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If I'm making a simple grid based game, for example, I might have a few 2d lists. One might be for terrain, another might be for objects, etc. Unfortunately, when I need to iterate over the lists and have the contents of a square in one list affect part of another list, I have to do something like this.

for i in range(len(alist)):
    for j in range(len(alist[i])):
        if alist[i][j].isWhatever:
            blist[i][j].doSomething()

Is there a nicer way to do something like this?

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10 Answers 10

up vote 14 down vote accepted

I'd start by writing a generator method:

def grid_objects(alist, blist):
    for i in range(len(alist)):
        for j in range(len(alist[i])):
            yield(alist[i][j], blist[i][j])

Then whenever you need to iterate over the lists your code looks like this:

for (a, b) in grid_objects(alist, blist):
    if a.is_whatever():
        b.do_something()
share|improve this answer
    
This is not the same thing, in the second for the range took the len of alist[i], why did you removed that index? – Andrea Ambu Oct 9 '08 at 21:08
    
I definitely like this one the most. It may not be the best answer but I'm quite likely to use it. – Eugene M Oct 9 '08 at 21:57
    
This is just syntax sugar over what Eugene wrote. I'm afraid that this generator could be very slow if grids are sufficiently large. After all, each yield still requires four index lookups. – DzinX Oct 9 '08 at 22:14
    
Also, it would be wise to change the range() calls to xrange(). – tzot Oct 9 '08 at 23:05

If anyone is interested in performance of the above solutions, here they are for 4000x4000 grids, from fastest to slowest:

EDIT: Added Brian's scores with izip modification and it won by a large amount!

John's solution is also very fast, although it uses indices (I was really surprised to see this!), whereas Robert's and Brian's (with zip) are slower than the question creator's initial solution.

So let's present Brian's winning function, as it is not shown in proper form anywhere in this thread:

from itertools import izip
for a_row,b_row in izip(alist, blist):
    for a_item, b_item in izip(a_row,b_row):
        if a_item.isWhatever:
            b_item.doSomething()
share|improve this answer
    
You tried Brian's solution as-is, or with itertools.izip? Also, would you care to benchmark my suggestion too? – tzot Oct 9 '08 at 22:53
    
Added, and results are again surprising. In your case, it seems that adding an unexpected (not in slots) variable to an object is very slow! – DzinX Oct 9 '08 at 23:25
    
Oh, the initialization can be merged with the existing matrix initialization. I don't know why you mention the "not in slots" part; we don't know how the cell objects are implemented. BTW, you forgot to call a_item.isWhatever (i.e. no parentheses) – tzot Oct 10 '08 at 3:03
    
Well, I used dummy objects with "normal" (i.e. dictionary) attribute management. As to parentheses, in original question there are none :) – DzinX Oct 10 '08 at 8:34
    
That's interesting. I had thought the original would perform better in cases where isWhatever was rare, since it didn't need to access blist at all, but it looks like the index lookup is much more important. Even at 0.5% isWhatever true, the izip method did better. – Brian Oct 10 '08 at 8:55

You could zip them. ie:

for a_row,b_row in zip(alist, blist):
    for a_item, b_item in zip(a_row,b_row):
        if a_item.isWhatever:
            b_item.doSomething()

However the overhead of zipping and iterating over the items may be higher than your original method if you rarely actually use the b_item (ie a_item.isWhatever is usually False). You could use itertools.izip instead of zip to reduce the memory impact of this, but its still probably going to be slightly slower unless you always need the b_item.

Alternatively, consider using a 3D list instead, so terrain for cell i,j is at l[i][j][0], objects at l[i][j][1] etc, or even combine the objects so you can do a[i][j].terrain, a[i][j].object etc.

[Edit] DzinX's timings actually show that the impact of the extra check for b_item isn't really significant, next to the performance penalty of re-looking up by index, so the above (using izip) seems to be fastest.

I've now given a quick test for the 3d approach as well, and it seems faster still, so if you can store your data in that form, it could be both simpler and faster to access. Here's an example of using it:

# Initialise 3d list:
alist = [ [[A(a_args), B(b_args)] for i in xrange(WIDTH)] for j in xrange(HEIGHT)]

# Process it:
for row in xlist:
    for a,b in row:
        if a.isWhatever(): 
            b.doSomething()

Here are my timings for 10 loops using a 1000x1000 array, with various proportions of isWhatever being true are:

            ( Chance isWhatever is True )
Method      100%     50%      10%      1%

3d          3.422    2.151    1.067    0.824
izip        3.647    2.383    1.282    0.985
original    5.422    3.426    1.891    1.534
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1  
This is the fastest solution here, but only if you change zip to itertools.izip (see my post somewhere below). – DzinX Oct 9 '08 at 23:27

As a slight style change, you could use enumerate:

for i, arow in enumerate(alist):
    for j, aval in enumerate(arow):
        if aval.isWhatever():
            blist[i][j].doSomething()

I don't think you'll get anything significantly simpler unless you rearrange your data structures as Federico suggests. So that you could turn the last line into something like "aval.b.doSomething()".

