Say we have a function that translates the morse symbols:

`.`

->`-.`

`-`

->`...-`

If we apply this function twice, we get e.g:

`.`

-> `-.`

-> `...--.`

Given an input string and a number of repetitions, want to know the length of the final string. (Problem 1 from the Flemish Programming Contest VPW, taken from these slides which provide a solution in Haskell).

For the given inputfile

```
4
. 4
.- 2
-- 2
--... 50
```

We expect the solution

```
44
16
20
34028664377246354505728
```

Since I don't know Haskell, this is my recursive solution in Python that I came up with:

```
def encode(msg, repetition, morse={'.': '-.', '-': '...-'}):
if isinstance(repetition, str):
repetition = eval(repetition)
while repetition > 0:
newmsg = ''.join(morse[c] for c in msg)
return encode(newmsg, repetition-1)
return len(msg)
def problem1(fn):
with open(fn) as f:
f.next()
for line in f:
print encode(*line.split())
```

which works for the first three inputs but dies with a memory error for the last input.

How would you rewrite this in a more efficient way?

**Edit**

Rewrite based on the comments given:

```
def encode(p, s, repetition):
while repetition > 0:
p,s = p + 3*s, p + s
return encode(p, s, repetition-1)
return p + s
def problem1(fn):
with open(fn) as f:
f.next()
for line in f:
msg, repetition = line.split()
print encode(msg.count('.'), msg.count('-'), int(repetition))
```

Comments on style and further improvements still welcome

34 trillion gigabytes. Even without any recursive overhead this would break. – David Robinson May 9 '12 at 17:43`p, s = p + 3*s, p + s`

as the product of the 2x2 matrix`A = [[1, 3], [1, 1]]`

by the column vector`[p, s]`

. Now, instead of multiplying the matrix by the vector`n`

times (O(n)matrix-vector multiplications), you can compute the matrix`A^n`

efficiently using exponentiation by squaring (O(log n)matrix-matrix multiplications), and then multiply that by`[p, s]`

to get the counts after`n`

steps. – hammar May 9 '12 at 19:07