# What is the Big-O complexity for this “Telephone Words” Algorithm?

This isn't homework, just an interview question I found on the web that looks interesting.

So I took a look at this first: Telephone Words problem -- but it seems to be poorly worded/created some controversy. My question is pretty much the same, except my question is more about the time complexity behind it.

You want to list all the possible words when given a 10-digit phone number as your input. So here is what I have done:`

``````def main(telephone_string)
hsh = {1 => "1", 2 => ["a","b","c"], 3 => ["d","e","f"], 4 => ["g","h","i"],
5 => ["j","k","l"], 6 => ["m","n","o"], 7 => ["p","q","r","s"],
8 => ["t","u","v"], 9 => ["w","x","y","z"], 0 => "0" }
telephone_array = telephone_string.split("-")
three_number_string = telephone_array[1]
four_number_string = telephone_array[2]
string = ""
result_array = []
hsh[three_number_string[0].to_i].each do |letter|
hsh[three_number_string[1].to_i].each do |second_letter|
string = letter + second_letter
hsh[three_number_string[2].to_i].each do |third_letter|
new_string = string + third_letter
result_array << new_string
end
end
end

second_string = ""
second_result = []
hsh[four_number_string[0].to_i].each do |letter|
hsh[four_number_string[1].to_i].each do |second_letter|
second_string = letter + second_letter
hsh[four_number_string[2].to_i].each do |third_letter|
new_string = second_string + third_letter
hsh[four_number_string[3].to_i].each do |fourth_letter|
last_string = new_string + fourth_letter
second_result << last_string
end
end
end
end
puts result_array.inspect
puts second_result.inspect
end
``````

First off, this is what I hacked together in a few minutes time, no refactoring has been done. So I apologize for the messy code, I just started learning Ruby 6 weeks ago, so please bear with me!

So finally to my question: I was wondering what the time complexity of this method would be. My guess is that it would be O(n^4) because the second loop (for the four letter words) is nested four times. I'm not really positive though. So I would like to know whether that is correct, and if there is a better way to do this problem.

-
Your estimate is way off. Given a number of length n, the size of the output can be 4^n. –  n.m. Apr 18 '12 at 22:23
Oh I see, that makes more sense. Do you think there is a better way of doing this, or is it just a permutations problem? –  Alexander Lucic Apr 18 '12 at 22:30

This is actually a constant time algorithm, so O(1) (or to be more explicit, O(4^3 + 4^4))

The reason this is a constant time algorithm is that for each digit in the telephone number, you're iterating through a fixed number (at most 4) of possible letters, that's known beforehand (which is why you can put `hsh` statically into your method).

One possible optimization would be to stop searching when you know there are no words with the current prefix. For example, if the 3-digit number is "234", you can ignore all strings that start with "bd" (there are some bd- words, like "bdellid", but none that are 3-letters, at least in my /usr/share/dict/words).

-

From the original phrasing, I would assume that is requesting all of the possibilities, instead of the number of possibilities as output.

Unfortunately, if you need to return every combination, there is no way to lower the complexity below that determined by the specified keys.

If it were simply the number, it could be in constant time. However, to print them all out, the end result depends highly on assumptions:

1) Assuming that all of the words you are checking for are composed solely of letters, you only need to check against the eight keys from 2 to 9. If this is incorrect, just sub out 8 in the function below.

2) Assuming the layout of all keys is exactly as set up here (no octothorpes or asterisks), with the contents of the empty arrays taking up no space in the final word.

``````{
1 => [],
2 => ["a", "b", "c"],
3 => ["d", "e", "f"],
4 => ["g", "h", "i"],
5 => ["j", "k", "l"],
6 => ["m", "n", "o"],
7 => ["p", "q", "r", "s"],
8 => ["t", "u", "v"],
9 => ["w", "x", "y", "z"],
0 => []
}
``````

At each stage, you would simply check the number of possibilities for the next step, and append each possible choice to the end of a string. If you were to do, so, the minimum time would be (essentially) constant time (0, if the number consisted of all ones and zeros). However, the function would be O(4^n), where n reaches a maximum at 10. The largest possible number of combinations would be 4^10, if they hit 7 or nine each time.

As for your code, I would recommend a single loop, with a few basic nested loops. Here is the code, in Ruby, although I haven't run it, so there may be syntax errors.

``````def get_words(number_string)
hsh = {"2" => ["a", "b", "c"],
"3" => ["d", "e", "f"],
"4" => ["g", "h", "i"],
"5" => ["j", "k", "l"],
"6" => ["m", "n", "o"],
"7" => ["p", "q", "r", "s"],
"8" => ["t", "u", "v"],
"9" => ["w", "x", "y", "z"]}

possible_array =  hsh.keys
number_array = number_string.split("").reject{|x| possible_array.include?(x)}

if number_array.length > 0
array = hsh[number_array[0]]
end

unless number_array[1,-1].nil?
number_array.each do |digit|
new_array = Array.new()
array.each do |combo|
hsh[digit].each do |new|
new_array = new_array + [combo + new]
end
end
array = new_array
end
new_array
end
``````
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I think the OP was asking for `Big-O` notation (maybe more of a CS question), not code. –  PlasmaPower Mar 20 '14 at 23:26
Probably. I just included code to help illustrate the reasoning behind the answer. –  user3433919 Apr 8 '14 at 3:31