You may get faster, and possibly even simpler, code by using
numpy, or other alternatives (see below for details). But from a theoretical point of view, in terms of algorithmic complexity, the best you can get is O(N*M), and you can do that with your design (if I understand it correctly). For example:
def neighbors(matrix, row, col):
for i in row-1, row, row+1:
if i < 0 or i == len(matrix): continue
for j in col-1, col, col+1:
if j < 0 or j == len(matrix[i]): continue
if i == row and j == col: continue
matrix = [[0,1,1,1,0,1], [1,1,1,0,0,1], [1,1,0,0,0,1], [1,1,1,1,1,1]]
for i, row in enumerate(matrix):
for j, cell in enumerate(cell):
for neighbor in neighbors(matrix, i, j):
This has takes N * M * 8 steps (actually, a bit less than that, because many cells will have fewer than 8 neighbors). And algorithmically, there's no way you can do better than O(N * M). So, you're done.
(In some cases, you can make things simpler—with no significant change either way in performance—by thinking in terms of iterator transformations. For example, you can easily create a grouper over adjacent triplets from a list
a by properly zipping
a[2:], and you can extend this to adjacent 2-dimensional nonets. But I think in this case, it would just make your code more complicated that writing an explicit
neighbors iterator and explicit
for loops over the matrix.)
However, practically, you can get a whole lot faster, in various ways. For example:
numpy, you may get an order of magnitude or so faster. When you're iterating a tight loop and doing simple arithmetic, that's one of the things that Python is particularly slow at, and
numpy can do it in C (or Fortran) instead.
- Using your favorite GPGPU library, you can explicitly vectorize your operations.
multiprocessing, you can break the matrix up into pieces and perform multiple pieces in parallel on separate cores (or even separate machines).
Of course for a single 4x6 matrix, none of these are worth doing… except possibly for
numpy, which may make your code simpler as well as faster, as long as you can express your operations naturally in matrix/broadcast terms.
In fact, even if you can't easily express things that way, just using
numpy to store the matrix may make things a little simpler (and save some memory, if that matters). For example,
numpy can let you access a single column from a matrix naturally, while in pure Python, you need to write something like
[row[col] for row in matrix].
So, how would you tackle this with
First, you should read over
ufunc (or, better, some higher-level tutorial, but I don't have one to recommend) before going too much further.
Anyway, it depends on what you're doing with each set of neighbors, but there are three basic ideas.
First, if you can convert your operation into simple matrix math, that's always easiest.
If not, you can create 8 "neighbor matrices" just by shifting the matrix in each direction, then perform simple operations against each neighbor. For some cases, it may be easier to start with an N+2 x N+2 matrix with suitable "empty" values (usually 0 or nan) in the outer rim. Alternatively, you can shift the matrix over and fill in empty values. Or, for some operations, you don't need an identical-sized matrix, so you can just crop the matrix to create a neighbor. It really depends on what operations you want to do.
For example, taking your input as a fixed 6x4 board for the Game of Life:
for i in -1, 0, 1:
for j in -1, 0, 1:
if i == 0 and j == 0: continue
yield np.roll(np.roll(matrix, i, 0), j, 1)
matrix = np.matrix([[0,0,0,0,0,0,0,0],
livecount = sum(neighbors(matrix))
matrix = (matrix & (livecount==2)) | (livecount==3)
(Note that this isn't the best way to solve this problem, but I think it's relatively easy to understand, and likely to illuminate whatever your actual problem is.)