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Generator expressions and izip from itertools module will do very nicely here:

from itertools import izip
for a, b in (pair for (aline, bline) in izip(alist, blist) 
             for pair in izip(aline, bline)):
    if a.isWhatever:
        b.doSomething()

The line in for statement above means:

  • take each line from combined grids alist and blist and make a tuple from them (aline, bline)
  • now combine these lists with izip again and take each element from them (pair).

This method has two advantages:

  • there are no indices used anywhere
  • you don't have to create lists with zip and use more efficient generators with izip instead.
share|improve this answer
    
Is this nicer? Is this more readable? – Andrea Ambu Oct 9 '08 at 21:15
    
I believe so, yes. By removing indices you get more explicit at what are you trying to accomplish here (manipulating objects, not their positions). – DzinX Oct 9 '08 at 21:30
    
This is clearly the best approach. – Robert Rossney Oct 10 '08 at 0:18
    
I think it's cleaner to iterate over objects than over numbers. A nice approach. – Brian Oct 10 '08 at 5:29

When you are operating with grids of numbers and want really good performance, you should consider using Numpy. It's surprisingly easy to use and lets you think in terms of operations with grids instead of loops over grids. The performance comes from the fact that the operations are then run over whole grids with optimised SSE code.

For example here is some numpy using code that I wrote that does brute force numerical simulation of charged particles connected by springs. This code calculates a timestep for a 3d system with 100 nodes and 99 edges in 31ms. That is over 10x faster than the best pure python code I could come up with.

from numpy import array, sqrt, float32, newaxis
def evolve(points, velocities, edges, timestep=0.01, charge=0.1, mass=1., edgelen=0.5, dampen=0.95):
    """Evolve a n body system of electrostatically repulsive nodes connected by
       springs by one timestep."""
    velocities *= dampen

    # calculate matrix of distance vectors between all points and their lengths squared
    dists = array([[p2 - p1 for p2 in points] for p1 in points])
    l_2 = (dists*dists).sum(axis=2)

    # make the diagonal 1's to avoid division by zero
    for i in xrange(points.shape[0]):
        l_2[i,i] = 1

    l_2_inv = 1/l_2
    l_3_inv = l_2_inv*sqrt(l_2_inv)

    # repulsive force: distance vectors divided by length cubed, summed and multiplied by scale
    scale = timestep*charge*charge/mass
    velocities -= scale*(l_3_inv[:,:,newaxis].repeat(points.shape[1], axis=2)*dists).sum(axis=1)

    # calculate spring contributions for each point
    for idx, (point, outedges) in enumerate(izip(points, edges)):
        edgevecs = point - points.take(outedges, axis=0)
        edgevec_lens = sqrt((edgevecs*edgevecs).sum(axis=1))
        scale = timestep/mass
        velocities[idx] += (edgevecs*((((edgelen*scale)/edgevec_lens - scale))[:,newaxis].repeat(points.shape[1],axis=1))).sum(axis=0)

    # move points to new positions
    points += velocities*timestep
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Are you sure that the objects in the two matrices you are iterating in parallel are instances of conceptually distinct classes? What about merging the two classes ending up with a matrix of objects that contain both isWhatever() and doSomething()?

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If the two 2D-lists remain constant during the lifetime of your game and you can't enjoy Python's multiple inheritance to join the alist[i][j] and blist[i][j] object classes (as others have suggested), you could add a pointer to the corresponding b item in each a item after the lists are created, like this:

for a_row, b_row  in itertools.izip(alist, blist):
    for a_item, b_item in itertools.izip(a_row, b_row):
        a_item.b_item= b_item

Various optimisations can apply here, like your classes having __slots__ defined, or the initialization code above could be merged with your own initialization code e.t.c. After that, your loop will become:

for a_row in alist:
    for a_item in a_row:
        if a_item.isWhatever():
            a_item.b_item.doSomething()

That should be more efficient.

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That's definitely an unexpected answer. Quite interesting. – Eugene M Oct 9 '08 at 21:55

If a.isWhatever is rarely true you could build an "index" once:

a_index = set((i,j) 
              for i,arow in enumerate(a) 
              for j,a in enumerate(arow) 
              if a.IsWhatever())

and each time you want something to be done:

for (i,j) in a_index:
    b[i][j].doSomething()

If a changes over time, then you will need to keep the index up-to-date. That's why I used a set, so items can be added and removed fast.

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for d1 in alist
   for d2 in d1
      if d2 = "whatever"
          do_my_thing()
share|improve this answer
    
you missed the blist – Toni Ruža Oct 9 '08 at 20:53

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