# Grid Permutation Algorithm - Fixed Row Order

Imagine a 3x3 grid:

``````[A, B, %]
[C, %, D]
[E, F, G]
``````

The percentages `%` stand for empty spaces/positions.

The rows can be moved like beads on a string, such that the permutations for the configurations for the first row could be any one of:

``````[A, B, %] or [A, %, B] or [%, A, B]
``````

Similarly for the second row. The third row contains no empty slots and so cannot change.

I am trying to produce all possible grids, given the possible permutations of each row.

The output should produce the following grids:

``````[A, B, %]    [A, B, %]    [A, B, %]
[C, D, %]    [C, %, D]    [%, C, D]
[E, F, G]    [E, F, G]    [E, F, G]

[A, %, B]    [A, %, B]    [A, %, B]
[C, D, %]    [C, %, D]    [%, C, D]
[E, F, G]    [E, F, G]    [E, F, G]

[%, A, B]    [%, A, B]    [%, A, B]
[C, D, %]    [C, %, D]    [%, C, D]
[E, F, G]    [E, F, G]    [E, F, G]
``````

I have tried a method of looking through each row and shifting the space left and right, then generating new grids off that and recursing. I keep all grids in a set and ensure I only produce positions which haven't already been examined to prevent infinite recursion.

However, my algorithm seems to be horrendously inefficient (~1s per permutation!!) and doesn't look very nice either. I was wondering if there was an eloquent way of doing this? In python in particular.

I have some vague ideas but I'm sure there is a way of doing this which is short and simple which I'm overlooking.

EDIT: 3x3 is just an example. Grid could be of any size and it's really the row combinations which matter. For example:

``````[A, %, C]
[D, E, %, G]
[H, I]
``````

is also a valid grid.

EDIT 2: The letters must maintain their order. For example `[A, %, B] != [B, %, A]` and `[B, A, %]` isn't valid

-
Does this need to work for arbitrary sized grids? – Vaughn Cato Apr 8 '12 at 14:59
is ["A","B","%] considered to be != ["B","A","%"]? – luke14free Apr 8 '12 at 15:08
The grid will be of arbitrary size, potentially each row could be different length also. 3x3 was just an example. – Peter Hamilton Apr 8 '12 at 16:05
indeed, ["A","B","%] is considered to be != ["B","A","%"] – Peter Hamilton Apr 8 '12 at 16:05

First you have to get all desired permutations for each line. Then you calculate the cross product of all lines.

The permutations of a line can be simple calculated by having the letters [A,B,%] and varying the starting index:

``````import itertools
# Example: line = ['A','B','%']
def line_permutations(line):
if '%' not in line:
return [line]
line.remove('%') # use copy.copy if you don't want to modify your matrix here
return (line[:i] + ['%'] + line[i:] for i in range(len(line) + 1))
``````

The cross product is easiest to achieve using itertools.product

``````matrix = [['A','B','%'], ['C', '%', 'D'], ['E', 'F', 'G']]
permutations = itertools.product(*[line_permutations(line) for line in matrix])
for p in permutations:
print(p)
``````

This solution is optimal in memory and CPU requirements, because permutations are never recomputed.

Example output:

``````(['%', 'A', 'B'], ['%', 'C', 'D'], ['E', 'F', 'G'])
(['%', 'A', 'B'], ['C', '%', 'D'], ['E', 'F', 'G'])
(['%', 'A', 'B'], ['C', 'D', '%'], ['E', 'F', 'G'])
(['A', '%', 'B'], ['%', 'C', 'D'], ['E', 'F', 'G'])
(['A', '%', 'B'], ['C', '%', 'D'], ['E', 'F', 'G'])
(['A', '%', 'B'], ['C', 'D', '%'], ['E', 'F', 'G'])
(['A', 'B', '%'], ['%', 'C', 'D'], ['E', 'F', 'G'])
(['A', 'B', '%'], ['C', '%', 'D'], ['E', 'F', 'G'])
(['A', 'B', '%'], ['C', 'D', '%'], ['E', 'F', 'G'])
``````
-
I may have not understood you correctly, but just changing the starting index will not grant all the permutations. Although it would grant the desired solution. – NeXuS Apr 8 '12 at 15:22
Can you use a return with argument(s) statement inside a generator? – Abhijit Apr 8 '12 at 15:28
@NeXuS: See the OP "The rows can be moved like beads on a string"; I'll adapt this to make it clearer. – j13r Apr 8 '12 at 15:30
@Abhijit it's not a generator until you reach yield. – j13r Apr 8 '12 at 15:30
@j13r: Are you sure? Check the result from running this in Python 3. – Abhijit Apr 8 '12 at 15:32

Define a function called cycle

``````>>> def cycle(lst):
while True:
lst=lst[1:]+lst[0:1] if '%' in lst else lst
yield lst
``````
• Given an iterator, this will generate and return a cyclic left shift.
• Now you have to pass each of the rows in the grid to the cycle generator for the total iteration matching the length of the row
• Now use itertools.product to find all combinations of the generated row cyclic combinations.
• In case there is no empty slot, no cycle permutation is generated

