Diagnosis
Symptom 1
I have noticed is that when looping at speed it sometimes doesn't detect
This is what happens:
When the mouse pointer moved too much between frames, it creates multiple segments, here:
var mouse_pos = get_global_mouse_position()
var distance = 20
while points_array[-1].distance_to(mouse_pos) > _distance:
var last_point = points_array[-1]
var cords = last_point + last_point.direction_to(mouse_pos) * distance
points_array.append(cords)
create_collision()
But the check for collisions is only comparing the last one, here:
for index in range(0, points_array.size() - 3):
if _segment_collision(
points_array[-1],
points_array[-2],
points_array[index],
points_array[index + 1]
):
new_loop()
break
*Remember that [-1]
gives the last item, and [-2]
gives the second to last.
As a consequence, the intersection can happen on one of the segments that weren't checked.
Symptom 2
how to make it more forgiving for example if the line is really close to a previous line I would like it to count that as a loop
We could check distance from point to segment.
Symptom 3
how would I make the line actually be the mouse pointer instead of having it ghost behind
Currently the segments are all of the same length. This seems to be a limitation of the way you create CollisionShape2D
.
Treatment selection
We could address Symptom 1 by checking every segment. Symptom 2 by improving said checking. But we would still need a solution for Symptom 3 that allows variable segment lengths.
If we create a solution that supports variable segment lengths, we would not need to create multiple segments at once, which solves Symptom 1. We would still need to improve the checking to solve Symptom 2.
If we need to improve the way we check collisions and we are rewriting the collisions anyway, we might as well implement something that allows us to detect self intersections.
We are going to transplant a new way to define collision shapes which allows us to make rotated rectangles of the dimensions we want.
Surgery
I ended up rewriting the whole script. Because I'm like that, I guess.
I decided to have the script create its child nodes in the following structure:
Node
├_line
├_segments
└_loops
Here_line
will be a Line2D
, _segments
will hold multiple Area2D
, each a segment. And _loops
will also hold Area2D
, but they are the polygons of the loops traced.
This will be done in _ready
:
var _line:Line2D
var _segments:Node2D
var _loops:Node2D
func _ready() -> void:
_line = Line2D.new()
_line.name = "_line"
add_child(_line)
_segments = Node2D.new()
_segments.name = "_segments"
add_child(_segments)
_loops = Node2D.new()
_loops.name = "_loops"
add_child(_loops)
Another decision I took was to consider the way of the data on the application: We are taking positions. The first position is when the click is just pressed. Subsequent positions are when it moves. From those positions we take points to add to both the line and the segments. From the segments we will get the loops. And we will continue in this manner until the click is released.
Well, if whether or not click was just pressed or it is held, it does not matter. Either way, we take the position of the mouse.
Now, _physics_process
will look like this:
func _physics_process(_delta:float) -> void:
if Input.is_action_pressed("left_click"):
position(get_global_mouse_position())
# TODO
We also need to handle when the click is released. Let us make a function for that and worry later about it:
func _physics_process(_delta:float) -> void:
if Input.is_action_pressed("left_click"):
position(get_global_mouse_position())
if Input.is_action_just_released("left_click"):
total_purge()
On position
we will follow that odd trick of moving the last point to match the most recent position. We need to make sure that there are at least two points. So the first point does not move, and we can safely move the last point.
var _points:PoolVector2Array = PoolVector2Array()
var _max_distance = 20
func position(pos:Vector2) -> void:
var point_count = _points.size()
if point_count == 0:
_points.append(pos)
_points.append(pos)
elif point_count == 1:
_points.append(pos)
else:
if _points[-2].distance_to(pos) > _max_distance:
_points.append(pos)
else:
_points[-1] = pos
Notice we check the distance to the second to last point. We cannot check against the last point because that is the one we are moving.
If the distance is greater than _max_dinstance
then we add a new point, otherwise we move the last point.
We also need to add and update segments:
var _points:PoolVector2Array = PoolVector2Array()
var _max_distance = 20
func position(pos:Vector2) -> void:
var point_count = _points.size()
if point_count == 0:
_points.append(pos)
_points.append(pos)
add_segment(pos, pos)
elif point_count == 1:
_points.append(pos)
add_segment(_points[-2], pos)
else:
if _points[-2].distance_to(pos) > _max_distance:
_points.append(pos)
add_segment(_points[-2], pos)
else:
_points[-1] = pos
change_segment(_points[-2], pos)
You know, we worry later about how that works.
