I am trying to generate all possible keypad sequences (7 digit length only right now). For example if the mobile keypad looks like this:

``````1 2 3
4 5 6
7 8 9
0
``````

Some of the possible sequences can be:

123698
147896
125698
789632

The requirement is that the each digit of number should be neighbor of previous digit.

Here is how I am planning to start this:

The information about the neighbor changes from keypad to keypad so we have to hardcode it like this:

``````neighbors = {0: 8, 1: [2,4], 2: [1,3,5], 3: [2,6], 4: [1,5,7], 5: [2,4,6,8], 6: [3,5,9], 7: [4,8], 8: [7,5,9,0], 9: [6,8]}
``````

I will be traversing through all digits and will append one of the possible neighbors to it until required length is achieved.

EDIT: Updated neighbors, no diagonals allowed EDIT 2: Digits can be reused

-
So, what's your question? You seem to understand the problem and you've made a start on the solution. What do you need help with? As a possible hint, note that all the 7-digit sequences can be found by caculating all the 6-digit sequences then adding all possible next moves to each of those. All the 6 digit sequences can be foudn by calculating all the 5-digit sequences... –  Paul Nov 22 '10 at 21:25
You are being very inconsistent with your neighbors. You show that 0 only has 1 neighbor, while 1 has 3. Do you count diagonals or not? If so, 2 should have 5 neighbors, if not, 1 should only have 2 neighbors, etc. –  Jeff B Nov 22 '10 at 21:26
Similar to stackoverflow.com/questions/2893470/…, except neighbors are defined differently. –  Steven Rumbalski Nov 22 '10 at 21:29
Thanks for the correction Jeff B, not counting diagonals. Changed! –  Irfan Nov 22 '10 at 22:14
Can numbers be used more than once in a given sequence, or is this like Boggle where each can only be used once? –  Justin Peel Nov 22 '10 at 22:29

Try this.

`````` neighbors = {0: [8],
1: [2,4],
2: [1,4,3],
3: [2,6],
4: [1,5,7],
5: [2,4,6,8],
6: [3,5,9],
7: [4,8],
8: [7,5,9,0],
9: [6,8]}

def get_sequences(n):
if not n:
return
stack = [(i,) for i in  range(10)]
while stack:
cur = stack.pop()
if len(cur) == n:
yield cur
else:
stack.extend(cur + (d, ) for d in neighbors[cur[-1]])

print list(get_sequences(3))
``````

This will produce all possible sequences. You didn't mention if you wanted ones that have cycles in them, for example `(0, 8, 9, 8)` so I left them in. If you don't want them, then just use

`````` stack.extend(cur + (d, )
for d in neighbors[cur[-1]]
if d not in cur)
``````

Note that I made the entry for `0` a list with one element instead of just an integer. This is for consistency. It's very nice be able to index into the dictionary and know that you're going to get a list back.

Also note that this isn't recursive. Recursive functions are great in languages that properly support them. In Python, you should almost always manage a stack like I demonstrate here. It's just as easy as a recursive solution and sidesteps function call overhead (python doesn't support tail recursion) and maximum recursion depth concerns.

-
thanks this works perfectly fine –  Irfan Nov 22 '10 at 23:02

Recursion isn't really much of an issue here because the sequence is relatively short as are the choices for each digit except the first -- so there appear to "only" be 4790 possibilities disallowing diagonals. This is written as an iterator to eliminate the need to create and return a large container with all possibilities produced in it.

It occurred to me that an additional benefit of the data-driven approach of storing the neighbor adjacency information in a data structure (as the OP suggested) was that besides easily supporting different keypads, it also makes controlling whether diagonals are allowed or not trivial.

