# Can this algorithm be improved without recursion

The question is to print all possible interleavings of two given strings. So I wrote a working code in Python which runs like this:

``````def inter(arr1,arr2,p1,p2,arr):
thisarr = copy(arr)
if p1 == len(arr1) and p2 == len(arr2):
printarr(thisarr)
elif p1 == len(arr1):
thisarr.extend(arr2[p2:])
printarr(thisarr)
elif p2 == len(arr2):
thisarr.extend(arr1[p1:])
printarr(thisarr)
else:
thisarr.append(arr1[p1])
inter(arr1,arr2,p1+1,p2,thisarr)
del thisarr[-1]
thisarr.append(arr2[p2])
inter(arr1,arr2,p1,p2+1,thisarr)
return
``````

It comes at each point in a string, then for one recursive call, it considers the current element as belonging to the first array, and in the next call, belonging to the other array. So if the input strings are `ab` and `cd`, it prints out `abcd`, `acbd`, `cdab`, `cabd`, etc. `p1` and `p2` are pointers to the arrays (Because Python strings are immutable, I am using arrays!). Can anybody tell me, what is this code's complexity, and if it can be improved or not? I have written a similar code to print all combinations of length `k` from a given array:

``````def kcomb(arr,i,thisarr,k):
thisarr = copy(thisarr)
j,n = len(thisarr),len(arr)
if n-i<k-j or j >k:
return
if j==k:
printarr(thisarr)
return
if i == n:
return
thisarr.append(arr[i])
kcomb(arr,i+1,thisarr,k)
del thisarr[-1]
kcomb(arr,i+1,thisarr,k)
return
``````

This too, works on the same principle. So in general, how to find the complexity of such functions, and how do I optimize them? Is it possible to do these by DP? Sample input-output for the first problem:

``````>>> arr1 = ['a','b','c']
>>> arr2 = ['d','e','f']
>>> inter(arr1,arr2,0,0,[])
abcdef
abdcef
abdecf
abdefc
dabcef
dabecf
dabefc
daebcf
daebfc
daefbc
deabcf
deabfc
deafbc
defabc
``````
-
can you please post the code for "printarr" –  Inbar Rose Oct 11 '12 at 9:30
Yeah I can, but that's trivial, it just takes the array as input, concatenates all the elements into a string and prints it out! –  Cupidvogel Oct 11 '12 at 9:31
It's hard to grasp what you're doing. Can you post the input and expected output. –  monkut Oct 11 '12 at 9:37
Sure. Give me a minute. –  Cupidvogel Oct 11 '12 at 9:39
Almost, but preserving the order of individual strings. That is, if string1 is `abcd`, and string2 is `efgh`, then in the interleaved string, `a' should come before `b`, which should come before `c`, which should come before `d`. In between these, characters from string2 should fit in, but on the same condition, preserving order of individual letters. –  Cupidvogel Oct 11 '12 at 9:49

Your problem can be reduced to that of creating all unique permutations of a particular list. Say `A` and `B` are the lengths of the strings `arr1` and `arr2`, respectively. Then construct a list like this:

``````[0] * A + [1] * B
``````

There exists a one-to-one correspondence (a bijection) from the unique permutations of this list to all the possible interleavings of the two strings `arr1` and `arr2`. The idea is to let each value of the permutation specify which string to take the next character from. Here is an example implementation showing how to construct an interleaving from a permutation:

``````>>> def make_interleave(arr1, arr2, permutation):
...     iters = [iter(arr1), iter(arr2)]
...     return "".join(iters[i].next() for i in permutation)
...
>>> make_interleave("ab", "cde", [1, 0, 0, 1, 1])
'cabde'
``````

I found this question in the python mailing list which asks how to solve this problem in an efficient manner. The answers suggest using an algorithm which is described in Knuth's The Art of Computer Programming, Volume 4, Fascicle 2: Generating All Permutations. I found an online pdf of the draft here. The algorithm is also described in this wikipedia article.

Here's my own annotated implementation of the `next_permutation` algorithm, as a python generator function.

``````def unique_permutations(seq):
"""
Yield only unique permutations of seq in an efficient way.

A python implementation of Knuth's "Algorithm L", also known from the
std::next_permutation function of C++, and as the permutation algorithm
of Narayana Pandita.
"""

# Precalculate the indices we'll be iterating over for speed
i_indices = range(len(seq) - 1, -1, -1)
k_indices = i_indices[1:]

# We use a good old-fashioned temporary variable for a little extra speed
tmp = 0

seq = sorted(seq)

while True:
yield seq

# Working backwards from the last-but-one index,             k
# we find the index of the first decrease in value.    0 0 1 0 1 1 1 0
for k in k_indices:
if seq[k] < seq[k + 1]:
break
else:
# Introducing the slightly unknown python for-else syntax:
# else is executed only if the break statement was never reached.
# If this is the case, seq is weakly decreasing, and we're done.
return

# Get item from sequence only once, for speed
k_val = seq[k]

# Working backwards starting with the last item,             k     i
# find the first one greater than the one at k         0 0 1 0 1 1 1 0
for i in i_indices:
if k_val < seq[i]:
break

# Swap them in the most efficient (but least readable) way
tmp = seq[k]
seq[k] = seq[i]                                      #       k     i
seq[i] = tmp                                         # 0 0 1 1 1 1 0 0

# Reverse the part after but not                             k
# including k, also efficiently.                       0 0 1 1 0 0 1 1
seq[k + 1:] = seq[-1:k:-1]
``````

Each yield of the algorithm has an amortized complexity of O(1), according to this question, but according to rici who commented below, this is only the case if all numbers are unique, which they are definately not in this case.