We also need to handle the case when there are too many points:
var _points:PoolVector2Array = PoolVector2Array()
var _max_points = 30
var _max_distance = 20
func position(pos:Vector2) -> void:
var point_count = _points.size()
if point_count == 0:
_points.append(pos)
_points.append(pos)
add_segment(pos, pos)
elif point_count == 1:
_points.append(pos)
add_segment(_points[-2], pos)
elif point_count > _max_points:
purge(point_count - _max_points)
else:
if _points[-2].distance_to(pos) > _max_distance:
_points.append(pos)
add_segment(_points[-2], pos)
else:
_points[-1] = pos
change_segment(_points[-2], pos)
We need to update the Line2D
, and we need to handle any loops:
var _points:PoolVector2Array = PoolVector2Array()
var _max_points = 30
var _max_distance = 20
func position(pos:Vector2) -> void:
var point_count = _points.size()
if point_count == 0:
_points.append(pos)
_points.append(pos)
add_segment(pos, pos)
elif point_count == 1:
_points.append(pos)
add_segment(_points[-2], pos)
elif point_count > _max_points:
purge(point_count - _max_points)
else:
if _points[-2].distance_to(pos) > _max_distance:
_points.append(pos)
add_segment(_points[-2], pos)
else:
_points[-1] = pos
change_segment(_points[-2], pos)
_line.points = _points
process_loop()
Alright, let us talk about adding and updating segments:
var _width = 5
func add_segment(start:Vector2, end:Vector2) -> void:
var points = rotated_rectangle_points(start, end, _width)
var segment = Area2D.new()
var collision = create_collision_polygon(points)
segment.add_child(collision)
_segments.add_child(segment)
func change_segment(start:Vector2, end:Vector2) -> void:
var points = rotated_rectangle_points(start, end, _width)
var segment = (_segments.get_child(_segments.get_child_count() - 1) as Area2D)
var collision = (segment.get_child(0) as CollisionPolygon2D)
collision.set_polygon(points)
Here _width
is the width of the collision polygons we want.
We are either adding an Area2D
with a collision polygon (created via function we will worry about later), or we are taking the last Area2D
and updating its collision polygon by the same means.
So, how do we get the points for the rotated rectangle?
static func rotated_rectangle_points(start:Vector2, end:Vector2, width:float) -> Array:
var diff = end - start
var normal = diff.rotated(TAU/4).normalized()
var offset = normal * width * 0.5
return [start + offset, start - offset, end - offset, end + offset]
So you take the vector that goes from the start to the end of the segment, and rotate it a quarter turn (a.k.a. 90º). That gives you a vector that is normal (perpendicular) to the segment, which we will use to give it width.
From the starting point, we find the first point of the rectangle by going half width in the normal direction, and we find the second by going the other half width in the opposite direction. Do the same with the ending point and we have the four corners of the rectangle.
And we return them in an order such that they go around the rectangle.
Creating a collision polygon with those points is straight forward:
static func create_collision_polygon(points:Array) -> CollisionPolygon2D:
var result = CollisionPolygon2D.new()
result.set_polygon(points)
return result
Ok, let us talk about purging. I added a function to purge points (of the line) and segments. That is part of the total purge. The other part will be removing the loops:
func total_purge():
purge(_points.size())
purge_loops()
That was easy.
Alright, to purge points and segment we iterate and remove them.
func purge(index:int) -> void:
var segments = _segments.get_children()
for _index in range(0, index):
_points.remove(0)
if segments.size() > 0:
_segments.remove_child(segments[0])
segments[0].queue_free()
segments.remove(0)
_line.points = _points
That check for if segments.size() > 0
is necessary, by the way. Sometimes the purge leaves points without segment, which cause problems later. And this is the simpler solution.
And, of course, we have to update the Line2D
.
What about purging loops? Well, you remove them all:
func purge_loops() -> void:
for loop in _loops.get_children():
if is_instance_valid(loop):
loop.queue_free()
Finally we can process the loops. We will be checking the overlapping areas of the segments to find if they intersect with each other.
One caveat: we want to ignore overlaps of adjacent segments (which are bound to happen, and do not constitute loops).
So we iterate over the segments, check the overlapping areas, look for them among the segments (if they are there at all), and if they are not adjacent (the different of their index among the segments must be greater than 1). If all that happens, we have a loop:
func process_loop() -> void:
var segments = _segments.get_children()
for index in range(segments.size() - 1, 0, -1):
var segment = segments[index]
var candidates = segment.get_overlapping_areas()
for candidate in candidates:
var candidate_index = segments.find(candidate)
if candidate_index == -1:
continue
if abs(candidate_index - index) > 1:
push_loop(candidate_index, index)
purge(index)
return
So, when a loops happens we want to do something with it, right? That is what push_loop
is for. We also want to remove the points and segments that were part of the loop (or were before the loop), so we call purge
.
Only push_loop
is left to discuss:
func push_loop(first_index:int, second_index:int) -> void:
purge_loops()
var loop = Area2D.new()
var points = _points
points.resize(second_index)
for point_index in first_index + 1:
points.remove(0)
var collision = create_collision_polygon(points)
loop.add_child(collision)
_loops.add_child(loop)
As you can see, it creates an Area2D
, with a collision polygon that corresponds to the loop. I decide to use rezise
to remove points that are after the loop, and a for loop to remove the points that are before. So only the points of the loop remain.
Also notice I'm calling purge_loops
at the start, that ensures there will only be one loop at a time.
Going back to the symptoms: Symptoms 1 and 3 are solved by that trick of always moving the last point (and updating the segment). And Symptom 2 is addressed by the width of the rectangles. Tweak that value.