper_biangle_focus, upper_center) * Mathf.Deg2Rad;
                }
                else
                {
                    cached_upper_start_angle = Vector3.Angle(-cached_upper_biangle_focus, middle_center) * Mathf.Deg2Rad + Mathf.PI;
                    cached_upper_end_angle   = Vector3.Angle(-cached_upper_biangle_focus, upper_center) * Mathf.Deg2Rad + Mathf.PI;
                }

                cached_north_hemisphere = Bearing.attractor(middle_center, upper_center);
                cached_east_hemisphere  = Bearing.attractor(middle_center, middle_right);

                cached_canvas = canvas;
            }
        }

Exemplo n.º 3

 public Vector3 get_acceleration()
 {
     return(Bearing.attractor(get_position(), gravity.normalized) * gravity.magnitude);
 }