In any case, the number of yields provides a lower bound for the time complexity, and it is given by

```(A + B)! / (A! * B!)
```

Then to find the real time complexity we need to sum the average complexity of each yield with the complexity of constructing the resulting string based on the permutation. If we multiply this sum with the above formula we get the total time complexity.

-
Please explain the code! –  Cupidvogel Oct 11 '12 at 11:12
@cupidvogel As I said, the algorithm is explained in the same blog where the code is. –  Lauritz V. Thaulow Oct 11 '12 at 11:14
@lazyr: that code is only O(1) amortized for permutations of sequences of unique elements. If the sequence has a lot of repetitions of one value, it becomes (I think) O(n) (for each permutation). (It's exercise 6 in the Knuth fascicle.) –  rici Oct 11 '12 at 17:37
@cupidvogel I've replaced the code with my own annotated reimplementation. Hopefully it will aid you in understanding the algorithm and the code. –  Lauritz V. Thaulow Oct 15 '12 at 20:06

okay, after some work, and usign advice from other answers. mainly lazyr. (and have now converted it into a class) the __all_perms is from: http://stackoverflow.com/a/104436/1561176

``````class Interleave():

def __init__(self, A, B):
self.A = A
self.B = B
self.results = list(self.__interleave())

# from http://stackoverflow.com/a/104436/1561176
def __all_perms(self, elements):
if len(elements) <=1:
yield elements
else:
for perm in self.__all_perms(elements[1:]):
for i in range(len(elements)):
#nb elements[0:1] works in both string and list contexts
yield perm[:i] + elements[0:1] + perm[i:]

def __sequences(self):
return list( sorted( set(
["".join(x) for x in self.__all_perms(['a'] * len(self.A) + ['b'] * len(self.B))] ) ) )

def __interleave(self):
for sequence in self.__sequences():
result = ""
a = 0
b = 0
for item in sequence:
if item == 'a':
result+=self.A[a]
a+=1
else:
result+=self.B[b]
b+=1
yield result

def __str__(self):
return str(self.results)

def __repr__(self):
return repr(self.results)
``````

and here is the usage:

``````>>> A = ['a', 'b', 'c']
>>> B = ['d', 'e', 'f']
>>> Interleave(A, B)
``````

also, you can access the Class members like:

``````>>> inter = Interleave(A, B)
>>> inter.results
>>> inter.A
['a', 'b', 'c']
>>> inter.B
['d', 'e', 'f']
``````
-
Can you please explain the code, as well as its complexity? –  Cupidvogel Oct 11 '12 at 11:11
@Cupidvogel well, the `all_perms()` is from an answer: stackoverflow.com/a/104436/1561176 and so i wont start discussing it here as it is discussed there. `_sequences()` simply calls the `all_perms()` and then converts the resulting lists to strings, makes them uniques, and sorts them, before converting them to a list and sending them to the `interleave()` which reads the lists and simply adds values from `A` or `B` depending on the order it is given from the sequence. –  Inbar Rose Oct 11 '12 at 11:16
Note that this algorithm generates all permutations and then filters out the duplicates, unlike the algorithm in my answer. For two strings of length 10 for example, `__all_perms` yields 2432902008176640000 times, while `next_permutation` only yields the necessary 184756 times. –  Lauritz V. Thaulow Oct 11 '12 at 12:00
@lazyr yes, you are right. best to use a combination of both answers in this case. when i wrote this answer i didnt see the code you wrote, only the link you provided where someone had a similar problem and your idea of making unique combinations. i suppose i hadn't thought about the scaling. –  Inbar Rose Oct 11 '12 at 12:42

Does `permutations` work for you? Or, is this coding practice?

``````>>> from itertools import permutations
>>> s1 = "ab"
>>> s2 = "cd"
>>> all_values = [c for c in s1 + s2]
>>> ["".join(r) for r in permutations(all_values)]
``````
-
No no, I am trying to develop a working code without resorting to these in-built functions. Plus your output is not correct, in many of the output strings, `b` comes before `a`, whereas `a` should always come before `b`. That is interleaving, not permutation! –  Cupidvogel Oct 11 '12 at 9:50
I believe a subset of the permuted outputs is required here -- where the 2 input strings are interleaved in order. So, abdc is not a valid output –  Dhara Oct 11 '12 at 9:51
@Cupidvogel You're not interested at all in a solution using itertools? –  Lauritz V. Thaulow Oct 11 '12 at 9:52
@lazyr seems not. –  Inbar Rose Oct 11 '12 at 9:53
@Cupidvogel What do you have against "resorting" to built-in functions? –  Dhara Oct 11 '12 at 9:53

This is what I think you're trying to do:

``````from itertools import product, chain

def interleave(a, b):
if len(b) > len(a):
a, b = b, a

boolean = (True, False)
for z in range(len(a) - len(b) + 1):
pairs = list(zip(a[z:], b))
for vector in product(*[boolean] * max(map(len, (a, b)))):
permutation = (pair if i else reversed(pair)
for i, pair in zip(vector, pairs))
yield a[:z] + ''.join(chain.from_iterable(permutation))
``````
-
Can you have a look at my solution and tell me the complexity. I a looking for a non-recursive solution without using `itertools`. –  Cupidvogel Oct 11 '12 at 9:57
Well, you could easily modify this to not use itertools. `product` in this case just iterates over all the values between `0` and `2^len(a)` in binary, you could probably just do `range(2^len(a)):` and convert to binary. I just realized though, that this code leaves out certain interleaves. It can be modified to include them easily however. I may be able to revisit this in a few hours. –  Joel Cornett Oct 11 '12 at 10:04