First of all, collision detection using masks is very time-intensive. Whether or not your game has entered an infinite loop, the processing requirements of a bitmask-bitmask overlap check will make your game run far too slowly.
A simple optimization exists, however:
Any object which is able to collide with things must have some maximum size -- that is, you can find a rectangle which will always contain your player, and your boulder can fit inside another. Therefore, if your player's box doesn't collide with the boulder's box, they can't possibly overlap. Since you insist on collision masking, (which can add some realism to any pixelart game), you can compute the per-pixel collision whenever (and only whenever) the bounding boxes collide.
Now, on to your coding style: >:O
It is never a good idea to put a potentially infinite loop within a function which should ideally compute an instant collision check. In the best-case scenario (which is certainly achievable), you would have one function to check whether two objects collide, and tell you some more useful information (the position of one relative to the other, etcetera); while a separate method of every moving object would fix the collisions.
This would translate to something like:
#This class controls an object which can move and fix collisions
self.x = 0 #add relevant initialization code here
self.y = 0
self.xVel = 0 # X and Y velocity (for movement)
self.yVel = 0
self.xSize = 0 # the width of the object in pixels
self.ySize = 0 # the height of the object in pixels
def iscolliding(self, other):
# using x and y as the center of the object,
# this returns an empty tuple if they don't collide
if ((self.xSize + other.xSize) / 2 <= abs(self.x - other.x)) and
((self.ySize + other.ySize) / 2 <= abs(self.y - other.y)): return ()
use pygame collidemask here to compute whether they collide.
if they do, return a vector of 'other's' position relative to self.
(this can be used to decide how to separate the objects)
def restitute(self, overlaps_with, distances):
Given some objects which overlap, and a list of 2D vectors of their
relative distances, this separates them however much you like.
As to where your colision checking is done, that depends upon your implementation of object management basics. I will heretofore assume that all of your in-game objects are contained within an iterable; and that on every frame you iterate through your objects, once to render, once to move them -- a structure something like this:
for object in objects:
object.move() # moves the object -- collisions, etc in here
event_handling_stuff() # handles events
In this case, every object can compute collision checking for anything which follows it in objects. In doing so, each object can collect how far it has to move from each. Afterwards, each object can move to be as far from each collider as possible.
In a few games I've written, I'd make objects move farther apart the more overlapped they are, giving collisions an elastic quality which makes even very rough restitution algorithms look very sexy. Generally, you can tinker with constants once you have a working check going and that would be the least of your worries.
Hopefully this will have helped you two a little (I realize now I went off a bit on a tangent, but you were asking about how to do the wrong things more efficiently :P).
tl;dr: Don't try to fix collisions within your collision check function. Instead, separate it into one which finds all collisions to other objects, and another which fixes all collisions for an object at the same time.
Add other questions and I'll update (:.
Expanding here on the
"vector of other to self" bit (which was explained a tad crudely:/)
Generally when two objects collide in real life, they bounce back somewhat in the direction they came from (when you drop a rubber bouncy ball on the floor, it bounces back from whence it came -- it doesn't just phaze through the floor). In most programming applications, you'd want to make bouncy balls (and other colliding things) behave in the same way (well, sometimes you might want the ball to phaze though the floor, but that's even easier than bouncing IMHO :P).
To know which way an object must bounce back, you have to know the direction from which it came. More strictly, you have to know the angle at which it collided. This is very easily found if you compare the distance and direction between the centers of each object during the collision. This will provide a pretty accurate representation of two objects bouncing, if the centers you are using are close enough to their centers of mass (in most games the middle of an object is an easy and good approximation).
So, since we don't need to worry about center of mass and all that, we just measure the vector distance between object positions:
#Continuing the previous example, we put some code like this in 'iscolliding' :)
if they collide (pygame mask stuff) :
x_distance = self.x - other.x
y_distance = self.y - other.y
return (x_distance, y_distance)
This code can give you the line along which each object should move to resolve the collision as fast as possible. The rest is a matter of accelerating each object along this line, making sure they don't go closer together (pay attention to signs), and tweaking constants to create a realistic effect.