The final result is as follows

``````>>> for g in list(itertools.product(*[[x for (x,y) in zip(cycle(row),
range(0,len(row) if '%' in row else 1))] for row in grid])):
for r in g:
print r
print "="*10
``````

For your Grid, this will generate

``````['B', '%', 'A']
['%', 'D', 'C']
['E', 'F', 'G']
===============
['B', '%', 'A']
['D', 'C', '%']
['E', 'F', 'G']
===============
['B', '%', 'A']
['C', '%', 'D']
['E', 'F', 'G']
===============
['%', 'A', 'B']
['%', 'D', 'C']
['E', 'F', 'G']
===============
['%', 'A', 'B']
['D', 'C', '%']
['E', 'F', 'G']
===============
['%', 'A', 'B']
['C', '%', 'D']
['E', 'F', 'G']
===============
['A', 'B', '%']
['%', 'D', 'C']
['E', 'F', 'G']
===============
['A', 'B', '%']
['D', 'C', '%']
['E', 'F', 'G']
===============
['A', 'B', '%']
['C', '%', 'D']
['E', 'F', 'G']
===============
``````
-

A naive implementation:

``````g=[['A', 'B', '%'],
['C', '%', 'D'],
['E', 'F', 'G']]

from collections import deque
from itertools import product

def rotations(it):
d = deque(it,len(it))
for i in xrange(len(it)):
d.rotate(1)
yield list(d)

for i in product(*[rotations(x) if '%' in x else [x] for x in g]):
print i
``````

gives:

``````(['%', 'A', 'B'], ['D', 'C', '%'], ['E', 'F', 'G'])
(['%', 'A', 'B'], ['%', 'D', 'C'], ['E', 'F', 'G'])
(['%', 'A', 'B'], ['C', '%', 'D'], ['E', 'F', 'G'])
(['B', '%', 'A'], ['D', 'C', '%'], ['E', 'F', 'G'])
(['B', '%', 'A'], ['%', 'D', 'C'], ['E', 'F', 'G'])
(['B', '%', 'A'], ['C', '%', 'D'], ['E', 'F', 'G'])
(['A', 'B', '%'], ['D', 'C', '%'], ['E', 'F', 'G'])
(['A', 'B', '%'], ['%', 'D', 'C'], ['E', 'F', 'G'])
(['A', 'B', '%'], ['C', '%', 'D'], ['E', 'F', 'G'])
``````
-
Traceback (most recent call last): File "sandbox.py", line 2, in <module> ['C', '%', 'D'] TypeError: list indices must be integers, not tuple – luke14free Apr 8 '12 at 15:26
Forgot to place the commas inside `g` :p – mshsayem Apr 8 '12 at 15:27

Here it is. Note that on one side this approach is less clean, but it allows you to compute the permutations of # len(matrix[0])-1 only once and use them as templates for the output.

``````from itertools import permutations,product

def charPermutation(matrix):
permutation_list=list(permutations(["%%"]+["%s"]*(len(matrix[0])-1))) #Compute once, use infinitely
perms={i:[] for i in range(len(matrix))}
for it,line in enumerate(matrix):
chars=list(set(line)-set(["%"]))
if sorted(line)==sorted(chars):
perms[it]+=["".join([str(i) for i in line])]
else:
for p in permutation_list:
perms[it]+=["".join(["".join(p) % tuple(chars)])]
perms[it]=list(set(perms[it]))
return product(*[[list(k) for k in i] for i in perms.values()])

g=[
["A", "B", "%"],
["C", "%", "D"],
["E", "F", "G"]]

for x in charPermutation(g):
print [i for i in x]

[['A', '%', 'B'], ['C', 'D', '%'], ['E', 'F', 'G']]
[['A', '%', 'B'], ['%', 'C', 'D'], ['E', 'F', 'G']]
[['A', '%', 'B'], ['C', '%', 'D'], ['E', 'F', 'G']]
[['%', 'A', 'B'], ['C', 'D', '%'], ['E', 'F', 'G']]
[['%', 'A', 'B'], ['%', 'C', 'D'], ['E', 'F', 'G']]
[['%', 'A', 'B'], ['C', '%', 'D'], ['E', 'F', 'G']]
[['A', 'B', '%'], ['C', 'D', '%'], ['E', 'F', 'G']]
[['A', 'B', '%'], ['%', 'C', 'D'], ['E', 'F', 'G']]
[['A', 'B', '%'], ['C', '%', 'D'], ['E', 'F', 'G']]
``````
-
What if the grid is of bigger size say 100*100? I think OP just gave a 3X3 grid as an example – Abhijit Apr 8 '12 at 15:25
I usually post just to make people understand what the reasoning is. Then it's better if they can implement what they really need (and if they can understand it). Anyhow it's trivial. – luke14free Apr 8 '12 at 15:27
This output is accurate and what I need, but I'm not sure this can be scaled. I will edit the question to make it clear that a 3x3 was just an example. – Peter Hamilton Apr 8 '12 at 16:03
And in the end.. puff! It scaled. :P – luke14free Apr 8 '12 at 17:07
@PeterHamilton Can you perform a benchmark of this algo with a big matrix (> 15x15)? – luke14free Apr 8 '12 at 17:24