I debated briefly about whether to make it a list instead of a dictionary for faster lookups, but realized that doing so would make it more difficult to adapt to produce sequences other than digits (and likely wouldn't make it significantly faster anyway).

``````adjacent = {1: [2,4],   2: [1,3,4],   3: [2,6],
4: [1,5,7], 5: [2,4,6,8], 6: [3,5,9],
7: [4,8],   8: [0,5,7,9], 9: [6,8],
0: [8]}

seq = [None]*ndigits  # pre-allocate

def next_level(i):
seq[i] = neighbor
if i == ndigits-1:  # last digit?
yield seq
else:
for digits in next_level(i+1):
yield digits

for first_digit in range(10):
seq[0] = first_digit
for digits in next_level(1):
yield digits

cnt = 1
print '{:d}: {!r}'.format(cnt, ''.join(map(str,digits)))
cnt += 1
``````
-
This is probably a better solution to the problem than mine. –  aaronasterling Nov 23 '10 at 6:45
``````states = [
[8],
[2, 4],
[1, 3, 5],
[2, 6],
[1, 5, 7],
[2, 4, 6, 8],
[3, 5, 9],
[4, 8],
[5, 7, 9, 0],
[6, 8]
]

def traverse(distance_left, last_state):
if not distance_left:
yield []
else:
distance_left -= 1
for s in states[last_state]:
for n in traverse(distance_left, s):
yield [s] + n

def produce_all_series():
return [t for i in range(10) for t in traverse(7, i)]

from pprint import pprint
pprint(produce_all_series())
``````
-
``````neighbors = {0: [8], 1: [2,5,4], 2: [1,4,3], 3: [2,5,6], 4: [1,5,7], 5: [2,4,6,8], 6: [3,5,9], 7: [4,5,8], 8: [7,5,9,0], 9: [6,5,8]}

def keyNeighborsRec(x, length):
if length == 0:
print x
return
for i in neighbors[x%10]:
keyNeighborsRec(x*10+i,length-1)

def keyNeighbors(l):
for i in range(10):
keyNeighborsRec(i,length-1)

keyNeighbors(7)
``````

its really easy without the neighbor condition...

``````def keypadSequences(length):
return map(lambda x: '0'*(length-len(repr(x)))+repr(x), range(10**length))

``````
-
doh! just noticed the neighbors thing... nevermind –  jon_darkstar Nov 22 '10 at 21:42
That's just printing all the possible number sequences. There's some rules in the problem about what the next number in the sequence can be. –  JOTN Nov 22 '10 at 21:45
yes, read my above comment. i noticed the neighbors thing afterwords. this would be the answer without neighbor conditions –  jon_darkstar Nov 22 '10 at 21:46
``````neighbors = {0: [8], 1: [2,5,4], 2: [1,4,3], 3: [2,5,6], 4: [1,5,7], 5: [2,4,6,8], 6: [3,5,9], 7: [4,5,8], 8: [7,5,9,0], 9: [6,5,8]}

def gen_neighbor_permutations(n, current_prefix, available_digit_set, removed_digits=set(), unique_digits=False):
if n == 0:
print current_prefix
return
for d in available_digit_set:
if unique_digits:
gen_neighbor_permutations(n-1, current_prefix + str(d), set(neighbors[d]).difference(removed_digits), removed_digits.union(set([d])), unique_digits=True )
else:
gen_neighbor_permutations(n-1, current_prefix + str(d), set(neighbors[d]).difference(removed_digits) )

gen_neighbor_permutations(n=3, current_prefix='', available_digit_set=start_set)
``````

I also couldn't help but notice that in your examples, none of the digits are reused. If you want that, then you would use the `unique_digits = True` option; this will disallow recursion on digits that are already used.

+1 What a fun puzzle. I hope this works for you!

``````gen_neighbor_permutations(n=3, current_prefix='', available_digit_set=start_set, unique_digits = True)
``````
-

That's a classic recursive algorithm. Some pseudo code to show the concept:

``````function(numbers) {
if (length(numbers)==7) {
print numbers;
return;
}
if (numbers[last]=='1') {
function(concat(numbers,  '2'));
function(concat(numbers,  '4'));
return;
}
if (numbers[last]==='2') {
function(concat(numbers,  '1'));
function(concat(numbers,  '3'));
function(concat(numbers,  '5'));
return;
}
...keep going with a condition for each digit..
}
``````
-
Is this how people actually program in non dynamic languages? Why not just use a hash table into lists of neighboring digits like OP suggested? You don't even need first class functions for that. –  aaronasterling Nov 22 '10 at 21:56
@aaron, some people just program like that. It doesn't matter if the language is dynamic or not. eg, your own answer here doesn't use any dynamic features. –  John La Rooy Nov 22 '10 at 22:43
This solution is really tightly coupled to the keypad layout, especially since the OP mentioned that "The information about the neighbor changes from keypad to keypad" Not going to -1 since it's not strictly wrong, but it's not very reusable for other key layouts. –  Davy8 Nov 22 '10 at 22:47
It's psuedo code. The purpose is to show the algorithm in an easily readable format and not how you actually implement it. –  JOTN Nov 22 '10 at 22:58