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Supposing I'm having the constants 3,5,6,9,10. How can I detect how to write $n, which is the input, as a sum of these constants with the least number of terms?


$n=10, S=10
$n=18, S=9+9
$n=24, S=9+9+6
$n=27, S=9+9+9
$n=28, S=10+9+9


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What thoughts do you have on the solution so far? Where are you stuck? – Eric J. Dec 5 '09 at 0:38
Should this also be tagged homework? – Mercurybullet Dec 5 '09 at 0:41
I thought about dividing repeatedly from the greatest to the smallest, and if in the end I end up with the remainder 0, then it can be written as sum of the numbers on the stack. However, it is not a good way, take for example $n=17. It would say 17=10+6, remainder 1. The right solution should be S=6+6+5 – user223083 Dec 5 '09 at 0:43
No, it's not a homework. I just oversimplified my problem so good, that it seems to be one :) Actually, it's for an online payment system via SMS. – user223083 Dec 5 '09 at 0:44
What about input values that cannot be represented by the sum of these constants? 0, 1, 2, 4, 7, 11, ...? – Eric J. Dec 5 '09 at 0:49
up vote 8 down vote accepted

This is another Python solution, but hopefully it's easy for you to convert to PHP (I would do it myself, but I'm no PHP expert - I'm sure you could do a better job of it). I've tried not to use any advanced Python funcitons, so that it is easier for non-Python readers to understand, but if some Python syntax is not clear, please just ask.

allowed = [3, 5, 6, 9, 10]
n = 28

solutions = [ None ] * (n + 1)
solutions[0] = []

for i in range(n + 1):
    if solutions[i] is None: continue
    for a in allowed:
    	if i + a > n: continue
    	if solutions[i + a] is None or len(solutions[i]) + 1 < len(solutions[i + a]):
    		solutions[i + a] = solutions[i] + [a]

print solutions[28]

It works by starting from 0 and building up to the desired number, keeping a cache of the shortest solution seen so far for each possible total. It has a running time of O(n * a), where a is the number of different allowed values.

By the way, your answer to n=28 is wrong. It should be [9, 9, 10].

Update: here's my attempt at a PHP solution:

$allowed = array(3, 5, 6, 9, 10);
$n = 28;

$solutions = array();
$solutions[0] = array();

foreach (range(0, $n) as $i) {
    if (is_null($solutions[$i])) continue;
    foreach ($allowed as $a) {
    	if ($i + $a > $n) continue;
    	if (is_null($solutions[$i + $a]) ||
    		sizeof($solutions[$i]) + 1 < sizeof($solutions[$i + $a])) {
    		$solutions[$i + $a] = array_merge($solutions[$i], array($a));


It gives the right answer, but please be aware that I'm not a professional PHP coder - I just looked up the equivalent functions in the PHP documentation.

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Great, I'll try to digest it and eventually accept your solution. – user223083 Dec 5 '09 at 1:23
Skeetch: I've had a go at converting it to PHP. See my updated answer. – Mark Byers Dec 5 '09 at 1:38
This is a nice, short-and-simple algorithm. I have reposted a cleaned-up PHP implementation, more in line with PHP's idioms. – Josh Davis Dec 5 '09 at 9:34

This is Mark Byers' algorithm, rewritten using loop structures that are more familiar to PHP developers, and constructs that won't generate PHP notices. $C is your set of integers, $S the solutions.

$n = 28;
$C = array(3, 5, 6, 9, 10);
$S = array(array());

// if your set isn't sorted already, you have to call sort()

for ($i = 0; $i <= $n; ++$i)
    if (!isset($S[$i]))

    foreach ($C as $v)
        if ($i + $v > $n)

        if (!isset($S[$i + $v])
         || count($S[$i + $v]) > 1 + count($S[$i]))
            $S[$i + $v]   = $S[$i];
            $S[$i + $v][] = $v;

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Sure. By the way, I didn't mention it initially, but if you sort your set of integers in ascending order you can exit the inner loop early, instead of iterating over every possible combination. I have updated the code snippet above accordingly. – Josh Davis Dec 5 '09 at 13:45
Yeah, I realized that. – Flavius Dec 5 '09 at 18:25

Two obvious approaches suggest themselves:

  1. Write a series of linear equations, and solve to find various solutions. Choose one with the least number of terms.
  2. Trial and error, starting with the largest terms first.
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Find all possible solutions for "S=3A+5B+6C+9D+10E" then choose the one with the most 0 values for A,B,C,D,E

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Actually you want the a solution that minimizes A+B+C+D+E. That's not necessarily on the has the most zero values ... is it? – Stephen C Dec 5 '09 at 2:10
Yes. The right keywords for the original problem are "solving linear Diophantine equations". This is a substantial research area and algorithms are not trivial. For example: – Matt Kennel Dec 5 '09 at 3:46
@Stephen I think you misread the question, he wants the least terms possible, hence the most zeros is what he's after – Paul Creasey Dec 5 '09 at 9:22

a rough sketch of an unscalable but correct solution (sorry, so far its only python ..):

#!/usr/bin/env python
import itertools, sys

pool = [3, 5, 6, 9, 10]

repeat, found, solutions = 1, False, set()

try: x = int(sys.argv[1])
except: x = 42

while not found:    
    for n in itertools.product(pool, repeat=repeat):
        s = sum(n)
        if s == x:
            found = True
    repeat = repeat + 1

print solutions

would yield:

$ python 11
set([(5, 6)])

$ python 19
set([(9, 10)])

$ python 21
set([(3, 9, 9)])

$ python 42
set([(3, 9, 10, 10, 10)])
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The post is tagged PHP just so you know :) – Doug Neiner Dec 5 '09 at 0:54
it's too late in my TZ .. should be reading a book || sleeping i guess .. ;) – miku Dec 5 '09 at 0:57

In addition to the excellent general answers already provided, bear in mind that if your set of values has certain properties, much more optimal solutions exist.

Specifically, if your solution is 'minimal' - that is, a single best solution exists for any value - then you can find the smallest number of elements using a 'greedy' algorithm: Simply add the largest value until the remainder is smaller than it, repeat with the next largest value, and so forth.

As an example, the denominations used for money in many countries are .01, .02, .05, .10, .20, .50, 1, 2, 5, .... This set is minimal, so you can just repeatedly add the largest valid denomination.

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NP-complete problem

Subset sum problem

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