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# Algorithm Issue: letter combinations

I'm trying to write a piece of code that will do the following:

Take the numbers 0 to 9 and assign one or more letters to this number. For example:

``````0 = N,
1 = L,
2 = T,
3 = D,
4 = R,
5 = V or F,
6 = B or P,
7 = Z,
8 = H or CH or J,
9 = G
``````

When I have a code like 0123, it's an easy job to encode it. It will obviously make up the code NLTD. When a number like 5,6 or 8 is introduced, things get different. A number like 051 would result in more than one possibility:

NVL and NFL

It should be obvious that this gets even "worse" with longer numbers that include several digits like 5,6 or 8.

Being pretty bad at mathematics, I have not yet been able to come up with a decent solution that will allow me to feed the program a bunch of numbers and have it spit out all the possible letter combinations. So I'd love some help with it, 'cause I can't seem to figure it out. Dug up some information about permutations and combinations, but no luck.

Thanks for any suggestions/clues. The language I need to write the code in is PHP, but any general hints would be highly appreciated.

### Update:

Some more background: (and thanks a lot for the quick responses!)

The idea behind my question is to build a script that will help people to easily convert numbers they want to remember to words that are far more easily remembered. This is sometimes referred to as "pseudo-numerology".

I want the script to give me all the possible combinations that are then held against a database of stripped words. These stripped words just come from a dictionary and have all the letters I mentioned in my question stripped out of them. That way, the number to be encoded can usually easily be related to a one or more database records. And when that happens, you end up with a list of words that you can use to remember the number you wanted to remember.

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This actually sounds like a nice interview question. Could ask for both iterative and recursive solutions and see what the person comes up with. I'll have to remember this. :) – Herms Sep 19 '08 at 15:12
That's no fair, my mind always worked a heck of alot better and faster when it was running around in circles. Especially, oh god, it's not 1:30 again is it? Yup, time for me to be going... – Matthew Scharley Sep 19 '08 at 15:30
Why does it seem that everyone automatically jump to recursion for the solution to this? Am I the only one that thinks that recursion is overkill for this problem? – jdmichal Sep 19 '08 at 17:25
Why is recursion overkill? Use the best tool for job, if you can make a five line recursive function that does the job, what's the problem? I went with it because my mind just works better when looking at problems via recursion than via interation. – Matthew Scharley Sep 19 '08 at 23:41
To me, all those stack frames for something that can be handled by 3 loops seems excessive. But you're right; whatever makes the most sense to the programmer. I tend to avoid recursion unless I would need a stack for traceback anyway. Iterative methods seem less error prone and easier to grok. – jdmichal Sep 22 '08 at 20:52

The general structure you want to hold your number -> letter assignments is an array or arrays, similar to:

``````// 0 = N, 1 = L, 2 = T, 3 = D, 4 = R, 5 = V or F, 6 = B or P, 7 = Z,
// 8 = H or CH or J, 9 = G
\$numberMap = new Array (
0 => new Array("N"),
1 => new Array("L"),
2 => new Array("T"),
3 => new Array("D"),
4 => new Array("R"),
5 => new Array("V", "F"),
6 => new Array("B", "P"),
7 => new Array("Z"),
8 => new Array("H", "CH", "J"),
9 => new Array("G"),
);
``````

Then, a bit of recursive logic gives us a function similar to:

``````function GetEncoding(\$number) {
\$ret = new Array();
for (\$i = 0; \$i < strlen(\$number); \$i++) {
// We're just translating here, nothing special.
// \$var + 0 is a cheap way of forcing a variable to be numeric
\$ret[] = \$numberMap[\$number[\$i]+0];
}
}

function PrintEncoding(\$enc, \$string = "") {
// If we're at the end of the line, then print!
if (count(\$enc) === 0) {
print \$string."\n";
return;
}

// Otherwise, soldier on through the possible values.
// Grab the next 'letter' and cycle through the possibilities for it.
foreach (\$enc[0] as \$letter) {
// And call this function again with it!
PrintEncoding(array_slice(\$enc, 1), \$string.\$letter);
}
}
``````

Three cheers for recursion! This would be used via:

``````PrintEncoding(GetEncoding("052384"));
``````

And if you really want it as an array, play with output buffering and explode using "\n" as your split string.

-

It can be done easily recursively.

The idea is that to handle the whole code of size n, you must handle first the n - 1 digits. Once you have all answers for n-1 digits, the answers for the whole are deduced by appending to them the correct(s) char(s) for the last one.

-

There's actually a much better solution than enumerating all the possible translations of a number and looking them up: Simply do the reverse computation on every word in your dictionary, and store the string of digits in another field. So if your mapping is:

``````0 = N,
1 = L,
2 = T,
3 = D,
4 = R,
5 = V or F,
6 = B or P,
7 = Z,
8 = H or CH or J,
9 = G
``````

``````N = 0,
L = 1,
T = 2,
D = 3,
R = 4,
V = 5,
F = 5,
B = 6,
P = 6,
Z = 7,
H = 8,
J = 8,
G = 9
``````

Note there's no mapping for 'ch', because the 'c' will be dropped, and the 'h' will be converted to 8 anyway.

Then, all you have to do is iterate through each letter in the dictionary word, output the appropriate digit if there's a match, and do nothing if there isn't.

Store all the generated digit strings as another field in the database. When you want to look something up, just perform a simple query for the number entered, instead of having to do tens (or hundreds, or thousands) of lookups of potential words.

-

This kind of problem are usually resolved with recursion. In ruby, one (quick and dirty) solution would be

``````@values = Hash.new([])

@values["0"] = ["N"]
@values["1"] = ["L"]
@values["2"] = ["T"]
@values["3"] = ["D"]
@values["4"] = ["R"]
@values["5"] = ["V","F"]
@values["6"] = ["B","P"]
@values["7"] = ["Z"]
@values["8"] = ["H","CH","J"]
@values["9"] = ["G"]

def find_valid_combinations(buffer,number)
first_char = number.shift
@values[first_char].each do |key|
if(number.length == 0) then
puts buffer + key
else
find_valid_combinations(buffer + key,number.dup)
end
end
end

find_valid_combinations("",ARGV[0].split(""))
``````

And if you run this from the command line you will get:

``````\$ ruby r.rb 051
NVL
NFL
``````

This is related to brute-force search and backtracking

-

Here is a recursive solution in Python.

``````#!/usr/bin/env/python

import sys

ENCODING = {'0':['N'],
'1':['L'],
'2':['T'],
'3':['D'],
'4':['R'],
'5':['V', 'F'],
'6':['B', 'P'],
'7':['Z'],
'8':['H', 'CH', 'J'],
'9':['G']
}

def decode(str):
if len(str) == 0:
return ''
elif len(str) == 1:
return ENCODING[str]
else:
result = []
for prefix in ENCODING[str[0]]:
result.extend([prefix + suffix for suffix in decode(str[1:])])
return result

if __name__ == '__main__':
print decode(sys.argv[1])
``````

Example output:

``````\$ ./demo 1
['L']
\$ ./demo 051
['NVL', 'NFL']
\$ ./demo 0518
['NVLH', 'NVLCH', 'NVLJ', 'NFLH', 'NFLCH', 'NFLJ']
``````
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Could you do the following: Create a results array. Create an item in the array with value ""

Loop through the numbers, say 051 analyzing each one individually.

Each time a 1 to 1 match between a number is found add the correct value to all items in the results array. So "" becomes N.

Each time a 1 to many match is found, add new rows to the results array with one option, and update the existing results with the other option. So N becomes NV and a new item is created NF

Then the last number is a 1 to 1 match so the items in the results array become NVL and NFL

To produce the results loop through the results array, printing them, or whatever.

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Let `pn` be a list of all possible letter combinations of a given number string `s` up to the `nth` digit.

Then, the following algorithm will generate `pn+1`:

``````digit = s[n+1];
foreach(letter l that digit maps to)
{
foreach(entry e in p(n))
{
newEntry = append l to e;
}
}
``````

The first iteration is somewhat of a special case, since p-1 is undefined. You can simply initialize p0 as the list of all possible characters for the first character.

Iteration 0:

``````p(0) = {N}
``````

Iteration 1:

``````digit = 5
foreach({V, F})
{
foreach(p(0) = {N})
{
newEntry = N + V  or  N + F
p(1) = {NV, NF}
}
}
``````

Iteration 2:

``````digit = 1
foreach({L})
{
foreach(p(1) = {NV, NF})
{
newEntry = NV + L  or  NF + L
p(2) = {NVL, NFL}
}
}
``````
-
Out of curiousity, does anyone know what language this is? Or is it just some form of pseudocode? I don't recognise the foreach syntax, especially in the iterations. – Matthew Scharley Sep 19 '08 at 15:27
Just some form of psuedocode with C syntax :) – jdmichal Sep 19 '08 at 17:09

The form you want is probably something like:

``````function combinations( \$str ){
\$l = len( \$str );
\$results = array( );
if (\$l == 0) { return \$results; }
if (\$l == 1)
{
foreach( \$codes[ \$str[0] ] as \$code )
{
\$results[] = \$code;
}
return \$results;
}
\$cur = \$str[0];
\$combs = combinations( substr( \$str, 1, \$l ) );
foreach (\$codes[ \$cur ] as \$code)
{
foreach (\$combs as \$comb)
{
\$results[] = \$code.\$comb;
}
}
return \$results;}
``````

This is ugly, pidgin-php so please verify it first. The basic idea is to generate every combination of the string from [1..n] and then prepend to the front of all those combinations each possible code for str[0]. Bear in mind that in the worst case this will have performance exponential in the length of your string, because that much ambiguity is actually present in your coding scheme.

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And there was evening and morning and there were iterative and recursive solutions, and all was well with the world. – Matthew Scharley Sep 19 '08 at 15:23

The trick is not only to generate all possible letter combinations that match a given number, but to select the letter sequence that is most easy to remember. A suggestion would be to run the soundex algorithm on each of the sequence and try to match against an English language dictionary such as Wordnet to find the most 'real-word-sounding' sequences.

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